1
2
3
6 """
7 Creates a new axis.
8
9
10 @param orientation: axis orientation I{(int)}
11 @return: New axis as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
12 """
13 return None
14
16 """
17 Sets logarithmic mode.
18
19 @param is_logarithmic: logarithmic mode I{(bool)}
20 """
21 pass
22
24 """
25 Sets the visibility of an axis.
26
27 @param is_visible: visibility I{(bool)}
28 """
29 pass
30
32 """
33 Determines whether axis is set to be visible.
34
35 Return: B{C{True}} if B{C{axis}} is set to be visible.
36
37 @return: I{(bool)}
38 """
39 return None
40
42 """
43 Determines whether axis is set to be locarithmic.
44
45
46 @return: B{C{True}} if B{C{axis}} is logarithmic. I{(bool)}
47 """
48 return None
49
51 """
52 Gets the orientation of an axis.
53
54
55 @return: The orientation. I{(GtkPositionType)}
56 """
57 return None
58
60 """
61 Enables or disables automatic axis adjustmet.
62
63 @param is_auto: B{C{True}} to enable automatic tick size and distribution adjustment,
64 B{C{False}} to disable it. I{(bool)}
65 """
66 pass
67
69 """
70 Sets the requisition of axis boundaries.
71
72 The axis will adjust the boundaries to satisfy requisition but still have
73 reasonable tick values and spacing. Use L{Axis.get_range}() to obtain the
74 boundaries the axis actually decided to use.
75
76 @param min: Minimum requisition (min boundary value). I{(float)}
77 @param max: Maximum requisition (max boundary value). I{(float)}
78 """
79 pass
80
82 """
83 Gets the actual boundaries of an axis.
84
85 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
86 """
87 return None, None
88
90 """
91 Gets the requested boundaries of an axis.
92
93 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
94 """
95 return None, None
96
98 """
99 Gets the magnification value of a graph axis.
100
101
102 @return: Magnification value of the axis. I{(float)}
103 """
104 return None
105
107 """
108 Gets the magnification string of an axis.
109
110
111 @return: Magnification string of the axis, owned by the axis. I{(string)}
112 """
113 return None
114
116 """
117 Sets the label text of an axis.
118
119 @param label: The new label text (it can be B{C{None}} for an empty label). I{(string)}
120 """
121 pass
122
124 """
125 Gets the label of an axis.
126
127
128 @return: Axis label as a string owned by B{C{axis}}. I{(string)}
129 """
130 return None
131
133 """
134 Sets the axis unit. This will be added automatically
135 to the label. B{C{unit}} is duplicated.
136
137 @param unit: axis unit I{(L{SIUnit})}
138 """
139 pass
140
142 """
143 Enables/disables user to change axis label by clicking on axis widget.
144
145 @param enable: enable/disable user to change axis label I{(bool)}
146 """
147 pass
148
150 """
151 Draws the x and y-axis on a drawable
152
153 @param drawable: Drawable to draw on. I{(L{gdk.Drawable})}
154 @param gc: Graphics context.
155 It is modified by this function unpredictably. I{(L{gdk.GC})}
156 @param xmin: The minimum x-axis value. I{(int)}
157 @param ymin: The minimum y-axis value. I{(int)}
158 @param width: The width of the x-axis. I{(int)}
159 @param height: The height of the y-axis. I{(int)}
160 """
161 pass
162
164 """
165 Renders a graph axis in PostScript.
166
167 This is a helper functions for L{Graph.export_postscript}() and probably
168 not useful anywhere else.
169
170
171 @param xmin: Left edge of the bounding rectangle. I{(int)}
172 @param ymin: Bottom edge of the bounding rectangle. I{(int)}
173 @param width: Width of the bounding rectangle. I{(int)}
174 @param height: Height of the bounding rectangle. I{(int)}
175 @param fontsize: Font size to use. I{(int)}
176 @return: A newly created B{C{GString}}. I{(string)}
177 """
178 return None
179
181 """
182 Gets the positions of major ticks of an axis.
183
184
185 @return: The positions of axis major ticks (as real values, not pixels).
186 The returned array is owned by the axis. I{(list)}
187 """
188 return None
192 """
193 Three-dimensional data representation
194
195
196 B{C{Brick}} represents 3D data arrays in Gwyddion. It is typically useful for
197 different volume data obtained from SPMs, like in force volume measurements.
198
199 """
200 - def __init__(xres, yres, zres, xreal, yreal, zreal, nullme):
201 """
202 Creates a new data brick.
203
204 @since: 2.31
205
206 @param xres: X resolution, i.e., the number of samples in x direction I{(int)}
207 @param yres: Y resolution, i.e., the number of samples in y direction I{(int)}
208 @param zres: Z resolution, i.e., the number of samples in z direction I{(int)}
209 @param xreal: Real physical dimension in x direction. I{(float)}
210 @param yreal: Real physical dimension in y direction. I{(float)}
211 @param zreal: Real physical dimension in z direction. I{(float)}
212 @param nullme: Whether the data brick should be initialized to zeroes. If B{C{False}},
213 the data will not be initialized. I{(bool)}
214 @return: A newly created data brick. I{(L{Brick})}
215 """
216 return None
217
219 """
220 Checks whether two data bricks are compatible.
221
222 Real dimensions are checked without regard to calibration. Calibrations are considered compatible if either both
223 exist and are identical or none exists.
224
225 @since: 2.51
226
227 @param brick2: Another data brick. I{(L{Brick})}
228 @param check: The compatibility tests to perform. Expected values: C{B{DATA_COMPATIBILITY_RES}}, C{B{DATA_COMPATIBILITY_REAL}}, C{B{DATA_COMPATIBILITY_MEASURE}}, C{B{DATA_COMPATIBILITY_LATERAL}}, C{B{DATA_COMPATIBILITY_VALUE}}, C{B{DATA_COMPATIBILITY_AXISCAL}}, C{B{DATA_COMPATIBILITY_NCURVES}}, C{B{DATA_COMPATIBILITY_CURVELEN}}, C{B{DATA_COMPATIBILITY_ALL}}. I{(L{DataCompatibilityFlags})}
229 @return: Zero if all tested properties are compatible. Flags corresponding to failed tests if bricks are not
230 compatible. I{(DataCompatibilityFlags)}
231 """
232 return None
233
235 """
236 Creates a new data brick similar to an existing one.
237
238 Use L{Brick.duplicate}() if you want to copy a data brick including
239 data.
240
241 @since: 2.31
242
243 @param nullme: Whether the data brick should be initialized to zeroes. If B{C{False}},
244 the data will not be initialized. I{(bool)}
245 @return: A newly created data brick. I{(L{Brick})}
246 """
247 return None
248
249 - def new_part(xpos, ypos, zpos, xres, yres, zres, keep_offsets):
250 """
251 Creates a new data brick as a part of existing one.
252
253 Use L{Brick.duplicate}() if you want to copy a whole data brick.
254
255 @since: 2.32
256
257 @param xpos: x position where to start from I{(int)}
258 @param ypos: y position where to start from I{(int)}
259 @param zpos: z position where to start from I{(int)}
260 @param xres: x resolution (width) to be extracted I{(int)}
261 @param yres: y resolution (height) to be extracted I{(int)}
262 @param zres: z resolution (depth) to be extracted I{(int)}
263 @param keep_offsets: keep offsets of data during extraction I{(bool)}
264 @return: A newly created data brick. I{(L{Brick})}
265 """
266 return None
267
269 """
270 Emits signal "data_changed" on a data brick.
271
272 @since: 2.31
273
274 """
275 pass
276
277 - def copy(dest, nondata_too):
278 """
279 Copies the contents of an already allocated brick to a brick
280 of the same size.
281
282 @param dest: Destination brick. I{(L{Brick})}
283 @param nondata_too: Whether non-data (units) should be copied too. I{(bool)}
284 """
285 pass
286
287 - def resample(xres, yres, zres, interpolation):
288 """
289 Resamples a data brick.
290
291 In other words changes the size of three dimensional field related with data
292 brick. The original values are used for resampling using a requested
293 interpolation alorithm.
294
295 @since: 2.31
296
297 @param xres: Desired x resolution. I{(int)}
298 @param yres: Desired y resolution. I{(int)}
299 @param zres: Desired z resolution. I{(int)}
300 @param interpolation: Interpolation method to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
301 """
302 pass
303
305 """
306 Gets the x resolution of a data brick.
307
308 @since: 2.31
309
310 @return: Resolution (number of data points). I{(int)}
311 """
312 return None
313
315 """
316 Gets the y resolution of a data brick.
317
318 @since: 2.31
319
320 @return: Resolution (number of data points). I{(int)}
321 """
322 return None
323
325 """
326 Gets the z resolution of a data brick.
327
328 @since: 2.31
329
330 @return: Resolution (number of data points). I{(int)}
331 """
332 return None
333
335 """
336 Gets the physical size of a data brick in the x direction.
337
338 @since: 2.31
339
340 @return: Real size of a data brick the x direction. I{(float)}
341 """
342 return None
343
345 """
346 Gets the physical size of a data brick in the y direction.
347
348 @since: 2.31
349
350 @return: Real size of a data brick the y direction. I{(float)}
351 """
352 return None
353
355 """
356 Gets the physical size of a data brick in the z direction.
357
358 @since: 2.31
359
360 @return: Real size of a data brick the z direction. I{(float)}
361 """
362 return None
363
365 """
366 Gets the offset of data brick origin in x direction.
367
368 @since: 2.31
369
370 @return: Offset value. I{(float)}
371 """
372 return None
373
375 """
376 Gets the offset of data brick origin in y direction.
377
378 @since: 2.31
379
380 @return: Offset value. I{(float)}
381 """
382 return None
383
385 """
386 Gets the offset of data brick origin in z direction.
387
388 @since: 2.31
389
390 @return: Offset value. I{(float)}
391 """
392 return None
393
395 """
396 Sets the real x dimension of a brick.
397
398 @since: 2.31
399
400 @param xreal: New real x dimensions value I{(float)}
401 """
402 pass
403
405 """
406 Sets the real y dimension of a brick.
407
408 @since: 2.31
409
410 @param yreal: New real y dimensions value I{(float)}
411 """
412 pass
413
415 """
416 Sets the real z dimension of a brick.
417
418 @since: 2.31
419
420 @param zreal: New real z dimensions value I{(float)}
421 """
422 pass
423
425 """
426 Sets the offset of a data brick origin in the x direction.
427
428 Note offsets don't affect any calculation, nor functions like
429 L{Brick.rtoi}().
430
431 @since: 2.31
432
433 @param xoffset: New offset value. I{(float)}
434 """
435 pass
436
438 """
439 Sets the offset of a data brick origin in the y direction.
440
441 Note offsets don't affect any calculation, nor functions like
442 L{Brick.rtoi}().
443
444 @since: 2.31
445
446 @param yoffset: New offset value. I{(float)}
447 """
448 pass
449
451 """
452 Sets the offset of a data brick origin in the z direction.
453
454 Note offsets don't affect any calculation, nor functions like
455 L{Brick.rtoi}().
456
457 @since: 2.31
458
459 @param zoffset: New offset value. I{(float)}
460 """
461 pass
462
464 """
465 Gets the horizontal (X) voxel size of a brick in real units.
466
467 The result is the same as
468 L{Brick.get_xreal}(brick)/L{Brick.get_xres}(brick).
469
470 @since: 2.52
471
472 @return: Horizontal voxel size. I{(float)}
473 """
474 return None
475
477 """
478 Gets the vertical (Y) voxel size of a brick in real units.
479
480 The result is the same as
481 L{Brick.get_yreal}(brick)/L{Brick.get_yres}(brick).
482
483 @since: 2.52
484
485 @return: Vertical voxel size. I{(float)}
486 """
487 return None
488
490 """
491 Gets the level-wise (Z) voxel size of a brick in real units.
492
493 The result is the same as
494 L{Brick.get_zreal}(brick)/L{Brick.get_zres}(brick).
495
496 Note that it cannot -- and hence does not -- take into account any attached
497 Z calibration.
498
499 @since: 2.52
500
501 @return: Level-wise voxel size. I{(float)}
502 """
503 return None
504
506 """
507 Returns x direction SI unit of a data brick.
508
509 @since: 2.31
510
511 @return: SI unit corresponding to the lateral (X) dimension of the data
512 brick. Its reference count is not incremented. I{(L{SIUnit})}
513 """
514 return None
515
517 """
518 Returns y direction SI unit of a data brick.
519
520 @since: 2.31
521
522 @return: SI unit corresponding to the lateral (Y) dimension of the data
523 brick. Its reference count is not incremented. I{(L{SIUnit})}
524 """
525 return None
526
528 """
529 Returns z direction SI unit of a data brick.
530
531 @since: 2.31
532
533 @return: SI unit corresponding to the "height" (Z) dimension of the data
534 brick. Its reference count is not incremented. I{(L{SIUnit})}
535 """
536 return None
537
539 """
540 Returns value SI unit of a data brick.
541
542 @since: 2.31
543
544 @return: SI unit corresponding to the "value" of the data
545 brick. Its reference count is not incremented. I{(L{SIUnit})}
546 """
547 return None
548
550 """
551 Sets the SI unit corresponding to the lateral (X) dimension of a data
552 brick.
553
554 It does not assume a reference on B{C{si_unit}}, instead it adds its own
555 reference.
556
557 @since: 2.31
558
559 @param si_unit: SI unit to be set. I{(L{SIUnit})}
560 """
561 pass
562
564 """
565 Sets the SI unit corresponding to the lateral (Y) dimension of a data
566 brick.
567
568 It does not assume a reference on B{C{si_unit}}, instead it adds its own
569 reference.
570
571 @since: 2.31
572
573 @param si_unit: SI unit to be set. I{(L{SIUnit})}
574 """
575 pass
576
578 """
579 Sets the SI unit corresponding to the "height" (Z) dimension of a data
580 brick.
581
582 It does not assume a reference on B{C{si_unit}}, instead it adds its own
583 reference.
584
585 @since: 2.31
586
587 @param si_unit: SI unit to be set. I{(L{SIUnit})}
588 """
589 pass
590
592 """
593 Sets the SI unit corresponding to the "value" of a data
594 brick.
595
596 It does not assume a reference on B{C{si_unit}}, instead it adds its own
597 reference.
598
599 @since: 2.31
600
601 @param si_unit: SI unit to be set. I{(L{SIUnit})}
602 """
603 pass
604
606 """
607 Find the minimum value in a data brick.
608
609 @since: 2.31
610
611 @return: The minimum value within the brick. I{(float)}
612 """
613 return None
614
616 """
617 Find the maximum value in a data brick.
618
619 @since: 2.31
620
621 @return: The maximum value within the brick. I{(float)}
622 """
623 return None
624
626 """
627 Sets lateral and value units of a data brick to match another data brick.
628
629 @since: 2.49
630
631 @param target: Target data brick. I{(L{Brick})}
632 """
633 pass
634
645
656
667
681
683 """
684 Transforms pixel coordinate to real (physical) coordinate in x direction.
685
686 That is it maps range [0..x resolution] to range [0..x real-size]. It is not
687 suitable for conversion of matrix indices to physical coordinates, you
688 have to use L{Brick.itor}(B{C{brick}}, B{C{pixpos}} + 0.5) for that.
689
690 @since: 2.31
691
692 @param pixpos: Pixel coordinate. I{(float)}
693 @return: B{C{pixpos}} in real coordinates. I{(float)}
694 """
695 return None
696
698 """
699 Transforms real (physical) coordinate to pixel coordinate in x axis.
700
701 That is it maps range [0..x real-size] to range [0..x resolution].
702
703 @since: 2.31
704
705 @param realpos: Real coordinate. I{(float)}
706 @return: B{C{realpos}} in pixel coordinates. I{(float)}
707 """
708 return None
709
711 """
712 Transforms pixel coordinate to real (physical) coordinate in y direction.
713
714 That is it maps range [0..y resolution] to range [0..y real-size]. It is not
715 suitable for conversion of matrix indices to physical coordinates, you
716 have to use L{Brick.itor}(B{C{brick}}, B{C{pixpos}} + 0.5) for that.
717
718 @since: 2.31
719
720 @param pixpos: Pixel coordinate. I{(float)}
721 @return: B{C{pixpos}} in real coordinates. I{(float)}
722 """
723 return None
724
726 """
727 Transforms real (physical) coordinate to pixel coordinate in y axis.
728
729 That is it maps range [0..y real-size] to range [0..y resolution].
730
731 @since: 2.31
732
733 @param realpos: Real coordinate. I{(float)}
734 @return: B{C{realpos}} in pixel coordinates. I{(float)}
735 """
736 return None
737
739 """
740 Transforms pixel coordinate to real (physical) coordinate in z direction.
741
742 That is it maps range [0..z resolution] to range [0..z real-size]. It is not
743 suitable for conversion of matrix indices to physical coordinates, you
744 have to use L{Brick.itor}(B{C{brick}}, B{C{pixpos}} + 0.5) for that.
745
746 @since: 2.31
747
748 @param pixpos: Pixel coordinate. I{(float)}
749 @return: B{C{pixpos}} in real coordinates. I{(float)}
750 """
751 return None
752
754 """
755 Transforms real (physical) coordinate to pixel coordinate in z axis.
756
757 That is it maps range [0..z real-size] to range [0..z resolution].
758
759 @since: 2.31
760
761 @param realpos: Real coordinate. I{(float)}
762 @return: B{C{realpos}} in pixel coordinates. I{(float)}
763 """
764 return None
765
767 """
768 Transforms pixel coordinate to real (physical) coordinate in z direction,
769 taking into account calibration.
770
771 Unlike L{Brick.ktor}(), this function takes into account the B{C{z}}
772 calibration and, if calibration is not present, the B{C{z}} axis offset.
773 Since the calibration is available only for discrete pixel coordinates,
774 the values are interpolated between and clamped if outside the range.
775
776 The values in the calibration are assumed to correspond to pixel centres.
777 This convention is also kept when no calibration is present.
778
779 @since: 2.42
780
781 @param pixpos: Pixel coordinate. I{(float)}
782 @return: B{C{pixpos}} in real coordinates. I{(float)}
783 """
784 return None
785
787 """
788 Transforms real (physical) coordinate to pixel coordinate in z axis,
789 taking into account calibration.
790
791 Unlike L{Brick.rtok}(), this function takes into account the B{C{z}}
792 calibration and, if calibration is not present, the B{C{z}} axis offset.
793 Since the calibration is available only for discrete pixel coordinates,
794 the values are interpolated between and clamped if outside the range.
795
796 The values in the calibration are assumed to correspond to pixel centres.
797 This convention is also kept when no calibration is present.
798
799 @since: 2.42
800
801 @param realpos: Real coordinate. I{(float)}
802 @return: B{C{realpos}} in pixel coordinates. I{(float)}
803 """
804 return None
805
807 """
808 Gets value at given position in a data brick.
809
810 Do not access data with this function inside inner loops, it's slow.
811 Get raw data buffer with L{Brick.get_data_const}() and access it
812 directly instead.
813
814 @since: 2.31
815
816 @param col: Position in the brick (column index). I{(int)}
817 @param row: Position in the brick (row index). I{(int)}
818 @param lev: Position in the brick (level index). I{(int)}
819 @return: Value at given index. I{(float)}
820 """
821 return None
822
823 - def set_val(col, row, lev, value):
824 """
825 Sets value at given position in a data brick.
826
827 Do not access data with this function inside inner loops, it's slow.
828 Get raw data buffer with L{Brick.get_data_const}() and access it
829 directly instead.
830
831 @since: 2.31
832
833 @param col: Position in the brick (column index). I{(int)}
834 @param row: Position in the brick (row index). I{(int)}
835 @param lev: Position in the brick (level index). I{(int)}
836 @param value: Value to be set. I{(float)}
837 """
838 pass
839
841 """
842 Gets value at given position in a data brick, in real coordinates.
843
844 Do not access data with this function inside inner loops, it's slow.
845 Get raw data buffer with L{Brick.get_data_const}() and access it
846 directly instead.
847
848 @since: 2.31
849
850 @param x: Position in the brick (x direction). I{(float)}
851 @param y: Position in the brick (y direction). I{(float)}
852 @param z: Position in the brick (z direction). I{(float)}
853 @return: Value at given index. I{(float)}
854 """
855 return None
856
858 """
859 Sets value at given position in a data brick.
860
861 Do not access data with this function inside inner loops, it's slow.
862 Get raw data buffer with L{Brick.get_data_const}() and access it
863 directly instead.
864
865 @since: 2.31
866
867 @param x: Position in the brick (x direction). I{(float)}
868 @param y: Position in the brick (y direction). I{(float)}
869 @param z: Position in the brick (z direction). I{(float)}
870 @param value: Value to be set. I{(float)}
871 """
872 pass
873
875 """
876 Gets interpolated value at arbitrary data brick point indexed by pixel
877 coordinates.
878
879 Note pixel values are centered in intervals [B{C{i}}, B{C{i}}+1].
880 See also L{Brick.get_dval_real}() that does the same, but takes
881 real coordinates.
882
883 @since: 2.31
884
885 @param x: Position in data brick in range [0, x resolution].
886 If the value is outside
887 this range, the nearest border value is returned. I{(float)}
888 @param y: Position in data brick in range [0, y resolution].
889 If the value is outside
890 this range, the nearest border value is returned. I{(float)}
891 @param z: Position in data brick in range [0, z resolution].
892 If the value is outside
893 this range, the nearest border value is returned. I{(float)}
894 @param interpolation: Interpolation method to use. I{(int)}
895 @return: Value interpolated in the data brick. I{(float)}
896 """
897 return None
898
900 """
901 Gets interpolated value at arbitrary data brick point indexed by pixel
902 coordinates.
903
904 Note pixel values are centered in intervals [B{C{j}}, B{C{j}}+1].
905 See also L{Brick.get_dval}() that does the same, but takes
906 pixel coordinates.
907
908 @since: 2.31
909
910 @param x: Position in data brick in range [0, x resolution]. If the value is
911 outside this range, the nearest border value is returned. I{(float)}
912 @param y: Position in data brick in range [0, y resolution]. If the value is
913 outside this range, the nearest border value is returned. I{(float)}
914 @param z: Position in data brick in range [0, z resolution]. If the value is
915 outside this range, the nearest border value is returned. I{(float)}
916 @param interpolation: Interpolation method to use. I{(int)}
917 @return: Value interpolated in the data brick. I{(float)}
918 """
919 return None
920
922 """
923 Fills a data brick with zeroes.
924
925 @since: 2.31
926
927 """
928 pass
929
931 """
932 Fills a data brick with specified value.
933
934 @since: 2.31
935
936 @param value: Value to fill data brick with. I{(float)}
937 """
938 pass
939
941 """
942 Multiplies all values in a data brick with a specified value.
943
944 @since: 2.31
945
946 @param value: Value to multiply data brick with. I{(float)}
947 """
948 pass
949
951 """
952 Adds a specified value to all values in a data brick.
953
954 @since: 2.31
955
956 @param value: Value to be added. I{(float)}
957 """
958 pass
959
961 """
962 Extracts a plane from a data brick.
963
964 One value of set (B{C{width}}, B{C{height}}, B{C{depth}}) needs to be -1, determining the
965 plane orientation.
966
967 Use L{Brick.extract_xy_plane}() to simply extract one entire XY plane.
968
969 @since: 2.31
970
971 @param target: Datafield to be filled by extracted plane. It will be resized if
972 necessary. I{(L{DataField})}
973 @param istart: Column where to start (pixel coordinates). I{(int)}
974 @param jstart: Row where to start (pixel coordinates). I{(int)}
975 @param kstart: Level where to start (pixel coordinates). I{(int)}
976 @param width: Pixel width of extracted plane. If B{C{width}} is -1, the yz plane will
977 be extracted. I{(int)}
978 @param height: Pixel height of extracted plane. If B{C{height}} is -1, the xz plane
979 will be extracted I{(int)}
980 @param depth: Pixel depth of extracted plane. If B{C{depth}} is -1, the xy plane will
981 be extracted I{(int)}
982 @param keep_offsets: Keep the physical offsets in extracted field. I{(bool)}
983 """
984 pass
985
987 """
988 Extracts one full XY plane of a data brick to a data field.
989
990 @since: 2.52
991
992 @param target: Datafield to be filled by extracted plane. It will be resized if
993 necessary. I{(L{DataField})}
994 @param lev: Position in the brick (level index). I{(int)}
995 """
996 pass
997
998 - def sum_plane(target, istart, jstart, kstart, width, height, depth, keep_offsets):
999 """
1000 Sums planes in certain direction
1001
1002 One value of set (B{C{width}}, B{C{height}}, B{C{depth}}) needs to be -1, determining the
1003 plane orientation. In contrast to L{Brick.extract_plane}, the appropriate
1004 start coordinate (e.g. B{C{istart}} if B{C{width}} = -1) is not used for single plane
1005 extraction, but the planes are accumulated in whole range (0..xres for given
1006 example).
1007
1008 @since: 2.31
1009
1010 @param target: Datafield to be filled by summed plane. It will be resized if
1011 necessary. I{(L{DataField})}
1012 @param istart: Column where to start (pixel coordinates). I{(int)}
1013 @param jstart: Row where to start (pixel coordinates). I{(int)}
1014 @param kstart: Level where to start (pixel coordinates). I{(int)}
1015 @param width: Pixel width of summed plane. If B{C{width}} is -1, the yz planes will be
1016 summed. I{(int)}
1017 @param height: Pixel height of summed plane. If B{C{height}} is -1, the xz planes will
1018 be summed I{(int)}
1019 @param depth: Pixel depth of summed plane. If B{C{depth}} is -1, the xy planes will
1020 be summed I{(int)}
1021 @param keep_offsets: Keep the physical offsets in extracted field. I{(bool)}
1022 """
1023 pass
1024
1026 """
1027 Sums all z-profiles of a data brick to a data field.
1028
1029 The result is an xy plane and can be alternatively imagined as the sum of
1030 all xy planes.
1031
1032 @since: 2.52
1033
1034 @param target: Datafield to be filled by the summary data. It will be resized if
1035 necessary. I{(L{DataField})}
1036 """
1037 pass
1038
1039 - def min_plane(target, istart, jstart, kstart, width, height, depth, keep_offsets):
1040 """
1041 Finds minima of profiles in certain direction.
1042
1043 One value of set (B{C{width}}, B{C{height}}, B{C{depth}}) needs to be -1, determining the
1044 plane orientation. In contrast to L{Brick.extract_plane}, the appropriate
1045 start coordinate (e.g. B{C{istart}} if B{C{width}} = -1) is not used for single plane
1046 extraction, but the planes are accumulated in whole range (0..xres for given
1047 example).
1048
1049 @since: 2.32
1050
1051 @param target: Datafield to be filled by the minima plane. It will be resized if
1052 necessary. I{(L{DataField})}
1053 @param istart: Column where to start (pixel coordinates). I{(int)}
1054 @param jstart: Row where to start (pixel coordinates). I{(int)}
1055 @param kstart: Level where to start (pixel coordinates). I{(int)}
1056 @param width: Pixel width of summarized plane. If B{C{width}} is -1, the yz planes will
1057 be summarized. I{(int)}
1058 @param height: Pixel height of summarized plane. If B{C{height}} is -1, the xz planes
1059 will be summarized. I{(int)}
1060 @param depth: Pixel depth of summarized plane. If B{C{depth}} is -1, the xy planes will
1061 be summarized I{(int)}
1062 @param keep_offsets: Keep the physical offsets in extracted field. I{(bool)}
1063 """
1064 pass
1065
1067 """
1068 Computes the minima along z-axis of a data brick to a data field.
1069
1070 The result is an xy plane.
1071
1072 @since: 2.52
1073
1074 @param target: Datafield to be filled by the summary data. It will be resized if
1075 necessary. I{(L{DataField})}
1076 """
1077 pass
1078
1079 - def max_plane(target, istart, jstart, kstart, width, height, depth, keep_offsets):
1080 """
1081 Finds minima of profiles in certain direction.
1082
1083 One value of set (B{C{width}}, B{C{height}}, B{C{depth}}) needs to be -1, determining the
1084 plane orientation. In contrast to L{Brick.extract_plane}, the appropriate
1085 start coordinate (e.g. B{C{istart}} if B{C{width}} = -1) is not used for single plane
1086 extraction, but the planes are accumulated in whole range (0..xres for given
1087 example).
1088
1089 @since: 2.32
1090
1091 @param target: Datafield to be filled by the maxima plane. It will be resized if
1092 necessary. I{(L{DataField})}
1093 @param istart: Column where to start (pixel coordinates). I{(int)}
1094 @param jstart: Row where to start (pixel coordinates). I{(int)}
1095 @param kstart: Level where to start (pixel coordinates). I{(int)}
1096 @param width: Pixel width of summarized plane. If B{C{width}} is -1, the yz planes will
1097 be summarized. I{(int)}
1098 @param height: Pixel height of summarized plane. If B{C{height}} is -1, the xz planes
1099 will be summarized. I{(int)}
1100 @param depth: Pixel depth of extracted plane. If B{C{depth}} is -1, the xy planes will
1101 be summarized I{(int)}
1102 @param keep_offsets: Keep the physical offsets in extracted field. I{(bool)}
1103 """
1104 pass
1105
1107 """
1108 Computes the maxima along z-axis of a data brick to a data field.
1109
1110 The result is an xy plane.
1111
1112 @since: 2.52
1113
1114 @param target: Datafield to be filled by the summary data. It will be resized if
1115 necessary. I{(L{DataField})}
1116 """
1117 pass
1118
1119 - def minpos_plane(target, istart, jstart, kstart, width, height, depth, keep_offsets):
1120 """
1121 Finds minima coordinates in profiles in certain direction.
1122
1123 One value of set (B{C{width}}, B{C{height}}, B{C{depth}}) needs to be -1,
1124 determining the plane orientation. In contrast to L{Brick.extract_plane},
1125 the appropriate start coordinate (e.g. B{C{istart}} if B{C{width}} = -1) is not used
1126 for single plane extraction, but the planes are accumulated in whole range
1127 (0..xres for given example)
1128
1129 @since: 2.32
1130
1131 @param target: Datafield to be filled by the minima positions plane.
1132 It will be resized if necessary. I{(L{DataField})}
1133 @param istart: Column where to start (pixel coordinates). I{(int)}
1134 @param jstart: Row where to start (pixel coordinates). I{(int)}
1135 @param kstart: Level where to start (pixel coordinates). I{(int)}
1136 @param width: Pixel width of summarized plane. If B{C{width}} is -1, the yz planes will
1137 be summarized. I{(int)}
1138 @param height: Pixel height of summarized plane. If B{C{height}} is -1, the xz planes
1139 will be summarized. I{(int)}
1140 @param depth: Pixel depth of summarized plane. If B{C{depth}} is -1, the xy planes will
1141 be summarized I{(int)}
1142 @param keep_offsets: Keep the physical offsets in summarized field. I{(bool)}
1143 """
1144 pass
1145
1147 """
1148 Computes the location of minima along z-axis of a data brick to a data field.
1149
1150 The result is an xy plane.
1151
1152 @since: 2.52
1153
1154 @param target: Datafield to be filled by the summary data. It will be resized if
1155 necessary. I{(L{DataField})}
1156 """
1157 pass
1158
1159 - def maxpos_plane(target, istart, jstart, kstart, width, height, depth, keep_offsets):
1160 """
1161 Finds maxima coordinates of profiles in certain direction.
1162
1163 One value of set (B{C{width}}, B{C{height}}, B{C{depth}}) needs to be -1,
1164 determining the plane orientation. In contrast to L{Brick.extract_plane},
1165 the appropriate start coordinate (e.g. B{C{istart}} if B{C{width}} = -1) is not used
1166 for single plane extraction, but the planes are accumulated in whole range
1167 (0..xres for given example).
1168
1169 @since: 2.32
1170
1171 @param target: Datafield to be filled by the maxima positions plane.
1172 It will be resized if necessary. I{(L{DataField})}
1173 @param istart: Column where to start (pixel coordinates). I{(int)}
1174 @param jstart: Row where to start (pixel coordinates). I{(int)}
1175 @param kstart: Level where to start (pixel coordinates). I{(int)}
1176 @param width: Pixel width of summarized plane. If B{C{width}} is -1, the yz planes will
1177 be summarized. I{(int)}
1178 @param height: Pixel height of summarized plane. If B{C{height}} is -1, the xz planes
1179 will be summarized I{(int)}
1180 @param depth: Pixel depth of summarized plane. If B{C{depth}} is -1, the xy planes will
1181 be summarized I{(int)}
1182 @param keep_offsets: Keep the physical offsets in summarized field. Not
1183 implemented. I{(bool)}
1184 """
1185 pass
1186
1188 """
1189 Computes the location of maxima along z-axis of a data brick to a data field.
1190
1191 The result is an xy plane.
1192
1193 @since: 2.52
1194
1195 @param target: Datafield to be filled by the summary data. It will be resized if
1196 necessary. I{(L{DataField})}
1197 """
1198 pass
1199
1200 - def mean_plane(target, istart, jstart, kstart, width, height, depth, keep_offsets):
1201 """
1202 Finds mean of planes in certain direction.
1203
1204 One value of set (B{C{width}}, B{C{height}}, B{C{depth}}) needs to be -1, determining the
1205 plane orientation. In contrast to L{Brick.extract_plane}, the appropriate
1206 start coordinate (e.g. B{C{istart}} if B{C{width}} = -1) is not used for single plane
1207 extraction, but the planes are accumulated in whole range (0..xres for given
1208 example).
1209
1210 @since: 2.32
1211
1212 @param target: Datafield to be filled by the mean plane. It will be resized if
1213 necessary. I{(L{DataField})}
1214 @param istart: Column where to start (pixel coordinates). I{(int)}
1215 @param jstart: Row where to start (pixel coordinates). I{(int)}
1216 @param kstart: Level where to start (pixel coordinates). I{(int)}
1217 @param width: Pixel width of summarized plane. If B{C{width}} is -1, the yz planes will
1218 be summarized. I{(int)}
1219 @param height: Pixel height of summarized plane. If B{C{height}} is -1, the xz planes
1220 will be summarized. I{(int)}
1221 @param depth: Pixel depth of summarized plane. If B{C{depth}} is -1, the xy planes will
1222 be summarized. I{(int)}
1223 @param keep_offsets: Keep the physical offsets in summarized field. I{(bool)}
1224 """
1225 pass
1226
1228 """
1229 Calculates mean values of all z-profiles of a data brick to a data field.
1230
1231 The result is an xy plane and can be alternatively imagined as the average
1232 of all xy planes.
1233
1234 @since: 2.52
1235
1236 @param target: Datafield to be filled by the summary data. It will be resized if
1237 necessary. I{(L{DataField})}
1238 """
1239 pass
1240
1241 - def rms_plane(target, istart, jstart, kstart, width, height, depth, keep_offsets):
1242 """
1243 Finds rms of planes in certain direction and extract the result
1244 (DataField). One value of set (B{C{width}}, B{C{height}}, B{C{depth}}) needs to be -1,
1245 determining the plane orientation. In contrast to L{Brick.extract_plane},
1246 the appropriate start coordinate (e.g. B{C{istart}} if B{C{width}} = -1) is not used
1247 for single plane extraction, but the planes are accumulated in whole range
1248 (0..xres for given example)
1249
1250 @since: 2.32
1251
1252 @param target: Datafield to be filled by the rms plane. It will be resized if
1253 necessary. I{(L{DataField})}
1254 @param istart: Column where to start (pixel coordinates). I{(int)}
1255 @param jstart: Row where to start (pixel coordinates). I{(int)}
1256 @param kstart: Level where to start (pixel coordinates). I{(int)}
1257 @param width: Pixel width of summarized plane. If B{C{width}} is -1, the yz planes will
1258 be summarized. I{(int)}
1259 @param height: Pixel height of summarized plane. If B{C{height}} is -1, the xz planes
1260 will be summarized. I{(int)}
1261 @param depth: Pixel depth of summarized plane. If B{C{depth}} is -1, the xy planes will
1262 be summarized. I{(int)}
1263 @param keep_offsets: Keep the physical offsets in extracted field. I{(bool)}
1264 """
1265 pass
1266
1268 """
1269 Calculates rms values of all z-profiles of a data brick to a data field.
1270
1271 The result is an xy plane and can be alternatively imagined as the variation
1272 among xy planes.
1273
1274 @since: 2.52
1275
1276 @param target: Datafield to be filled by the summary data. It will be resized if
1277 necessary. I{(L{DataField})}
1278 """
1279 pass
1280
1282 """
1283 Extracts a line (DataLine) from the brick.
1284
1285 Only line orientations parallel to coordinate axes are supported now, i.e.
1286 two of the start coordinates need to be same as end ones.
1287
1288 @since: 2.31
1289
1290 @param target: Dataline to be filled by extracted line. It will be resized if
1291 necessary. I{(L{DataLine})}
1292 @param istart: Column where to start (pixel coordinates). I{(int)}
1293 @param jstart: Row where to start (pixel coordinates). I{(int)}
1294 @param kstart: Level where to start (pixel coordinates). I{(int)}
1295 @param iend: Column where to end, exclusive (pixel coordinates). I{(int)}
1296 @param jend: Row where to end, exclusive (pixel coordinates). I{(int)}
1297 @param kend: Level where to end, exclusive (pixel coordinates). I{(int)}
1298 @param keep_offsets: Keep physical offsets in extracted line. I{(bool)}
1299 """
1300 pass
1301
1303 """
1304 Extracts one full Z profile of a data brick to a data line.
1305
1306 @since: 2.52
1307
1308 @param target: Dataline to be filled by extracted line. It will be resized if
1309 necessary. I{(L{DataLine})}
1310 @param i: Column index. I{(int)}
1311 @param j: Row index. I{(int)}
1312 """
1313 pass
1314
1316 """
1317 Gets the z-axis non-linear calibration of a data brick.
1318
1319 @since: 2.32
1320
1321 @return: Z Calibration (non-linear Z-axis values as ordinates). I{(L{DataLine})}
1322 """
1323 return None
1324
1326 """
1327 Sets the z-axis non-linear calibration of a data brick.
1328
1329 @since: 2.32
1330
1331 @param calibration: DataLine pointer with z-axis non-linear calibration
1332 of a data brick (values are stored as ordinates). It can also
1333 be B{C{None}} to unset the calibration. I{(L{DataLine})}
1334 """
1335 pass
1336
1338 """
1339 Copies non-linear z-axis calibration between two data bricks.
1340
1341 Both bricks must have the same Z resolution. For a meaningful usage, they
1342 should also have the same Z real sizes and units (uncalibrated).
1343
1344 If B{C{brick}} has no z-axis calibration, existing B{C{targets}}' calibration is
1345 deleted.
1346
1347 @since: 2.52
1348
1349 @param target: Target data brick. I{(L{Brick})}
1350 """
1351 pass
1352
1353 - def transpose(target, type, xflipped, yflipped, zflipped):
1354 """
1355 Transposes a data brick, exchanging and/or flipping axes.
1356
1357 Real dimensions and units are updated. Since real sizes cannot go backward,
1358 flipping an axis results in the corresponding offset being reset (the
1359 real dimension stays positive). If the Z axis is preserved its calibration
1360 is copied to the target; otherwise the target will have no Z axis
1361 calibration.
1362
1363 @since: 2.51
1364
1365 @param target: Destination data brick. It will be resized as needed. I{(L{Brick})}
1366 @param type: Basic transposition type (which axes are swapped). Expected values: C{B{BRICK_TRANSPOSE_XYZ}}, C{B{BRICK_TRANSPOSE_XZY}}, C{B{BRICK_TRANSPOSE_YXZ}}, C{B{BRICK_TRANSPOSE_YZX}}, C{B{BRICK_TRANSPOSE_ZXY}}, C{B{BRICK_TRANSPOSE_ZYX}}. I{(L{BrickTransposeType})}
1367 @param xflipped: B{C{True}} to reflect X, i.e. rows within XY planes. I{(bool)}
1368 @param yflipped: B{C{True}} to reflect Y, i.e. columns within XY planes. I{(bool)}
1369 @param zflipped: B{C{True}} to reflect Z, i.e. the XY plane order. I{(bool)}
1370 """
1371 pass
1372
1373 - def invert(xflipped, yflipped, zflipped, wflipped):
1374 """
1375 Reflects and/or inverts a data brick in place.
1376
1377 In the case of value reflection, it's inverted about the mean value.
1378
1379 Since real sizes cannot go backward, flipping an axis results in the
1380 corresponding offset being reset (the real dimension stays positive).
1381
1382 Note that the axis parameter convention is different from the confusing one
1383 of L{DataField.invert}(). Here parameters simply correspond to directions
1384 that should be flipped.
1385
1386 @since: 2.59
1387
1388 @param xflipped: B{C{True}} to reflect X, i.e. rows within XY planes. I{(bool)}
1389 @param yflipped: B{C{True}} to reflect Y, i.e. columns within XY planes. I{(bool)}
1390 @param zflipped: B{C{True}} to reflect Z, i.e. the XY plane order. I{(bool)}
1391 @param wflipped: B{C{True}} to invert values. I{(bool)}
1392 """
1393 pass
1394
1395 - def set_plane(plane, istart, jstart, kstart, width, height, depth):
1396 """
1397 Fill a single plane in the brick by a two-dimensional data (DataField).
1398
1399 One value of set (B{C{width}}, B{C{height}}, B{C{depth}}) needs to be -1, determining the
1400 plane orientation.
1401
1402 @since: 2.51
1403
1404 @param plane: Datafield to be inserted into brick. It must have the appropriate
1405 size. I{(L{DataField})}
1406 @param istart: Column where to start (pixel coordinates). I{(int)}
1407 @param jstart: Row where to start (pixel coordinates). I{(int)}
1408 @param kstart: Level where to start (pixel coordinates). I{(int)}
1409 @param width: Pixel width of the inserted plane.
1410 If B{C{width}} is -1, the yz plane will be filled. I{(int)}
1411 @param height: Pixel height of insered plane.
1412 If B{C{height}} is -1, the xz plane will be filled. I{(int)}
1413 @param depth: Pixel depth of inserted plane.
1414 If B{C{depth}} is -1, the xy plane will be filled. I{(int)}
1415 """
1416 pass
1417
1419 """
1420 Sets one full single XY plane in a data brick from data field values.
1421
1422 @since: 2.52
1423
1424 @param plane: Datafield to be inserted into brick. It must have dimensions
1425 B{C{xres}} by B{C{yres}}. I{(L{DataField})}
1426 @param lev: Position in the brick (level index). I{(int)}
1427 """
1428 pass
1429
1431 """
1432 Adds a data field to all brick XY planes.
1433
1434 @since: 2.55
1435
1436 @param plane: Datafield to be added to all brick XY planes. It must have
1437 dimensions B{C{xres}} by B{C{yres}}. I{(L{DataField})}
1438 """
1439 pass
1440
1442 """
1443 Adds a data line to all brick Z lines.
1444
1445 @since: 2.55
1446
1447 @param line: Data line to add to each Z lines. It must have dimension B{C{zres}}. I{(L{DataLine})}
1448 """
1449 pass
1450
1452 """
1453 Extract the data of a data brick.
1454
1455 The returned list contains a copy of the data. Changing its contents does
1456 not change the data brick's data.
1457
1458
1459 @return: List containing extracted data brick data. I{(list)}
1460 """
1461 return None
1462
1464 """
1465 Sets the entire contents of a data brick.
1466
1467 The length of B{C{data}} must be equal to the number of elements of the data
1468 brick.
1469
1470 @param data: Sequence of floating point values. I{(list)}
1471 """
1472 pass
1473
1475 """
1476 Convenience macro doing L{gwy_serializable_duplicate}() with all the necessary
1477 typecasting.
1478
1479 @since: 2.31
1480
1481 @return: I{(L{Brick})}
1482 """
1483 return None
1484
1486 """
1487 Gets pointer to data which the brick contains.
1488
1489
1490 @return: integer pointing to the raw data of the brick I{(long)}
1491 """
1492 return None
1493
1494
1497 """
1498 Creates a new color axis.
1499
1500
1501 @param orientation: The orientation of the axis. I{(GtkOrientation)}
1502 @return: The newly created color axis as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
1503 """
1504 return None
1505
1507 """
1508 Gets the range of a color axis.
1509
1510 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
1511 """
1512 return None, None
1513
1515 """
1516 Sets the range of a color axis.
1517
1518 @param min: The range minimum. I{(float)}
1519 @param max: The range maximum. I{(float)}
1520 """
1521 pass
1522
1524 """
1525 Gets the SI unit a color axis displays.
1526
1527
1528 @return: The SI unit. I{(L{SIUnit})}
1529 """
1530 return None
1531
1533 """
1534 Sets the SI unit a color axis displays.
1535
1536 @param unit: A SI unit to display next to minimum and maximum value. I{(L{SIUnit})}
1537 """
1538 pass
1539
1541 """
1542 Sets the color gradient a color axis should use.
1543
1544 @param gradient: Name of gradient B{C{axis}} should use. It should exist. I{(string)}
1545 """
1546 pass
1547
1549 """
1550 Gets the color gradient a color axis uses.
1551
1552
1553 @return: The color gradient. I{(string)}
1554 """
1555 return None
1556
1558 """
1559 Gets ticks style of a color axis.
1560
1561
1562 @return: The ticks style. I{(TicksStyle)}
1563 """
1564 return None
1565
1567 """
1568 Sets the ticks style of a color axis.
1569
1570 @param ticks_style: The ticks style to use. Expected values: C{B{TICKS_STYLE_NONE}}, C{B{TICKS_STYLE_CENTER}}, C{B{TICKS_STYLE_AUTO}}, C{B{TICKS_STYLE_UNLABELED}}, C{B{TICKS_STYLE_UNLABELLED}}. I{(L{TicksStyle})}
1571 """
1572 pass
1573
1575 """
1576 Gets the visibility of labels of a color axis.
1577
1578
1579 @return: B{C{True}} if labels are displayed, B{C{False}} if they are omitted. I{(bool)}
1580 """
1581 return None
1582
1584 """
1585 Sets the visibility of labels of a color axis.
1586
1587 @param labels_visible: B{C{True}} to display labels with minimum and maximum values,
1588 B{C{False}} to display no labels. I{(bool)}
1589 """
1590 pass
1642 """
1643 A container with items identified by a GQuark
1644
1645
1646 B{C{Container}} is a general-purpose container, it can hold atomic types,
1647 strings and objects. However, objects must implement the B{C{Serializable}}
1648 interface, because the container itself is serializable.
1649
1650 A new container can be created with L{Container.new}(), items can be stored
1651 with function like L{Container.set_double}(), read with
1652 L{Container.get_double}(), and removed with L{Container.remove}() or
1653 L{Container.remove_by_prefix}(). A presence of a value can be tested with
1654 L{Container.contains}(), convenience functions for reading (updating) a
1655 value only if it is present like L{Container.gis_double}(), are available
1656 too.
1657
1658 B{C{Container}} takes ownership of stored non-atomic items. For strings, this
1659 means you cannot store static strings (use g_strdup() to duplicate them),
1660 and must not free stored dynamic strings, as the container will free them
1661 itself when they are removed or when the container is finalized. For
1662 objects, this means it takes a reference on the object (released when the
1663 object is removed or the container is finalized), so you usually want to
1664 g_object_unref() objects after storing them to a container.
1665
1666 Items in a B{C{Container}} can be identified by a B{C{GQuark}} or the corresponding
1667 string. While B{C{GQuark}}'s are atomic values and allow faster acces, they are
1668 less convenient for casual usage -- each B{C{GQuark}} key function like
1669 L{Container.set_double}() thus has a string-key counterpart
1670 L{Container.set_double_by_name}().
1671
1672 """
1674 """
1675 Creates a new B{C{Container}}.
1676
1677
1678 @return: The container, as a B{C{GObject}}. I{(L{Container})}
1679 """
1680 return None
1681
1683 """
1684 Gets the number of items in a container.
1685
1686
1687 @return: The number of items. I{(int)}
1688 """
1689 return None
1690
1692 """
1693 Returns the type of value in B{C{container}} identified by B{C{key}}.
1694
1695
1696 @param key: A B{C{GQuark}} key. I{(int)}
1697 @return: The value type as B{C{GType}}; 0 if there is no such value. I{(GType)}
1698 """
1699 return None
1700
1702 """
1703 Returns B{C{True}} if B{C{container}} contains a value identified by B{C{key}}.
1704
1705
1706 @param key: A B{C{GQuark}} key. I{(int)}
1707 @return: Whether B{C{container}} contains something identified by B{C{key}}. I{(bool)}
1708 """
1709 return None
1710
1712 """
1713 Removes a value identified by B{C{key}} from a container.
1714
1715
1716 @param key: A B{C{GQuark}} key. I{(int)}
1717 @return: B{C{True}} if there was such a value and was removed. I{(bool)}
1718 """
1719 return None
1720
1722 """
1723 Removes a values whose key start with B{C{prefix}} from container B{C{container}}.
1724
1725 B{C{prefix}} can be B{C{None}}, all values are then removed.
1726
1727
1728 @param prefix: A nul-terminated id prefix. I{(string)}
1729 @return: The number of values removed. I{(int)}
1730 """
1731 return None
1732
1733 - def transfer(dest, source_prefix, dest_prefix, force):
1734 """
1735 Copies a items from one place in container to another place.
1736
1737 The copies are shallow, objects are not physically duplicated, only
1738 referenced in B{C{dest}}.
1739
1740
1741 @param dest: Destination container. It may be the same container as B{C{source}}, but
1742 B{C{source_prefix}} and B{C{dest_prefix}} may not overlap then. I{(L{Container})}
1743 @param source_prefix: Prefix in B{C{source}} to take values from. I{(string)}
1744 @param dest_prefix: Prefix in B{C{dest}} to put values to. I{(string)}
1745 @param force: B{C{True}} to replace existing values in B{C{dest}}. I{(bool)}
1746 @return: The number of actually transferred items. I{(int)}
1747 """
1748 return None
1749
1750 - def rename(key, newkey, force):
1751 """
1752 Makes a value in B{C{container}} identified by B{C{key}} to be identified by B{C{newkey}}.
1753
1754 When B{C{force}} is B{C{True}} existing value at B{C{newkey}} is removed from B{C{container}}.
1755 When it's B{C{False}}, an existing value B{C{newkey}} inhibits the rename and B{C{False}}
1756 is returned.
1757
1758
1759 @param key: The current key. I{(int)}
1760 @param newkey: A new key for the value. I{(int)}
1761 @param force: Whether to replace existing value at B{C{newkey}}. I{(bool)}
1762 @return: Whether the rename succeeded. I{(bool)}
1763 """
1764 return None
1765
1766 - def foreach(prefix, function, user_data):
1767 """
1768 Calls B{C{function}} on each B{C{container}} item whose identifier starts with
1769 B{C{prefix}}.
1770
1771 The function is called B{C{function}}(B{C{GQuark}} key, B{C{GValue}} *value, user_data).
1772
1773
1774 @param prefix: A nul-terminated id prefix. I{(string)}
1775 @param function: The function called on the items. I{(GHFunc)}
1776 @param user_data: The user data passed to B{C{function}}. I{(gpointer)}
1777 @return: The number of items B{C{function}} was called on. I{(int)}
1778 """
1779 return None
1780
1782 """
1783 Stores a boolean into B{C{container}}, identified by B{C{key}}.
1784
1785 @param key: A B{C{GQuark}} key. I{(int)}
1786 @param value: A boolean. I{(bool)}
1787 """
1788 pass
1789
1791 """
1792 Returns the boolean in B{C{container}} identified by B{C{key}}.
1793
1794
1795 @param key: A B{C{GQuark}} key. I{(int)}
1796 @return: The boolean as B{C{gboolean}}. I{(bool)}
1797 """
1798 return None
1799
1801 """
1802 Stores an unsigned character into B{C{container}}, identified by B{C{key}}.
1803
1804 @param key: A B{C{GQuark}} key. I{(int)}
1805 @param value: An unsigned character. I{(guchar)}
1806 """
1807 pass
1808
1810 """
1811 Returns the unsigned character in B{C{container}} identified by B{C{key}}.
1812
1813
1814 @param key: A B{C{GQuark}} key. I{(int)}
1815 @return: The character as B{C{guchar}}. I{(guchar)}
1816 """
1817 return None
1818
1820 """
1821 Stores a 32bit integer into B{C{container}}, identified by B{C{key}}.
1822
1823 @param key: A B{C{GQuark}} key. I{(int)}
1824 @param value: A 32bit integer. I{(int)}
1825 """
1826 pass
1827
1829 """
1830 Returns the 32bit integer in B{C{container}} identified by B{C{key}}.
1831
1832
1833 @param key: A B{C{GQuark}} key. I{(int)}
1834 @return: The integer as B{C{guint32}}. I{(int)}
1835 """
1836 return None
1837
1839 """
1840 Stores an enum into B{C{container}}, identified by B{C{key}}.
1841
1842 Note enums are treated as 32bit integers.
1843
1844 @param key: A B{C{GQuark}} key. I{(int)}
1845 @param value: An enum integer. I{(int)}
1846 """
1847 pass
1848
1850 """
1851 Returns the enum in B{C{container}} identified by B{C{key}}.
1852
1853 Note enums are treated as 32bit integers.
1854
1855
1856 @param key: A B{C{GQuark}} key. I{(int)}
1857 @return: The enum as B{C{gint}}. I{(int)}
1858 """
1859 return None
1860
1862 """
1863 Stores a 64bit integer into B{C{container}}, identified by B{C{key}}.
1864
1865 @param key: A B{C{GQuark}} key. I{(int)}
1866 @param value: A 64bit integer. I{(gint64)}
1867 """
1868 pass
1869
1871 """
1872 Returns the 64bit integer in B{C{container}} identified by B{C{key}}.
1873
1874
1875 @param key: A B{C{GQuark}} key. I{(int)}
1876 @return: The 64bit integer as B{C{guint64}}. I{(gint64)}
1877 """
1878 return None
1879
1881 """
1882 Stores a double into B{C{container}}, identified by B{C{key}}.
1883
1884 @param key: A B{C{GQuark}} key. I{(int)}
1885 @param value: A double. I{(float)}
1886 """
1887 pass
1888
1890 """
1891 Returns the double in B{C{container}} identified by B{C{key}}.
1892
1893
1894 @param key: A B{C{GQuark}} key. I{(int)}
1895 @return: The double as B{C{gdouble}}. I{(float)}
1896 """
1897 return None
1898
1900 """
1901 Returns the string in B{C{container}} identified by B{C{key}}.
1902
1903 The returned string must be treated as constant and never freed or modified.
1904
1905
1906 @param key: A B{C{GQuark}} key. I{(int)}
1907 @return: The string. I{(string)}
1908 """
1909 return None
1910
1912 """
1913 Stores an object into B{C{container}}, identified by B{C{key}}.
1914
1915 The container claims ownership on the object, i.e. its reference count is
1916 incremented.
1917
1918 The object must implement B{C{Serializable}} interface to allow serialization
1919 of the container.
1920
1921 @param key: A B{C{GQuark}} key. I{(int)}
1922 @param value: An object to store into container. I{(L{gobject.GObject})}
1923 """
1924 pass
1925
1927 """
1928 Returns the object in B{C{container}} identified by B{C{key}}.
1929
1930 The returned object doesn't have its reference count increased, use
1931 g_object_ref() if you want to access it even when B{C{container}} may cease
1932 to exist.
1933
1934
1935 @param key: A B{C{GQuark}} key. I{(int)}
1936 @return: The object as B{C{gpointer}}. I{(L{gobject.GObject})}
1937 """
1938 return None
1939
1941 """
1942 Gets all quark keys of a container.
1943
1944 @since: 2.7
1945
1946 @return: A newly allocated array with quark keys of all B{C{container}} items,
1947 in no particular order. The number of items can be obtained
1948 with L{Container.get_n_items}(). If there are no items, B{C{None}}
1949 is returned. I{(list)}
1950 """
1951 return None
1952
1954 """
1955 Gets all string keys of a container.
1956
1957 @since: 2.7
1958
1959 @return: A newly allocated array with string keys of all B{C{container}} items,
1960 in no particular order. The number of items can be obtained
1961 with L{Container.get_n_items}(). If there are no items, B{C{None}}
1962 is returned. Unlike the array the strings are owned by GLib and
1963 must not be freed. I{(ConstStringArray*)}
1964 """
1965 return None
1966
1968 """
1969 Duplicates a container keeping only values under given prefixes.
1970
1971 Like L{Container.duplicate}(), this method creates a deep copy, that is
1972 contained object are physically duplicated too, not just referenced again.
1973
1974
1975 @param keys: I{(StringArray*)}
1976 @return: A newly created container. I{(L{Container})}
1977 """
1978 return None
1979
1981 """
1982 Creates a text representation of B{C{container}} contents.
1983
1984 Note only simple data types are supported as serialization of compound
1985 objects is not controllable.
1986
1987
1988 @return: A pointer array, each item containing string with one container
1989 item representation (name, type, value). The array is sorted by name. I{(StringArray*)}
1990 """
1991 return None
1992
1994 """
1995 Expands to B{C{True}} if container B{C{c}} contains a value identified by name B{C{n}}.
1996
1997 @param n: A nul-terminated name (id). I{(string)}
1998 @return: I{(bool)}
1999 """
2000 return None
2001
2003 """
2004 Removes a value identified by name B{C{n}} from container B{C{c}}.
2005
2006 Expands to B{C{True}} if there was such a value and was removed.
2007
2008 @param n: A nul-terminated name (id). I{(string)}
2009 @return: I{(bool)}
2010 """
2011 return None
2012
2014 """
2015 Makes a value in container B{C{c}} identified by name B{C{n}} to be identified by
2016 new name B{C{nn}}.
2017
2018 See L{Container.rename}() for details.
2019
2020 @param n: A nul-terminated name (id). I{(string)}
2021 @param new_name: I{(string)}
2022 @param force: I{(bool)}
2023 @return: I{(bool)}
2024 """
2025 return None
2026
2028 """
2029 Stores a boolean into container B{C{c}}, identified by name B{C{n}}.
2030
2031 @param n: A nul-terminated name (id). I{(string)}
2032 @param v: A boolean. I{(bool)}
2033 """
2034 pass
2035
2037 """
2038 Stores a double into container B{C{c}}, identified by name B{C{n}}.
2039
2040 @param n: A nul-terminated name (id). I{(string)}
2041 @param v: A double integer. I{(float)}
2042 """
2043 pass
2044
2046 """
2047 Stores an enum into container B{C{c}}, identified by name B{C{n}}.
2048
2049 Note enums are treated as 32bit integers.
2050
2051 @param n: A nul-terminated name (id). I{(string)}
2052 @param v: An enum. I{(int)}
2053 """
2054 pass
2055
2057 """
2058 Stores a 32bit integer into container B{C{c}}, identified by name B{C{n}}.
2059
2060 @param n: A nul-terminated name (id). I{(string)}
2061 @param v: A 32bit integer. I{(int)}
2062 """
2063 pass
2064
2066 """
2067 Stores a 64bit integer into container B{C{c}}, identified by name B{C{n}}.
2068
2069 @param n: A nul-terminated name (id). I{(string)}
2070 @param v: A 64bit integer. I{(gint64)}
2071 """
2072 pass
2073
2075 """
2076 Stores an object into container B{C{c}}, identified by name B{C{n}}.
2077
2078 See L{Container.set_object}() for details.
2079
2080 @param n: A nul-terminated name (id). I{(string)}
2081 @param v: An object to store into container. I{(L{gobject.GObject})}
2082 """
2083 pass
2084
2086 """
2087 Stores an unsigned character into container B{C{c}}, identified by name B{C{n}}.
2088
2089 @param n: A nul-terminated name (id). I{(string)}
2090 @param v: An unsigned character. I{(guchar)}
2091 """
2092 pass
2093
2095 """
2096 Gets the boolean in container B{C{c}} identified by name B{C{n}}.
2097
2098 @param n: A nul-terminated name (id). I{(string)}
2099 @return: I{(bool)}
2100 """
2101 return None
2102
2104 """
2105 Gets the double in container B{C{c}} identified by name B{C{n}}.
2106
2107 @param n: A nul-terminated name (id). I{(string)}
2108 @return: I{(float)}
2109 """
2110 return None
2111
2113 """
2114 Gets the enum in container B{C{c}} identified by name B{C{n}}.
2115
2116 Note enums are treated as 32bit integers.
2117
2118 @param n: A nul-terminated name (id). I{(string)}
2119 @return: I{(int)}
2120 """
2121 return None
2122
2124 """
2125 Gets the 32bit integer in container B{C{c}} identified by name B{C{n}}.
2126
2127 @param n: A nul-terminated name (id). I{(string)}
2128 @return: I{(int)}
2129 """
2130 return None
2131
2133 """
2134 Gets the 64bit integer in container B{C{c}} identified by name B{C{n}}.
2135
2136 @param n: A nul-terminated name (id). I{(string)}
2137 @return: I{(gint64)}
2138 """
2139 return None
2140
2142 """
2143 Gets the unsigned character in container B{C{c}} identified by name B{C{n}}.
2144
2145 @param n: A nul-terminated name (id). I{(string)}
2146 @return: I{(guchar)}
2147 """
2148 return None
2149
2151 """
2152 Gets the object in container B{C{c}} identified by name B{C{n}}.
2153
2154 The returned object doesn't have its reference count increased, use
2155 g_object_ref() if you want to access it even when B{C{container}} may cease
2156 to exist.
2157
2158 @param n: A nul-terminated name (id). I{(string)}
2159 @return: I{(L{gobject.GObject})}
2160 """
2161 return None
2162
2164 """
2165 Gets the string in container B{C{c}} identified by name B{C{n}}.
2166
2167 The returned string must be treated as constant and never freed or modified.
2168
2169 @param n: A nul-terminated name (id). I{(string)}
2170 @return: I{(string)}
2171 """
2172 return None
2173
2175 """
2176 Convenience macro doing L{gwy_serializable_duplicate}() with all the necessary
2177 typecasting.
2178
2179 @return: I{(L{Container})}
2180 """
2181 return None
2182
2184 """
2185 Stores a string into container B{C{c}}, identified by name B{C{n}}.
2186
2187 The container makes a copy of the string, so it can be used on static
2188 strings.
2189
2190 @since: 2.38
2191
2192 @param name: I{(string)}
2193 @param value: I{(string)}
2194 """
2195 pass
2196
2198 """
2199 Stores a string into B{C{container}}, identified by B{C{key}}.
2200
2201 The container makes a copy of the string, so it can be used on static
2202 strings.
2203
2204 @since: 2.38
2205
2206 @param key: A B{C{GQuark}} key. I{(int)}
2207 @param value: A nul-terminated string. I{(string)}
2208 """
2209 pass
2210
2212 """
2213 Gets all string keys of a container.
2214
2215 @since: 2.7
2216
2217 @return: A newly allocated array with string keys of all B{C{container}} items,
2218 in no particular order. The number of items can be obtained
2219 with L{Container.get_n_items}(). If there are no items, B{C{None}}
2220 is returned. Unlike the array the strings are owned by GLib and
2221 must not be freed. I{(list)}
2222 """
2223 return None
2224
2226 """
2227 Gets the value in container B{C{c}} identified by name B{C{n}}.
2228
2229 @param name: I{(string)}
2230 @return: I{(any)}
2231 """
2232 return None
2233
2235 """
2236 Returns the value in B{C{container}} identified by B{C{key}}.
2237
2238
2239 @param key: A B{C{GQuark}} key. I{(int)}
2240 @return: The value as a B{C{GValue}}. I{(any)}
2241 """
2242 return None
2243
2245 """
2246 Inserts or updates several values in B{C{container}}.
2247
2248 @param name: I{(string)}
2249 @param value: I{(any)}
2250 """
2251 pass
2252
2254 """
2255 Inserts or updates several values in B{C{container}}.
2256
2257 @param key: I{(int)}
2258 @param value: I{(any)}
2259 """
2260 pass
2261
2262
2265 """
2266 Creates B{C{Curve}} widget. By default, the widget will have 3 curves.
2267
2268
2269 @return: new B{C{Curve}} widget. I{(L{gtk.Widget})}
2270 """
2271 return None
2272
2274 """
2275 Removes all control points, resetting the curves to their initial state.
2276
2277
2278 """
2279 pass
2280
2283
2286
2292 """
2293 Two-dimensional data representation
2294
2295
2296 B{C{DataField}} is an object that is used for representation of all
2297 two-dimensional data matrices. Most of the basic data handling and
2298 processing functions in Gwyddion are declared here as they are connected
2299 with B{C{DataField}}.
2300
2301 """
2302 - def __init__(xres, yres, xreal, yreal, nullme):
2303 """
2304 Creates a new data field.
2305
2306
2307 @param xres: X-resolution, i.e., the number of columns. I{(int)}
2308 @param yres: Y-resolution, i.e., the number of rows. I{(int)}
2309 @param xreal: Real horizontal physical dimension. I{(float)}
2310 @param yreal: Real vertical physical dimension. I{(float)}
2311 @param nullme: Whether the data field should be initialized to zeroes. If B{C{False}},
2312 the data will not be initialized. I{(bool)}
2313 @return: A newly created data field. I{(L{DataField})}
2314 """
2315 return None
2316
2318 """
2319 Sums two data fields.
2320
2321 @param operand1: First data field operand. I{(L{DataField})}
2322 @param operand2: Second data field operand. I{(L{DataField})}
2323 """
2324 pass
2325
2327 """
2328 Subtracts one data field from another.
2329
2330 @param operand1: First data field operand. I{(L{DataField})}
2331 @param operand2: Second data field operand. I{(L{DataField})}
2332 """
2333 pass
2334
2336 """
2337 Divides one data field with another.
2338
2339 @param operand1: First data field operand. I{(L{DataField})}
2340 @param operand2: Second data field operand. I{(L{DataField})}
2341 """
2342 pass
2343
2345 """
2346 Multiplies two data fields.
2347
2348 @param operand1: First data field operand. I{(L{DataField})}
2349 @param operand2: Second data field operand. I{(L{DataField})}
2350 """
2351 pass
2352
2354 """
2355 Finds point-wise maxima of two data fields.
2356
2357 @param operand1: First data field operand. I{(L{DataField})}
2358 @param operand2: Second data field operand. I{(L{DataField})}
2359 """
2360 pass
2361
2363 """
2364 Finds point-wise minima of two data fields.
2365
2366 @param operand1: First data field operand. I{(L{DataField})}
2367 @param operand2: Second data field operand. I{(L{DataField})}
2368 """
2369 pass
2370
2372 """
2373 Finds point-wise hypotenuse of two data fields.
2374
2375 @since: 2.31
2376
2377 @param operand1: First data field operand. I{(L{DataField})}
2378 @param operand2: Second data field operand. I{(L{DataField})}
2379 """
2380 pass
2381
2383 """
2384 Computes point-wise general linear combination of two data fields.
2385
2386 @since: 2.59
2387
2388 @param coeff1: Factor to multiply the first operand with. I{(float)}
2389 @param operand1: First data field operand. I{(L{DataField})}
2390 @param coeff2: Factor to multiply the second operand with. I{(float)}
2391 @param operand2: Second data field operand. I{(L{DataField})}
2392 @param constant: Constant term to add to the result. I{(float)}
2393 """
2394 pass
2395
2397 """
2398 Checks whether two data fields are compatible.
2399
2400
2401 @param data_field2: Another data field. I{(L{DataField})}
2402 @param check: The compatibility tests to perform. Expected values: C{B{DATA_COMPATIBILITY_RES}}, C{B{DATA_COMPATIBILITY_REAL}}, C{B{DATA_COMPATIBILITY_MEASURE}}, C{B{DATA_COMPATIBILITY_LATERAL}}, C{B{DATA_COMPATIBILITY_VALUE}}, C{B{DATA_COMPATIBILITY_AXISCAL}}, C{B{DATA_COMPATIBILITY_NCURVES}}, C{B{DATA_COMPATIBILITY_CURVELEN}}, C{B{DATA_COMPATIBILITY_ALL}}. I{(L{DataCompatibilityFlags})}
2403 @return: Zero if all tested properties are compatible. Flags corresponding to failed tests if data fields are not
2404 compatible. I{(DataCompatibilityFlags)}
2405 """
2406 return None
2407
2409 """
2410 Checks whether a data field is compatible with brick XY-planes.
2411
2412 @since: 2.51
2413
2414 @param brick: A three-dimensional data brick. I{(L{Brick})}
2415 @param check: The compatibility tests to perform. Expected values: C{B{DATA_COMPATIBILITY_RES}}, C{B{DATA_COMPATIBILITY_REAL}}, C{B{DATA_COMPATIBILITY_MEASURE}}, C{B{DATA_COMPATIBILITY_LATERAL}}, C{B{DATA_COMPATIBILITY_VALUE}}, C{B{DATA_COMPATIBILITY_AXISCAL}}, C{B{DATA_COMPATIBILITY_NCURVES}}, C{B{DATA_COMPATIBILITY_CURVELEN}}, C{B{DATA_COMPATIBILITY_ALL}}. I{(L{DataCompatibilityFlags})}
2416 @return: Zero if all tested properties are compatible. Flags corresponding to failed tests if the data objects are
2417 not compatible. I{(DataCompatibilityFlags)}
2418 """
2419 return None
2420
2423
2424 - def extend(left, right, up, down, exterior, fill_value, keep_offsets):
2425 """
2426 Creates a new data field by extending another data field using the specified method of exterior handling.
2427
2428 @since: 2.36
2429
2430 @param left: Number of pixels to extend to the left (towards lower column indices). I{(int)}
2431 @param right: Number of pixels to extend to the right (towards higher column indices). I{(int)}
2432 @param up: Number of pixels to extend up (towards lower row indices). I{(int)}
2433 @param down: Number of pixels to extend down (towards higher row indices). I{(int)}
2434 @param exterior: Exterior pixels handling. Expected values: C{B{EXTERIOR_UNDEFINED}}, C{B{EXTERIOR_BORDER_EXTEND}}, C{B{EXTERIOR_MIRROR_EXTEND}}, C{B{EXTERIOR_PERIODIC}}, C{B{EXTERIOR_FIXED_VALUE}}, C{B{EXTERIOR_LAPLACE}}. I{(L{ExteriorType})}
2435 @param fill_value: The value to use with B{C{EXTERIOR_FIXED_VALUE}} exterior. I{(float)}
2436 @param keep_offsets: B{C{True}} to set the X and Y offsets of the new field using B{C{field}} offsets. B{C{False}} to set offsets of
2437 the new field to zeroes. I{(bool)}
2438 @return: A newly created data field. I{(L{DataField})}
2439 """
2440 return None
2441
2443 """
2444 Replaces masked areas by the solution of Laplace equation.
2445
2446 The boundary conditions on mask boundaries are Dirichlet with values given
2447 by pixels on the outer boundary of the masked area. Boundary conditions at
2448 field edges are Neumann conditions ∂z/∂n=0 where n denotes the normal to the
2449 edge. If entire area of B{C{field}} is to be replaced the problem is
2450 underspecified; B{C{field}} will be filled with zeros.
2451
2452 For the default value of B{C{qprec}} the the result should be good enough for any
2453 image processing purposes with the typical local error of order 10⁻⁵ for
2454 very large grains and possibly much smaller for small grains. You can lower
2455 B{C{qprec}} down to about 0.3 or even 0.2 if speed is crucial and some precision
2456 can be sacrificed. Below that the result just starts becoming somewhat
2457 worse for not much speed increase. Conversely, you may wish to increase
2458 B{C{qprec}} up to 3 or even 5 if accuracy is important and you can afford the
2459 increased computation time.
2460
2461 @since: 2.47
2462
2463 @param mask: A two-dimensional data field containing mask defining the areas to
2464 interpolate. I{(L{DataField})}
2465 @param grain_id: The id number of the grain to replace with the solution of
2466 Laplace equation, from 1 to B{C{ngrains}} (see
2467 L{DataField.grain_numbers}()). Passing 0 means to replace the
2468 entire empty space outside grains while passing a negative value
2469 means to replace the entire masked area. I{(int)}
2470 @param qprec: Speed-accuracy tuning parameter. Pass 1.0 for the default that is
2471 fast and sufficiently precise. I{(float)}
2472 """
2473 pass
2474
2476 """
2477 Performs one interation of Laplace data correction.
2478
2479 Tries to remove all the points in mask off the data by using
2480 iterative method similar to solving heat flux equation.
2481
2482 Use this function repeatedly until reasonable B{C{error}} is reached.
2483
2484 @warning:For almost all purposes this function was superseded by
2485 non-iterative L{DataField.laplace_solve}() which is simultaneously much
2486 faster and more accurate.
2487
2488 @param mask_field: Mask of places to be corrected. I{(L{DataField})}
2489 @param buffer_field: Initialized to same size as mask and data. I{(L{DataField})}
2490 @param corrfactor: Correction factor within step. I{(float)}
2491 @return: Value B{C{error}}. (I{(float)})
2492 """
2493 return None
2494
2496 """
2497 Fills data under mask with the average value.
2498
2499 This function simply puts average value of all the B{C{data_field}} values (both
2500 masked and unmasked) into points in B{C{data_field}} lying under points where
2501 B{C{mask_field}} values are nonzero.
2502
2503 In most cases you probably want to use
2504 L{DataField.correct_average_unmasked}() instead.
2505
2506 @param mask_field: Mask of places to be corrected. I{(L{DataField})}
2507 """
2508 pass
2509
2511 """
2512 Fills data under mask with the average value of unmasked data.
2513
2514 This function calculates the average value of all unmasked pixels in
2515 B{C{data_field}} and then fills all the masked pixels with this average value.
2516 It is useful as the first rough step of correction of data under the mask.
2517
2518 If all data are masked the field is filled with zeroes.
2519
2520 @since: 2.44
2521
2522 @param mask_field: Mask of places to be corrected. I{(L{DataField})}
2523 """
2524 pass
2525
2527 """
2528 Creates mask of data that are above or below B{C{thresh}}*sigma from average
2529 height.
2530
2531 Sigma denotes root-mean square deviation of heights. This criterium
2532 corresponds to the usual Gaussian distribution outliers detection if
2533 B{C{thresh}} is 3.
2534
2535 @param mask_field: A data field to be filled with mask. I{(L{DataField})}
2536 @param thresh: Threshold value. I{(float)}
2537 """
2538 pass
2539
2541 """
2542 Creates mask of data that are above or below multiples of rms from average
2543 height.
2544
2545 Data that are below B{C{mean}}-B{C{thresh_low}}*B{C{sigma}} or above
2546 B{C{mean}}+B{C{thresh_high}}*B{C{sigma}} are marked as outliers, where B{C{sigma}} denotes the
2547 root-mean square deviation of heights.
2548
2549 @since: 2.26
2550
2551 @param mask_field: A data field to be filled with mask. I{(L{DataField})}
2552 @param thresh_low: Lower threshold value. I{(float)}
2553 @param thresh_high: Upper threshold value. I{(float)}
2554 """
2555 pass
2556
2557 - def distort(dest, invtrans, user_data, interp, exterior, fill_value):
2558 """
2559 Distorts a data field in the horizontal plane.
2560
2561 Note the transform function B{C{invtrans}} is the inverse transform, in other
2562 words it calculates the old coordinates from the new coordinates (the
2563 transform would not be uniquely defined the other way round).
2564
2565 The B{C{EXTERIOR_LAPLACE}} exterior type cannot be used with this function.
2566
2567 @since: 2.5
2568
2569 @param dest: Destination data field. I{(L{DataField})}
2570 @param invtrans: Inverse transform function, that is the transformation from
2571 new coordinates to old coordinates. It gets
2572 (B{C{j}}+0.5, B{C{i}}+0.5), where B{C{i}} and B{C{j}} are the new row and column
2573 indices, passed as the input coordinates. The output coordinates
2574 should follow the same convention. Unless a special exterior
2575 handling is required, the transform function does not need to
2576 concern itself with coordinates being outside of the data. I{(CoordTransform2DFunc)}
2577 @param user_data: Pointer passed as B{C{user_data}} to B{C{invtrans}}. I{(gpointer)}
2578 @param interp: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
2579 @param exterior: Exterior pixels handling. Expected values: C{B{EXTERIOR_UNDEFINED}}, C{B{EXTERIOR_BORDER_EXTEND}}, C{B{EXTERIOR_MIRROR_EXTEND}}, C{B{EXTERIOR_PERIODIC}}, C{B{EXTERIOR_FIXED_VALUE}}, C{B{EXTERIOR_LAPLACE}}. I{(L{ExteriorType})}
2580 @param fill_value: The value to use with B{C{EXTERIOR_FIXED_VALUE}}. I{(float)}
2581 """
2582 pass
2583
2585 """
2586 Resamples a data field in an arbitrarily distorted manner.
2587
2588 Each item in B{C{coords}} corresponds to one pixel in B{C{dest}} and gives the
2589 coordinates in B{C{source}} defining the value to set in this pixel.
2590
2591 The B{C{EXTERIOR_LAPLACE}} exterior type cannot be used with this function.
2592
2593 @since: 2.45
2594
2595 @param dest: Destination data field. I{(L{DataField})}
2596 @param coords: Array of B{C{source}} coordinates with the same number of items as
2597 B{C{dest}}, ordered as data field data.
2598 See L{DataField.distort}() for coordinate convention discussion. I{(const-XY*)}
2599 @param interp: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
2600 @param exterior: Exterior pixels handling. Expected values: C{B{EXTERIOR_UNDEFINED}}, C{B{EXTERIOR_BORDER_EXTEND}}, C{B{EXTERIOR_MIRROR_EXTEND}}, C{B{EXTERIOR_PERIODIC}}, C{B{EXTERIOR_FIXED_VALUE}}, C{B{EXTERIOR_LAPLACE}}. I{(L{ExteriorType})}
2601 @param fill_value: The value to use with B{C{EXTERIOR_FIXED_VALUE}}. I{(float)}
2602 """
2603 pass
2604
2605 - def mark_scars(result, threshold_high, threshold_low, min_scar_len, max_scar_width, negative):
2606 """
2607 Find and marks scars in a data field.
2608
2609 Scars are linear horizontal defects, consisting of shifted values.
2610 Zero or negative values in B{C{result}} siginify normal data, positive
2611 values siginify samples that are part of a scar.
2612
2613 @since: 2.46
2614
2615 @param result: A data field to store the result to (it is resized to match
2616 B{C{data_field}}). I{(L{DataField})}
2617 @param threshold_high: Miminum relative step for scar marking, must be positive. I{(float)}
2618 @param threshold_low: Definite relative step for scar marking, must be at least
2619 equal to B{C{threshold_high}}. I{(float)}
2620 @param min_scar_len: Minimum length of a scar, shorter ones are discarded
2621 (must be at least one). I{(float)}
2622 @param max_scar_width: Maximum width of a scar, must be at least one. I{(float)}
2623 @param negative: B{C{True}} to detect negative scars, B{C{False}} to positive. I{(bool)}
2624 """
2625 pass
2626
2628 """
2629 Shifts entire data field rows as specified by given data line.
2630
2631 Data line B{C{shifts}} must have resolution corresponding to the number of
2632 B{C{data_field}} rows. Its values are subtracted from individual field rows.
2633
2634 @since: 2.52
2635
2636 @param shifts: Data line containing the row shifts. I{(L{DataLine})}
2637 """
2638 pass
2639
2641 """
2642 Finds row shifts to misaligned row correction using trimmed row means.
2643
2644 For zero B{C{trimfrac}} the function calculates row means. For B{C{trimfrac}} of 1/2
2645 or larger it calculates row medians. Values between correspond to trimmed
2646 means.
2647
2648 @since: 2.52
2649
2650 @param mask: Mask of values to take values into account/exclude, or B{C{None}} for full
2651 B{C{data_field}}. I{(L{DataField})}
2652 @param masking: Masking mode to use. See the introduction for description of
2653 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
2654 @param trimfrac: Fraction of lowest values and highest values to discard when
2655 trimming. I{(float)}
2656 @param mincount: Minimum number of values in a row necessary for per-row
2657 calculation. Rows which are essentially completely masked are
2658 not shifted with respect to a global value. Pass a non-positive
2659 number to use an automatic minimum count. I{(int)}
2660 @return: A newly created data line containing the row shifts, for instance
2661 row means, medians or trimmed means. I{(L{DataLine})}
2662 """
2663 return None
2664
2666 """
2667 Finds row shifts to misaligned row correction using trimmed means of row
2668 differences.
2669
2670 For zero B{C{trimfrac}} the function calculates row means. For B{C{trimfrac}} of 1/2
2671 or larger it calculates row medians. Values between correspond to trimmed
2672 means.
2673
2674 @since: 2.52
2675
2676 @param mask: Mask of values to take values into account/exclude, or B{C{None}} for full
2677 B{C{data_field}}. I{(L{DataField})}
2678 @param masking: Masking mode to use. See the introduction for description of
2679 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
2680 @param trimfrac: Fraction of lowest values and highest values to discard when
2681 trimming. I{(float)}
2682 @param mincount: Minimum number of values in a row necessary for per-row
2683 calculation. Rows which are essentially completely masked are
2684 not shifted with respect to a global value. Pass a non-positive
2685 number to use an automatic minimum count. I{(int)}
2686 @return: A newly created data line containing the row shifts, for instance
2687 row means, medians or trimmed means. I{(L{DataLine})}
2688 """
2689 return None
2690
2691 - def get_correlation_score(kernel_field, col, row, kernel_col, kernel_row, kernel_width, kernel_height):
2692 """
2693 Calculates a correlation score in one point.
2694
2695 Correlation window size is given by B{C{kernel_col}}, B{C{kernel_row}}, B{C{kernel_width}}, B{C{kernel_height}}, postion of the
2696 correlation window on data is given by B{C{col}}, B{C{row}}.
2697
2698 If anything fails (data too close to boundary, etc.), function returns -1.0 (none correlation)..
2699
2700
2701 @param kernel_field: Kernel to correlate data field with. I{(L{DataField})}
2702 @param col: Upper-left column position in the data field. I{(int)}
2703 @param row: Upper-left row position in the data field. I{(int)}
2704 @param kernel_col: Upper-left column position in kernel field. I{(int)}
2705 @param kernel_row: Upper-left row position in kernel field. I{(int)}
2706 @param kernel_width: Width of kernel field area. I{(int)}
2707 @param kernel_height: Heigh of kernel field area. I{(int)}
2708 @return: Correlation score (between -1.0 and 1.0). Value 1.0 denotes maximum correlation, -1.0 none correlation. I{(float)}
2709 """
2710 return None
2711
2713 """
2714 Calculates a correlation score in one point using weights to center the used information to the center of kernel.
2715
2716 Correlation window size is given by B{C{kernel_col}}, B{C{kernel_row}}, B{C{kernel_width}}, B{C{kernel_height}}, postion of the
2717 correlation window on data is given by B{C{col}}, B{C{row}}.
2718
2719 If anything fails (data too close to boundary, etc.), function returns -1.0 (none correlation)..
2720
2721
2722 @param kernel_field: Kernel to correlate data field with. I{(L{DataField})}
2723 @param weight_field: data field of same size as kernel window size I{(L{DataField})}
2724 @param col: Upper-left column position in the data field. I{(int)}
2725 @param row: Upper-left row position in the data field. I{(int)}
2726 @param kernel_col: Upper-left column position in kernel field. I{(int)}
2727 @param kernel_row: Upper-left row position in kernel field. I{(int)}
2728 @param kernel_width: Width of kernel field area. I{(int)}
2729 @param kernel_height: Heigh of kernel field area. I{(int)}
2730 @return: Correlation score (between -1.0 and 1.0). Value 1.0 denotes maximum correlation, -1.0 none correlation. I{(float)}
2731 """
2732 return None
2733
2734 - def crosscorrelate(data_field2, x_dist, y_dist, score, search_width, search_height, window_width, window_height):
2735 """
2736 Algorithm for matching two different images of the same object under changes.
2737
2738 It does not use any special features for matching. It simply searches for all points (with their neighbourhood) of
2739 B{C{data_field1}} within B{C{data_field2}}. Parameters B{C{search_width}} and B{C{search_height}} determine maimum area where to search
2740 for points. The area is cenetered in the B{C{data_field2}} at former position of points at B{C{data_field1}}.
2741
2742 @param data_field2: A data field. I{(L{DataField})}
2743 @param x_dist: A data field to store x-distances to. I{(L{DataField})}
2744 @param y_dist: A data field to store y-distances to. I{(L{DataField})}
2745 @param score: Data field to store correlation scores to. I{(L{DataField})}
2746 @param search_width: Search area width. I{(int)}
2747 @param search_height: Search area height. I{(int)}
2748 @param window_width: Correlation window width. This parameter is not actually used. Pass zero. I{(int)}
2749 @param window_height: Correlation window height. This parameter is not actually used. Pass zero. I{(int)}
2750 """
2751 pass
2752
2753 - def crosscorrelate_init(data_field2, x_dist, y_dist, score, search_width, search_height, window_width, window_height):
2754 """
2755 Initializes a cross-correlation iterator.
2756
2757 This iterator reports its state as B{C{ComputationStateType}}.
2758
2759
2760 @param data_field2: A data field. I{(L{DataField})}
2761 @param x_dist: A data field to store x-distances to, or B{C{None}}. I{(L{DataField})}
2762 @param y_dist: A data field to store y-distances to, or B{C{None}}. I{(L{DataField})}
2763 @param score: Data field to store correlation scores to, or B{C{None}}. I{(L{DataField})}
2764 @param search_width: Search area width. I{(int)}
2765 @param search_height: Search area height. I{(int)}
2766 @param window_width: Correlation window width. I{(int)}
2767 @param window_height: Correlation window height. I{(int)}
2768 @return: A new cross-correlation iterator. I{(ComputationState*)}
2769 """
2770 return None
2771
2772 - def correlate(kernel_field, score, method):
2773 """
2774 Computes correlation score for all positions in a data field.
2775
2776 Correlation score is compute for all points in data field B{C{data_field}} and full size of correlation kernel
2777 B{C{kernel_field}}.
2778
2779 The points in B{C{score}} correspond to centers of kernel. More precisely, the point ((B{C{kxres}}-1)/2, (B{C{kyres}}-1)/2) in
2780 B{C{score}} corresponds to kernel field top left corner coincident with data field top left corner. Points outside the
2781 area where the kernel field fits into the data field completely are set to -1 for B{C{CORRELATION_NORMAL}}.
2782
2783 This function is mostly made obsolete by L{DataField.correlation_search}() which offers, beside the plain
2784 FFT-based correlation, a method equivalent to B{C{CORRELATION_NORMAL}} as well as several others, all computed
2785 efficiently using FFT.
2786
2787 @param kernel_field: Correlation kernel. I{(L{DataField})}
2788 @param score: Data field to store correlation scores to. I{(L{DataField})}
2789 @param method: Correlation score calculation method. Expected values: C{B{CORRELATION_NORMAL}}, C{B{CORRELATION_FFT}}, C{B{CORRELATION_POC}}. I{(L{CorrelationType})}
2790 """
2791 pass
2792
2794 """
2795 Creates a new correlation iterator.
2796
2797 This iterator reports its state as B{C{ComputationStateType}}.
2798
2799 This function is mostly made obsolete by L{DataField.correlation_search}() which offers, beside the plain
2800 FFT-based correlation, a method equivalent to B{C{CORRELATION_NORMAL}} as well as several others, all computed
2801 efficiently using FFT.
2802
2803
2804 @param kernel_field: Kernel to correlate data field with. I{(L{DataField})}
2805 @param score: Data field to store correlation scores to. I{(L{DataField})}
2806 @return: A new correlation iterator. I{(ComputationState*)}
2807 """
2808 return None
2809
2810 - def correlation_search(kernel, kernel_weight, target, method, regcoeff, exterior, fill_value):
2811 """
2812 Performs correlation search of a detail in a larger data field.
2813
2814 There are two basic classes of methods: Covariance (products of kernel and data values are summed) and height
2815 difference (squared differences between kernel and data values are summed). For the second class, the sign of the
2816 output is inverted. So in both cases higher values mean better match. All methods are implemented efficiently
2817 using FFT.
2818
2819 Usually you want to use B{C{CORR_SEARCH_COVARIANCE}} or B{C{CORR_SEARCH_HEIGHT_DIFF}}, in which the absolute data
2820 offsets play no role (only the differences).
2821
2822 If the detail can also occur with different height scales, use B{C{CORR_SEARCH_COVARIANCE_SCORE}} or
2823 B{C{CORR_SEARCH_HEIGHT_DIFF_SCORE}} in which the local data variance is normalised. In this case B{C{dfield}} regions
2824 with very small (or zero) variance can lead to odd results and spurious maxima. Use B{C{regcoeff}} to suppress them:
2825 Score of image details is suppressed if their variance is B{C{regcoeff}} times the mean local variance.
2826
2827 If B{C{kernel_weight}} is non-B{C{None}} is allows specify masking/weighting of kernel. The simplest use is masking when
2828 searching for a non-rectangular detail. Fill B{C{kernel_weight}} with 1s for important kernel pixels and with 0s for
2829 irrelevant pixels. However, you can use arbitrary non-negative weights.
2830
2831 @since: 2.50
2832
2833 @param kernel: Detail to find (kernel). I{(L{DataField})}
2834 @param kernel_weight: Kernel weight, or B{C{None}}. If given, its dimensions must match B{C{kernel}}. I{(L{DataField})}
2835 @param target: Data field to fill with the score. It will be resampled to match B{C{dfield}}. I{(L{DataField})}
2836 @param method: Method, determining the type of output to put into B{C{target}}. Expected values: C{B{CORR_SEARCH_COVARIANCE_RAW}}, C{B{CORR_SEARCH_COVARIANCE}}, C{B{CORR_SEARCH_COVARIANCE_SCORE}}, C{B{CORR_SEARCH_HEIGHT_DIFF_RAW}}, C{B{CORR_SEARCH_HEIGHT_DIFF}}, C{B{CORR_SEARCH_HEIGHT_DIFF_SCORE}}. I{(L{CorrSearchType})}
2837 @param regcoeff: Regularisation coefficient, any positive number. Pass something like 0.1 if unsure. You can also pass
2838 zero, it means the same as B{C{glib.MINDOUBLE}}. I{(float)}
2839 @param exterior: Exterior pixels handling. Expected values: C{B{EXTERIOR_UNDEFINED}}, C{B{EXTERIOR_BORDER_EXTEND}}, C{B{EXTERIOR_MIRROR_EXTEND}}, C{B{EXTERIOR_PERIODIC}}, C{B{EXTERIOR_FIXED_VALUE}}, C{B{EXTERIOR_LAPLACE}}. I{(L{ExteriorType})}
2840 @param fill_value: The value to use with B{C{EXTERIOR_FIXED_VALUE}} exterior. I{(float)}
2841 """
2842 pass
2843
2845 """
2846 Invalidates cached data field stats.
2847
2848 User code should rarely need this macro, as all B{C{DataField}} methods do
2849 proper invalidation when they change data, as well as
2850 L{DataField.get_data}() does.
2851
2852 However, if you get raw data with L{DataField.get_data}() and then mix
2853 direct changes to it with calls to methods like L{DataField.get_max}(),
2854 you may need to explicitely invalidate cached values to let
2855 L{DataField.get_max}() know it has to recompute the maximum.
2856
2857 """
2858 pass
2859
2861 """
2862 Creates a new data field similar to an existing one.
2863
2864 Use L{DataField.duplicate}() if you want to copy a data field including
2865 data.
2866
2867
2868 @param nullme: Whether the data field should be initialized to zeroes. If B{C{False}},
2869 the data will not be initialized. I{(bool)}
2870 @return: A newly created data field. I{(L{DataField})}
2871 """
2872 return None
2873
2875 """
2876 Emits signal "data-changed" on a data field.
2877
2878 """
2879 pass
2880
2882 """
2883 Creates a new data field by resampling an existing one.
2884
2885 This method is equivalent to L{DataField.duplicate}() followed by
2886 L{DataField.resample}(), but it is more efficient.
2887
2888
2889 @param xres: Desired X resolution. I{(int)}
2890 @param yres: Desired Y resolution. I{(int)}
2891 @param interpolation: Interpolation method to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
2892 @return: A newly created data field. I{(L{DataField})}
2893 """
2894 return None
2895
2896 - def resample(xres, yres, interpolation):
2897 """
2898 Resamples a data field using given interpolation method
2899
2900 This method may invalidate raw data buffer returned by
2901 L{DataField.get_data}().
2902
2903 @param xres: Desired X resolution. I{(int)}
2904 @param yres: Desired Y resolution. I{(int)}
2905 @param interpolation: Interpolation method to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
2906 """
2907 pass
2908
2909 - def bin(target, binw, binh, xoff, yoff, trimlowest, trimhighest):
2910 """
2911 Bins a data field into another data field.
2912
2913 See L{DataField.new_binned}() for a detailed description.
2914
2915 @since: 2.55
2916
2917 @param target: Target data field. It will be resized as necessary. I{(L{DataField})}
2918 @param binw: Bin height (in pixels). I{(int)}
2919 @param binh: Bin width (in pixels). I{(int)}
2920 @param xoff: Horizontal offset of bins (in pixels). I{(int)}
2921 @param yoff: Vertical offset of bins (in pixels). I{(int)}
2922 @param trimlowest: Number of lowest values to discard. I{(int)}
2923 @param trimhighest: Number of highest values to discard. I{(int)}
2924 """
2925 pass
2926
2927 - def new_binned(binw, binh, xoff, yoff, trimlowest, trimhighest):
2928 """
2929 Creates a new data field by binning an existing one.
2930
2931 The data field is divided into rectangles of dimensions B{C{binw}}×B{C{binh}}, offset
2932 by (B{C{xoff}}, B{C{yoff}}). The values in each complete rectangle are averaged and
2933 the average becomes the pixel value in the newly created, smaller data
2934 field.
2935
2936 Note that the result is the average – not sum – of the individual values.
2937 Multiply the returned data field with B{C{binw}}×B{C{binh}} if you want sum.
2938
2939 By giving non-zero B{C{trimlowest}} and B{C{trimhighest}} you can change the plain
2940 average to a trimmed one (even turning it to median in the extreme case).
2941 It must always hold that B{C{trimlowest}} + B{C{trimhighest}} is smaller than
2942 B{C{binw}}×B{C{binh}}.
2943
2944 @since: 2.50
2945
2946 @param binw: Bin height (in pixels). I{(int)}
2947 @param binh: Bin width (in pixels). I{(int)}
2948 @param xoff: Horizontal offset of bins (in pixels). I{(int)}
2949 @param yoff: Vertical offset of bins (in pixels). I{(int)}
2950 @param trimlowest: Number of lowest values to discard. I{(int)}
2951 @param trimhighest: Number of highest values to discard. I{(int)}
2952 @return: A newly created data field. I{(L{DataField})}
2953 """
2954 return None
2955
2956 - def resize(ulcol, ulrow, brcol, brrow):
2957 """
2958 Resizes (crops) a data field.
2959
2960 Crops a data field to a rectangle between upper-left and bottom-right
2961 points, recomputing real size.
2962
2963 This method may invalidate raw data buffer returned by
2964 L{DataField.get_data}().
2965
2966 @param ulcol: Upper-left column coordinate. I{(int)}
2967 @param ulrow: Upper-left row coordinate. I{(int)}
2968 @param brcol: Bottom-right column coordinate + 1. I{(int)}
2969 @param brrow: Bottom-right row coordinate + 1. I{(int)}
2970 """
2971 pass
2972
2974 """
2975 Extracts a rectangular part of a data field to a new data field.
2976
2977
2978 @param col: Upper-left column coordinate. I{(int)}
2979 @param row: Upper-left row coordinate. I{(int)}
2980 @param width: Area width (number of columns). I{(int)}
2981 @param height: Area height (number of rows). I{(int)}
2982 @return: The extracted area as a newly created data field. I{(L{DataField})}
2983 """
2984 return None
2985
2986 - def copy(dest, nondata_too):
2987 """
2988 Copies the contents of an already allocated data field to a data field
2989 of the same size.
2990
2991 @param dest: Destination data field. I{(L{DataField})}
2992 @param nondata_too: Whether non-data (units) should be copied too. I{(bool)}
2993 """
2994 pass
2995
2996 - def area_copy(dest, col, row, width, height, destcol, destrow):
2997 """
2998 Copies a rectangular area from one data field to another.
2999
3000 The area starts at (B{C{col}}, B{C{row}}) in B{C{src}} and its dimension is B{C{width}}*B{C{height}}.
3001 It is copied to B{C{dest}} starting from (B{C{destcol}}, B{C{destrow}}).
3002
3003 The source area has to be completely contained in B{C{src}}. No assumptions are
3004 made about destination position, however, parts of the source area sticking
3005 out the destination data field B{C{dest}} are cut off.
3006
3007 If B{C{src}} is equal to B{C{dest}}, the areas may not overlap.
3008
3009 @param dest: Destination data field. I{(L{DataField})}
3010 @param col: Area upper-left column coordinate in B{C{src}}. I{(int)}
3011 @param row: Area upper-left row coordinate B{C{src}}. I{(int)}
3012 @param width: Area width (number of columns), pass -1 for full B{C{src}} widdth. I{(int)}
3013 @param height: Area height (number of rows), pass -1 for full B{C{src}} height. I{(int)}
3014 @param destcol: Destination column in B{C{dest}}. I{(int)}
3015 @param destrow: Destination row in B{C{dest}}. I{(int)}
3016 """
3017 pass
3018
3020 """
3021 Gets X resolution (number of columns) of a data field.
3022
3023
3024 @return: X resolution. I{(int)}
3025 """
3026 return None
3027
3029 """
3030 Gets Y resolution (number of rows) of the field.
3031
3032
3033 @return: Y resolution. I{(int)}
3034 """
3035 return None
3036
3038 """
3039 Gets the X real (physical) size of a data field.
3040
3041
3042 @return: X real size value. I{(float)}
3043 """
3044 return None
3045
3047 """
3048 Gets the Y real (physical) size of a data field.
3049
3050
3051 @return: Y real size value. I{(float)}
3052 """
3053 return None
3054
3056 """
3057 Sets X real (physical) size value of a data field.
3058
3059 @param xreal: New X real size value. I{(float)}
3060 """
3061 pass
3062
3064 """
3065 Sets Y real (physical) size value of a data field.
3066
3067 @param yreal: New Y real size value. I{(float)}
3068 """
3069 pass
3070
3072 """
3073 Gets the horizontal pixel size of a data field in real units.
3074
3075 The result is the same as
3076 L{DataField.get_xreal}(data_field)/L{DataField.get_xres}(data_field).
3077
3078 @since: 2.52
3079
3080 @return: Horizontal pixel size. I{(float)}
3081 """
3082 return None
3083
3085 """
3086 Gets the vertical pixel size of a data field in real units.
3087
3088 The result is the same as
3089 L{DataField.get_yreal}(data_field)/L{DataField.get_yres}(data_field).
3090
3091 @since: 2.52
3092
3093 @return: Vertical pixel size. I{(float)}
3094 """
3095 return None
3096
3098 """
3099 Gets the X offset of data field origin.
3100
3101
3102 @return: X offset value. I{(float)}
3103 """
3104 return None
3105
3107 """
3108 Gets the Y offset of data field origin.
3109
3110
3111 @return: Y offset value. I{(float)}
3112 """
3113 return None
3114
3116 """
3117 Sets the X offset of a data field origin.
3118
3119 Note offsets don't affect any calculation, nor functions like
3120 L{DataField.rtoj}().
3121
3122 @param xoff: New X offset value. I{(float)}
3123 """
3124 pass
3125
3127 """
3128 Sets the Y offset of a data field origin.
3129
3130 Note offsets don't affect any calculation, nor functions like
3131 L{DataField.rtoi}().
3132
3133 @param yoff: New Y offset value. I{(float)}
3134 """
3135 pass
3136
3138 """
3139 Returns lateral SI unit of a data field.
3140
3141
3142 @return: SI unit corresponding to the lateral (XY) dimensions of the data
3143 field. Its reference count is not incremented. I{(L{SIUnit})}
3144 """
3145 return None
3146
3148 """
3149 Returns value SI unit of a data field.
3150
3151
3152 @return: SI unit corresponding to the "height" (Z) dimension of the data
3153 field. Its reference count is not incremented. I{(L{SIUnit})}
3154 """
3155 return None
3156
3158 """
3159 Sets the SI unit corresponding to the lateral (XY) dimensions of a data
3160 field.
3161
3162 It does not assume a reference on B{C{si_unit}}, instead it adds its own
3163 reference.
3164
3165 @param si_unit: SI unit to be set. I{(L{SIUnit})}
3166 """
3167 pass
3168
3170 """
3171 Sets the SI unit corresponding to the "height" (Z) dimension of a data
3172 field.
3173
3174 It does not assume a reference on B{C{si_unit}}, instead it adds its own
3175 reference.
3176
3177 @param si_unit: SI unit to be set. I{(L{SIUnit})}
3178 """
3179 pass
3180
3190
3200
3202 """
3203 Sets lateral and value units of a data field to match another data field.
3204
3205 @since: 2.49
3206
3207 @param target: Target data field. I{(L{DataField})}
3208 """
3209 pass
3210
3212 """
3213 Sets lateral and value units of a data line to match a data field.
3214
3215 @param data_line: A data line to set units of. I{(L{DataLine})}
3216 """
3217 pass
3218
3220 """
3221 Transforms vertical pixel coordinate to real (physical) Y coordinate.
3222
3223 That is it maps range [0..y-resolution] to range [0..real-y-size].
3224 It is not suitable for conversion of matrix indices to physical coordinates,
3225 you have to use L{DataField.itor}(B{C{data_field}}, B{C{row}} + 0.5) for that.
3226
3227
3228 @param row: Vertical pixel coordinate. I{(float)}
3229 @return: Real Y coordinate. I{(float)}
3230 """
3231 return None
3232
3234 """
3235 Transforms horizontal pixel coordinate to real (physical) X coordinate.
3236
3237 That is it maps range [0..x-resolution] to range [0..real-x-size].
3238 It is not suitable for conversion of matrix indices to physical coordinates,
3239 you have to use L{DataField.jtor}(B{C{data_field}}, B{C{col}} + 0.5) for that.
3240
3241
3242 @param col: Horizontal pixel coordinate. I{(float)}
3243 @return: Real X coordinate. I{(float)}
3244 """
3245 return None
3246
3248 """
3249 Transforms real (physical) Y coordinate to row.
3250
3251 That is it maps range [0..real-y-size] to range [0..y-resolution].
3252
3253
3254 @param realy: Real (physical) Y coordinate. I{(float)}
3255 @return: Vertical pixel coodinate. I{(float)}
3256 """
3257 return None
3258
3260 """
3261 Transforms real (physical) X coordinate to column.
3262
3263 That is it maps range [0..real-x-size] to range [0..x-resolution].
3264
3265
3266 @param realx: Real (physical) X coodinate. I{(float)}
3267 @return: Horizontal pixel coordinate. I{(float)}
3268 """
3269 return None
3270
3272 """
3273 Gets value at given position in a data field.
3274
3275 Do not access data with this function inside inner loops, it's slow.
3276 Get the raw data buffer with L{DataField.get_data_const}() and access it
3277 directly instead.
3278
3279
3280 @param col: Column index. I{(int)}
3281 @param row: Row index. I{(int)}
3282 @return: Value at (B{C{col}}, B{C{row}}). I{(float)}
3283 """
3284 return None
3285
3287 """
3288 Sets value at given position in a data field.
3289
3290 Do not set data with this function inside inner loops, it's slow. Get the
3291 raw data buffer with L{DataField.get_data}() and write to it directly
3292 instead.
3293
3294 @param col: Column index. I{(int)}
3295 @param row: Row index. I{(int)}
3296 @param value: Value to set. I{(float)}
3297 """
3298 pass
3299
3301 """
3302 Gets interpolated value at arbitrary data field point indexed by pixel
3303 coordinates.
3304
3305 Note pixel values are centered in pixels, so to get the same
3306 value as L{DataField.get_val}(B{C{data_field}}, B{C{j}}, B{C{i}}) returns,
3307 it's necessary to add 0.5:
3308 L{DataField.get_dval}(B{C{data_field}}, B{C{j}}+0.5, B{C{i}}+0.5, B{C{interpolation}}).
3309
3310 See also L{DataField.get_dval_real}() that does the same, but takes
3311 real coordinates.
3312
3313
3314 @param x: Horizontal position in pixel units, in range [0, x-resolution]. I{(float)}
3315 @param y: Vertical postition in pixel units, in range [0, y-resolution]. I{(float)}
3316 @param interpolation: Interpolation method to be used. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
3317 @return: Interpolated value at position (B{C{x}},B{C{y}}). I{(float)}
3318 """
3319 return None
3320
3322 """
3323 Gets interpolated value at arbitrary data field point indexed by real
3324 coordinates.
3325
3326 See also L{DataField.get_dval}() that does the same, but takes pixel
3327 coordinates.
3328
3329
3330 @param x: X postion in real coordinates. I{(float)}
3331 @param y: Y postition in real coordinates. I{(float)}
3332 @param interpolation: Interpolation method to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
3333 @return: Value at position (B{C{x}},B{C{y}}). I{(float)}
3334 """
3335 return None
3336
3337 - def rotate(angle, interpolation):
3338 """
3339 Rotates a data field by a given angle.
3340
3341 This function is mostly obsolete. See L{DataField.new_rotated}()
3342 and L{DataField.new_rotated_90}().
3343
3344 Values that get outside of data field by the rotation are lost.
3345 Undefined values from outside of data field that get inside are set to
3346 data field minimum value.
3347
3348 The rotation is performed in pixel space, i.e. it can be in fact a more
3349 general affine transform in the real coordinates when pixels are not square.
3350
3351 @param angle: Rotation angle (in radians). I{(float)}
3352 @param interpolation: Interpolation method to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
3353 """
3354 pass
3355
3356 - def new_rotated(exterior_mask, angle, interp, resize):
3357 """
3358 Creates a new data field by rotating a data field by an atribtrary angle.
3359
3360 The returned data field can have pixel corresponding to exterior in B{C{dfield}}
3361 (unless B{C{resize}} is B{C{ROTATE_RESIZE_CUT}}). They are filled with a neutral
3362 value; pass B{C{exterior_mask}} and replace them as you wish if you need more
3363 control.
3364
3365 The rotation is performed in real space, i.e. it is a more general affine
3366 transform in the pixel space for data field with non-square pixels.
3367 See L{DataField.rotate}() which rotates in the pixel space.
3368
3369 The returned data field has always square pixels. If you want to rotate
3370 by a multiple of B{C{glib.PI}}/2 while preserving non-square pixels, you must use
3371 explicitly a function such as L{DataField.new_rotated_90}().
3372
3373 @since: 2.46
3374
3375 @param exterior_mask: Optional data field where pixels corresponding to exterior
3376 will be set to 1. It will be resized to match the returned
3377 field. I{(L{DataField})}
3378 @param angle: Rotation angle (in radians). I{(float)}
3379 @param interp: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
3380 @param resize: Controls how the result size is determined. Expected values: C{B{ROTATE_RESIZE_SAME_SIZE}}, C{B{ROTATE_RESIZE_EXPAND}}, C{B{ROTATE_RESIZE_CUT}}. I{(L{RotateResizeType})}
3381 @return: A newly created data field. I{(L{DataField})}
3382 """
3383 return None
3384
3386 """
3387 Creates a new data field by rotating a data field by 90 degrees.
3388
3389 @since: 2.46
3390
3391 @param clockwise: B{C{True}} to rotate clocwise, B{C{False}} to rotate anti-clockwise. I{(bool)}
3392 @return: A newly created data field. I{(L{DataField})}
3393 """
3394 return None
3395
3397 """
3398 Reflects and/or inverts a data field.
3399
3400 In the case of value reflection, it's inverted about the mean value.
3401
3402 Note that the axis parameter convention is confusing and different from
3403 L{Brick.invert}() and L{DataLine.invert}(). Parameters B{C{x}} an B{C{y}}
3404 correspond the axes around which to flip (which themselves stay unchanged).
3405 You may need to swap B{C{x}} and B{C{y}} arguments compared what you would pass
3406 naturally.
3407
3408 @param x: B{C{True}} to reflect Y, i.e. rows within the XY plane. I{(bool)}
3409 @param y: B{C{True}} to reflect X, i.e. columns within the XY plane. I{(bool)}
3410 @param z: B{C{True}} to invert values. I{(bool)}
3411 """
3412 pass
3413
3415 """
3416 Copies data from one data field to another with transposition.
3417
3418 The destination data field is resized as necessary, its real dimensions set
3419 to transposed B{C{src}} dimensions and its offsets are reset. Units are not
3420 updated.
3421
3422 @since: 2.49
3423
3424 @param dest: Destination data field. I{(L{DataField})}
3425 @param minor: B{C{True}} to mirror about the minor diagonal; B{C{False}} to mirror about
3426 major diagonal. I{(bool)}
3427 """
3428 pass
3429
3431 """
3432 Copies data from a rectangular part of one data field to another with
3433 transposition.
3434
3435 The destination data field is resized as necessary, its real dimensions set
3436 to transposed B{C{src}} area dimensions and its offsets are reset. Units are not
3437 updated.
3438
3439 @since: 2.49
3440
3441 @param col: Upper-left column coordinate in B{C{src}}. I{(int)}
3442 @param row: Upper-left row coordinate in B{C{src}}. I{(int)}
3443 @param width: Area width (number of columns) in B{C{src}}. I{(int)}
3444 @param height: Area height (number of rows) in B{C{src}}. I{(int)}
3445 @param dest: Destination data field. I{(L{DataField})}
3446 @param minor: B{C{True}} to mirror about the minor diagonal; B{C{False}} to mirror about
3447 major diagonal. I{(bool)}
3448 """
3449 pass
3450
3452 """
3453 Fills a data field with given value.
3454
3455 @param value: Value to be entered. I{(float)}
3456 """
3457 pass
3458
3460 """
3461 Fills a data field with zeroes.
3462
3463 """
3464 pass
3465
3467 """
3468 Multiplies all values in a data field by given value.
3469
3470 @param value: Value to multiply B{C{data_field}} with. I{(float)}
3471 """
3472 pass
3473
3475 """
3476 Adds given value to all values in a data field.
3477
3478 @param value: Value to be added to data field values. I{(float)}
3479 """
3480 pass
3481
3483 """
3484 Takes absolute value of all values in a data field.
3485
3486 @since: 2.52
3487
3488 """
3489 pass
3490
3491 - def area_fill(col, row, width, height, value):
3492 """
3493 Fills a rectangular part of a data field with given value.
3494
3495 @param col: Upper-left column coordinate. I{(int)}
3496 @param row: Upper-left row coordinate. I{(int)}
3497 @param width: Area width (number of columns). I{(int)}
3498 @param height: Area height (number of rows). I{(int)}
3499 @param value: Value to be entered I{(float)}
3500 """
3501 pass
3502
3504 """
3505 Fills a masked rectangular part of a data field with given value.
3506
3507 @since: 2.44
3508
3509 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
3510 @param mode: Masking mode to use. See the introduction for description of
3511 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
3512 @param col: Upper-left column coordinate. I{(int)}
3513 @param row: Upper-left row coordinate. I{(int)}
3514 @param width: Area width (number of columns). I{(int)}
3515 @param height: Area height (number of rows). I{(int)}
3516 @param value: Value to be entered I{(float)}
3517 """
3518 pass
3519
3521 """
3522 Fills a rectangular part of a data field with zeroes.
3523
3524 @param col: Upper-left column coordinate. I{(int)}
3525 @param row: Upper-left row coordinate. I{(int)}
3526 @param width: Area width (number of columns). I{(int)}
3527 @param height: Area height (number of rows). I{(int)}
3528 """
3529 pass
3530
3532 """
3533 Multiplies values in a rectangular part of a data field by given value
3534
3535 @param col: Upper-left column coordinate. I{(int)}
3536 @param row: Upper-left row coordinate. I{(int)}
3537 @param width: Area width (number of columns). I{(int)}
3538 @param height: Area height (number of rows). I{(int)}
3539 @param value: Value to multiply area with. I{(float)}
3540 """
3541 pass
3542
3543 - def area_add(col, row, width, height, value):
3544 """
3545 Adds given value to all values in a rectangular part of a data field.
3546
3547 @param col: Upper-left column coordinate. I{(int)}
3548 @param row: Upper-left row coordinate. I{(int)}
3549 @param width: Area width (number of columns). I{(int)}
3550 @param height: Area height (number of rows). I{(int)}
3551 @param value: Value to be added to area values. I{(float)}
3552 """
3553 pass
3554
3555 - def area_abs(col, row, width, height):
3556 """
3557 Takes absolute value of values in a rectangular part of a data field.
3558
3559 @since: 2.52
3560
3561 @param col: Upper-left column coordinate. I{(int)}
3562 @param row: Upper-left row coordinate. I{(int)}
3563 @param width: Area width (number of columns). I{(int)}
3564 @param height: Area height (number of rows). I{(int)}
3565 """
3566 pass
3567
3568 - def get_profile(scol, srow, ecol, erow, res, thickness, interpolation):
3569 """
3570 Extracts a possibly averaged profile from data field to a data line.
3571
3572
3573 @param scol: The column the line starts at (inclusive). I{(int)}
3574 @param srow: The row the line starts at (inclusive). I{(int)}
3575 @param ecol: The column the line ends at (inclusive). I{(int)}
3576 @param erow: The row the line ends at (inclusive). I{(int)}
3577 @param res: Requested resolution of data line (the number of samples to take).
3578 If nonpositive, data line resolution is chosen to match B{C{data_field}}'s. I{(int)}
3579 @param thickness: Thickness of line to be averaged. I{(int)}
3580 @param interpolation: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
3581 @return: Tuple consisting of 2 values (B{C{value}}, B{C{data_line}}). (I{(L{DataLine})}, I{(SkipArg)})
3582 """
3583 return None, None
3584
3586 """
3587 Extracts a data field row into a data line.
3588
3589 @param data_line: A data line. It will be resized to width ot B{C{data_field}}. I{(L{DataLine})}
3590 @param row: Row index. I{(int)}
3591 """
3592 pass
3593
3595 """
3596 Extracts a data field column into a data line.
3597
3598 @param data_line: A data line. It will be resized to height of B{C{data_field}}. I{(L{DataLine})}
3599 @param col: Column index. I{(int)}
3600 """
3601 pass
3602
3604 """
3605 Sets a row in the data field to values of a data line.
3606
3607 Data line length must be equal to width of data field.
3608
3609 @param data_line: A data line. I{(L{DataLine})}
3610 @param row: Row index. I{(int)}
3611 """
3612 pass
3613
3615 """
3616 Sets a column in the data field to values of a data line.
3617
3618 Data line length must be equal to height of data field.
3619
3620 @param data_line: A data line. I{(L{DataLine})}
3621 @param col: Column index. I{(int)}
3622 """
3623 pass
3624
3626 """
3627 Extracts part of a data field row into a data line.
3628
3629 @param data_line: A data line. It will be resized to the row part width. I{(L{DataLine})}
3630 @param row: Row index. I{(int)}
3631 @param from_: I{(int)}
3632 @param to: End column index + 1. I{(int)}
3633 """
3634 pass
3635
3637 """
3638 Extracts part of a data field column into a data line.
3639
3640 @param data_line: A data line. It will be resized to the column part height. I{(L{DataLine})}
3641 @param col: Column index. I{(int)}
3642 @param from_: I{(int)}
3643 @param to: End row index + 1. I{(int)}
3644 """
3645 pass
3646
3648 """
3649 Puts a data line into a data field row.
3650
3651 If data line length differs from B{C{to}}-B{C{from}}, it is resampled to this length.
3652
3653 @param data_line: A data line. I{(L{DataLine})}
3654 @param row: Row index. I{(int)}
3655 @param from_: I{(int)}
3656 @param to: End row index + 1. I{(int)}
3657 """
3658 pass
3659
3661 """
3662 Puts a data line into data field column.
3663
3664 If data line length differs from B{C{to}}-B{C{from}}, it is resampled to this length.
3665
3666 @param data_line: A data line. I{(L{DataLine})}
3667 @param col: Column index. I{(int)}
3668 @param from_: I{(int)}
3669 @param to: End row index + 1. I{(int)}
3670 """
3671 pass
3672
3674 """
3675 Computes central derivative in X direction.
3676
3677 On border points, one-side derivative is returned.
3678
3679
3680 @param col: Column index. I{(int)}
3681 @param row: Row index. I{(int)}
3682 @return: Derivative in X direction. I{(float)}
3683 """
3684 return None
3685
3687 """
3688 Computes central derivative in Y direction.
3689
3690 On border points, one-side derivative is returned.
3691
3692 Note the derivative is for legacy reasons calulcated for the opposite
3693 y direction than is usual elsewhere in Gwyddion, i.e. if values increase
3694 with increasing row number, the returned value is negative.
3695
3696
3697 @param col: Column index. I{(int)}
3698 @param row: Row index. I{(int)}
3699 @return: Derivative in Y direction I{(float)}
3700 """
3701 return None
3702
3704 """
3705 Computes derivative in direction specified by given angle.
3706
3707
3708 @param col: Column index. I{(int)}
3709 @param row: Row index. I{(int)}
3710 @param theta: Angle defining the direction (in radians, counterclockwise). I{(float)}
3711 @return: Derivative in direction given by angle B{C{theta}}. I{(float)}
3712 """
3713 return None
3714
3716 """
3717 Fills a data field with regularised XYZ data using a simple method.
3718
3719 The real dimensions and offsets of B{C{field}} determine the rectangle in the XY
3720 plane that will be regularised. The regularisation method is fast but
3721 simple and there are no absolute guarantees of quality, even though the
3722 result will be usually quite acceptable.
3723
3724 This especially applies to reasonable views of the XYZ data. Unreasonable
3725 views can be rendered unreasonably. In particular if the rectangle does not
3726 contain any point from B{C{points}} (either due to high zoom to an empty region
3727 or by just being completely off) B{C{data_field}} will be filled entirely with
3728 the value of the closest point or something similar.
3729
3730 @since: 2.44
3731
3732 @param density_map: Optional data field to fill with XYZ point density map. It can
3733 be B{C{None}}. I{(L{DataField})}
3734 @param points: Array of XYZ points. Coordinates X and Y represent positions in
3735 the plane; the Z-coordinate represents values. I{(const-XYZ*)}
3736 @param npoints: Number of points. I{(int)}
3737 """
3738 pass
3739
3740 - def xdwt(wt_coefs, direction, minsize):
3741 """
3742 Performs steps of the X-direction image wavelet decomposition.
3743
3744 The smallest low pass coefficients block is equal to B{C{minsize}}. Run with
3745 B{C{minsize}} = B{C{dfield}}->xres/2 to perform one step of decomposition
3746 or B{C{minsize}} = 4 to perform full decomposition (or anything between).
3747
3748
3749 @param wt_coefs: Data line where the wavelet transform coefficients are stored. I{(L{DataLine})}
3750 @param direction: Transform direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
3751 @param minsize: size of minimal transform result block I{(int)}
3752 """
3753 pass
3754
3755 - def ydwt(wt_coefs, direction, minsize):
3756 """
3757 Performs steps of the Y-direction image wavelet decomposition.
3758
3759 The smallest low pass coefficients block is equal to B{C{minsize}}. Run with
3760 B{C{minsize}} = B{C{dfield}}->yres/2 to perform one step of decomposition
3761 or B{C{minsize}} = 4 to perform full decomposition (or anything between).
3762
3763
3764 @param wt_coefs: Data line where the wavelet transform coefficients are stored. I{(L{DataLine})}
3765 @param direction: Transform direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
3766 @param minsize: size of minimal transform result block I{(int)}
3767 """
3768 pass
3769
3770 - def dwt(wt_coefs, direction, minsize):
3771 """
3772 Performs steps of the 2D image wavelet decomposition.
3773
3774 The smallest low pass coefficients block is equal to B{C{minsize}}. Run with
3775 B{C{minsize}} = B{C{dfield}}->xres/2 to perform one step of decomposition
3776 or B{C{minsize}} = 4 to perform full decomposition (or anything between).
3777
3778
3779 @param wt_coefs: Data line where the wavelet transform coefficients are stored. I{(L{DataLine})}
3780 @param direction: Transform direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
3781 @param minsize: size of minimal transform result block I{(int)}
3782 """
3783 pass
3784
3786 """
3787 Performs steps of the 2D image wavelet decomposition.
3788
3789 The smallest low pass coefficients block is equal to B{C{minsize}}. Run with
3790 B{C{minsize}} = B{C{dfield}}->xres/2 to perform one step of decomposition
3791 or B{C{minsize}} = 4 to perform full decomposition (or anything between).
3792
3793
3794 @param mask: I{(L{DataField})}
3795 @param wt_coefs: Data line to store wavelet transform coefficients to. I{(L{DataLine})}
3796 @param ratio: I{(float)}
3797 @param lowlimit: I{(int)}
3798 """
3799 pass
3800
3802 """
3803 Fills an elliptic region of a data field with given value.
3804
3805 The elliptic region is defined by its bounding box. In versions prior to 2.59 the bounding box must be completely
3806 contained in the data field. Since version 2.59 the ellipse can intersect the data field in any manner.
3807
3808
3809 @param col: Upper-left bounding box column coordinate. I{(int)}
3810 @param row: Upper-left bounding box row coordinate. I{(int)}
3811 @param width: Bounding box width (number of columns). I{(int)}
3812 @param height: Bounding box height (number of rows). I{(int)}
3813 @param value: Value to be entered. I{(float)}
3814 @return: The number of filled values. I{(int)}
3815 """
3816 return None
3817
3819 """
3820 Calculates an upper bound of the number of samples in an elliptic region intersecting a data field.
3821
3822 @since: 2.59
3823
3824 @param col: Upper-left bounding box column coordinate. I{(int)}
3825 @param row: Upper-left bounding box row coordinate. I{(int)}
3826 @param width: Bounding box width. I{(int)}
3827 @param height: Bounding box height. I{(int)}
3828 @return: The number of pixels in an elliptic region with given rectangular bounds (or its upper bound). I{(int)}
3829 """
3830 return None
3831
3833 """
3834 Fills an elliptic region of a data field with given value.
3835
3836
3837 @param col: Row index of circular area centre. I{(int)}
3838 @param row: Column index of circular area centre. I{(int)}
3839 @param radius: Circular area radius (in pixels). Any value is allowed, although to get areas that do not deviate from
3840 true circles after pixelization too much, half-integer values are recommended, integer values are NOT
3841 recommended. I{(float)}
3842 @param value: Value to be entered. I{(float)}
3843 @return: The number of filled values. I{(int)}
3844 """
3845 return None
3846
3848 """
3849 Normalizes data in a data field to range 0.0 to 1.0.
3850
3851 It is equivalent to L{DataField.renormalize}(B{C{data_field}}, 1.0, 0.0);
3852
3853 If B{C{data_field}} is filled with only one value, it is changed to 0.0.
3854
3855 """
3856 pass
3857
3859 """
3860 Transforms data in a data field with linear function to given range.
3861
3862 When B{C{range}} is positive, the new data range is (B{C{offset}}, B{C{offset}}+B{C{range}}); when B{C{range}} is negative, the new data
3863 range is (B{C{offset}}-B{C{range}}, B{C{offset}}). In neither case the data are flipped, negative range only means different
3864 selection of boundaries.
3865
3866 When B{C{range}} is zero, this method is equivalent to L{DataField.fill}(B{C{data_field}}, B{C{offset}}).
3867
3868 @param range: New data interval size. I{(float)}
3869 @param offset: New data interval offset. I{(float)}
3870 """
3871 pass
3872
3874 """
3875 Transforms data in a part of a data field with linear function to given range.
3876
3877 When B{C{range}} is positive, the new data range is (B{C{offset}}, B{C{offset}}+B{C{range}}); when B{C{range}} is negative, the new data
3878 range is (B{C{offset}}-B{C{range}}, B{C{offset}}). In neither case the data are flipped, negative range only means different
3879 selection of boundaries.
3880
3881 When B{C{range}} is zero, this method is equivalent to L{DataField.fill}(B{C{data_field}}, B{C{offset}}).
3882
3883 @since: 2.45
3884
3885 @param col: Upper-left column coordinate. I{(int)}
3886 @param row: Upper-left row coordinate. I{(int)}
3887 @param width: Area width (number of columns). I{(int)}
3888 @param height: Area height (number of rows). I{(int)}
3889 @param range: New data interval size. I{(float)}
3890 @param offset: New data interval offset. I{(float)}
3891 """
3892 pass
3893
3895 """
3896 Tresholds values of a data field.
3897
3898 Values smaller than B{C{threshold}} are set to value B{C{bottom}}, values higher than B{C{threshold}} or equal to it are set to
3899 value B{C{top}}
3900
3901
3902 @param threshval: Threshold value. I{(float)}
3903 @param bottom: Lower replacement value. I{(float)}
3904 @param top: Upper replacement value. I{(float)}
3905 @return: The total number of values above threshold. I{(int)}
3906 """
3907 return None
3908
3909 - def area_threshold(col, row, width, height, threshval, bottom, top):
3910 """
3911 Tresholds values of a rectangular part of a data field.
3912
3913 Values smaller than B{C{threshold}} are set to value B{C{bottom}}, values higher than B{C{threshold}} or equal to it are set to
3914 value B{C{top}}
3915
3916
3917 @param col: Upper-left column coordinate. I{(int)}
3918 @param row: Upper-left row coordinate. I{(int)}
3919 @param width: Area width (number of columns). I{(int)}
3920 @param height: Area height (number of rows). I{(int)}
3921 @param threshval: Threshold value. I{(float)}
3922 @param bottom: Lower replacement value. I{(float)}
3923 @param top: Upper replacement value. I{(float)}
3924 @return: The total number of values above threshold. I{(int)}
3925 """
3926 return None
3927
3928 - def clamp(bottom, top):
3929 """
3930 Limits data field values to a range.
3931
3932
3933 @param bottom: Lower limit value. I{(float)}
3934 @param top: Upper limit value. I{(float)}
3935 @return: The number of changed values, i.e., values that were outside [B{C{bottom}}, B{C{top}}]. I{(int)}
3936 """
3937 return None
3938
3939 - def area_clamp(col, row, width, height, bottom, top):
3940 """
3941 Limits values in a rectangular part of a data field to a range.
3942
3943
3944 @param col: Upper-left column coordinate. I{(int)}
3945 @param row: Upper-left row coordinate. I{(int)}
3946 @param width: Area width (number of columns). I{(int)}
3947 @param height: Area height (number of rows). I{(int)}
3948 @param bottom: Lower limit value. I{(float)}
3949 @param top: Upper limit value. I{(float)}
3950 @return: The number of changed values, i.e., values that were outside [B{C{bottom}}, B{C{top}}]. I{(int)}
3951 """
3952 return None
3953
3954 - def area_gather(result, buffer, hsize, vsize, average, col, row, width, height):
3955 """
3956 Sums or averages values in reactangular areas around each sample in a data field.
3957
3958 When the gathered area extends out of calculation area, only samples from their intersection are taken into the
3959 local sum (or average).
3960
3961 There are no restrictions on values of B{C{hsize}} and B{C{vsize}} with regard to B{C{width}} and B{C{height}}, but they have to be
3962 positive.
3963
3964 The result is calculated by the means of two-dimensional rolling sums. One one hand it means the calculation time
3965 depends linearly on (B{C{width}} + B{C{hsize}})*(B{C{height}} + B{C{vsize}}) instead of B{C{width}}*B{C{hsize}}*B{C{height}}*B{C{vsize}}. On the other
3966 hand it means absolute rounding errors of all output values are given by the largest input values, that is relative
3967 precision of results small in absolute value may be poor.
3968
3969 @param result: A data field to put the result to, it may be B{C{data_field}} itself. I{(L{DataField})}
3970 @param buffer: A data field to use as a scratch area, its size must be at least B{C{width}}*B{C{height}}. May be B{C{None}} to allocate
3971 a private temporary buffer. I{(L{DataField})}
3972 @param hsize: Horizontal size of gathered area. The area is centered around each sample if B{C{hsize}} is odd, it extends one
3973 pixel more to the right if B{C{hsize}} is even. I{(int)}
3974 @param vsize: Vertical size of gathered area. The area is centered around each sample if B{C{vsize}} is odd, it extends one
3975 pixel more down if B{C{vsize}} is even. I{(int)}
3976 @param average: B{C{True}} to divide resulting sums by the number of involved samples to get averages instead of sums. I{(bool)}
3977 @param col: Upper-left column coordinate. I{(int)}
3978 @param row: Upper-left row coordinate. I{(int)}
3979 @param width: Area width (number of columns). I{(int)}
3980 @param height: Area height (number of rows). I{(int)}
3981 """
3982 pass
3983
3985 """
3986 Convolves a data field with given kernel.
3987
3988 Note that the convolution is done by summation and can be slow for large kernels.
3989
3990 @param kernel_field: Kenrel field to convolve B{C{data_field}} with. I{(L{DataField})}
3991 """
3992 pass
3993
3995 """
3996 Convolves a rectangular part of a data field with given kernel.
3997
3998 Note that the convolution is done by summation and can be slow for large kernels.
3999
4000 @param kernel_field: Kenrel field to convolve B{C{data_field}} with. I{(L{DataField})}
4001 @param col: Upper-left column coordinate. I{(int)}
4002 @param row: Upper-left row coordinate. I{(int)}
4003 @param width: Area width (number of columns). I{(int)}
4004 @param height: Area height (number of rows). I{(int)}
4005 """
4006 pass
4007
4009 """
4010 Convolves a data field with given kernel of the same size using FFT.
4011
4012 This is a simple FFT-based convolution done by multiplication in the frequency domain.
4013
4014 This is a somewhat low-level function. There is no padding or boundary treatment; images are considered periodic.
4015 The result is normalised as if the convolution was done by summation and the physical units of B{C{data_field}} are
4016 unchanged.
4017
4018 Also note that in order to obtain unshifted result, the kernel needs to be centered around the top left corner.
4019 You can use L{DataField.fft2d_dehumanize}() to transform a centered kernel.
4020
4021 @since: 2.54
4022
4023 @param kernel_field: Kenrel field to convolve B{C{data_field}} with. It must have the same size as B{C{data_field}}. I{(L{DataField})}
4024 """
4025 pass
4026
4027 - def area_ext_convolve(col, row, width, height, target, kernel, exterior, fill_value, as_integral):
4028 """
4029 Convolve a field with a two-dimensional kernel.
4030
4031 Pixel dimensions of B{C{target}} may match either B{C{field}} or just the rectangular area. In the former case the result is
4032 written in the same rectangular area; in the latter case the result fills the entire B{C{target}}.
4033
4034 The convolution is performed with the kernel centred on the respective field pixels. For directions in which the
4035 kernel has an odd size this holds precisely. For an even-sized kernel this means the kernel centre is placed 0.5
4036 pixel left or up (towards lower indices) from the respective field pixel.
4037
4038 See L{DataField.extend}() for what constitutes the exterior and how it is handled.
4039
4040 If B{C{as_integral}} is B{C{False}} the function performs a simple discrete convolution sum and the value units of B{C{target}}
4041 are set to product of B{C{field}} and B{C{kernel}} units.
4042
4043 If B{C{as_integral}} is B{C{True}} the function approximates a convolution integral. In this case B{C{kernel}} should be a sampled
4044 continuous transfer function. The units of value B{C{target}} are set to product of B{C{field}} and B{C{kernel}} value units and
4045 B{C{field}} lateral units squared. Furthermore, the discrete sum is multiplied by the pixel size (i.e. dB{C{x}} dB{C{y}} in the
4046 integral).
4047
4048 In either case, the lateral units and pixel size of B{C{kernel}} are assumed to be the same as for B{C{field}} (albeit not
4049 checked), because the convolution does not make sense otherwise.
4050
4051 @since: 2.49
4052
4053 @param col: Upper-left column coordinate. I{(int)}
4054 @param row: Upper-left row coordinate. I{(int)}
4055 @param width: Area width (number of columns). I{(int)}
4056 @param height: Area height (number of rows). I{(int)}
4057 @param target: A two-dimensional data field where the result will be placed. It may be B{C{field}} for an in-place
4058 modification. I{(L{DataField})}
4059 @param kernel: Kernel to convolve B{C{field}} with. I{(L{DataField})}
4060 @param exterior: Exterior pixels handling. Expected values: C{B{EXTERIOR_UNDEFINED}}, C{B{EXTERIOR_BORDER_EXTEND}}, C{B{EXTERIOR_MIRROR_EXTEND}}, C{B{EXTERIOR_PERIODIC}}, C{B{EXTERIOR_FIXED_VALUE}}, C{B{EXTERIOR_LAPLACE}}. I{(L{ExteriorType})}
4061 @param fill_value: The value to use with B{C{EXTERIOR_FIXED_VALUE}} exterior. I{(float)}
4062 @param as_integral: B{C{True}} for normalisation and units as a convolution integral, B{C{False}} as a sum. I{(bool)}
4063 """
4064 pass
4065
4067 """
4068 Convolves a data field with given linear kernel.
4069
4070 @since: 2.4
4071
4072 @param kernel_line: Kenrel line to convolve B{C{data_field}} with. I{(L{DataLine})}
4073 @param orientation: Filter orientation (see L{DataField.area_convolve_1d}()). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
4074 """
4075 pass
4076
4078 """
4079 Convolves a rectangular part of a data field with given linear kernel.
4080
4081 For large separable kernels it can be more efficient to use a sequence of horizontal and vertical convolutions
4082 instead one 2D convolution.
4083
4084 @since: 2.4
4085
4086 @param kernel_line: Kernel line to convolve B{C{data_field}} with. I{(L{DataLine})}
4087 @param orientation: Filter orientation (B{C{ORIENTATION_HORIZONTAL}} for row-wise convolution, B{C{ORIENTATION_VERTICAL}}
4088 for column-wise convolution). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
4089 @param col: Upper-left column coordinate. I{(int)}
4090 @param row: Upper-left row coordinate. I{(int)}
4091 @param width: Area width (number of columns). I{(int)}
4092 @param height: Area height (number of rows). I{(int)}
4093 """
4094 pass
4095
4097 """
4098 Convolve a field row-wise with a one-dimensional kernel.
4099
4100 Pixel dimensions of B{C{target}} may match either B{C{field}} or just the rectangular area. In the former case the result is
4101 written in the same rectangular area; in the latter case the result fills the entire B{C{target}}.
4102
4103 The convolution is performed with the kernel centred on the respective field pixels. For an odd-sized kernel this
4104 holds precisely. For an even-sized kernel this means the kernel centre is placed 0.5 pixel to the left (towards
4105 lower column indices) from the respective field pixel.
4106
4107 See L{DataField.extend}() for what constitutes the exterior and how it is handled.
4108
4109 If B{C{as_integral}} is B{C{False}} the function performs a simple discrete convolution sum and the value units of B{C{target}}
4110 are set to product of B{C{field}} and B{C{kernel}} units.
4111
4112 If B{C{as_integral}} is B{C{True}} the function approximates a convolution integral. In this case B{C{kernel}} should be a sampled
4113 continuous transfer function. The units of value B{C{target}} are set to product of B{C{field}} and B{C{kernel}} value units and
4114 B{C{field}} lateral units. Furthermore, the discrete sum is multiplied by the pixel size (i.e. dB{C{x}} in the integral).
4115
4116 In either case, the lateral units and pixel size of B{C{kernel}} are assumed to be the same as for a B{C{field}}'s row
4117 (albeit not checked), because the convolution does not make sense otherwise.
4118
4119 @since: 2.49
4120
4121 @param col: Upper-left column coordinate. I{(int)}
4122 @param row: Upper-left row coordinate. I{(int)}
4123 @param width: Area width (number of columns). I{(int)}
4124 @param height: Area height (number of rows). I{(int)}
4125 @param target: A two-dimensional data field where the result will be placed. It may be B{C{field}} for an in-place
4126 modification. I{(L{DataField})}
4127 @param kernel: Kernel to convolve B{C{field}} with. I{(L{DataLine})}
4128 @param exterior: Exterior pixels handling. Expected values: C{B{EXTERIOR_UNDEFINED}}, C{B{EXTERIOR_BORDER_EXTEND}}, C{B{EXTERIOR_MIRROR_EXTEND}}, C{B{EXTERIOR_PERIODIC}}, C{B{EXTERIOR_FIXED_VALUE}}, C{B{EXTERIOR_LAPLACE}}. I{(L{ExteriorType})}
4129 @param fill_value: The value to use with B{C{EXTERIOR_FIXED_VALUE}} exterior. I{(float)}
4130 @param as_integral: B{C{True}} for normalisation and units as a convolution integral, B{C{False}} as a sum. I{(bool)}
4131 """
4132 pass
4133
4144
4159
4161 """
4162 Filters a data field with mean filter of size B{C{size}}.
4163
4164 This method is a simple L{DataField.area_gather}() wrapper, so the kernel is square. Use convolution
4165 L{DataField.area_ext_convolve}() to perform a mean filter with different, for instance circular, kernel.
4166
4167 @param size: Averaged area size. I{(int)}
4168 """
4169 pass
4170
4172 """
4173 Filters a rectangular part of a data field with mean filter of size B{C{size}}.
4174
4175 This method is a simple L{DataField.area_gather}() wrapper, so the kernel is square. Use convolution
4176 L{DataField.area_ext_convolve}() to perform a mean filter with different, for instance circular, kernel.
4177
4178 @param size: Averaged area size. I{(int)}
4179 @param col: Upper-left column coordinate. I{(int)}
4180 @param row: Upper-left row coordinate. I{(int)}
4181 @param width: Area width (number of columns). I{(int)}
4182 @param height: Area height (number of rows). I{(int)}
4183 """
4184 pass
4185
4187 """
4188 Filters a data field with conservative denoise filter.
4189
4190 @param size: Filtered area size. I{(int)}
4191 """
4192 pass
4193
4195 """
4196 Filters a rectangular part of a data field with conservative denoise filter.
4197
4198 @param size: Filtered area size. I{(int)}
4199 @param col: Upper-left column coordinate. I{(int)}
4200 @param row: Upper-left row coordinate. I{(int)}
4201 @param width: Area width (number of columns). I{(int)}
4202 @param height: Area height (number of rows). I{(int)}
4203 """
4204 pass
4205
4207 """
4208 Filters a data field with Laplacian filter.
4209
4210 """
4211 pass
4212
4214 """
4215 Filters a rectangular part of a data field with Laplacian filter.
4216
4217 @param col: Upper-left column coordinate. I{(int)}
4218 @param row: Upper-left row coordinate. I{(int)}
4219 @param width: Area width (number of columns). I{(int)}
4220 @param height: Area height (number of rows). I{(int)}
4221 """
4222 pass
4223
4225 """
4226 Filters a data field with Laplacian of Gaussians filter.
4227
4228 @since: 2.23
4229
4230 """
4231 pass
4232
4234 """
4235 Filters a rectangular part of a data field with Laplacian of Gaussians filter.
4236
4237 @since: 2.23
4238
4239 @param col: Upper-left column coordinate. I{(int)}
4240 @param row: Upper-left row coordinate. I{(int)}
4241 @param width: Area width (number of columns). I{(int)}
4242 @param height: Area height (number of rows). I{(int)}
4243 """
4244 pass
4245
4247 """
4248 Filters a data field with a directional Sobel filter.
4249
4250 @param orientation: Filter orientation. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
4251 """
4252 pass
4253
4255 """
4256 Filters a rectangular part of a data field with a directional Sobel filter.
4257
4258 @param orientation: Filter orientation. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
4259 @param col: Upper-left column coordinate. I{(int)}
4260 @param row: Upper-left row coordinate. I{(int)}
4261 @param width: Area width (number of columns). I{(int)}
4262 @param height: Area height (number of rows). I{(int)}
4263 """
4264 pass
4265
4267 """
4268 Filters a data field with total Sobel filter.
4269
4270 @since: 2.31
4271
4272 """
4273 pass
4274
4276 """
4277 Filters a data field with Prewitt filter.
4278
4279 @param orientation: Filter orientation. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
4280 """
4281 pass
4282
4284 """
4285 Filters a rectangular part of a data field with a directional Prewitt filter.
4286
4287 @param orientation: Filter orientation. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
4288 @param col: Upper-left column coordinate. I{(int)}
4289 @param row: Upper-left row coordinate. I{(int)}
4290 @param width: Area width (number of columns). I{(int)}
4291 @param height: Area height (number of rows). I{(int)}
4292 """
4293 pass
4294
4296 """
4297 Filters a data field with total Prewitt filter.
4298
4299 @since: 2.31
4300
4301 """
4302 pass
4303
4305 """
4306 Calculates x and y derivaties for an entire field.
4307
4308 The derivatives are calculated as the simple symmetrical differences (in physical units, not pixel-wise), except at
4309 the edges where the differences are one-sided.
4310
4311 @since: 2.37
4312
4313 @param xder: Data field where the x-derivarive is to be stored, or B{C{None}} if you are only interested in the y-derivarive. I{(L{DataField})}
4314 @param yder: Data field where the y-derivarive is to be stored, or B{C{None}} if you are only interested in the x-derivarive. I{(L{DataField})}
4315 """
4316 pass
4317
4319 """
4320 Processes a data field with Gaussian step detection filter.
4321
4322 The filter is a multi-directional combination of convolutions with Gaussian multiplied by a signed step function.
4323
4324 The resulting values correspond roughly to the step height around the pixel.
4325
4326 @since: 2.54
4327
4328 @param sigma: Gaussian filter width (in pixels). I{(float)}
4329 """
4330 pass
4331
4333 """
4334 Filters a data field with 5x5 checker pattern removal filter.
4335
4336 @since: 2.1
4337
4338 """
4339 pass
4340
4342 """
4343 Filters a rectangular part of a data field with 5x5 checker pattern removal
4344 filter.
4345
4346 @since: 2.1
4347
4348 @param col: Upper-left column coordinate. I{(int)}
4349 @param row: Upper-left row coordinate. I{(int)}
4350 @param width: Area width (number of columns). I{(int)}
4351 @param height: Area height (number of rows). I{(int)}
4352 """
4353 pass
4354
4356 """
4357 Filters a data field with a Gaussian filter.
4358
4359 @since: 2.4
4360
4361 @param sigma: The sigma parameter of the Gaussian. I{(float)}
4362 """
4363 pass
4364
4366 """
4367 Filters a rectangular part of a data field with a Gaussian filter.
4368
4369 The Gausian is normalized, i.e. it is sum-preserving.
4370
4371 @since: 2.4
4372
4373 @param sigma: The sigma parameter of the Gaussian. I{(float)}
4374 @param col: Upper-left column coordinate. I{(int)}
4375 @param row: Upper-left row coordinate. I{(int)}
4376 @param width: Area width (number of columns). I{(int)}
4377 @param height: Area height (number of rows). I{(int)}
4378 """
4379 pass
4380
4382 """
4383 Filters a data field with a Gaussian filter in horizontal direction.
4384
4385 The Gausian is normalized, i.e. it is sum-preserving.
4386
4387 @since: 2.54
4388
4389 @param sigma: The sigma parameter of the Gaussian. I{(float)}
4390 """
4391 pass
4392
4394 """
4395 Filters a data field with a Gaussian filter in vertical direction.
4396
4397 The Gausian is normalized, i.e. it is sum-preserving.
4398
4399 @since: 2.54
4400
4401 @param sigma: The sigma parameter of the Gaussian. I{(float)}
4402 """
4403 pass
4404
4406 """
4407 Filters a data field with minimum filter.
4408
4409 This method uses a simple square kernel. Use the general function L{DataField.area_filter_min_max}() to perform
4410 filtering with a different kernel, for instance circular.
4411
4412 @param size: Neighbourhood size for minimum search. I{(int)}
4413 """
4414 pass
4415
4417 """
4418 Filters a rectangular part of a data field with minimum filter.
4419
4420 This operation is often called erosion filter.
4421
4422 This method uses a simple square kernel. Use the general function L{DataField.area_filter_min_max}() to perform
4423 filtering with a different kernel, for instance circular.
4424
4425 @param size: Neighbourhood size for minimum search. I{(int)}
4426 @param col: Upper-left column coordinate. I{(int)}
4427 @param row: Upper-left row coordinate. I{(int)}
4428 @param width: Area width (number of columns). I{(int)}
4429 @param height: Area height (number of rows). I{(int)}
4430 """
4431 pass
4432
4434 """
4435 Filters a data field with maximum filter.
4436
4437 This method uses a simple square kernel. Use the general function L{DataField.area_filter_min_max}() to perform
4438 filtering with a different kernel, for instance circular.
4439
4440 @param size: Neighbourhood size for maximum search. I{(int)}
4441 """
4442 pass
4443
4445 """
4446 Filters a rectangular part of a data field with maximum filter.
4447
4448 This operation is often called dilation filter.
4449
4450 This method uses a simple square kernel. Use the general function L{DataField.area_filter_min_max}() to perform
4451 filtering with a different kernel, for instance circular.
4452
4453 @param size: Neighbourhood size for maximum search. I{(int)}
4454 @param col: Upper-left column coordinate. I{(int)}
4455 @param row: Upper-left row coordinate. I{(int)}
4456 @param width: Area width (number of columns). I{(int)}
4457 @param height: Area height (number of rows). I{(int)}
4458 """
4459 pass
4460
4462 """
4463 Applies a morphological operation with a flat structuring element to a part of a data field.
4464
4465 Morphological operations with flat structuring elements can be expressed using minimum (erosion) and maximum
4466 (dilation) filters that are the basic operations this function can perform.
4467
4468 The kernel field is a mask that defines the shape of the flat structuring element. It is reflected for all maximum
4469 operations (dilation). For symmetrical kernels this does not matter. You can use
4470 L{DataField.elliptic_area_fill}() to create a true circular (or elliptical) kernel.
4471
4472 The kernel is implicitly centered, i.e. it will be applied symmetrically to avoid unexpected data movement.
4473 Even-sized kernels (generally not recommended) will extend farther towards the top left image corner for minimum
4474 (erosion) and towards the bottom right corner for maximum (dilation) operations due to the reflection. If you need
4475 off-center structuring elements you can add empty rows or columns to one side of the kernel to counteract the
4476 symmetrisation.
4477
4478 The operation is linear-time in kernel size for any convex kernel. Note L{DataField.area_filter_minimum}() and
4479 L{DataField.area_filter_maximum}(), which are limited to square structuring elements, are much faster for large
4480 sizes of the squares.
4481
4482 The exterior is always handled as B{C{EXTERIOR_BORDER_EXTEND}}.
4483
4484 @since: 2.43
4485
4486 @param kernel: Data field defining the flat structuring element. I{(L{DataField})}
4487 @param filtertype: The type of filter to apply. Expected values: C{B{MIN_MAX_FILTER_MINIMUM}}, C{B{MIN_MAX_FILTER_EROSION}}, C{B{MIN_MAX_FILTER_MAXIMUM}}, C{B{MIN_MAX_FILTER_DILATION}}, C{B{MIN_MAX_FILTER_OPENING}}, C{B{MIN_MAX_FILTER_CLOSING}}, C{B{MIN_MAX_FILTER_RANGE}}, C{B{MIN_MAX_FILTER_NORMALIZATION}}. I{(L{MinMaxFilterType})}
4488 @param col: Upper-left column coordinate. I{(int)}
4489 @param row: Upper-left row coordinate. I{(int)}
4490 @param width: Area width (number of columns). I{(int)}
4491 @param height: Area height (number of rows). I{(int)}
4492 """
4493 pass
4494
4496 """
4497 Applies an alternating sequential morphological filter with a flat disc structuring element to a part of a data
4498 field.
4499
4500 Alternating sequential filter is a filter consisting of repeated opening and closing (or closing and opening) with
4501 progressively larger structuring elements. This function performs such filtering for sequence of structuring
4502 elements consisting of true Euclidean discs with increasing radii. The largest disc in the sequence fits into
4503 a (2B{C{size}} + 1) × (2B{C{size}} + 1) square.
4504
4505 @since: 2.43
4506
4507 @param radius: Maximum radius of the circular structuring element, in pixels. For radius 0 and smaller the filter is
4508 no-op. I{(int)}
4509 @param closing: B{C{True}} requests an opening-closing filter (i.e. ending with closing), B{C{False}} requests a closing-opening
4510 filter (i.e. ending with opening). I{(bool)}
4511 @param col: Upper-left column coordinate. I{(int)}
4512 @param row: Upper-left row coordinate. I{(int)}
4513 @param width: Area width (number of columns). I{(int)}
4514 @param height: Area height (number of rows). I{(int)}
4515 """
4516 pass
4517
4519 """
4520 Applies a B{C{k}}-th rank filter to a part of a data field.
4521
4522 Pass half the number of non-zero values in B{C{kernel}} as B{C{k}} for a median filter.
4523
4524 The kernel field is a mask that defines the shape of the kernel. You can use L{DataField.elliptic_area_fill}()
4525 to create a true circular (or elliptical) kernel. The kernel must be non-empty.
4526
4527 The kernel is implicitly centered, i.e. it will be applied symmetrically to avoid unexpected data movement.
4528 Even-sized kernels (generally not recommended) will extend farther towards the top left image corner for minimum
4529 (erosion) and towards the bottom right corner for maximum (dilation) operations due to the reflection. If you need
4530 off-center structuring elements you can add empty rows or columns to one side of the kernel to counteract the
4531 symmetrisation.
4532
4533 The exterior is always handled as B{C{EXTERIOR_BORDER_EXTEND}}.
4534
4535 If the operation is aborted the contents of B{C{data_field}} is untouched.
4536
4537 @since: 2.51
4538
4539 @param kernel: Data field defining the kernel shape. I{(L{DataField})}
4540 @param col: Upper-left column coordinate. I{(int)}
4541 @param row: Upper-left row coordinate. I{(int)}
4542 @param width: Area width (number of columns). I{(int)}
4543 @param height: Area height (number of rows). I{(int)}
4544 @param k: Rank of the value to store as the output (from lowest to highest). I{(int)}
4545 @return: Tuple consisting of 2 values (B{C{value}}, B{C{set_fraction}}). (I{(bool)}, I{(SkipArg)})
4546 """
4547 return None, None
4548
4550 """
4551 Applies a trimmed mean filter to a part of a data field.
4552
4553 At least one value must remain after the trimming, i.e. B{C{nlowest}} + B{C{nhighest}} must be smaller than the number of
4554 non-zero values in B{C{kernel}}. Usually one passes the same number as both B{C{nlowest}} and B{C{nhighest}}, but it is not
4555 a requirement.
4556
4557 The kernel field is a mask that defines the shape of the kernel. You can use L{DataField.elliptic_area_fill}()
4558 to create a true circular (or elliptical) kernel. The kernel must be non-empty.
4559
4560 The kernel is implicitly centered, i.e. it will be applied symmetrically to avoid unexpected data movement.
4561 Even-sized kernels (generally not recommended) will extend farther towards the top left image corner for minimum
4562 (erosion) and towards the bottom right corner for maximum (dilation) operations due to the reflection. If you need
4563 off-center structuring elements you can add empty rows or columns to one side of the kernel to counteract the
4564 symmetrisation.
4565
4566 The exterior is always handled as B{C{EXTERIOR_BORDER_EXTEND}}.
4567
4568 If the operation is aborted the contents of B{C{data_field}} is untouched.
4569
4570 @since: 2.53
4571
4572 @param kernel: Data field defining the kernel shape. I{(L{DataField})}
4573 @param col: Upper-left column coordinate. I{(int)}
4574 @param row: Upper-left row coordinate. I{(int)}
4575 @param width: Area width (number of columns). I{(int)}
4576 @param height: Area height (number of rows). I{(int)}
4577 @param nlowest: The number of lowest values to discard. I{(int)}
4578 @param nhighest: The number of highest values to discard. I{(int)}
4579 @return: Tuple consisting of 2 values (B{C{value}}, B{C{set_fraction}}). (I{(bool)}, I{(SkipArg)})
4580 """
4581 return None, None
4582
4584 """
4585 Filters a data field with RMS filter.
4586
4587 @param size: Area size. I{(int)}
4588 """
4589 pass
4590
4592 """
4593 Filters a rectangular part of a data field with RMS filter of size B{C{size}}.
4594
4595 RMS filter computes root mean square in given area.
4596
4597 @param size: Area size. I{(int)}
4598 @param col: Upper-left column coordinate. I{(int)}
4599 @param row: Upper-left row coordinate. I{(int)}
4600 @param width: Area width (number of columns). I{(int)}
4601 @param height: Area height (number of rows). I{(int)}
4602 """
4603 pass
4604
4606 """
4607 Filters a data field with Kuwahara filter.
4608
4609 """
4610 pass
4611
4613 """
4614 Filters a rectangular part of a data field with a Kuwahara (edge-preserving smoothing) filter.
4615
4616 @param col: Upper-left column coordinate. I{(int)}
4617 @param row: Upper-left row coordinate. I{(int)}
4618 @param width: Area width (number of columns). I{(int)}
4619 @param height: Area height (number of rows). I{(int)}
4620 """
4621 pass
4622
4624 """
4625 Filters a rectangular part of a data field with canny edge detector filter.
4626
4627 @param threshold: Slope detection threshold (range 0..1). I{(float)}
4628 """
4629 pass
4630
4631 - def shade(target_field, theta, phi):
4632 """
4633 Shades a data field.
4634
4635 @param target_field: A data field to put the shade to. It will be resized to
4636 match B{C{data_field}}. I{(L{DataField})}
4637 @param theta: Shading angle (in radians, from north pole). I{(float)}
4638 @param phi: Shade orientation in xy plane (in radians, counterclockwise). I{(float)}
4639 """
4640 pass
4641
4643 """
4644 Applies Harris corner detection filter to a pair of gradient data fields.
4645
4646 All passed data field must have the same size.
4647
4648 @param y_gradient: Data field with pre-calculated vertical derivative. I{(L{DataField})}
4649 @param result: Data field for the result. I{(L{DataField})}
4650 @param neighbourhood: Neighbourhood size. I{(int)}
4651 @param alpha: Sensitivity paramter (the squared trace is multiplied by it). I{(float)}
4652 """
4653 pass
4654
4656 """
4657 Performs deconvolution of a data field using a simple regularization.
4658
4659 The operation can be used to deblur an image or conversely recover the point spread function from ideal response
4660 image.
4661
4662 Convolving the result with the operand using L{DataField.area_ext_convolve}() with B{C{as_integral}}=B{C{True}} will
4663 recover (approximately) the image. This means the deconvolution assumes continous convolution, not discrete sums.
4664 Note that for the latter case this means the point spread function will be centered in B{C{out}}.
4665
4666 For recovery of transfer function, B{C{dfield}} and B{C{operand}} should be windowed beforehand if they are not periodic.
4667
4668 @since: 2.51
4669
4670 @param operand: One of the factors entering the convolution resulting in B{C{dfield}}. It must have the same dimensions as
4671 B{C{dfield}} and it is assumed it has also the same physical size. I{(L{DataField})}
4672 @param out: Data field where to put the result into. It will be resized to match B{C{dfield}}. It can also be B{C{dfield}}
4673 itself. I{(L{DataField})}
4674 @param sigma: Regularization parameter. I{(float)}
4675 """
4676 pass
4677
4679 """
4680 Performs reconstruction of transfer function from convolved and ideal sharp images.
4681
4682 The transfer function is reconstructed by solving the corresponding least squares problem. This method is suitable
4683 when the dimensions of B{C{out}} are much smaller than the images.
4684
4685 Since the method accumulates errors close to edges, they can be removed within the procedure by reconstructing
4686 a slightly larger transfer function and then cutting the result. The extension is given by B{C{border}}, typical
4687 suitable values are 2 or 3.
4688
4689 Convolving the result with the operand using L{DataField.area_ext_convolve}() with B{C{as_integral}}=B{C{True}} will
4690 recover (approximately) the image. This means the deconvolution assumes continous convolution, not discrete sums.
4691 Note that for the latter case this means the point spread function will be centered in B{C{out}}.
4692
4693 Fields B{C{dfield}} and B{C{operand}} should be windowed beforehand if they are not periodic.
4694
4695 @since: 2.52
4696
4697 @param operand: Ideal sharp measurement (before convolution). It must have the same dimensions as B{C{dfield}} and it is
4698 assumed it has also the same physical size. I{(L{DataField})}
4699 @param out: Output field for the transfer function. Its dimensions are preserved and determine the transfer function
4700 support. It must be smaller than half of B{C{dfield}}. I{(L{DataField})}
4701 @param sigma: Regularization parameter. I{(float)}
4702 @param border: Number of pixel to extend and cut off the transfer function. I{(int)}
4703 """
4704 pass
4705
4707 """
4708 Finds regularization parameter for point spread function calculation using regularized deconvolution.
4709
4710 The estimated value should be suitable for reconstruction of the point spread function using
4711 L{DataField.deconvolve_regularized}(). The estimate is only suitable for PSF, it does not work for image
4712 sharpening using a known PSF.
4713
4714 @since: 2.51
4715
4716 @param ideal: A data field with ideal sharp data. I{(L{DataField})}
4717 @return: Estimated regularization parameter. I{(float)}
4718 """
4719 return None
4720
4722 """
4723 Finds regularization parameter for point spread function calculation using least squares method.
4724
4725 The estimated value should be suitable for reconstruction of the point spread function using
4726 L{DataField.deconvolve_psf_leastsq}().
4727
4728 @since: 2.52
4729
4730 @param ideal: A data field with ideal sharp data. I{(L{DataField})}
4731 @param width: Horizontal size of transfer function support. I{(int)}
4732 @param height: Vertical size of transfer function support. I{(int)}
4733 @param border: Number of pixel to extend and cut off the transfer function. I{(int)}
4734 @return: Estimated regularization parameter. I{(float)}
4735 """
4736 return None
4737
4739 """
4740 Computes data for log-log plot by partitioning.
4741
4742 Data lines B{C{xresult}} and B{C{yresult}} will be resized to the output size and they will contain corresponding values at
4743 each position.
4744
4745 @param xresult: Data line to store x-values for log-log plot to. I{(L{DataLine})}
4746 @param yresult: Data line to store y-values for log-log plot to. I{(L{DataLine})}
4747 @param interpolation: Interpolation type. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
4748 """
4749 pass
4750
4752 """
4753 Computes data for log-log plot by cube counting.
4754
4755 Data lines B{C{xresult}} and B{C{yresult}} will be resized to the output size and they will contain corresponding values at
4756 each position.
4757
4758 @param xresult: Data line to store x-values for log-log plot to. I{(L{DataLine})}
4759 @param yresult: Data line to store y-values for log-log plot to. I{(L{DataLine})}
4760 @param interpolation: Interpolation type. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
4761 """
4762 pass
4763
4765 """
4766 Computes data for log-log plot by triangulation.
4767
4768 Data lines B{C{xresult}} and B{C{yresult}} will be resized to the output size and they will contain corresponding values at
4769 each position.
4770
4771 @param xresult: Data line to store x-values for log-log plot to. I{(L{DataLine})}
4772 @param yresult: Data line to store y-values for log-log plot to. I{(L{DataLine})}
4773 @param interpolation: Interpolation type. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
4774 """
4775 pass
4776
4778 """
4779 Computes data for log-log plot by spectral density method.
4780
4781 Data lines B{C{xresult}} and B{C{yresult}} will be resized to the output size and they will contain corresponding values at
4782 each position.
4783
4784 @param xresult: Data line to store x-values for log-log plot to. I{(L{DataLine})}
4785 @param yresult: Data line to store y-values for log-log plot to. I{(L{DataLine})}
4786 @param interpolation: Interpolation type. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
4787 """
4788 pass
4789
4791 """
4792 Replaces data under mask with interpolated values using fractal interpolation.
4793
4794 @param mask_field: Mask of places to be corrected. I{(L{DataField})}
4795 @param interpolation: Interpolation type. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
4796 """
4797 pass
4798
4800 """
4801 Marks data that are above/below curvature threshold.
4802
4803 @param grain_field: Data field to store the resulting mask to. I{(L{DataField})}
4804 @param threshval: Relative curvature threshold, in percents. I{(float)}
4805 @param below: If B{C{True}}, data below threshold are marked, otherwise data above threshold are marked. I{(bool)}
4806 """
4807 pass
4808
4809 - def grains_mark_watershed(grain_field, locate_steps, locate_thresh, locate_dropsize, wshed_steps, wshed_dropsize, prefilter, below):
4810 """
4811 Performs watershed algorithm.
4812
4813 @param grain_field: Result of marking (mask). I{(L{DataField})}
4814 @param locate_steps: Locating algorithm steps. I{(int)}
4815 @param locate_thresh: Locating algorithm threshold. I{(int)}
4816 @param locate_dropsize: Locating drop size. I{(float)}
4817 @param wshed_steps: Watershed steps. I{(int)}
4818 @param wshed_dropsize: Watershed drop size. I{(float)}
4819 @param prefilter: Use prefiltering. I{(bool)}
4820 @param below: If B{C{True}}, valleys are marked, otherwise mountains are marked. I{(bool)}
4821 """
4822 pass
4823
4825 """
4826 Removes one grain at given position.
4827
4828
4829 @param col: Column inside a grain. I{(int)}
4830 @param row: Row inside a grain. I{(int)}
4831 @return: B{C{True}} if a grain was actually removed, i.e. (B{C{col}},B{C{row}}) was inside a grain. I{(bool)}
4832 """
4833 return None
4834
4836 """
4837 Removes all grains except that one at given position.
4838
4839 If there is no grain at (B{C{col}}, B{C{row}}), all grains are removed.
4840
4841
4842 @param col: Column inside a grain. I{(int)}
4843 @param row: Row inside a grain. I{(int)}
4844 @return: B{C{True}} if a grain remained (i.e., (B{C{col}},B{C{row}}) was inside a grain). I{(bool)}
4845 """
4846 return None
4847
4849 """
4850 Removes grain identified by B{C{number}}.
4851
4852 @since: 2.35
4853
4854 @param number: Grain number was filled by L{DataField.number_grains}(). I{(int)}
4855 """
4856 pass
4857
4859 """
4860 Removes all grains below specified area.
4861
4862 @param size: Grain area threshold, in square pixels. I{(int)}
4863 """
4864 pass
4865
4867 """
4868 Removes grains that are higher/lower than given threshold value.
4869
4870 @param grain_field: Field of marked grains (mask) I{(L{DataField})}
4871 @param threshval: Relative height threshold, in percents. I{(float)}
4872 @param below: If B{C{True}}, grains below threshold are removed, otherwise grains above threshold are removed. I{(bool)}
4873 """
4874 pass
4875
4877 """
4878 Removes all grains that touch field borders.
4879
4880 @since: 2.30
4881
4882 """
4883 pass
4884
4885 - def grains_watershed_init(grain_field, locate_steps, locate_thresh, locate_dropsize, wshed_steps, wshed_dropsize, prefilter, below):
4886 """
4887 Initializes the watershed algorithm.
4888
4889 This iterator reports its state as B{C{WatershedStateType}}.
4890
4891
4892 @param grain_field: Result of marking (mask). I{(L{DataField})}
4893 @param locate_steps: Locating algorithm steps. I{(int)}
4894 @param locate_thresh: Locating algorithm threshold. I{(int)}
4895 @param locate_dropsize: Locating drop size. I{(float)}
4896 @param wshed_steps: Watershed steps. I{(int)}
4897 @param wshed_dropsize: Watershed drop size. I{(float)}
4898 @param prefilter: Use prefiltering. I{(bool)}
4899 @param below: If B{C{True}}, valleys are marked, otherwise mountains are marked. I{(bool)}
4900 @return: A new watershed iterator. I{(ComputationState*)}
4901 """
4902 return None
4903
4905 """
4906 Marks data that are above/below height threshold.
4907
4908 @param grain_field: Data field to store the resulting mask to. I{(L{DataField})}
4909 @param threshval: Relative height threshold, in percents. I{(float)}
4910 @param below: If B{C{True}}, data below threshold are marked, otherwise data above threshold are marked. I{(bool)}
4911 """
4912 pass
4913
4915 """
4916 Marks data that are above/below slope threshold.
4917
4918 @param grain_field: Data field to store the resulting mask to. I{(L{DataField})}
4919 @param threshval: Relative slope threshold, in percents. I{(float)}
4920 @param below: If B{C{True}}, data below threshold are marked, otherwise data above threshold are marked. I{(bool)}
4921 """
4922 pass
4923
4925 """
4926 Finds Otsu's height threshold for a data field.
4927
4928 The Otsu's threshold is optimal in the sense that it minimises the inter-class variances of two classes of pixels:
4929 above and below theshold.
4930
4931 @since: 2.37
4932
4933 @return: I{(float)}
4934 """
4935 return None
4936
4938 """
4939 Adds B{C{add_field}} grains to B{C{grain_field}}.
4940
4941 Note: This function is equivalent to
4942 |[
4943 L{DataField.max_of_fields}(grain_field, grain_field, add_field);
4944 ]|
4945
4946 @param add_field: Field of marked grains (mask) to be added. I{(L{DataField})}
4947 """
4948 pass
4949
4951 """
4952 Performs intersection betweet two grain fields, result is stored in B{C{grain_field}}.
4953
4954 Note: This function is equivalent to
4955 |[
4956 L{DataField.min_of_fields}(grain_field, grain_field, intersect_field);
4957 ]|
4958
4959 @param intersect_field: Field of marked grains (mask). I{(L{DataField})}
4960 """
4961 pass
4962
4964 """
4965 Inverts a data field representing a mask.
4966
4967 All non-positive values are transformed to 1.0. All positive values are transformed to 0.0.
4968
4969 @since: 2.43
4970
4971 """
4972 pass
4973
4975 """
4976 Removes empty border rows and columns from a data field representing a mask.
4977
4978 If there are border rows and columns filled completely with non-positive values the size of the data field is
4979 reduced, removing these rows. The parameter B{C{symmetrically}} controls whether the size reduction is maximum possible
4980 or symmetrical.
4981
4982 When there is no positive value in the field the field size is reduced to the smallest possible. This means 1x1
4983 for B{C{symmetrical}} being B{C{False}} and even original dimensions to 2 for B{C{symmetrical}} being B{C{True}}.
4984
4985 @since: 2.43
4986
4987 @param symmetrically: B{C{True}} to remove borders symmetrically, i.e the same number of pixels from left and right, and also
4988 top and bottom. B{C{False}} to remove as many empty rows and columns as possible. I{(bool)}
4989 @return: Tuple consisting of 5 values (B{C{value}}, B{C{left}}, B{C{right}}, B{C{up}}, B{C{down}}). (I{(bool)}, I{(int)}, I{(int)}, I{(int)}, I{(int)})
4990 """
4991 return None, None, None, None, None
4992
4994 """
4995 Calculates threshold grain number distribution.
4996
4997 This function is a simple L{DataField.area_grains_tgnd_range}() that calculates the distribution in the full
4998 range.
4999
5000 @param target_line: A data line to store the distribution to. It will be resampled to the requested width. I{(L{DataLine})}
5001 @param col: Upper-left column coordinate. I{(int)}
5002 @param row: Upper-left row coordinate. I{(int)}
5003 @param width: Area width (number of columns). I{(int)}
5004 @param height: Area height (number of rows). I{(int)}
5005 @param below: If B{C{True}}, valleys are marked, otherwise mountains are marked. I{(bool)}
5006 @param nstats: The number of samples to take on the distribution function. If nonpositive, a suitable resolution is
5007 determined automatically. I{(int)}
5008 """
5009 pass
5010
5012 """
5013 Calculates threshold grain number distribution in given height range.
5014
5015 This is the number of grains for each of B{C{nstats}} equidistant height threshold levels. For large B{C{nstats}} this
5016 function is much faster than the equivalent number of L{DataField.grains_mark_height}() calls.
5017
5018 @param target_line: A data line to store the distribution to. It will be resampled to the requested width. I{(L{DataLine})}
5019 @param col: Upper-left column coordinate. I{(int)}
5020 @param row: Upper-left row coordinate. I{(int)}
5021 @param width: Area width (number of columns). I{(int)}
5022 @param height: Area height (number of rows). I{(int)}
5023 @param min: Minimum threshold value. I{(float)}
5024 @param max: Maximum threshold value. I{(float)}
5025 @param below: If B{C{True}}, valleys are marked, otherwise mountains are marked. I{(bool)}
5026 @param nstats: The number of samples to take on the distribution function. If nonpositive, a suitable resolution is
5027 determined automatically. I{(int)}
5028 """
5029 pass
5030
5033
5048
5050 """
5051 Performs a distance transform of a data field with grains.
5052
5053 Each non-zero value will be replaced with a distance to the grain boundary,
5054 measured in pixels.
5055
5056 Note this function can calculate the true Euclidean distance transform
5057 only since 2.43. Use L{DataField.grain_distance_transform}() for the EDT
5058 if you need compatibility with older versions.
5059
5060 @since: 2.41
5061
5062 @param dtype: Type of simple distance to use. Expected values: C{B{DISTANCE_TRANSFORM_CITYBLOCK}}, C{B{DISTANCE_TRANSFORM_CONN4}}, C{B{DISTANCE_TRANSFORM_CHESS}}, C{B{DISTANCE_TRANSFORM_CONN8}}, C{B{DISTANCE_TRANSFORM_OCTAGONAL48}}, C{B{DISTANCE_TRANSFORM_OCTAGONAL84}}, C{B{DISTANCE_TRANSFORM_OCTAGONAL}}, C{B{DISTANCE_TRANSFORM_EUCLIDEAN}}. I{(L{DistanceTransformType})}
5063 @param from_border: B{C{True}} to consider image edges to be grain boundaries. I{(bool)}
5064 """
5065 pass
5066
5068 """
5069 Erodes a data field containing mask by specified amount using a distance
5070 measure.
5071
5072 Non-zero pixels in B{C{data_field}} will be replaced with zeroes if they are not
5073 farther than B{C{amount}} from the grain boundary as defined by B{C{dtype}}.
5074
5075 @since: 2.43
5076
5077 @param amount: How much the grains should be reduced, in pixels. It is inclusive,
5078 i.e. pixels that are B{C{amount}} far from the border will be removed. I{(float)}
5079 @param dtype: Type of simple distance to use. Expected values: C{B{DISTANCE_TRANSFORM_CITYBLOCK}}, C{B{DISTANCE_TRANSFORM_CONN4}}, C{B{DISTANCE_TRANSFORM_CHESS}}, C{B{DISTANCE_TRANSFORM_CONN8}}, C{B{DISTANCE_TRANSFORM_OCTAGONAL48}}, C{B{DISTANCE_TRANSFORM_OCTAGONAL84}}, C{B{DISTANCE_TRANSFORM_OCTAGONAL}}, C{B{DISTANCE_TRANSFORM_EUCLIDEAN}}. I{(L{DistanceTransformType})}
5080 @param from_border: B{C{True}} to consider image edges to be grain boundaries.
5081 B{C{False}} to reduce grains touching field boundaries only along
5082 the boundaries. I{(bool)}
5083 """
5084 pass
5085
5087 """
5088 Dilates a data field containing mask by specified amount using a distance
5089 measure.
5090
5091 Non-positive pixels in B{C{data_field}} will be replaced with ones if they are
5092 not farther than B{C{amount}} from the grain boundary as defined by B{C{dtype}}.
5093
5094 @since: 2.43
5095
5096 @param amount: How much the grains should be expanded, in pixels. It is
5097 inclusive, i.e. exterior pixels that are B{C{amount}} far from the
5098 border will be filled. I{(float)}
5099 @param dtype: Type of simple distance to use. Expected values: C{B{DISTANCE_TRANSFORM_CITYBLOCK}}, C{B{DISTANCE_TRANSFORM_CONN4}}, C{B{DISTANCE_TRANSFORM_CHESS}}, C{B{DISTANCE_TRANSFORM_CONN8}}, C{B{DISTANCE_TRANSFORM_OCTAGONAL48}}, C{B{DISTANCE_TRANSFORM_OCTAGONAL84}}, C{B{DISTANCE_TRANSFORM_OCTAGONAL}}, C{B{DISTANCE_TRANSFORM_EUCLIDEAN}}. I{(L{DistanceTransformType})}
5100 @param prevent_merging: B{C{True}} to prevent grain merging, i.e. the growth stops
5101 where two grains would merge. B{C{False}} to simply expand the
5102 grains, without regard to grain connectivity. I{(bool)}
5103 """
5104 pass
5105
5107 """
5108 Performs thinning of a data field containing mask.
5109
5110 The result of thinning is a ‘skeleton’ mask consisting of single-pixel thin
5111 lines.
5112
5113 @since: 2.48
5114
5115 """
5116 pass
5117
5119 """
5120 Fills voids in grains in a data field representing a mask.
5121
5122 Voids in grains are zero pixels in B{C{data_field}} from which no path exists through other zero pixels to the field
5123 boundary. The paths are considered in 8-connectivity because grains themselves are considered in 4-connectivity.
5124
5125 @since: 2.37
5126
5127 @param nonsimple: Pass B{C{True}} to fill also voids that are not simple-connected (e.g. ring-like). This can result in grain
5128 merging if a small grain is contained within a void. Pass B{C{False}} to fill only simple-connected grains. I{(bool)}
5129 @return: B{C{True}} if any voids were filled at all, B{C{False}} if no change was made. I{(bool)}
5130 """
5131 return None
5132
5134 """
5135 Marks local maxima or minima in a two-dimensional field.
5136
5137 Local (or regional) maximum is a contiguous set of pixels that have the same
5138 value and this value is sharply greater than the value of any pixel touching
5139 the set. A minimum is defined analogously. A field filled with a single
5140 value is considered to have neither minimum nor maximum.
5141
5142 @since: 2.37
5143
5144 @param extrema: Target field for the extrema mask. I{(L{DataField})}
5145 @param maxima: B{C{True}} to mark maxima, B{C{False}} to mark minima. I{(bool)}
5146 """
5147 pass
5148
5149 - def hough_line(x_gradient, y_gradient, result, hwidth, overlapping):
5151
5154
5157
5160
5162 return None, None, None, None
5163
5164 - def zoom_fft(isrc, rdest, idest, mx, my, fx0, fy0, fx1, fy1):
5165 """
5166 Computes Zoom FFT of a data field.
5167
5168 The output is DFTs, but computed for an arbitrary 2D Cartesian grid of frequencies along B{C{x}} and B{C{y}}. The frequencies
5169 do not have to be in any relation to the data sampling step.
5170
5171 The top-left pixel of output corresponds exactly to (B{C{fx0}},B{C{fy0}}) and the bottom right exactly to (B{C{fx1}},B{C{fy1}}). So
5172 the frequency sampling steps will be (B{C{fx1}} − B{C{fx0}})/(B{C{mx}} − 1) and (B{C{fy1}} − B{C{fy0}})/(B{C{my}} − 1), instead of the more usual
5173 division by B{C{mx}} and B{C{my}}. To follow the usual Gwyddion conventions, the output data field real size will be (B{C{fx1}}
5174 − B{C{fx0}})/(B{C{mx}} − 1)*B{C{mx}} along B{C{x}}, and similarly along B{C{y}}. If it seems confusing, just take the output as indexed by
5175 integers and work with that.
5176
5177 Frequency step of one corresponds to the normal DFT frequency step. Therefore, passing B{C{fx0}}=0, B{C{fx1}}=B{C{xres}}–1,
5178 B{C{fy0}}=0, B{C{fy1}}=B{C{yres}}–1 (where B{C{rsrc}} has B{C{xres}} × B{C{yres}} points), B{C{mx}}=B{C{xres}} and B{C{my}}=B{C{yres}} reproduces the usual DFT,
5179 except more slowly. The result is normalised as raw FFT and the units of the output data fields are unchanged.
5180
5181 The transform direction is always forward. Windowing or other preprocessing need to be done separately beforehand.
5182 They would be usually once, but followed by any number of (Zoom) FFTs.
5183
5184 @since: 2.62
5185
5186 @param isrc: Imaginary input data field. It can be B{C{None}} for real-to-complex transform. I{(L{DataField})}
5187 @param rdest: Real output data field. It will be resized to B{C{mx}} × B{C{my}} samples. I{(L{DataField})}
5188 @param idest: Imaginary output data field. It will be resized to B{C{mx}} × B{C{my}} samples. I{(L{DataField})}
5189 @param mx: The number of horizontal frequencies to compute. It must be at least 2. I{(int)}
5190 @param my: The number of vertical frequencies to compute. It must be at least 2. I{(int)}
5191 @param fx0: The first horizontal spatial frequency, measured in DFT frequency steps. I{(float)}
5192 @param fy0: The first vertical spatial frequency, measured in DFT frequency steps. I{(float)}
5193 @param fx1: The last horizontal spatial frequency, measured in DFT frequency steps. I{(float)}
5194 @param fy1: The last vetical spatial frequency, measured in DFT frequency steps. I{(float)}
5195 """
5196 pass
5197
5198 - def fft1d(iin, rout, iout, orientation, windowing, direction, interpolation, preserverms, level):
5199 """
5200 Transforms all rows or columns in a data field with Fast Fourier Transform.
5201
5202 If requested a windowing and/or leveling is applied to preprocess data to obtain reasonable results.
5203
5204 @param iin: Imaginary input data field. It can be B{C{None}} for real-to-complex transform which can be somewhat faster than
5205 complex-to-complex transform. I{(L{DataField})}
5206 @param rout: Real output data field, it will be resized to area size. I{(L{DataField})}
5207 @param iout: Imaginary output data field, it will be resized to area size. I{(L{DataField})}
5208 @param orientation: Orientation: pass B{C{ORIENTATION_HORIZONTAL}} to transform rows, B{C{ORIENTATION_VERTICAL}} to
5209 transform columns. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
5210 @param windowing: Windowing type. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
5211 @param direction: FFT direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
5212 @param interpolation: Interpolation type. Ignored since 2.8 as no resampling is performed. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
5213 @param preserverms: B{C{True}} to preserve RMS while windowing. I{(bool)}
5214 @param level: 0 to perform no leveling, 1 to subtract mean value, 2 to subtract line (the number can be interpreted as
5215 the first polynomial degree to keep, but only the enumerated three values are available). I{(int)}
5216 """
5217 pass
5218
5219 - def area_1dfft(iin, rout, iout, col, row, width, height, orientation, windowing, direction, interpolation, preserverms, level):
5220 """
5221 Transforms all rows or columns in a rectangular part of a data field with Fast Fourier Transform.
5222
5223 If requested a windowing and/or leveling is applied to preprocess data to obtain reasonable results.
5224
5225 @param iin: Imaginary input data field. It can be B{C{None}} for real-to-complex transform which can be somewhat faster than
5226 complex-to-complex transform. I{(L{DataField})}
5227 @param rout: Real output data field, it will be resized to area size. I{(L{DataField})}
5228 @param iout: Imaginary output data field, it will be resized to area size. I{(L{DataField})}
5229 @param col: Upper-left column coordinate. I{(int)}
5230 @param row: Upper-left row coordinate. I{(int)}
5231 @param width: Area width (number of columns), must be at least 2 for horizontal transforms. I{(int)}
5232 @param height: Area height (number of rows), must be at least 2 for vertical transforms. I{(int)}
5233 @param orientation: Orientation: pass B{C{ORIENTATION_HORIZONTAL}} to transform rows, B{C{ORIENTATION_VERTICAL}} to
5234 transform columns. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
5235 @param windowing: Windowing type. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
5236 @param direction: FFT direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
5237 @param interpolation: Interpolation type. Ignored since 2.8 as no resampling is performed. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
5238 @param preserverms: B{C{True}} to preserve RMS while windowing. I{(bool)}
5239 @param level: 0 to perform no leveling, 1 to subtract mean value, 2 to subtract lines (the number can be interpreted as
5240 the first polynomial degree to keep, but only the enumerated three values are available). I{(int)}
5241 """
5242 pass
5243
5244 - def fft1d_raw(iin, rout, iout, orientation, direction):
5245 """
5246 Transforms all rows or columns in a data field with Fast Fourier Transform.
5247
5248 No leveling, windowing nor scaling is performed.
5249
5250 The normalisation of FFT is symmetrical, so transformations in both directions are unitary.
5251
5252 Since 2.8 the dimensions need not to be from the set of sizes returned by L{gwy_fft_find_nice_size}().
5253
5254 @since: 2.1
5255
5256 @param iin: Imaginary input data field. It can be B{C{None}} for real-to-complex transform. I{(L{DataField})}
5257 @param rout: Real output data field, it will be resized to B{C{rin}} size. I{(L{DataField})}
5258 @param iout: Imaginary output data field, it will be resized to B{C{rin}} size. I{(L{DataField})}
5259 @param orientation: Orientation: pass B{C{ORIENTATION_HORIZONTAL}} to transform rows, B{C{ORIENTATION_VERTICAL}} to
5260 transform columns. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
5261 @param direction: FFT direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
5262 """
5263 pass
5264
5265 - def fft2d(iin, rout, iout, windowing, direction, interpolation, preserverms, level):
5266 """
5267 Calculates 2D Fast Fourier Transform of a rectangular a data field.
5268
5269 If requested a windowing and/or leveling is applied to preprocess data to obtain reasonable results.
5270
5271 Lateral dimensions, offsets and units are unchanged. See L{DataField.fft_postprocess}() for that.
5272
5273 @param iin: Imaginary input data field. It can be B{C{None}} for real-to-complex transform which can be somewhat faster than
5274 complex-to-complex transform. I{(L{DataField})}
5275 @param rout: Real output data field, it will be resized to area size. I{(L{DataField})}
5276 @param iout: Imaginary output data field, it will be resized to area size. I{(L{DataField})}
5277 @param windowing: Windowing type. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
5278 @param direction: FFT direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
5279 @param interpolation: Interpolation type. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
5280 @param preserverms: B{C{True}} to preserve RMS while windowing. I{(bool)}
5281 @param level: 0 to perform no leveling, 1 to subtract mean value, 2 to subtract plane (the number can be interpreted as
5282 the first polynomial degree to keep, but only the enumerated three values are available). I{(int)}
5283 """
5284 pass
5285
5286 - def area_2dfft(iin, rout, iout, col, row, width, height, windowing, direction, interpolation, preserverms, level):
5287 """
5288 Calculates 2D Fast Fourier Transform of a rectangular area of a data field.
5289
5290 If requested a windowing and/or leveling is applied to preprocess data to
5291 obtain reasonable results.
5292
5293 @param iin: Imaginary input data field. It can be B{C{None}} for real-to-complex transform which can be somewhat faster than
5294 complex-to-complex transform. I{(L{DataField})}
5295 @param rout: Real output data field, it will be resized to area size. I{(L{DataField})}
5296 @param iout: Imaginary output data field, it will be resized to area size. I{(L{DataField})}
5297 @param col: Upper-left column coordinate. I{(int)}
5298 @param row: Upper-left row coordinate. I{(int)}
5299 @param width: Area width (number of columns), must be at least 2. I{(int)}
5300 @param height: Area height (number of rows), must be at least 2. I{(int)}
5301 @param windowing: Windowing type. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
5302 @param direction: FFT direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
5303 @param interpolation: Interpolation type. Ignored since 2.8 as no resampling is performed. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
5304 @param preserverms: B{C{True}} to preserve RMS while windowing. I{(bool)}
5305 @param level: 0 to perform no leveling, 1 to subtract mean value, 2 to subtract plane (the number can be interpreted as
5306 the first polynomial degree to keep, but only the enumerated three values are available). I{(int)}
5307 """
5308 pass
5309
5311 """
5312 Calculates 2D Fast Fourier Transform of a data field.
5313
5314 No leveling, windowing nor scaling is performed.
5315
5316 The normalisation of FFT is symmetrical, so transformations in both directions are unitary.
5317
5318 Since 2.8 the dimensions need not to be from the set of sizes returned by L{gwy_fft_find_nice_size}().
5319
5320 Lateral dimensions, offsets and units are unchanged. See L{DataField.fft_postprocess}() for that.
5321
5322 Since 2.53 B{C{iout}} can be B{C{None}} for complex-to-real transforms. Note that this means Hermitean symmetry of the input
5323 data is assumed, i.e. about half of the input is ignored. If you want to extract the real part of a complex
5324 transform, you must pass a non-B{C{None}} B{C{iout}}.
5325
5326 @since: 2.1
5327
5328 @param iin: Imaginary input data field. It can be B{C{None}} for real-to-complex transform. I{(L{DataField})}
5329 @param rout: Real output data field, it will be resized to B{C{rin}} size. I{(L{DataField})}
5330 @param iout: Imaginary output data field, it will be resized to B{C{rin}} size. I{(L{DataField})}
5331 @param direction: FFT direction. It should be B{C{TRANSFORM_DIRECTION_FORWARD}} for real-to-complex transforms and
5332 B{C{TRANSFORM_DIRECTION_BACKWARD}} for complex-to-real transforms. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
5333 """
5334 pass
5335
5337 """
5338 Rearranges 2D FFT output to a human-friendly form.
5339
5340 Top-left, top-right, bottom-left and bottom-right sub-rectangles are swapped to obtain a humanized 2D FFT output
5341 with (0,0) in the centre.
5342
5343 More precisely, for even field dimensions the equally-sized blocks starting with the Nyquist frequency and with the
5344 zero frequency (constant component) will exchange places. For odd field dimensions, the block containing the zero
5345 frequency is one item larger and the constant component will actually end up in the exact centre.
5346
5347 Also note if both dimensions are even, this function is involutory and identical to
5348 L{DataField.fft2d_dehumanize}(). However, if any dimension is odd, L{DataField.fft2d_humanize}() and
5349 L{DataField.fft2d_dehumanize}() are different, therefore they must be paired properly.
5350
5351 """
5352 pass
5353
5355 """
5356 Rearranges 2D FFT output back from the human-friendly form.
5357
5358 Top-left, top-right, bottom-left and bottom-right sub-rectangles are swapped to reshuffle a humanized 2D FFT output
5359 back into the natural positions.
5360
5361 See L{DataField.fft2d_humanize}() for discussion.
5362
5363 @since: 2.8
5364
5365 """
5366 pass
5367
5368 - def fft_postprocess(humanize):
5369 """
5370 Updates units, dimensions and offsets for a 2D FFT-processed field.
5371
5372 The field is expected to have dimensions and units of the original direct-space data. The lateral units and
5373 resolutions are updated to correspond to its Fourier transform.
5374
5375 The real dimensions are set for spatial frequencies, not wavevectors. For wavevector lateral coordinates, mutiply
5376 all real dimensions and offsets by 2*B{C{glib.PI}}.
5377
5378 If B{C{humanize}} is B{C{True}} L{DataField.fft2d_humanize}() is applied to the field data and the lateral offsets are set
5379 accordingly. Otherwise the offsets are cleared.
5380
5381 Value units are kept intact.
5382
5383 @since: 2.38
5384
5385 @param humanize: B{C{True}} to rearrange data to have the frequency origin in the centre. I{(bool)}
5386 """
5387 pass
5388
5389 - def fft_filter_1d(result_field, weights, orientation, interpolation):
5390 """
5391 Performs 1D FFT filtering of a data field.
5392
5393 @param result_field: A data field to store the result to. It will be resampled to B{C{data_field}}'s size. I{(L{DataField})}
5394 @param weights: Filter weights for the lower half of the spectrum (the other half is symmetric). Its size can be
5395 arbitrary, it will be interpolated. I{(L{DataLine})}
5396 @param orientation: Filter direction. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
5397 @param interpolation: The interpolation to use for resampling. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
5398 """
5399 pass
5400
5402 """
5403 Performs two-dimensional windowing of a data field in preparation for 2D FFT.
5404
5405 The same windowing function is used row-wise and column-wise.
5406
5407 @since: 2.62
5408
5409 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
5410 """
5411 pass
5412
5414 """
5415 Performs row-wise or column-wise windowing of a data field in preparation for 1D FFT.
5416
5417 @since: 2.62
5418
5419 @param orientation: Windowing orientation (the same as corresponding FFT orientation). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
5420 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
5421 """
5422 pass
5423
5424 - def cwt(interpolation, scale, wtype):
5425 """
5426 Computes a continuous wavelet transform (CWT) at given scale and using given wavelet.
5427
5428 @param interpolation: Interpolation type. Ignored since 2.8 as no resampling is performed. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
5429 @param scale: Wavelet scale. I{(float)}
5430 @param wtype: Wavelet type. Expected values: C{B{2DCWT_GAUSS}}, C{B{2DCWT_HAT}}. I{(L{2DCWTWaveletType})}
5431 """
5432 pass
5433
5435 """
5436 Fits a plane through a rectangular part of a data field.
5437
5438 The coefficients can be used for plane leveling using the same relation
5439 as in L{DataField.fit_plane}(), counting indices from area top left
5440 corner.
5441
5442 @param mask: Mask of values to take values into account, or B{C{None}} for full
5443 B{C{data_field}}. Values equal to 0.0 and below cause corresponding
5444 B{C{data_field}} samples to be ignored, values equal to 1.0 and above
5445 cause inclusion of corresponding B{C{data_field}} samples. The behaviour
5446 for values inside (0.0, 1.0) is undefined (it may be specified
5447 in the future). I{(L{DataField})}
5448 @param col: Upper-left column coordinate. I{(int)}
5449 @param row: Upper-left row coordinate. I{(int)}
5450 @param width: Area width (number of columns). I{(int)}
5451 @param height: Area height (number of rows). I{(int)}
5452 @return: Tuple consisting of 3 values (B{C{pa}}, B{C{pbx}}, B{C{pby}}). (I{(float)}, I{(float)}, I{(float)})
5453 """
5454 return None, None, None
5455
5457 """
5458 Fits a plane through a data field.
5459
5460 The coefficients can be used for plane leveling using relation
5461 data[i] := data[i] - (pa + pby*i + pbx*j);
5462
5463 @return: Tuple consisting of 3 values (B{C{pa}}, B{C{pbx}}, B{C{pby}}). (I{(float)}, I{(float)}, I{(float)})
5464 """
5465 return None, None, None
5466
5468 """
5469 Calculates the inclination of a plane close to the dominant plane in a data
5470 field.
5471
5472 The dominant plane is determined by taking into account larger local slopes
5473 with exponentially smaller weight.
5474
5475 This is the basis of so-called facet levelling algorithm. Usually, the
5476 plane found by this method is subtracted using L{DataField.plane_level}()
5477 and the entire process is repeated until it converges. A convergence
5478 criterion may be sufficiently small values of the x and y plane
5479 coefficients. Note that since L{DataField.plane_level}() uses pixel-based
5480 lateral coordinates, the coefficients must be divided by
5481 L{DataField.get_dx}(data_field) and
5482 L{DataField.get_dy}(data_field) to obtain physical plane
5483 coefficients.
5484
5485 @since: 2.37
5486
5487 @param mfield: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
5488 @param masking: Masking mode to use. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
5489 @return: Tuple consisting of 4 values (B{C{value}}, B{C{pa}}, B{C{pbx}}, B{C{pby}}). (I{(bool)}, I{(float)}, I{(float)}, I{(float)})
5490 """
5491 return None, None, None, None
5492
5494 """
5495 Subtracts plane from a data field.
5496
5497 See L{DataField.fit_plane}() for details.
5498
5499 @param a: Constant coefficient. I{(float)}
5500 @param bx: X plane coefficient. I{(float)}
5501 @param by: Y plane coefficient. I{(float)}
5502 """
5503 pass
5504
5506 """
5507 Performs rotation of plane along x and y axis.
5508
5509 @param xangle: Rotation angle in x direction (rotation along y axis, in radians). I{(float)}
5510 @param yangle: Rotation angle in y direction (rotation along x axis, in radians). I{(float)}
5511 @param interpolation: Interpolation type (can be only of two-point type). Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
5512 """
5513 pass
5514
5515 - def fit_lines(col, row, width, height, degree, exclude, orientation):
5516 """
5517 Independently levels profiles on each row/column in a data field.
5518
5519 Lines that have no intersection with area selected by B{C{ulcol}}, B{C{ulrow}},
5520 B{C{brcol}}, B{C{brrow}} are always leveled as a whole. Lines that have intersection
5521 with selected area, are leveled using polynomial coefficients computed only
5522 from data inside (or outside for B{C{exclude}} = B{C{True}}) the area.
5523
5524 @param col: Upper-left column coordinate. I{(int)}
5525 @param row: Upper-left row coordinate. I{(int)}
5526 @param width: Area width (number of columns). I{(int)}
5527 @param height: Area height (number of rows). I{(int)}
5528 @param degree: Fitted polynomial degree. I{(int)}
5529 @param exclude: If B{C{True}}, outside of area selected by B{C{ulcol}}, B{C{ulrow}}, B{C{brcol}},
5530 B{C{brrow}} will be used for polynomial coefficients computation,
5531 instead of inside. I{(bool)}
5532 @param orientation: Line orientation. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
5533 """
5534 pass
5535
5537 """
5538 Convenience function to get just one quantity from
5539 L{DataField.area_fit_local_planes}().
5540
5541
5542 @param size: Neighbourhood size. I{(int)}
5543 @param col: Upper-left column coordinate. I{(int)}
5544 @param row: Upper-left row coordinate. I{(int)}
5545 @param width: Area width (number of columns). I{(int)}
5546 @param height: Area height (number of rows). I{(int)}
5547 @param type: The type of requested quantity. Expected values: C{B{PLANE_FIT_A}}, C{B{PLANE_FIT_BX}}, C{B{PLANE_FIT_BY}}, C{B{PLANE_FIT_ANGLE}}, C{B{PLANE_FIT_SLOPE}}, C{B{PLANE_FIT_S0}}, C{B{PLANE_FIT_S0_REDUCED}}. I{(L{PlaneFitQuantity})}
5548 @param result: A data field to store result to, or B{C{None}} to allocate a new one. I{(L{DataField})}
5549 @return: B{C{result}} if it isn't B{C{None}}, otherwise a newly allocated data field. I{(L{DataField})}
5550 """
5551 return None
5552
5554 """
5555 Convenience function to get just one quantity from
5556 L{DataField.fit_local_planes}().
5557
5558
5559 @param size: Neighbourhood size. I{(int)}
5560 @param type: The type of requested quantity. Expected values: C{B{PLANE_FIT_A}}, C{B{PLANE_FIT_BX}}, C{B{PLANE_FIT_BY}}, C{B{PLANE_FIT_ANGLE}}, C{B{PLANE_FIT_SLOPE}}, C{B{PLANE_FIT_S0}}, C{B{PLANE_FIT_S0_REDUCED}}. I{(L{PlaneFitQuantity})}
5561 @param result: A data field to store result to, or B{C{None}} to allocate a new one. I{(L{DataField})}
5562 @return: B{C{result}} if it isn't B{C{None}}, otherwise a newly allocated data field. I{(L{DataField})}
5563 """
5564 return None
5565
5567 """
5568 Calculates stray field for perpendicular media, based on a mask showing the
5569 magnetisation orientation.
5570
5571 @since: 2.51
5572
5573 @param out: Target data field to put the result to. It will be resized to match
5574 B{C{mfield}}. I{(L{DataField})}
5575 @param height: Height above the surface. I{(float)}
5576 @param thickness: Film thickness. I{(float)}
5577 @param sigma: Magnetic charge. I{(float)}
5578 @param walls: Include domain walls. I{(bool)}
5579 @param wall_delta: Domain wall thickness I{(float)}
5580 """
5581 pass
5582
5584 """
5585 Performs correction of magnetic data for cantilever tilt.
5586
5587 @since: 2.54
5588
5589 @param angle: I{(float)}
5590 @param orientation: Cantilever orientation with respect of the data. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
5591 """
5592 pass
5593
5595 """
5596 Calculates force as evaluated from z-component of the magnetic field for a given probe type.
5597
5598 @since: 2.51
5599
5600 @param fz: Target data field to put the result to. It will be resized to match
5601 B{C{hz}}. I{(L{DataField})}
5602 @param type: Probe type. Expected values: C{B{MFM_PROBE_CHARGE}}, C{B{MFM_PROBE_BAR}}. I{(L{MFMProbeType})}
5603 @param mtip: Probe magnetic moment. I{(float)}
5604 @param bx: x size for parallelpiped probe. I{(float)}
5605 @param by: y size for parallelpiped probe. I{(float)}
5606 @param length: length (z size) for parallelpiped probe. I{(float)}
5607 """
5608 pass
5609
5611 """
5612 Shifts magnetic field to a different lift height above the surface.
5613
5614 Positive B{C{zdiff}} means away from the measured surface and blurring the data.
5615 Negative B{C{zdiff}} means shifting towards (or within) the measured surface
5616 and sharpening the data. For negative B{C{zdiff}} the result grows exponentially
5617 and is generally not very useful.
5618
5619 @since: 2.51
5620
5621 @param out: Target data field to put the result to. I{(L{DataField})}
5622 @param zdiff: The shift distance in physical units. I{(float)}
5623 """
5624 pass
5625
5627 """
5628 Estimates the height difference between two magnetic field images.
5629
5630 See L{DataField.mfm_shift_z}() for the sign convention. It is generally
5631 only meaningful to estimate the shift whe B{C{shifted}} was measured at larger
5632 lift height than B{C{dfield}}.
5633
5634 @since: 2.51
5635
5636 @param shifted: Data field containing magnetic field component measured at
5637 a different lift height. I{(L{DataField})}
5638 @param zdiffmin: Start of shift scan range. I{(float)}
5639 @param zdiffmax: Start of shift scan range. I{(float)}
5640 @return: The estimated shift between B{C{shifted}} and B{C{dfield}}. I{(float)}
5641 """
5642 return None
5643
5644 - def mfm_parallel_medium(height, size_a, size_b, size_c, magnetisation, thickness, component):
5645 """
5646 Calculates magnetic field or its derivatives above a simple medium
5647 consisting of stripes of left and right direction magnetisation.
5648 Results are added to the B{C{hfield}} array, so it should be cleared if
5649 function is run only once.
5650
5651 @since: 2.51
5652
5653 @param height: Height above surface. I{(float)}
5654 @param size_a: Left direction oriented area width. I{(float)}
5655 @param size_b: Right direction orientated area width. I{(float)}
5656 @param size_c: Gap size. I{(float)}
5657 @param magnetisation: Remanent magnetisation. I{(float)}
5658 @param thickness: Film thickness. I{(float)}
5659 @param component: Component to output. Expected values: C{B{MFM_COMPONENT_HX}}, C{B{MFM_COMPONENT_HY}}, C{B{MFM_COMPONENT_HZ}}, C{B{MFM_COMPONENT_DHZ_DZ}}, C{B{MFM_COMPONENT_D2HZ_DZ2}}. I{(L{MFMComponentType})}
5660 """
5661 pass
5662
5664 """
5665 Calculates magnetic field or its derivatives above a flat current line (stripe).
5666 Results are added to the B{C{hfield}} array, so it should be cleared if
5667 function is run only once.
5668
5669 @since: 2.51
5670
5671 @param height: Height above surface. I{(float)}
5672 @param width: Current line width. I{(float)}
5673 @param position: Current line x position in the resulting array. I{(float)}
5674 @param current: Curent passing through the line. I{(float)}
5675 @param component: Component to output. Expected values: C{B{MFM_COMPONENT_HX}}, C{B{MFM_COMPONENT_HY}}, C{B{MFM_COMPONENT_HZ}}, C{B{MFM_COMPONENT_DHZ_DZ}}, C{B{MFM_COMPONENT_D2HZ_DZ2}}. I{(L{MFMComponentType})}
5676 """
5677 pass
5678
5680 """
5681 Finds the maximum value of a data field.
5682
5683 This quantity is cached.
5684
5685
5686 @return: The maximum value. I{(float)}
5687 """
5688 return None
5689
5691 """
5692 Finds the minimum value of a data field.
5693
5694 This quantity is cached.
5695
5696
5697 @return: The minimum value. I{(float)}
5698 """
5699 return None
5700
5702 """
5703 Finds minimum and maximum values of a data field.
5704
5705 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
5706 """
5707 return None, None
5708
5710 """
5711 Computes average value of a data field.
5712
5713 This quantity is cached.
5714
5715
5716 @return: The average value. I{(float)}
5717 """
5718 return None
5719
5721 """
5722 Computes root mean square value of a data field.
5723
5724 The root mean square value is calculated with respect to the mean value.
5725 See L{DataField.get_mean_square}() for a similar function which does not
5726 subtract the mean value.
5727
5728 This quantity is cached.
5729
5730
5731 @return: The root mean square value. I{(float)}
5732 """
5733 return None
5734
5736 """
5737 Computes mean square value of a data field.
5738
5739 See L{DataField.area_get_mean_square}() for remarks.
5740
5741 @since: 2.52
5742
5743 @return: The mean square value. I{(float)}
5744 """
5745 return None
5746
5748 """
5749 Sums all values in a data field.
5750
5751 This quantity is cached.
5752
5753
5754 @return: The sum of all values. I{(float)}
5755 """
5756 return None
5757
5768
5770 """
5771 Computes surface area of a data field.
5772
5773 This quantity is cached.
5774
5775
5776 @return: The surface area. I{(float)}
5777 """
5778 return None
5779
5781 """
5782 Computes root mean square surface slope (Sdq) of a data field.
5783
5784 @since: 2.58
5785
5786 @return: The root mean square surface slope. I{(float)}
5787 """
5788 return None
5789
5791 """
5792 Computes the total variation of a data field.
5793
5794 See L{DataField.area_get_variation}() for the definition.
5795
5796 This quantity is cached.
5797
5798 @since: 2.38
5799
5800 @return: The variation. I{(float)}
5801 """
5802 return None
5803
5805 """
5806 Computes the entropy of a data field.
5807
5808 See L{DataField.area_get_entropy}() for the definition.
5809
5810 This quantity is cached.
5811
5812 @since: 2.42
5813
5814 @return: The value distribution entropy. I{(float)}
5815 """
5816 return None
5817
5819 """
5820 Computes the entropy of a two-dimensional point cloud.
5821
5822 Each pair of corresponding B{C{xfield}} and B{C{yfield}} pixels is assumed to
5823 represent the coordinates (B{C{x}},B{C{y}}) of a point in plane. Hence they must have
5824 the same dimensions.
5825
5826 @since: 2.44
5827
5828 @param yfield: A data field containing the B{C{y}}-coordinates. I{(L{DataField})}
5829 @return: The two-dimensional distribution entropy. I{(float)}
5830 """
5831 return None
5832
5834 """
5835 Finds the maximum value in a rectangular part of a data field.
5836
5837
5838 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
5839 @param col: Upper-left column coordinate. I{(int)}
5840 @param row: Upper-left row coordinate. I{(int)}
5841 @param width: Area width (number of columns). I{(int)}
5842 @param height: Area height (number of rows). I{(int)}
5843 @return: The maximum value. When the number of samples to calculate
5844 maximum of is zero, -B{C{glib.MAXDOUBLE}} is returned. I{(float)}
5845 """
5846 return None
5847
5849 """
5850 Finds the minimum value in a rectangular part of a data field.
5851
5852
5853 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
5854 @param col: Upper-left column coordinate. I{(int)}
5855 @param row: Upper-left row coordinate. I{(int)}
5856 @param width: Area width (number of columns). I{(int)}
5857 @param height: Area height (number of rows). I{(int)}
5858 @return: The minimum value. When the number of samples to calculate
5859 minimum of is zero, -B{C{glib.MAXDOUBLE}} is returned. I{(float)}
5860 """
5861 return None
5862
5864 """
5865 Finds minimum and maximum values in a rectangular part of a data field.
5866
5867 This function is equivalent to calling
5868 B{C{L{DataField.area_get_min_max_mask}}}()
5869 with masking mode B{C{MASK_INCLUDE}}.
5870
5871 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
5872 @param col: Upper-left column coordinate. I{(int)}
5873 @param row: Upper-left row coordinate. I{(int)}
5874 @param width: Area width (number of columns). I{(int)}
5875 @param height: Area height (number of rows). I{(int)}
5876 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
5877 """
5878 return None, None
5879
5881 """
5882 Finds minimum and maximum values in a rectangular part of a data field.
5883
5884 @since: 2.18
5885
5886 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
5887 @param mode: Masking mode to use. See the introduction for description of
5888 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
5889 @param col: Upper-left column coordinate. I{(int)}
5890 @param row: Upper-left row coordinate. I{(int)}
5891 @param width: Area width (number of columns). I{(int)}
5892 @param height: Area height (number of rows). I{(int)}
5893 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
5894 """
5895 return None, None
5896
5898 """
5899 Computes average value of a rectangular part of a data field.
5900
5901 This function is equivalent to calling B{C{L{DataField.area_get_avg_mask}}}()
5902 with masking mode B{C{MASK_INCLUDE}}.
5903
5904
5905 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
5906 @param col: Upper-left column coordinate. I{(int)}
5907 @param row: Upper-left row coordinate. I{(int)}
5908 @param width: Area width (number of columns). I{(int)}
5909 @param height: Area height (number of rows). I{(int)}
5910 @return: The average value. I{(float)}
5911 """
5912 return None
5913
5915 """
5916 Computes average value of a rectangular part of a data field.
5917
5918 @since: 2.18
5919
5920 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
5921 @param mode: Masking mode to use. See the introduction for description of
5922 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
5923 @param col: Upper-left column coordinate. I{(int)}
5924 @param row: Upper-left row coordinate. I{(int)}
5925 @param width: Area width (number of columns). I{(int)}
5926 @param height: Area height (number of rows). I{(int)}
5927 @return: The average value. I{(float)}
5928 """
5929 return None
5930
5932 """
5933 Computes root mean square value of a rectangular part of a data field.
5934
5935 The root mean square value is calculated with respect to the mean value.
5936
5937 This function is equivalent to calling B{C{L{DataField.area_get_rms_mask}}}()
5938 with masking mode B{C{MASK_INCLUDE}}.
5939
5940
5941 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
5942 @param col: Upper-left column coordinate. I{(int)}
5943 @param row: Upper-left row coordinate. I{(int)}
5944 @param width: Area width (number of columns). I{(int)}
5945 @param height: Area height (number of rows). I{(int)}
5946 @return: The root mean square value. I{(float)}
5947 """
5948 return None
5949
5951 """
5952 Computes root mean square value of deviations of a rectangular part of a
5953 data field.
5954
5955 The root mean square value is calculated with respect to the mean value.
5956
5957 @since: 2.18
5958
5959 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
5960 @param mode: Masking mode to use. See the introduction for description of
5961 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
5962 @param col: Upper-left column coordinate. I{(int)}
5963 @param row: Upper-left row coordinate. I{(int)}
5964 @param width: Area width (number of columns). I{(int)}
5965 @param height: Area height (number of rows). I{(int)}
5966 @return: The root mean square value of deviations from the mean value. I{(float)}
5967 """
5968 return None
5969
5971 """
5972 Computes grain-wise root mean square value of deviations of a rectangular
5973 part of a data field.
5974
5975 Grain-wise means that the mean value is determined for each grain (i.e.
5976 cotinguous part of the mask or inverted mask) separately and the deviations
5977 are calculated from these mean values.
5978
5979 @since: 2.29
5980
5981 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
5982 @param mode: Masking mode to use. See the introduction for description of
5983 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
5984 @param col: Upper-left column coordinate. I{(int)}
5985 @param row: Upper-left row coordinate. I{(int)}
5986 @param width: Area width (number of columns). I{(int)}
5987 @param height: Area height (number of rows). I{(int)}
5988 @return: The root mean square value of deviations from the mean value. I{(float)}
5989 """
5990 return None
5991
5993 """
5994 Sums values of a rectangular part of a data field.
5995
5996 This function is equivalent to calling B{C{L{DataField.area_get_sum_mask}}}()
5997 with masking mode B{C{MASK_INCLUDE}}.
5998
5999
6000 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6001 @param col: Upper-left column coordinate. I{(int)}
6002 @param row: Upper-left row coordinate. I{(int)}
6003 @param width: Area width (number of columns). I{(int)}
6004 @param height: Area height (number of rows). I{(int)}
6005 @return: The sum of all values inside area. I{(float)}
6006 """
6007 return None
6008
6010 """
6011 Sums values of a rectangular part of a data field.
6012
6013 @since: 2.18
6014
6015 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6016 @param mode: Masking mode to use. See the introduction for description of
6017 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6018 @param col: Upper-left column coordinate. I{(int)}
6019 @param row: Upper-left row coordinate. I{(int)}
6020 @param width: Area width (number of columns). I{(int)}
6021 @param height: Area height (number of rows). I{(int)}
6022 @return: The sum of all values inside area. I{(float)}
6023 """
6024 return None
6025
6043
6060
6062 """
6063 Computes surface area of a rectangular part of a data field.
6064
6065 This function is equivalent to calling
6066 B{C{L{DataField.area_get_surface_area_mask}}}() with masking mode
6067 B{C{MASK_INCLUDE}}.
6068
6069
6070 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6071 @param col: Upper-left column coordinate. I{(int)}
6072 @param row: Upper-left row coordinate. I{(int)}
6073 @param width: Area width (number of columns). I{(int)}
6074 @param height: Area height (number of rows). I{(int)}
6075 @return: The surface area. I{(float)}
6076 """
6077 return None
6078
6080 """
6081 Computes surface area of a rectangular part of a data field.
6082
6083 This quantity makes sense only if the lateral dimensions and values of
6084 B{C{data_field}} are the same physical quantities.
6085
6086 @since: 2.18
6087
6088 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6089 @param mode: Masking mode to use. See the introduction for description of
6090 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6091 @param col: Upper-left column coordinate. I{(int)}
6092 @param row: Upper-left row coordinate. I{(int)}
6093 @param width: Area width (number of columns). I{(int)}
6094 @param height: Area height (number of rows). I{(int)}
6095 @return: The surface area. I{(float)}
6096 """
6097 return None
6098
6100 """
6101 Computes root mean square surface slope (Sdq) of a rectangular part of
6102 a data field.
6103
6104 @since: 2.58
6105
6106 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6107 @param mode: Masking mode to use. See the introduction for description of
6108 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6109 @param col: Upper-left column coordinate. I{(int)}
6110 @param row: Upper-left row coordinate. I{(int)}
6111 @param width: Area width (number of columns). I{(int)}
6112 @param height: Area height (number of rows). I{(int)}
6113 @return: The root mean square surface slope. I{(float)}
6114 """
6115 return None
6116
6118 """
6119 Computes mean square value of a rectangular part of a data field.
6120
6121 Unlike L{DataField.get_rms}(), this function does I{not}
6122 subtract the mean value beforehand. Therefore, it is useful to sum the
6123 squared values of data fields which can have the zero level set differently,
6124 for instance when the field contains a distribution.
6125
6126 @since: 2.52
6127
6128 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6129 @param mode: Masking mode to use. See the introduction for description of
6130 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6131 @param col: Upper-left column coordinate. I{(int)}
6132 @param row: Upper-left row coordinate. I{(int)}
6133 @param width: Area width (number of columns). I{(int)}
6134 @param height: Area height (number of rows). I{(int)}
6135 @return: The mean square value. I{(float)}
6136 """
6137 return None
6138
6140 """
6141 Calculates estimates of value distribution entropy at various scales.
6142
6143 @since: 2.44
6144
6145 @param target_line: A data line to store the result to. It will be resampled to
6146 B{C{maxdiv}}+1 items. I{(L{DataLine})}
6147 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6148 @param mode: Masking mode to use. See the introduction for description of
6149 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6150 @param col: Upper-left column coordinate. I{(int)}
6151 @param row: Upper-left row coordinate. I{(int)}
6152 @param width: Area width (number of columns). I{(int)}
6153 @param height: Area height (number of rows). I{(int)}
6154 @param maxdiv: Maximum number of divisions of the value range. Pass zero to
6155 choose it automatically. I{(int)}
6156 @return: The best estimate, as L{DataField.area_get_entropy}(). I{(float)}
6157 """
6158 return None
6159
6161 """
6162 Calculates estimates of entropy of two-dimensional point cloud at various
6163 scales.
6164
6165 @since: 2.44
6166
6167 @param yfield: A data field containing the B{C{y}}-coordinates. I{(L{DataField})}
6168 @param target_line: A data line to store the result to. It will be resampled to
6169 B{C{maxdiv}}+1 items. I{(L{DataLine})}
6170 @param maxdiv: Maximum number of divisions of the value range. Pass zero to
6171 choose it automatically. I{(int)}
6172 @return: The best estimate, as L{DataField.get_entropy_2d}(). I{(float)}
6173 """
6174 return None
6175
6177 """
6178 Computes the total variation of a rectangular part of a data field.
6179
6180 The total variation is estimated as the integral of the absolute value of
6181 local gradient.
6182
6183 This quantity has the somewhat odd units of value unit times lateral unit.
6184 It can be envisioned as follows. If the surface has just two height levels
6185 (upper and lower planes) then the quantity is the length of the boundary
6186 between the upper and lower part, multiplied by the step height. If the
6187 surface is piece-wise constant, then the variation is the step height
6188 integrated along the boundaries between the constant parts. Therefore, for
6189 non-fractal surfaces it scales with the linear dimension of the image, not
6190 with its area, despite being an area integral.
6191
6192 @since: 2.38
6193
6194 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6195 @param mode: Masking mode to use. See the introduction for description of
6196 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6197 @param col: Upper-left column coordinate. I{(int)}
6198 @param row: Upper-left row coordinate. I{(int)}
6199 @param width: Area width (number of columns). I{(int)}
6200 @param height: Area height (number of rows). I{(int)}
6201 @return: The variation. I{(float)}
6202 """
6203 return None
6204
6206 """
6207 Estimates the entropy of field data distribution.
6208
6209 The estimate is calculated as B{C{S}} = ln(B{C{n}} Δ) − 1/B{C{n}} ∑ B{C{n_i}} ln(B{C{n_i}}), where
6210 B{C{n}} is the number of pixels considered, Δ the bin size and B{C{n_i}} the count in
6211 the B{C{i}}-th bin. If B{C{S}} is plotted as a function of the bin size Δ, it is,
6212 generally, a growing function with a plateau for ‘reasonable’ bin sizes.
6213 The estimate is taken at the plateau. If no plateau is found, which means
6214 the distribution is effectively a sum of δ-functions, -B{C{glib.MAXDOUBLE}} is
6215 returned.
6216
6217 It should be noted that this estimate may be biased.
6218
6219 @since: 2.42
6220
6221 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6222 @param mode: Masking mode to use. See the introduction for description of
6223 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6224 @param col: Upper-left column coordinate. I{(int)}
6225 @param row: Upper-left row coordinate. I{(int)}
6226 @param width: Area width (number of columns). I{(int)}
6227 @param height: Area height (number of rows). I{(int)}
6228 @return: The estimated entropy of the data values. The entropy of no data
6229 or a single single is returned as -B{C{glib.MAXDOUBLE}}. I{(float)}
6230 """
6231 return None
6232
6234 """
6235 Computes volume of a rectangular part of a data field.
6236
6237 @since: 2.3
6238
6239 @param basis: The basis or background for volume calculation if not B{C{None}}.
6240 The height of each vertex is then the difference between
6241 B{C{data_field}} value and B{C{basis}} value. Value B{C{None}} is the same
6242 as passing all zeroes for the basis. I{(L{DataField})}
6243 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6244 @param col: Upper-left column coordinate. I{(int)}
6245 @param row: Upper-left row coordinate. I{(int)}
6246 @param width: Area width (number of columns). I{(int)}
6247 @param height: Area height (number of rows). I{(int)}
6248 @return: The volume. I{(float)}
6249 """
6250 return None
6251
6253 """
6254 Computes data field value range with outliers cut-off.
6255
6256 The purpose of this function is to find a range is suitable for false color
6257 mapping. The precise method how it is calculated is unspecified and may be
6258 subject to changes.
6259
6260 However, it is guaranteed minimum <= B{C{from}} <= B{C{to}} <= maximum.
6261
6262 This quantity is cached.
6263
6264 @return: Tuple consisting of 2 values (B{C{from_}}, B{C{to}}). (I{(float)}, I{(float)})
6265 """
6266 return None, None
6267
6269 """
6270 Computes basic statistical quantities of a data field.
6271
6272 Note the kurtosis returned by this function returns is the excess kurtosis
6273 which is zero for the Gaussian distribution (not 3).
6274
6275 @return: Tuple consisting of 5 values (B{C{avg}}, B{C{ra}}, B{C{rms}}, B{C{skew}}, B{C{kurtosis}}). (I{(float)}, I{(float)}, I{(float)}, I{(float)}, I{(float)})
6276 """
6277 return None, None, None, None, None
6278
6280 """
6281 Computes basic statistical quantities of a rectangular part of a data field.
6282
6283 This function is equivalent to calling B{C{L{DataField.area_get_stats_mask}}}()
6284 with masking mode B{C{MASK_INCLUDE}}.
6285
6286 Note the kurtosis returned by this function returns is the excess kurtosis
6287 which is zero for the Gaussian distribution (not 3).
6288
6289 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6290 @param col: Upper-left column coordinate. I{(int)}
6291 @param row: Upper-left row coordinate. I{(int)}
6292 @param width: Area width (number of columns). I{(int)}
6293 @param height: Area height (number of rows). I{(int)}
6294 @return: Tuple consisting of 5 values (B{C{avg}}, B{C{ra}}, B{C{rms}}, B{C{skew}}, B{C{kurtosis}}). (I{(float)}, I{(float)}, I{(float)}, I{(float)}, I{(float)})
6295 """
6296 return None, None, None, None, None
6297
6299 """
6300 Computes basic statistical quantities of a rectangular part of a data field.
6301
6302 Note the kurtosis returned by this function returns is the excess kurtosis
6303 which is zero for the Gaussian distribution (not 3).
6304
6305 @since: 2.18
6306
6307 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6308 @param mode: Masking mode to use. See the introduction for description of
6309 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6310 @param col: Upper-left column coordinate. I{(int)}
6311 @param row: Upper-left row coordinate. I{(int)}
6312 @param width: Area width (number of columns). I{(int)}
6313 @param height: Area height (number of rows). I{(int)}
6314 @return: Tuple consisting of 5 values (B{C{avg}}, B{C{ra}}, B{C{rms}}, B{C{skew}}, B{C{kurtosis}}). (I{(float)}, I{(float)}, I{(float)}, I{(float)}, I{(float)})
6315 """
6316 return None, None, None, None, None
6317
6319 """
6320 Counts data samples in given range.
6321
6322 No assertion is made about the values of B{C{above}} and B{C{below}}, in other words
6323 B{C{above}} may be larger than B{C{below}}. To count samples in an open interval
6324 instead of a closed interval, exchange B{C{below}} and B{C{above}} and then subtract
6325 the B{C{nabove}} and B{C{nbelow}} from B{C{width}}*B{C{height}} to get the complementary counts.
6326
6327 With this trick the common task of counting positive values can be
6328 realized:
6329 <informalexample><programlisting>
6330 L{DataField.area_count_in_range}(data_field, None,
6331 col, row, width, height,
6332 0.0, 0.0, &count, None);
6333 count = width*height - count;
6334 </programlisting></informalexample>
6335
6336 @param mask: Mask specifying which values to take into account, or B{C{None}}. I{(L{DataField})}
6337 @param col: Upper-left column coordinate. I{(int)}
6338 @param row: Upper-left row coordinate. I{(int)}
6339 @param width: Area width (number of columns). I{(int)}
6340 @param height: Area height (number of rows). I{(int)}
6341 @param below: Upper bound to compare data to. The number of samples less
6342 than or equal to B{C{below}} is stored in B{C{nbelow}}. I{(float)}
6343 @param above: Lower bound to compare data to. The number of samples greater
6344 than or equal to B{C{above}} is stored in B{C{nabove}}. I{(float)}
6345 @return: Tuple consisting of 2 values (B{C{nbelow}}, B{C{nabove}}). (I{(int)}, I{(int)})
6346 """
6347 return None, None
6348
6349 - def area_dh(mask, target_line, col, row, width, height, nstats):
6350 """
6351 Calculates distribution of heights in a rectangular part of data field.
6352
6353 @param mask: Mask specifying which values to take into account, or B{C{None}}. I{(L{DataField})}
6354 @param target_line: A data line to store the distribution to. It will be
6355 resampled to requested width. I{(L{DataLine})}
6356 @param col: Upper-left column coordinate. I{(int)}
6357 @param row: Upper-left row coordinate. I{(int)}
6358 @param width: Area width (number of columns). I{(int)}
6359 @param height: Area height (number of rows). I{(int)}
6360 @param nstats: The number of samples to take on the distribution function. If
6361 nonpositive, a suitable resolution is determined automatically. I{(int)}
6362 """
6363 pass
6364
6365 - def dh(target_line, nstats):
6366 """
6367 Calculates distribution of heights in a data field.
6368
6369 @param target_line: A data line to store the distribution to. It will be
6370 resampled to requested width. I{(L{DataLine})}
6371 @param nstats: The number of samples to take on the distribution function. If
6372 nonpositive, a suitable resolution is determined automatically. I{(int)}
6373 """
6374 pass
6375
6376 - def area_cdh(mask, target_line, col, row, width, height, nstats):
6377 """
6378 Calculates cumulative distribution of heights in a rectangular part of data
6379 field.
6380
6381 @param mask: Mask specifying which values to take into account, or B{C{None}}. I{(L{DataField})}
6382 @param target_line: A data line to store the distribution to. It will be
6383 resampled to requested width. I{(L{DataLine})}
6384 @param col: Upper-left column coordinate. I{(int)}
6385 @param row: Upper-left row coordinate. I{(int)}
6386 @param width: Area width (number of columns). I{(int)}
6387 @param height: Area height (number of rows). I{(int)}
6388 @param nstats: The number of samples to take on the distribution function. If
6389 nonpositive, a suitable resolution is determined automatically. I{(int)}
6390 """
6391 pass
6392
6393 - def cdh(target_line, nstats):
6394 """
6395 Calculates cumulative distribution of heights in a data field.
6396
6397 @param target_line: A data line to store the distribution to. It will be
6398 resampled to requested width. I{(L{DataLine})}
6399 @param nstats: The number of samples to take on the distribution function. If
6400 nonpositive, a suitable resolution is determined automatically. I{(int)}
6401 """
6402 pass
6403
6404 - def area_da(target_line, col, row, width, height, orientation, nstats):
6405 """
6406 Calculates distribution of slopes in a rectangular part of data field.
6407
6408 @param target_line: A data line to store the distribution to. It will be
6409 resampled to requested width. I{(L{DataLine})}
6410 @param col: Upper-left column coordinate. I{(int)}
6411 @param row: Upper-left row coordinate. I{(int)}
6412 @param width: Area width (number of columns). I{(int)}
6413 @param height: Area height (number of rows). I{(int)}
6414 @param orientation: Orientation to compute the slope distribution in. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6415 @param nstats: The number of samples to take on the distribution function. If
6416 nonpositive, a suitable resolution is determined automatically. I{(int)}
6417 """
6418 pass
6419
6420 - def area_da_mask(mask, target_line, col, row, width, height, orientation, nstats):
6421 """
6422 Calculates distribution of slopes in a rectangular part of data field, with
6423 masking.
6424
6425 @since: 2.49
6426
6427 @param mask: Mask specifying which values to take into account, or B{C{None}}. I{(L{DataField})}
6428 @param target_line: A data line to store the distribution to. It will be
6429 resampled to requested width. I{(L{DataLine})}
6430 @param col: Upper-left column coordinate. I{(int)}
6431 @param row: Upper-left row coordinate. I{(int)}
6432 @param width: Area width (number of columns). I{(int)}
6433 @param height: Area height (number of rows). I{(int)}
6434 @param orientation: Orientation to compute the slope distribution in. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6435 @param nstats: The number of samples to take on the distribution function. If
6436 nonpositive, a suitable resolution is determined automatically. I{(int)}
6437 """
6438 pass
6439
6440 - def da(target_line, orientation, nstats):
6441 """
6442 Calculates distribution of slopes in a data field.
6443
6444 @param target_line: A data line to store the distribution to. It will be
6445 resampled to requested width. I{(L{DataLine})}
6446 @param orientation: Orientation to compute the slope distribution in. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6447 @param nstats: The number of samples to take on the distribution function. If
6448 nonpositive, a suitable resolution is determined automatically. I{(int)}
6449 """
6450 pass
6451
6452 - def area_cda(target_line, col, row, width, height, orientation, nstats):
6453 """
6454 Calculates cumulative distribution of slopes in a rectangular part of data
6455 field.
6456
6457 @param target_line: A data line to store the distribution to. It will be
6458 resampled to requested width. I{(L{DataLine})}
6459 @param col: Upper-left column coordinate. I{(int)}
6460 @param row: Upper-left row coordinate. I{(int)}
6461 @param width: Area width (number of columns). I{(int)}
6462 @param height: Area height (number of rows). I{(int)}
6463 @param orientation: Orientation to compute the slope distribution in. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6464 @param nstats: The number of samples to take on the distribution function. If
6465 nonpositive, a suitable resolution is determined automatically. I{(int)}
6466 """
6467 pass
6468
6469 - def area_cda_mask(mask, target_line, col, row, width, height, orientation, nstats):
6470 """
6471 Calculates cumulative distribution of slopes in a rectangular part of data
6472 field, with masking.
6473
6474 @since: 2.49
6475
6476 @param mask: Mask specifying which values to take into account, or B{C{None}}. I{(L{DataField})}
6477 @param target_line: A data line to store the distribution to. It will be
6478 resampled to requested width. I{(L{DataLine})}
6479 @param col: Upper-left column coordinate. I{(int)}
6480 @param row: Upper-left row coordinate. I{(int)}
6481 @param width: Area width (number of columns). I{(int)}
6482 @param height: Area height (number of rows). I{(int)}
6483 @param orientation: Orientation to compute the slope distribution in. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6484 @param nstats: The number of samples to take on the distribution function. If
6485 nonpositive, a suitable resolution is determined automatically. I{(int)}
6486 """
6487 pass
6488
6489 - def cda(target_line, orientation, nstats):
6490 """
6491 Calculates cumulative distribution of slopes in a data field.
6492
6493 @param target_line: A data line to store the distribution to. It will be
6494 resampled to requested width. I{(L{DataLine})}
6495 @param orientation: Orientation to compute the slope distribution in. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6496 @param nstats: The number of samples to take on the distribution function. If
6497 nonpositive, a suitable resolution is determined automatically. I{(int)}
6498 """
6499 pass
6500
6501 - def area_acf(target_line, col, row, width, height, orientation, interpolation, nstats):
6502 """
6503 Calculates one-dimensional autocorrelation function of a rectangular part of a data field.
6504
6505 @param target_line: A data line to store the distribution to. It will be resampled to requested width. I{(L{DataLine})}
6506 @param col: Upper-left column coordinate. I{(int)}
6507 @param row: Upper-left row coordinate. I{(int)}
6508 @param width: Area width (number of columns). I{(int)}
6509 @param height: Area height (number of rows). I{(int)}
6510 @param orientation: Orientation of lines (ACF is simply averaged over the other orientation). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6511 @param interpolation: Interpolation to use when B{C{nstats}} is given and requires resampling. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
6512 @param nstats: The number of samples to take on the distribution function. If nonpositive, B{C{width}} (B{C{height}}) is used. I{(int)}
6513 """
6514 pass
6515
6516 - def acf(target_line, orientation, interpolation, nstats):
6517 """
6518 Calculates one-dimensional autocorrelation function of a data field.
6519
6520 @param target_line: A data line to store the distribution to. It will be resampled to requested width. I{(L{DataLine})}
6521 @param orientation: Orientation of lines (ACF is simply averaged over the other orientation). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6522 @param interpolation: Interpolation to use when B{C{nstats}} is given and requires resampling. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
6523 @param nstats: The number of samples to take on the distribution function. If nonpositive, data field width (height) is
6524 used. I{(int)}
6525 """
6526 pass
6527
6528 - def area_row_acf(mask, masking, col, row, width, height, level, weights):
6529 """
6530 Calculates the row-wise autocorrelation function (ACF) of a field.
6531
6532 The calculated ACF has the natural number of points, i.e. B{C{width}}.
6533
6534 Masking is performed by omitting all terms that contain excluded pixels. Since different rows contain different
6535 numbers of pixels, the resulting ACF values are calculated as a weighted sums where weight of each row's
6536 contribution is proportional to the number of contributing terms. In other words, the weighting is fair: each
6537 contributing pixel has the same influence on the result.
6538
6539 Only B{C{level}} values 0 (no levelling) and 1 (subtract the mean value) used to be available. For SPM data, you usually
6540 wish to pass 1. Since 2.56 you can also pass 2 for mean line subtraction.
6541
6542
6543 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6544 @param masking: Masking mode to use (has any effect only with non-B{C{None}} B{C{mask}}). Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6545 @param col: Upper-left column coordinate. I{(int)}
6546 @param row: Upper-left row coordinate. I{(int)}
6547 @param width: Area width (number of columns). I{(int)}
6548 @param height: Area height (number of rows). I{(int)}
6549 @param level: The first polynomial degree to keep in the rows, lower degrees than B{C{level}} are subtracted. I{(int)}
6550 @param weights: Line to store the denominators to (or B{C{None}}). It will be resized to match the returned line. The
6551 denominators are integers equal to the number of terms that contributed to each value. They are suitable
6552 as fitting weights if the ACF is fitted. I{(L{DataLine})}
6553 @return: A new one-dimensional data line with the ACF. I{(L{DataLine})}
6554 """
6555 return None
6556
6557 - def area_hhcf(target_line, col, row, width, height, orientation, interpolation, nstats):
6558 """
6559 Calculates one-dimensional autocorrelation function of a rectangular part of a data field.
6560
6561 @param target_line: A data line to store the distribution to. It will be resampled to requested width. I{(L{DataLine})}
6562 @param col: Upper-left column coordinate. I{(int)}
6563 @param row: Upper-left row coordinate. I{(int)}
6564 @param width: Area width (number of columns). I{(int)}
6565 @param height: Area height (number of rows). I{(int)}
6566 @param orientation: Orientation of lines (HHCF is simply averaged over the other orientation). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6567 @param interpolation: Interpolation to use when B{C{nstats}} is given and requires resampling. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
6568 @param nstats: The number of samples to take on the distribution function. If nonpositive, B{C{width}} (B{C{height}}) is used. I{(int)}
6569 """
6570 pass
6571
6572 - def hhcf(target_line, orientation, interpolation, nstats):
6573 """
6574 Calculates one-dimensional autocorrelation function of a data field.
6575
6576 @param target_line: A data line to store the distribution to. It will be resampled to requested width. I{(L{DataLine})}
6577 @param orientation: Orientation of lines (HHCF is simply averaged over the other orientation). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6578 @param interpolation: Interpolation to use when B{C{nstats}} is given and requires resampling. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
6579 @param nstats: The number of samples to take on the distribution function. If nonpositive, data field width (height) is
6580 used. I{(int)}
6581 """
6582 pass
6583
6584 - def area_row_hhcf(mask, masking, col, row, width, height, level, weights):
6585 """
6586 Calculates the row-wise height-height correlation function (HHCF) of a rectangular part of a field.
6587
6588 The calculated HHCF has the natural number of points, i.e. B{C{width}}.
6589
6590 Masking is performed by omitting all terms that contain excluded pixels. Since different rows contain different
6591 numbers of pixels, the resulting HHCF values are calculated as a weighted sums where weight of each row's
6592 contribution is proportional to the number of contributing terms. In other words, the weighting is fair: each
6593 contributing pixel has the same influence on the result.
6594
6595 Only B{C{level}} values 0 (no levelling) and 1 (subtract the mean value) used to be available. There is no difference
6596 between them for HHCF. Since 2.56 you can also pass 2 for mean line subtraction.
6597
6598
6599 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6600 @param masking: Masking mode to use (has any effect only with non-B{C{None}} B{C{mask}}). Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6601 @param col: Upper-left column coordinate. I{(int)}
6602 @param row: Upper-left row coordinate. I{(int)}
6603 @param width: Area width (number of columns). I{(int)}
6604 @param height: Area height (number of rows). I{(int)}
6605 @param level: The first polynomial degree to keep in the rows, lower degrees than B{C{level}} are subtracted. I{(int)}
6606 @param weights: Line to store the denominators to (or B{C{None}}). It will be resized to match the returned line. The
6607 denominators are integers equal to the number of terms that contributed to each value. They are suitable
6608 as fitting weights if the HHCF is fitted. I{(L{DataLine})}
6609 @return: A new one-dimensional data line with the HHCF. I{(L{DataLine})}
6610 """
6611 return None
6612
6613 - def area_psdf(target_line, col, row, width, height, orientation, interpolation, windowing, nstats):
6614 """
6615 Calculates one-dimensional power spectrum density function of a rectangular part of a data field.
6616
6617 @param target_line: A data line to store the distribution to. It will be resampled to requested width. I{(L{DataLine})}
6618 @param col: Upper-left column coordinate. I{(int)}
6619 @param row: Upper-left row coordinate. I{(int)}
6620 @param width: Area width (number of columns). I{(int)}
6621 @param height: Area height (number of rows). I{(int)}
6622 @param orientation: Orientation of lines (PSDF is simply averaged over the other orientation). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6623 @param interpolation: Interpolation to use when B{C{nstats}} is given and requires resampling. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
6624 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
6625 @param nstats: The number of samples to take on the distribution function. If nonpositive, data field width (height) is
6626 used. I{(int)}
6627 """
6628 pass
6629
6630 - def psdf(target_line, orientation, interpolation, windowing, nstats):
6631 """
6632 Calculates one-dimensional power spectrum density function of a data field.
6633
6634 @param target_line: A data line to store the distribution to. It will be resampled to requested width. I{(L{DataLine})}
6635 @param orientation: Orientation of lines (PSDF is simply averaged over the other orientation). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
6636 @param interpolation: Interpolation to use when B{C{nstats}} is given and requires resampling. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
6637 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
6638 @param nstats: The number of samples to take on the distribution function. If nonpositive, data field width (height) is
6639 used. I{(int)}
6640 """
6641 pass
6642
6643 - def area_row_psdf(mask, masking, col, row, width, height, windowing, level):
6644 """
6645 Calculates the row-wise power spectrum density function (PSDF) of a rectangular part of a field.
6646
6647 The calculated PSDF has the natural number of points that follows from DFT, i.e. B{C{width}}/2+1.
6648
6649 The reduction of the total energy by windowing is compensated by multiplying the PSDF to make its sum of squares
6650 equal to the input data sum of squares.
6651
6652 Masking is performed by omitting all terms that contain excluded pixels. Since different rows contain different
6653 numbers of pixels, the resulting PSDF is calculated as a weighted sum where each row's weight is proportional to
6654 the number of contributing pixels. In other words, the weighting is fair: each contributing pixel has the same
6655 influence on the result.
6656
6657 Only B{C{level}} values 0 (no levelling) and 1 (subtract the mean value) used to be available. For SPM data, you usually
6658 wish to pass 1. Since 2.56 you can also pass 2 for mean line subtraction.
6659
6660 Do not assume the PSDF values are all positive, when masking is in effect. The PSDF should still have the correct
6661 integral, but it will be contaminated with noise, both positive and negative.
6662
6663
6664 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6665 @param masking: Masking mode to use (has any effect only with non-B{C{None}} B{C{mask}}). Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6666 @param col: Upper-left column coordinate. I{(int)}
6667 @param row: Upper-left row coordinate. I{(int)}
6668 @param width: Area width (number of columns). I{(int)}
6669 @param height: Area height (number of rows). I{(int)}
6670 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
6671 @param level: The first polynomial degree to keep in the rows; lower degrees than B{C{level}} are subtracted. I{(int)}
6672 @return: A new one-dimensional data line with the PSDF. I{(L{DataLine})}
6673 """
6674 return None
6675
6676 - def area_rpsdf(target_line, col, row, width, height, interpolation, windowing, nstats):
6677 """
6678 Calculates radial power spectrum density function of a rectangular part of a data field.
6679
6680 @since: 2.7
6681
6682 @param target_line: A data line to store the distribution to. It will be resampled to requested width. I{(L{DataLine})}
6683 @param col: Upper-left column coordinate. I{(int)}
6684 @param row: Upper-left row coordinate. I{(int)}
6685 @param width: Area width (number of columns). I{(int)}
6686 @param height: Area height (number of rows). I{(int)}
6687 @param interpolation: Interpolation to use when B{C{nstats}} is given and requires resampling. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
6688 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
6689 @param nstats: The number of samples to take on the distribution function. If nonpositive, data field width (height) is
6690 used. I{(int)}
6691 """
6692 pass
6693
6694 - def rpsdf(target_line, interpolation, windowing, nstats):
6695 """
6696 Calculates radial power spectrum density function of a data field.
6697
6698 @since: 2.7
6699
6700 @param target_line: A data line to store the distribution to. It will be resampled to requested width. I{(L{DataLine})}
6701 @param interpolation: Interpolation to use when B{C{nstats}} is given and requires resampling. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
6702 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
6703 @param nstats: The number of samples to take on the distribution function. If nonpositive, data field width (height) is
6704 used. I{(int)}
6705 """
6706 pass
6707
6708 - def area_row_asg(mask, masking, col, row, width, height, level):
6709 """
6710 Calculates the row-wise area scale graph (ASG) of a rectangular part of a field.
6711
6712 The calculated ASG has the natural number of points, i.e. B{C{width}}-1.
6713
6714 The ASG represents the apparent area excess (ratio of surface and projected area minus one) observed at given
6715 length scale. The quantity calculated by this function serves a similar purpose as ASME B46.1 area scale graph but
6716 is defined differently, based on the HHCF. See L{DataField.area_row_hhcf}() for details of its calculation.
6717
6718 Only B{C{level}} values 0 (no levelling) and 1 (subtract the mean value) used to be available. There is no difference
6719 between them for HHCF. Since 2.56 you can also pass 2 for mean line subtraction.
6720
6721
6722 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6723 @param masking: Masking mode to use (has any effect only with non-B{C{None}} B{C{mask}}). Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6724 @param col: Upper-left column coordinate. I{(int)}
6725 @param row: Upper-left row coordinate. I{(int)}
6726 @param width: Area width (number of columns). I{(int)}
6727 @param height: Area height (number of rows). I{(int)}
6728 @param level: The first polynomial degree to keep in the rows, lower degrees than B{C{level}} are subtracted. I{(int)}
6729 @return: A new one-dimensional data line with the ASG. I{(L{DataLine})}
6730 """
6731 return None
6732
6733 - def area_2dacf(target_field, col, row, width, height, xrange, yrange):
6734 """
6735 Calculates two-dimensional autocorrelation function of a data field area.
6736
6737 The resulting data field has the correlation corresponding to (0,0) in the centre.
6738
6739 The maximum possible values of B{C{xrange}} and B{C{yrange}} are B{C{data_field}} width and height, respectively. However, as the
6740 values for longer distances are calculated from smaller number of data points they become increasingly bogus,
6741 therefore the default range is half of the size.
6742
6743 @since: 2.7
6744
6745 @param target_field: A data field to store the result to. It will be resampled to (2B{C{xrange}}-1)×(2B{C{yrange}}-1). I{(L{DataField})}
6746 @param col: Upper-left column coordinate. I{(int)}
6747 @param row: Upper-left row coordinate. I{(int)}
6748 @param width: Area width (number of columns). I{(int)}
6749 @param height: Area height (number of rows). I{(int)}
6750 @param xrange: Horizontal correlation range. Non-positive value means the default range of half of B{C{data_field}} width
6751 will be used. I{(int)}
6752 @param yrange: Vertical correlation range. Non-positive value means the default range of half of B{C{data_field}} height will
6753 be used. I{(int)}
6754 """
6755 pass
6756
6757 - def area_2dacf_mask(target_field, mask, masking, col, row, width, height, xrange, yrange, weights):
6758 """
6759 Calculates two-dimensional autocorrelation function of a data field area.
6760
6761 The resulting data field has the correlation corresponding to (0,0) in the centre.
6762
6763 The maximum possible values of B{C{xrange}} and B{C{yrange}} are B{C{data_field}} width and height, respectively. However, as the
6764 values for longer distances are calculated from smaller number of data points they become increasingly bogus,
6765 therefore the default range is half of the size.
6766
6767 @since: 2.50
6768
6769 @param target_field: A data field to store the result to. It will be resampled to (2B{C{xrange}}-1)×(2B{C{yrange}}-1). I{(L{DataField})}
6770 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6771 @param masking: Masking mode to use (has any effect only with non-B{C{None}} B{C{mask}}). Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6772 @param col: Upper-left column coordinate. I{(int)}
6773 @param row: Upper-left row coordinate. I{(int)}
6774 @param width: Area width (number of columns). I{(int)}
6775 @param height: Area height (number of rows). I{(int)}
6776 @param xrange: Horizontal correlation range. Non-positive value means the default range of half of B{C{data_field}} width
6777 will be used. I{(int)}
6778 @param yrange: Vertical correlation range. Non-positive value means the default range of half of B{C{data_field}} height will
6779 be used. I{(int)}
6780 @param weights: Field to store the denominators to (or B{C{None}}). It will be resized like B{C{target_field}}. The denominators
6781 are integers equal to the number of terms that contributed to each value. They are suitable as fitting
6782 weights if the ACF is fitted. I{(L{DataField})}
6783 """
6784 pass
6785
6786 - def acf2d(target_field):
6787 """
6788 Calculates two-dimensional autocorrelation function of a data field.
6789
6790 See L{DataField.area_2dacf}() for details. Parameters missing (not adjustable) in this function are set to their
6791 default values.
6792
6793 @since: 2.7
6794
6795 @param target_field: A data field to store the result to. I{(L{DataField})}
6796 """
6797 pass
6798
6799 - def area_2dpsdf_mask(target_field, mask, masking, col, row, width, height, windowing, level):
6800 """
6801 Calculates two-dimensional power spectrum density function of a data field area.
6802
6803 The resulting data field has the spectrum density corresponding zero frequency (0,0) in the centre.
6804
6805 Only B{C{level}} values 0 (no levelling) and 1 (subtract the mean value) used to be available. For SPM data, you usually
6806 wish to pass 1. Since 2.56 you can also pass 2 for mean plane subtraction.
6807
6808 The reduction of the total energy by windowing is compensated by multiplying the PSDF to make its sum of squares
6809 equal to the input data sum of squares.
6810
6811 Do not assume the PSDF values are all positive, when masking is in effect. The PSDF should still have the correct
6812 integral, but it will be contaminated with noise, both positive and negative.
6813
6814 @since: 2.51
6815
6816 @param target_field: A data field to store the result to. It will be resampled to B{C{width}}×B{C{height}}. I{(L{DataField})}
6817 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6818 @param masking: Masking mode to use (has any effect only with non-B{C{None}} B{C{mask}}). Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6819 @param col: Upper-left column coordinate. I{(int)}
6820 @param row: Upper-left row coordinate. I{(int)}
6821 @param width: Area width (number of columns). I{(int)}
6822 @param height: Area height (number of rows). I{(int)}
6823 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
6824 @param level: The first polynomial degree to keep in the area; lower degrees than B{C{level}} are subtracted. I{(int)}
6825 """
6826 pass
6827
6828 - def psdf2d(target_field, windowing, level):
6829 """
6830 Calculates two-dimensional power spectrum density function of a data field.
6831
6832 See L{DataField.area_2dpsdf_mask}() for details and discussion.
6833
6834 @since: 2.51
6835
6836 @param target_field: A data field to store the result to. It will be resampled to the same size as B{C{data_field}}. I{(L{DataField})}
6837 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
6838 @param level: The first polynomial degree to keep in the area; lower degrees than B{C{level}} are subtracted. Note only
6839 values 0, 1, and 2 are available at present. For SPM data, you usually wish to pass 1. I{(int)}
6840 """
6841 pass
6842
6843 - def area_racf(target_line, col, row, width, height, nstats):
6844 """
6845 Calculates radially averaged autocorrelation function of a rectangular part of a data field.
6846
6847 @since: 2.22
6848
6849 @param target_line: A data line to store the autocorrelation function to. It will be resampled to requested width. I{(L{DataLine})}
6850 @param col: Upper-left column coordinate. I{(int)}
6851 @param row: Upper-left row coordinate. I{(int)}
6852 @param width: Area width (number of columns). I{(int)}
6853 @param height: Area height (number of rows). I{(int)}
6854 @param nstats: The number of samples to take on the autocorrelation function. If nonpositive, a suitable resolution is
6855 chosen automatically. I{(int)}
6856 """
6857 pass
6858
6859 - def racf(target_line, nstats):
6860 """
6861 Calculates radially averaged autocorrelation function of a data field.
6862
6863 @since: 2.22
6864
6865 @param target_line: A data line to store the autocorrelation function to. It will be resampled to requested width. I{(L{DataLine})}
6866 @param nstats: The number of samples to take on the autocorrelation function. If nonpositive, a suitable resolution is
6867 chosen automatically. I{(int)}
6868 """
6869 pass
6870
6872 """
6873 Calculates Minkowski volume functional of a rectangular part of a data
6874 field.
6875
6876 Volume functional is calculated as the number of values above each
6877 threshold value (,white pixels`) divided by the total number of samples
6878 in the area. Is it's equivalent to 1-CDH.
6879
6880 @param target_line: A data line to store the distribution to. It will be
6881 resampled to requested width. I{(L{DataLine})}
6882 @param col: Upper-left column coordinate. I{(int)}
6883 @param row: Upper-left row coordinate. I{(int)}
6884 @param width: Area width (number of columns). I{(int)}
6885 @param height: Area height (number of rows). I{(int)}
6886 @param nstats: The number of samples to take on the distribution function. If
6887 nonpositive, a suitable resolution is determined automatically. I{(int)}
6888 """
6889 pass
6890
6892 """
6893 Calculates Minkowski volume functional of a data field.
6894
6895 See L{DataField.area_minkowski_volume}() for details.
6896
6897 @param target_line: A data line to store the distribution to. It will be
6898 resampled to requested width. I{(L{DataLine})}
6899 @param nstats: The number of samples to take on the distribution function. If
6900 nonpositive, a suitable resolution is determined automatically. I{(int)}
6901 """
6902 pass
6903
6905 """
6906 Calculates Minkowski boundary functional of a rectangular part of a data
6907 field.
6908
6909 Boundary functional is calculated as the number of boundaries for each
6910 threshold value (the number of pixel sides where of neighouring pixels is
6911 ,white` and the other ,black`) divided by the total number of samples
6912 in the area.
6913
6914 @param target_line: A data line to store the distribution to. It will be
6915 resampled to requested width. I{(L{DataLine})}
6916 @param col: Upper-left column coordinate. I{(int)}
6917 @param row: Upper-left row coordinate. I{(int)}
6918 @param width: Area width (number of columns). I{(int)}
6919 @param height: Area height (number of rows). I{(int)}
6920 @param nstats: The number of samples to take on the distribution function. If
6921 nonpositive, a suitable resolution is determined automatically. I{(int)}
6922 """
6923 pass
6924
6926 """
6927 Calculates Minkowski boundary functional of a data field.
6928
6929 See L{DataField.area_minkowski_boundary}() for details.
6930
6931 @param target_line: A data line to store the distribution to. It will be
6932 resampled to requested width. I{(L{DataLine})}
6933 @param nstats: The number of samples to take on the distribution function. If
6934 nonpositive, a suitable resolution is determined automatically. I{(int)}
6935 """
6936 pass
6937
6939 """
6940 Calculates Minkowski connectivity functional (Euler characteristics) of
6941 a rectangular part of a data field.
6942
6943 Connectivity functional is calculated as the number connected areas of
6944 pixels above threhsold (,white`) minus the number of connected areas of
6945 pixels below threhsold (,black`) for each threshold value, divided by the
6946 total number of samples in the area.
6947
6948 @param target_line: A data line to store the distribution to. It will be
6949 resampled to requested width. I{(L{DataLine})}
6950 @param col: Upper-left column coordinate. I{(int)}
6951 @param row: Upper-left row coordinate. I{(int)}
6952 @param width: Area width (number of columns). I{(int)}
6953 @param height: Area height (number of rows). I{(int)}
6954 @param nstats: The number of samples to take on the distribution function. If
6955 nonpositive, a suitable resolution is determined automatically. I{(int)}
6956 """
6957 pass
6958
6960 """
6961 Calculates Minkowski connectivity functional (Euler characteristics) of
6962 a data field.
6963
6964 See L{DataField.area_minkowski_euler}() for details.
6965
6966 @param target_line: A data line to store the distribution to. It will be
6967 resampled to requested width. I{(L{DataLine})}
6968 @param nstats: The number of samples to take on the distribution function. If
6969 nonpositive, a suitable resolution is determined automatically. I{(int)}
6970 """
6971 pass
6972
6974 """
6975 Calculates the dispersion of a data field area, taking it as a distribution.
6976
6977 The function takes B{C{data_field}} as a distribution, finds the centre of mass
6978 in the area and then calculates the mean squared distance from this centre,
6979 weighted by B{C{data_field}} values. Normally B{C{data_field}} should contain only
6980 non-negative data.
6981
6982 The dispersion is measured in real coordinates, so horizontal and vertical
6983 pixel sizes play a role and the units are squared lateral units of
6984 B{C{data_field}}. Note, however, that B{C{xcenter}} and B{C{ycenter}} is returned in pixel
6985 coordinates since it is usually more convenient.
6986
6987 @since: 2.52
6988
6989 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
6990 @param masking: Masking mode to use (has any effect only with non-B{C{None}} B{C{mask}}). Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
6991 @param col: Upper-left column coordinate. I{(int)}
6992 @param row: Upper-left row coordinate. I{(int)}
6993 @param width: Area width (number of columns). I{(int)}
6994 @param height: Area height (number of rows). I{(int)}
6995 @return: Tuple consisting of 3 values (B{C{value}}, B{C{xcenter}}, B{C{ycenter}}). (I{(float)}, I{(float)}, I{(float)})
6996 """
6997 return None, None, None
6998
7000 """
7001 Calculates the dispersion of a data field, taking it as a distribution.
7002
7003 See L{DataField.area_get_dispersion}() for discussion.
7004
7005 @since: 2.52
7006
7007 @return: Tuple consisting of 3 values (B{C{value}}, B{C{xcenter}}, B{C{ycenter}}). (I{(float)}, I{(float)}, I{(float)})
7008 """
7009 return None, None, None
7010
7012 """
7013 Computes angular slope distribution.
7014
7015 @param derdist: A data line to fill with angular slope distribution. Its
7016 resolution determines resolution of the distribution. I{(L{DataLine})}
7017 @param kernel_size: If positive, local plane fitting will be used for slope
7018 computation; if nonpositive, plain central derivations
7019 will be used. I{(int)}
7020 """
7021 pass
7022
7024 """
7025 Computes average normal vector of a data field.
7026
7027 @param normalize1: true to normalize the normal vector to 1, false to normalize
7028 the vector so that z-component is 1. I{(bool)}
7029 @return: Tuple consisting of 3 values (B{C{nx}}, B{C{ny}}, B{C{nz}}). (I{(float)}, I{(float)}, I{(float)})
7030 """
7031 return None, None, None
7032
7034 """
7035 Computes average normal vector of an area of a data field.
7036
7037 @param col: Upper-left column coordinate. I{(int)}
7038 @param row: Upper-left row coordinate. I{(int)}
7039 @param width: Area width (number of columns). I{(int)}
7040 @param height: Area height (number of rows). I{(int)}
7041 @param normalize1: true to normalize the normal vector to 1, false to normalize
7042 the vector so that z-component is 1. I{(bool)}
7043 @return: Tuple consisting of 3 values (B{C{nx}}, B{C{ny}}, B{C{nz}}). (I{(float)}, I{(float)}, I{(float)})
7044 """
7045 return None, None, None
7046
7048 """
7049 Calculates the inclination of the image (polar and azimuth angle).
7050
7051 @param col: Upper-left column coordinate. I{(int)}
7052 @param row: Upper-left row coordinate. I{(int)}
7053 @param width: Area width (number of columns). I{(int)}
7054 @param height: Area height (number of rows). I{(int)}
7055 @return: Tuple consisting of 2 values (B{C{theta}}, B{C{phi}}). (I{(float)}, I{(float)})
7056 """
7057 return None, None
7058
7060 """
7061 Calculates the inclination of the image (polar and azimuth angle).
7062
7063 @return: Tuple consisting of 2 values (B{C{theta}}, B{C{phi}}). (I{(float)}, I{(float)})
7064 """
7065 return None, None
7066
7068 """
7069 Calculates a line quantity for each row or column in a data field area.
7070
7071 Use L{DataField.get_line_stats_mask}() for full masking type options.
7072
7073 @since: 2.2
7074
7075 @param mask: Mask of values to take values into account, or B{C{None}} for full
7076 B{C{data_field}}. I{(L{DataField})}
7077 @param target_line: A data line to store the distribution to. It will be
7078 resampled to the number of rows (columns). I{(L{DataLine})}
7079 @param col: Upper-left column coordinate. I{(int)}
7080 @param row: Upper-left row coordinate. I{(int)}
7081 @param width: Area width (number of columns). I{(int)}
7082 @param height: Area height (number of rows). I{(int)}
7083 @param quantity: The line quantity to calulate for each row (column). Expected values: C{B{LINE_STAT_MEAN}}, C{B{LINE_STAT_MEDIAN}}, C{B{LINE_STAT_MINIMUM}}, C{B{LINE_STAT_MAXIMUM}}, C{B{LINE_STAT_RMS}}, C{B{LINE_STAT_LENGTH}}, C{B{LINE_STAT_SLOPE}}, C{B{LINE_STAT_TAN_BETA0}}, C{B{LINE_STAT_RA}}, C{B{LINE_STAT_RZ}}, C{B{LINE_STAT_RT}}, C{B{LINE_STAT_SKEW}}, C{B{LINE_STAT_KURTOSIS}}, C{B{LINE_STAT_RANGE}}, C{B{LINE_STAT_VARIATION}}, C{B{LINE_STAT_MINPOS}}, C{B{LINE_STAT_MAXPOS}}. I{(L{LineStatQuantity})}
7084 @param orientation: Line orientation. For B{C{ORIENTATION_HORIZONTAL}} each
7085 B{C{target_line}} point corresponds to a row of the area,
7086 for B{C{ORIENTATION_VERTICAL}} each B{C{target_line}} point
7087 corresponds to a column of the area. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
7088 """
7089 pass
7090
7091 - def get_line_stats_mask(mask, masking, target_line, weights, col, row, width, height, quantity, orientation):
7092 """
7093 Calculates a line quantity for each row or column in a data field area.
7094
7095 @since: 2.46
7096
7097 @param mask: Mask of values to take values into account, or B{C{None}} for full
7098 B{C{data_field}}. I{(L{DataField})}
7099 @param masking: Masking mode to use. See the introduction for description of
7100 masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
7101 @param target_line: A data line to store the distribution to. It will be
7102 resampled to the number of rows (columns). I{(L{DataLine})}
7103 @param weights: A data line to store number of data points contributing to each
7104 value in B{C{target_line}}, or B{C{None}}. It is useful when masking is
7105 used to possibly exclude values calculated from too few data
7106 points. I{(L{DataLine})}
7107 @param col: Upper-left column coordinate. I{(int)}
7108 @param row: Upper-left row coordinate. I{(int)}
7109 @param width: Area width (number of columns). I{(int)}
7110 @param height: Area height (number of rows). I{(int)}
7111 @param quantity: The line quantity to calulate for each row (column). Expected values: C{B{LINE_STAT_MEAN}}, C{B{LINE_STAT_MEDIAN}}, C{B{LINE_STAT_MINIMUM}}, C{B{LINE_STAT_MAXIMUM}}, C{B{LINE_STAT_RMS}}, C{B{LINE_STAT_LENGTH}}, C{B{LINE_STAT_SLOPE}}, C{B{LINE_STAT_TAN_BETA0}}, C{B{LINE_STAT_RA}}, C{B{LINE_STAT_RZ}}, C{B{LINE_STAT_RT}}, C{B{LINE_STAT_SKEW}}, C{B{LINE_STAT_KURTOSIS}}, C{B{LINE_STAT_RANGE}}, C{B{LINE_STAT_VARIATION}}, C{B{LINE_STAT_MINPOS}}, C{B{LINE_STAT_MAXPOS}}. I{(L{LineStatQuantity})}
7112 @param orientation: Line orientation. For B{C{ORIENTATION_HORIZONTAL}} each
7113 B{C{target_line}} point corresponds to a row of the area,
7114 for B{C{ORIENTATION_VERTICAL}} each B{C{target_line}} point
7115 corresponds to a column of the area. Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
7116 """
7117 pass
7118
7120 """
7121 Calculates a line quantity for each row or column of a data field.
7122
7123 @since: 2.2
7124
7125 @param target_line: A data line to store the distribution to. It will be
7126 resampled to B{C{data_field}} height (width). I{(L{DataLine})}
7127 @param quantity: The line quantity to calulate for each row (column). Expected values: C{B{LINE_STAT_MEAN}}, C{B{LINE_STAT_MEDIAN}}, C{B{LINE_STAT_MINIMUM}}, C{B{LINE_STAT_MAXIMUM}}, C{B{LINE_STAT_RMS}}, C{B{LINE_STAT_LENGTH}}, C{B{LINE_STAT_SLOPE}}, C{B{LINE_STAT_TAN_BETA0}}, C{B{LINE_STAT_RA}}, C{B{LINE_STAT_RZ}}, C{B{LINE_STAT_RT}}, C{B{LINE_STAT_SKEW}}, C{B{LINE_STAT_KURTOSIS}}, C{B{LINE_STAT_RANGE}}, C{B{LINE_STAT_VARIATION}}, C{B{LINE_STAT_MINPOS}}, C{B{LINE_STAT_MAXPOS}}. I{(L{LineStatQuantity})}
7128 @param orientation: Line orientation. See L{DataField.area_get_line_stats}(). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
7129 """
7130 pass
7131
7133 """
7134 Counts the number of regional maxima in a data field.
7135
7136 See L{DataField.mark_extrema}() for the definition of a regional maximum.
7137
7138 @since: 2.38
7139
7140 @return: The number of regional maxima. I{(int)}
7141 """
7142 return None
7143
7145 """
7146 Counts the number of regional minima in a data field.
7147
7148 See L{DataField.mark_extrema}() for the definition of a regional minimum.
7149
7150 @since: 2.38
7151
7152 @return: The number of regional minima. I{(int)}
7153 """
7154 return None
7155
7157 """
7158 Transforms 2D power spectral density to an angular spectrum.
7159
7160 @since: 2.56
7161
7162 @param nstats: The number of samples to take on the distribution function. If nonpositive, a suitable number is chosen
7163 automatically. I{(int)}
7164 @return: A new one-dimensional data line with the angular spectrum. I{(L{DataLine})}
7165 """
7166 return None
7167
7169 """
7170 Performs angular averaging of a part of a data field.
7171
7172 The result of such averaging is an radial profile, starting from the disc centre.
7173
7174 The function does not guarantee that B{C{target_line}} will have exactly B{C{nstats}} samples upon return. A smaller number
7175 of samples than requested may be calculated for instance if either central or outer part of the disc is excluded by
7176 masking.
7177
7178 @since: 2.42
7179
7180 @param target_line: A data line to store the distribution to. It will be resampled to B{C{nstats}} size. I{(L{DataLine})}
7181 @param mask: Mask of pixels to include from/exclude in the averaging, or B{C{None}} for full B{C{data_field}}. I{(L{DataField})}
7182 @param masking: Masking mode to use. See the introduction for description of masking modes. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
7183 @param x: X-coordinate of the averaging disc origin, in real coordinates including offsets. I{(float)}
7184 @param y: Y-coordinate of the averaging disc origin, in real coordinates including offsets. I{(float)}
7185 @param r: Radius, in real coordinates. It determines the real length of the resulting line. I{(float)}
7186 @param nstats: The number of samples the resulting line should have. A non-positive value means the sampling will be
7187 determined automatically. I{(int)}
7188 """
7189 pass
7190
7192 """
7193 Sets lateral and value units of a surface to match a data field.
7194
7195 @since: 2.46
7196
7197 @param surface: A surface. I{(L{Surface})}
7198 """
7199 pass
7200
7202 """
7203 Extract the data of a data field.
7204
7205 The returned list contains a copy of the data. Changing its contents does
7206 not change the data field's data.
7207
7208
7209 @return: List containing extracted data field data. I{(list)}
7210 """
7211 return None
7212
7214 """
7215 Sets the entire contents of a data field.
7216
7217 The length of B{C{data}} must be equal to the number of elements of the data
7218 field.
7219
7220 @param data: Sequence of floating point values. I{(list)}
7221 """
7222 pass
7223
7225 """
7226 Fits a two-dimensional polynomial to a data field.
7227
7228
7229 @param col_degree: Degree of polynomial to fit column-wise (x-coordinate). I{(int)}
7230 @param row_degree: Degree of polynomial to fit row-wise (y-coordinate). I{(int)}
7231 @return: a newly allocated array with coefficients. I{(list)}
7232 """
7233 return None
7234
7236 """
7237 Fits a two-dimensional polynomial to a rectangular part of a data field.
7238
7239 The coefficients are stored by row into B{C{coeffs}}, like data in a datafield.
7240 Row index is y-degree, column index is x-degree.
7241
7242 Note naive x^n y^m polynomial fitting is numerically unstable, therefore
7243 this method works only up to B{C{col_degree}} = B{C{row_degree}} = 6.
7244
7245
7246 @param col: Upper-left column coordinate. I{(int)}
7247 @param row: Upper-left row coordinate. I{(int)}
7248 @param width: Area width (number of columns). I{(int)}
7249 @param height: Area height (number of rows). I{(int)}
7250 @param col_degree: Degree of polynomial to fit column-wise (x-coordinate). I{(int)}
7251 @param row_degree: Degree of polynomial to fit row-wise (y-coordinate). I{(int)}
7252 @return: a newly allocated array with coefficients. I{(list)}
7253 """
7254 return None
7255
7257 """
7258 Subtracts a two-dimensional polynomial from a data field.
7259
7260 @param col_degree: Degree of polynomial to subtract column-wise (x-coordinate). I{(int)}
7261 @param row_degree: Degree of polynomial to subtract row-wise (y-coordinate). I{(int)}
7262 @param coeffs: An array of size (B{C{row_degree}}+1)*(B{C{col_degree}}+1) with coefficients,
7263 see L{DataField.area_fit_polynom}() for details. I{(list)}
7264 """
7265 pass
7266
7268 """
7269 Subtracts a two-dimensional polynomial from a rectangular part of a data
7270 field.
7271
7272 @param col: Upper-left column coordinate. I{(int)}
7273 @param row: Upper-left row coordinate. I{(int)}
7274 @param width: Area width (number of columns). I{(int)}
7275 @param height: Area height (number of rows). I{(int)}
7276 @param col_degree: Degree of polynomial to subtract column-wise (x-coordinate). I{(int)}
7277 @param row_degree: Degree of polynomial to subtract row-wise (y-coordinate). I{(int)}
7278 @param coeffs: An array of size (B{C{row_degree}}+1)*(B{C{col_degree}}+1) with coefficients,
7279 see L{DataField.area_fit_polynom}() for details. I{(list)}
7280 """
7281 pass
7282
7284 """
7285 Fits two-dimensional Legendre polynomial to a data field.
7286
7287 See L{DataField.area_fit_legendre}() for details.
7288
7289
7290 @param col_degree: Degree of polynomial to fit column-wise (x-coordinate). I{(int)}
7291 @param row_degree: Degree of polynomial to fit row-wise (y-coordinate). I{(int)}
7292 @return: Either B{C{coeffs}} if it was not B{C{None}}, or a newly allocated array
7293 with coefficients. I{(list)}
7294 """
7295 return None
7296
7298 """
7299 Fits two-dimensional Legendre polynomial to a rectangular part of a data
7300 field.
7301
7302 The B{C{col_degree}} and B{C{row_degree}} parameters limit the maximum powers of x and
7303 y exactly as if simple powers were fitted, therefore if you do not intend to
7304 interpret contents of B{C{coeffs}} youself, the only difference is that this
7305 method is much more numerically stable.
7306
7307 The coefficients are organized exactly like in
7308 L{DataField.area_fit_polynom}(), but they are not coefficients of
7309 x^n y^m, instead they are coefficients of P_n(x) P_m(x), where P are
7310 Legendre polynomials. The polynomials are evaluated in coordinates where
7311 first row (column) corresponds to -1.0, and the last row (column) to 1.0.
7312
7313 Note the polynomials are normal Legendre polynomials that are not exactly
7314 orthogonal on a discrete point set (if their degrees are equal mod 2).
7315
7316
7317 @param col: Upper-left column coordinate. I{(int)}
7318 @param row: Upper-left row coordinate. I{(int)}
7319 @param width: Area width (number of columns). I{(int)}
7320 @param height: Area height (number of rows). I{(int)}
7321 @param col_degree: Degree of polynomial to fit column-wise (x-coordinate). I{(int)}
7322 @param row_degree: Degree of polynomial to fit row-wise (y-coordinate). I{(int)}
7323 @return: Either B{C{coeffs}} if it was not B{C{None}}, or a newly allocated array
7324 with coefficients. I{(list)}
7325 """
7326 return None
7327
7329 """
7330 Subtracts a two-dimensional Legendre polynomial fit from a data field.
7331
7332 @param col_degree: Degree of polynomial to subtract column-wise (x-coordinate). I{(int)}
7333 @param row_degree: Degree of polynomial to subtract row-wise (y-coordinate). I{(int)}
7334 @param coeffs: An array of size (B{C{row_degree}}+1)*(B{C{col_degree}}+1) with coefficients,
7335 see L{DataField.area_fit_legendre}() for details. I{(list)}
7336 """
7337 pass
7338
7340 """
7341 Subtracts a two-dimensional Legendre polynomial fit from a rectangular part
7342 of a data field.
7343
7344 Due to the transform of coordinates to [-1,1] x [-1,1], this method can be
7345 used on an area of dimensions different than the area the coefficients were
7346 calculated for.
7347
7348 @param col: Upper-left column coordinate. I{(int)}
7349 @param row: Upper-left row coordinate. I{(int)}
7350 @param width: Area width (number of columns). I{(int)}
7351 @param height: Area height (number of rows). I{(int)}
7352 @param col_degree: Degree of polynomial to subtract column-wise (x-coordinate). I{(int)}
7353 @param row_degree: Degree of polynomial to subtract row-wise (y-coordinate). I{(int)}
7354 @param coeffs: An array of size (B{C{row_degree}}+1)*(B{C{col_degree}}+1) with coefficients,
7355 see L{DataField.area_fit_legendre}() for details. I{(list)}
7356 """
7357 pass
7358
7360 """
7361 Fits two-dimensional polynomial with limited total degree to a data field.
7362
7363 See L{DataField.area_fit_poly_max}() for details.
7364
7365
7366 @param max_degree: Maximum total polynomial degree, that is the maximum of m+n
7367 in x^n y^m terms. I{(int)}
7368 @return: Either B{C{coeffs}} if it was not B{C{None}}, or a newly allocated array
7369 with coefficients. I{(list)}
7370 """
7371 return None
7372
7374 """
7375 Fits two-dimensional polynomial with limited total degree to a rectangular
7376 part of a data field.
7377
7378 See L{DataField.area_fit_legendre}() for description. This function
7379 differs by limiting the total maximum degree, while
7380 L{DataField.area_fit_legendre}() limits the maximum degrees in horizontal
7381 and vertical directions independently.
7382
7383
7384 @param col: Upper-left column coordinate. I{(int)}
7385 @param row: Upper-left row coordinate. I{(int)}
7386 @param width: Area width (number of columns). I{(int)}
7387 @param height: Area height (number of rows). I{(int)}
7388 @param max_degree: Maximum total polynomial degree, that is the maximum of m+n
7389 in x^n y^m terms. I{(int)}
7390 @return: Either B{C{coeffs}} if it was not B{C{None}}, or a newly allocated array
7391 with coefficients. I{(list)}
7392 """
7393 return None
7394
7396 """
7397 Subtracts a two-dimensional polynomial with limited total degree from
7398 a data field.
7399
7400 @param max_degree: Maximum total polynomial degree, that is the maximum of m+n
7401 in x^n y^m terms. I{(int)}
7402 @param coeffs: An array of size (B{C{row_degree}}+1)*(B{C{col_degree}}+2)/2 with
7403 coefficients, see L{DataField.area_fit_poly_max}() for details. I{(list)}
7404 """
7405 pass
7406
7408 """
7409 Subtracts a two-dimensional polynomial with limited total degree from a
7410 rectangular part of a data field.
7411
7412 Due to the transform of coordinates to [-1,1] x [-1,1], this method can be
7413 used on an area of dimensions different than the area the coefficients were
7414 calculated for.
7415
7416 @param col: Upper-left column coordinate. I{(int)}
7417 @param row: Upper-left row coordinate. I{(int)}
7418 @param width: Area width (number of columns). I{(int)}
7419 @param height: Area height (number of rows). I{(int)}
7420 @param max_degree: Maximum total polynomial degree, that is the maximum of m+n
7421 in x^n y^m terms. I{(int)}
7422 @param coeffs: An array of size (B{C{row_degree}}+1)*(B{C{col_degree}}+2)/2 with
7423 coefficients, see L{DataField.area_fit_poly_max}() for details. I{(list)}
7424 """
7425 pass
7426
7427 - def fit_poly(mask_field, term_powers, exclude):
7428 """
7429 Fit a given set of polynomial terms to a data field.
7430
7431 @since: 2.11
7432
7433 @param mask_field: Mask of values to take values into account, or B{C{None}} for full
7434 B{C{data_field}}. Values equal to 0.0 and below cause corresponding
7435 B{C{data_field}} samples to be ignored, values equal to 1.0 and above
7436 cause inclusion of corresponding B{C{data_field}} samples. The behaviour
7437 for values inside (0.0, 1.0) is undefined (it may be specified
7438 in the future). I{(L{DataField})}
7439 @param term_powers: Array of size 2*B{C{nterms}} describing the terms to fit. Each
7440 terms is described by a couple of powers (powerx, powery). I{(list)}
7441 @param exclude: Interpret values B{C{w}} in the mask as 1.0-B{C{w}}. I{(bool)}
7442 @return: Value B{C{coeffs}}. (I{(list)})
7443 """
7444 return None
7445
7446 - def area_fit_poly(mask_field, col, row, width, height, term_powers, exclude):
7447 """
7448 Fit a given set of polynomial terms to a rectangular part of a data field.
7449
7450 The polynomial coefficients correspond to normalized coordinates that
7451 are always from the interval [-1,1] where -1 corresponds to the left/topmost
7452 pixel and 1 corresponds to the bottom/rightmost pixel of the area.
7453
7454 @since: 2.11
7455
7456 @param mask_field: Mask of values to take values into account, or B{C{None}} for full
7457 B{C{data_field}}. Values equal to 0.0 and below cause corresponding
7458 B{C{data_field}} samples to be ignored, values equal to 1.0 and above
7459 cause inclusion of corresponding B{C{data_field}} samples. The behaviour
7460 for values inside (0.0, 1.0) is undefined (it may be specified
7461 in the future). I{(L{DataField})}
7462 @param col: Upper-left column coordinate. I{(int)}
7463 @param row: Upper-left row coordinate. I{(int)}
7464 @param width: Area width (number of columns). I{(int)}
7465 @param height: Area height (number of rows). I{(int)}
7466 @param term_powers: Array of size 2*B{C{nterms}} describing the terms to fit. Each
7467 terms is described by a couple of powers (powerx, powery). I{(list)}
7468 @param exclude: Interpret values B{C{w}} in the mask as 1.0-B{C{w}}. I{(bool)}
7469 @return: Value B{C{coeffs}}. (I{(list)})
7470 """
7471 return None
7472
7474 """
7475 Subtract a given set of polynomial terms from a data field.
7476
7477 @since: 2.11
7478
7479 @param term_powers: Array of size 2*B{C{nterms}} describing the fitter terms. Each
7480 terms is described by a couple of powers (powerx, powery). I{(list)}
7481 @param coeffs: Array of size B{C{nterms}} to store with the coefficients. I{(list)}
7482 """
7483 pass
7484
7486 """
7487 Subtract a given set of polynomial terms from a rectangular part of a data
7488 field.
7489
7490 @since: 2.11
7491
7492 @param col: Upper-left column coordinate. I{(int)}
7493 @param row: Upper-left row coordinate. I{(int)}
7494 @param width: Area width (number of columns). I{(int)}
7495 @param height: Area height (number of rows). I{(int)}
7496 @param term_powers: Array of size 2*B{C{nterms}} describing the fitted terms. Each
7497 terms is described by a couple of powers (powerx, powery). I{(list)}
7498 @param coeffs: Array of size B{C{nterms}} to store with the coefficients. I{(list)}
7499 """
7500 pass
7501
7503 """
7504 Fits a plane through neighbourhood of each sample in a rectangular part
7505 of a data field.
7506
7507 The sample is always in the origin of its local (x,y) coordinate system,
7508 even if the neighbourhood is not centered about it (e.g. because sample
7509 is on the edge of data field). Z-coordinate is however not centered,
7510 that is B{C{PLANE_FIT_A}} is normal mean value.
7511
7512
7513 @param size: Neighbourhood size (must be at least 2). It is centered around
7514 each pixel, unless B{C{size}} is even when it sticks to the right. I{(int)}
7515 @param col: Upper-left column coordinate. I{(int)}
7516 @param row: Upper-left row coordinate. I{(int)}
7517 @param width: Area width (number of columns). I{(int)}
7518 @param height: Area height (number of rows). I{(int)}
7519 @param types: The types of requested quantities. I{(list)}
7520 @return: An array of data fields with requested quantities, that is
7521 B{C{results}} unless it was B{C{None}} and a new array was allocated. I{(list)}
7522 """
7523 return None
7524
7526 """
7527 Fits a plane through neighbourhood of each sample in a data field.
7528
7529 See L{DataField.area_fit_local_planes}() for details.
7530
7531
7532 @param size: Neighbourhood size. I{(int)}
7533 @param types: The types of requested quantities. I{(list)}
7534 @return: An array of data fields with requested quantities. I{(list)}
7535 """
7536 return None
7537
7539 """
7540 Extracts values from an elliptic region of a data field.
7541
7542 The elliptic region is defined by its bounding box which must be completely
7543 contained in the data field.
7544
7545
7546 @param col: Upper-left bounding box column coordinate. I{(int)}
7547 @param row: Upper-left bounding box row coordinate. I{(int)}
7548 @param width: Bounding box width (number of columns). I{(int)}
7549 @param height: Bounding box height (number of rows). I{(int)}
7550 @return: The number of extracted values. I{(list)}
7551 """
7552 return None
7553
7555 """
7556 Puts values back to an elliptic region of a data field.
7557
7558 The elliptic region is defined by its bounding box. In versions prior to 2.59 the bounding box must be completely
7559 contained in the data field. Since version 2.59 the ellipse can intersect the data field in any manner.
7560
7561 This method does the reverse of L{DataField.elliptic_area_extract}() allowing to implement pixel-wise filters on
7562 elliptic areas. Values from B{C{data}} are put back to the same positions L{DataField.elliptic_area_extract}() took
7563 them from.
7564
7565 @param col: Upper-left bounding box column coordinate. I{(int)}
7566 @param row: Upper-left bounding box row coordinate. I{(int)}
7567 @param width: Bounding box width (number of columns). I{(int)}
7568 @param height: Bounding box height (number of rows). I{(int)}
7569 @param data: The values to put back. It must be the same array as in previous L{DataField.elliptic_area_extract}(). I{(list)}
7570 """
7571 pass
7572
7574 """
7575 Extracts values from a circular region of a data field.
7576
7577
7578 @param col: Row index of circular area centre. I{(int)}
7579 @param row: Column index of circular area centre. I{(int)}
7580 @param radius: Circular area radius (in pixels). See
7581 L{DataField.circular_area_extract_with_pos}() for caveats. I{(float)}
7582 @return: Array of values. I{(list)}
7583 """
7584 return None
7585
7587 """
7588 Puts values back to a circular region of a data field.
7589
7590 This method does the reverse of L{DataField.circular_area_extract}() allowing to implement pixel-wise filters on
7591 circular areas. Values from B{C{data}} are put back to the same positions L{DataField.circular_area_extract}() took
7592 them from.
7593
7594 @param col: Row index of circular area centre. I{(int)}
7595 @param row: Column index of circular area centre. I{(int)}
7596 @param radius: Circular area radius (in pixels). I{(float)}
7597 @param data: The values to put back. It must be the same array as in previous L{DataField.circular_area_unextract}(). I{(list)}
7598 """
7599 pass
7600
7602 """
7603 Extracts values with positions from a circular region of a data field.
7604
7605 The row and column indices stored to B{C{xpos}} and B{C{ypos}} are relative to the area centre, i.e. to (B{C{col}}, B{C{row}}). The
7606 central pixel will therefore have 0 at the corresponding position in both B{C{xpos}} and B{C{ypos}}.
7607
7608 @since: 2.2
7609
7610 @param col: Row index of circular area centre. I{(int)}
7611 @param row: Column index of circular area centre. I{(int)}
7612 @param radius: Circular area radius (in pixels). Any value is allowed, although to get areas that do not deviate from
7613 true circles after pixelization too much, half-integer values are recommended, integer radii are NOT
7614 recommended. I{(float)}
7615 @return: Tuple consisting of 3 values (B{C{value}}, B{C{xpos}}, B{C{ypos}}). (I{(list)}, I{(list)}, I{(list)})
7616 """
7617 return None, None, None
7618
7620 """
7621 Searches an elliptical area in a data field for local maximum.
7622
7623 The area may stick outside the data field.
7624
7625 The function first finds the maximum within the ellipse, intersected with the data field and then tries subpixel
7626 refinement. The maximum is considered successfully located if it is inside the data field, i.e. not on edge, there
7627 is no higher value in its 8-neighbourhood, and the subpixel refinement of its position succeeds (which usually
7628 happens when the first two conditions are met, but not always).
7629
7630 Even if the function returns B{C{False}} the values of B{C{x}} and B{C{y}} are reasonable, but they may not correspond to an
7631 actual maximum.
7632
7633 The radii can be zero. A single pixel is then examined, but if it is indeed a local maximum, its position is
7634 refined.
7635
7636 @since: 2.49
7637
7638 @param x: Approximate maximum B{C{x}}-location to be improved (in pixels). I{(float)}
7639 @param y: Approximate maximum B{C{y}}-location to be improved (in pixels). I{(float)}
7640 @param ax: Horizontal search radius. I{(int)}
7641 @param ay: Vertical search radius. I{(int)}
7642 @return: Tuple consisting of 3 values (B{C{value}}, B{C{x_out}}, B{C{y_out}}). (I{(bool)}, I{(float)}, I{(float)})
7643 """
7644 return None, None, None
7645
7646 - def affine(dest, affine, interp, exterior, fill_value):
7647 """
7648 Performs an affine transformation of a data field in the horizontal plane.
7649
7650 Note the transform B{C{invtrans}} is the inverse transform, in other
7651 words it calculates the old coordinates from the new coordinates. This
7652 way even degenerate (non-invertible) transforms can be meaningfully used.
7653 Also note that the (column, row) coordinate system is left-handed.
7654
7655 The B{C{EXTERIOR_LAPLACE}} exterior type cannot be used with this function.
7656
7657 @since: 2.34
7658
7659 @param dest: Destination data field. I{(L{DataField})}
7660 @param affine: I{(list)}
7661 @param interp: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
7662 @param exterior: Exterior pixels handling. Expected values: C{B{EXTERIOR_UNDEFINED}}, C{B{EXTERIOR_BORDER_EXTEND}}, C{B{EXTERIOR_MIRROR_EXTEND}}, C{B{EXTERIOR_PERIODIC}}, C{B{EXTERIOR_FIXED_VALUE}}, C{B{EXTERIOR_LAPLACE}}. I{(L{ExteriorType})}
7663 @param fill_value: The value to use with B{C{EXTERIOR_FIXED_VALUE}}. I{(float)}
7664 """
7665 pass
7666
7667 - def affine_prepare(dest, a1a2, a1a2_corr, scaling, prevent_rotation, oversampling):
7668 """
7669 Resolves an affine transformation of a data field in the horizontal plane.
7670
7671 This function calculates suitable arguments for L{DataField.affine}()
7672 from given images and lattice vectors (in real coordinates).
7673
7674 Data field B{C{dest}} will be resized and its real dimensions and units set in
7675 anticipation of L{DataField.affine}(). Its contents will be destroyed.
7676
7677 Note that B{C{a1a2_corr}} is an input-output parameter. In general, the vectors
7678 will be modified according to B{C{scaling}} and B{C{prevent_rotation}} to the actual
7679 vectors in B{C{dest}} after the transformation. Only if B{C{prevent_rotation}} is
7680 B{C{False}} and B{C{scaling}} is B{C{AFFINE_SCALING_AS_GIVEN}} the vectors are
7681 preserved.
7682
7683 @since: 2.49
7684
7685 @param dest: Destination data field. I{(L{DataField})}
7686 @param a1a2: Lattice vectors (or generally base vectors) in B{C{source}}, as an array
7687 of four components: B{C{x1}}, B{C{y1}}, B{C{x2}} and B{C{y2}}. I{(list)}
7688 @param a1a2_corr: Correct lattice vectors (or generally base vectors) B{C{dest}} should
7689 have after the affine transform, in the same form as B{C{a1a2}}. I{(list)}
7690 @param scaling: How (or if) to scale the correct lattice vectors. Expected values: C{B{AFFINE_SCALING_AS_GIVEN}}, C{B{AFFINE_SCALING_PRESERVE_AREA}}, C{B{AFFINE_SCALING_PRESERVE_X}}. I{(L{AffineScalingType})}
7691 @param prevent_rotation: B{C{True}} to prevent rotation of the data by rotating
7692 B{C{a1a2_corr}} as a whole to a direction preserving the
7693 data orientation. B{C{False}} to take B{C{a1a2_corr}} as given. I{(bool)}
7694 @param oversampling: Oversampling factor. Values larger than 1 mean smaller
7695 pixels (and more of them) in B{C{dest}}, values smaller than 1
7696 the opposite. Pass 1.0 for the default pixel size choice. I{(float)}
7697 @return: Tuple consisting of 2 values (B{C{a1a2_corr_out}}, B{C{invtrans}}). (I{(list)}, I{(list)})
7698 """
7699 return None, None
7700
7702 """
7703 Performs the classical Vincent watershed segmentation of a data field.
7704
7705 The segmentation always results in the entire field being masked with the
7706 exception of thin (8-connectivity) lines separating the segments (grains).
7707
7708 Compared to L{DataField.grains_mark_watershed}(), this algorithm is very
7709 fast. However, when used alone, it typically results in a serious
7710 oversegmentation as each local minimum gives raise to a grain. Furthermore,
7711 the full segmentation means that also pixels which would be considered
7712 outside any grain in the topographical sense will be assigned to some
7713 catchment basin. Therefore, pre- or postprocessing is usually necessary,
7714 using the gradient image or a more sophisticated method.
7715
7716 The function does not assign pixels with value B{C{HUGE_VAL}} or larger to any
7717 segment. This can be used to pre-mark certain areas explicitly as
7718 boundaries.
7719
7720 Since the algorithm numbers the grains as a side effect, you can pass a
7721 B{C{grains}} array and get the grain numbers immediatelly, avoiding the
7722 relatively (although not drastically) expensive
7723 L{DataField.number_grains}() call.
7724
7725 @since: 2.37
7726
7727 @param result: Data field that will be filled with the resulting mask. It will be
7728 resized to the dimensions of B{C{data_field}} and its properties set
7729 accordingly. I{(L{DataField})}
7730 @return: Tuple consisting of 2 values (B{C{value}}, B{C{grains}}). (I{(int)}, I{(list)})
7731 """
7732 return None, None
7733
7735 """
7736 Estimates or improves estimate of lattice vectors from a 2D ACF field.
7737
7738 Note that the 2D ACF of a data field has to be passed, not the data field
7739 itself. The correlation function can be for instance calculated by
7740 L{DataField.acf2d}(). However, you can calculate and/or process the
7741 correlation function in any way you see fit.
7742
7743 When the vectors in B{C{a1a2}} are zero the function attempts to estimate the
7744 lattice from scratch. But if B{C{a1a2}} contains two non-zero vectors it takes
7745 them as approximate lattice vectors to improve.
7746
7747 If the function return B{C{False}} the array B{C{a1a2}} is filled with useless values
7748 and must be ignored.
7749
7750 @since: 2.49
7751
7752 @param a1a2: Lattice vectors as an array of four components: B{C{x1}}, B{C{y1}}, B{C{x2}} and
7753 B{C{y2}} (in real coordinates). I{(list)}
7754 @return: Tuple consisting of 2 values (B{C{a1a2_out}}, B{C{succeeded}}). (I{(list)}, I{(BooleanOutArg)})
7755 """
7756 return None, None
7757
7759 """
7760 Estimates or improves estimate of lattice vectors from a 2D PSDF field.
7761
7762 Note that the 2D PSDF of a data field has to be passed, not the data field
7763 itself. The spectral density can be for instance calculated by
7764 L{DataField.fft2d}() and summing the squares of real and imaginary parts
7765 However, you can calculate and/or process the spectral density in any way
7766 you see fit.
7767
7768 When the vectors in B{C{a1a2}} are zero the function attempts to estimate the
7769 lattice from scratch. But if B{C{a1a2}} contains two non-zero vectors it takes
7770 them as approximate lattice vectors to improve.
7771
7772 If the function return B{C{False}} the array B{C{a1a2}} is filled with useless values
7773 and must be ignored.
7774
7775 @since: 2.49
7776
7777 @param a1a2: Lattice vectors as an array of four components: B{C{x1}}, B{C{y1}}, B{C{x2}} and
7778 B{C{y2}} (in real coordinates). I{(list)}
7779 @return: Tuple consisting of 2 values (B{C{a1a2_out}}, B{C{succeeded}}). (I{(list)}, I{(BooleanOutArg)})
7780 """
7781 return None, None
7782
7784 """
7785 Locates local maxima in a data field.
7786
7787 At most B{C{ndata}} maxima are located (with the largest values).
7788
7789
7790 @param ndata: Number of items in B{C{xdata}}, B{C{ydata}} and B{C{zdata}}. I{(int)}
7791 @param skip: Minimum pixel distance between maxima. I{(int)}
7792 @param threshold: Minimum value to be considered a maximum. I{(float)}
7793 @param subpixel: B{C{True}} for subpixel refinement. I{(bool)}
7794 @return: Tuple consisting of 3 values (B{C{xdata}}, B{C{ydata}}, B{C{zdata}}). (I{(list)}, I{(list)}, I{(list)})
7795 """
7796 return None, None, None
7797
7798 - def get_profile_mask(mask, masking, xfrom, yfrom, xto, yto, res, thickness, interpolation):
7799 """
7800 Extracts a possibly averaged profile from data field, with masking.
7801
7802 The extracted profile can contain holes due to masking. It can also contain
7803 no points at all if the all data values along the profile were excluded due
7804 to masking – in this case B{C{None}} is returned.
7805
7806 Unlike L{DataField.get_profile}(), this function takes real coordinates
7807 (without offsets), not row and column indices.
7808
7809 @since: 2.49
7810
7811 @param mask: Mask specifying which values to take into account/exclude, or B{C{None}}. I{(L{DataField})}
7812 @param masking: Masking mode to use. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
7813 @param xfrom: The real B{C{x}}-coordinate where the line starts. I{(float)}
7814 @param yfrom: The real B{C{y}}-coordinate where line starts. I{(float)}
7815 @param xto: The real B{C{x}}-coordinate where the line ends. I{(float)}
7816 @param yto: The real B{C{y}}-coordinate where line ends. I{(float)}
7817 @param res: Requested resolution, i.e. the number of samples to take.
7818 If nonpositive, sampling is chosen to match B{C{data_field}}'s. I{(int)}
7819 @param thickness: Thickness of line to be averaged. I{(int)}
7820 @param interpolation: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
7821 @return: A newly allocated array of B{C{XY}} coordinare pairs, or B{C{None}}.
7822 The caller must free the returned array with g_free(). I{(list)}
7823 """
7824 return None
7825
7827 """
7828 Constructs an array with grain numbers from a mask data field.
7829
7830
7831 @return: A list of integers, containing 0 outside grains and the grain
7832 number inside a grain. I{(list)}
7833 """
7834 return None
7835
7837 """
7838 Constructs an array with grain numbers from a mask data field treated as
7839 periodic.
7840
7841
7842 @return: A list of integers, containing 0 outside grains and the grain
7843 number inside a grain. I{(list)}
7844 """
7845 return None
7846
7848 """
7849 Find sizes of all grains in a mask data field.
7850
7851 Size is the number of pixels in the grain.
7852
7853 The zeroth element of B{C{sizes}} is filled with the number of pixels not covered by the mask.
7854
7855 @since: 2.47
7856
7857 @param grains: Grain numbers filled with L{DataField.number_grains}(). I{(list)}
7858 @return: Value B{C{sizes}}. (I{(list)})
7859 """
7860 return None
7861
7863 """
7864 Finds bounding boxes of all grains in a mask data field.
7865
7866 The array B{C{grains}} must have the same number of elements as B{C{mask_field}}.
7867 Normally it is obtained from a function such as
7868 L{DataField.number_grains}().
7869
7870
7871 @param grains: Array of grain numbers. I{(list)}
7872 @return: Value B{C{bboxes}}. (I{(list)})
7873 """
7874 return None
7875
7877 """
7878 Finds bounding boxes of all grains in a mask data field, assuming periodic
7879 boundary condition.
7880
7881 The array B{C{grains}} must have the same number of elements as B{C{mask_field}}.
7882 Normally it is obtained from a function such as
7883 L{DataField.number_grains}().
7884
7885
7886 @param grains: Array of grain numbers. I{(list)}
7887 @return: Value B{C{bboxes}}. (I{(list)})
7888 """
7889 return None
7890
7892 """
7893 Finds maximum-area inscribed boxes of all grains in a mask data field.
7894
7895 The array B{C{grains}} must have the same number of elements as B{C{mask_field}}.
7896 Normally it is obtained from a function such as
7897 L{DataField.number_grains}().
7898
7899
7900 @param grains: Array of grain numbers. I{(list)}
7901 @return: Value B{C{bboxes}}. (I{(list)})
7902 """
7903 return None
7904
7906 """
7907 Finds a speficied quantity for all grains in a data field.
7908
7909 The array B{C{grains}} must have the same number of elements as B{C{data_field}}.
7910 Normally it is obtained from a function such as
7911 L{DataField.number_grains}() for the corresponding mask.
7912
7913
7914 @param grains: Array of grain numbers. I{(list)}
7915 @param quantity: The quantity to calculate, identified by GrainQuantity. Expected values: C{B{GRAIN_VALUE_PROJECTED_AREA}}, C{B{GRAIN_VALUE_EQUIV_SQUARE_SIDE}}, C{B{GRAIN_VALUE_EQUIV_DISC_RADIUS}}, C{B{GRAIN_VALUE_SURFACE_AREA}}, C{B{GRAIN_VALUE_MAXIMUM}}, C{B{GRAIN_VALUE_MINIMUM}}, C{B{GRAIN_VALUE_MEAN}}, C{B{GRAIN_VALUE_MEDIAN}}, C{B{GRAIN_VALUE_PIXEL_AREA}}, C{B{GRAIN_VALUE_HALF_HEIGHT_AREA}}, C{B{GRAIN_VALUE_FLAT_BOUNDARY_LENGTH}}, C{B{GRAIN_VALUE_RMS}}, C{B{GRAIN_VALUE_MINIMUM_BOUND_SIZE}}, C{B{GRAIN_VALUE_MINIMUM_BOUND_ANGLE}}, C{B{GRAIN_VALUE_MAXIMUM_BOUND_SIZE}}, C{B{GRAIN_VALUE_MAXIMUM_BOUND_ANGLE}}, C{B{GRAIN_VALUE_CENTER_X}}, C{B{GRAIN_VALUE_CENTER_Y}}, C{B{GRAIN_VALUE_VOLUME_0}}, C{B{GRAIN_VALUE_VOLUME_MIN}}, C{B{GRAIN_VALUE_VOLUME_LAPLACE}}, C{B{GRAIN_VALUE_SLOPE_THETA}}, C{B{GRAIN_VALUE_SLOPE_PHI}}, C{B{GRAIN_VALUE_BOUNDARY_MAXIMUM}}, C{B{GRAIN_VALUE_BOUNDARY_MINIMUM}}, C{B{GRAIN_VALUE_CURVATURE_CENTER_X}}, C{B{GRAIN_VALUE_CURVATURE_CENTER_Y}}, C{B{GRAIN_VALUE_CURVATURE_CENTER_Z}}, C{B{GRAIN_VALUE_CURVATURE1}}, C{B{GRAIN_VALUE_CURVATURE2}}, C{B{GRAIN_VALUE_CURVATURE_ANGLE1}}, C{B{GRAIN_VALUE_CURVATURE_ANGLE2}}, C{B{GRAIN_VALUE_INSCRIBED_DISC_R}}, C{B{GRAIN_VALUE_INSCRIBED_DISC_X}}, C{B{GRAIN_VALUE_INSCRIBED_DISC_Y}}, C{B{GRAIN_VALUE_CONVEX_HULL_AREA}}, C{B{GRAIN_VALUE_CIRCUMCIRCLE_R}}, C{B{GRAIN_VALUE_CIRCUMCIRCLE_X}}, C{B{GRAIN_VALUE_CIRCUMCIRCLE_Y}}, C{B{GRAIN_VALUE_MEAN_RADIUS}}, C{B{GRAIN_VALUE_EQUIV_ELLIPSE_MAJOR}}, C{B{GRAIN_VALUE_EQUIV_ELLIPSE_MINOR}}, C{B{GRAIN_VALUE_EQUIV_ELLIPSE_ANGLE}}, C{B{GRAIN_VALUE_MINIMUM_MARTIN_DIAMETER}}, C{B{GRAIN_VALUE_MINIMUM_MARTIN_ANGLE}}, C{B{GRAIN_VALUE_MAXIMUM_MARTIN_DIAMETER}}, C{B{GRAIN_VALUE_MAXIMUM_MARTIN_ANGLE}}. I{(L{GrainQuantity})}
7916 @return: Value B{C{values}}. (I{(list)})
7917 """
7918 return None
7919
7921 """
7922 Calculates the distribution of a speficied grain quantity.
7923
7924 The array B{C{grains}} must have the same number of elements as B{C{data_field}}.
7925 Normally it is obtained from a function such as
7926 L{DataField.number_grains}() for the corresponding mask.
7927
7928
7929 @param grain_field: A data field representing the mask. It must have the same
7930 dimensions as the data field. I{(L{DataField})}
7931 @param grains: Array of grain numbers. I{(list)}
7932 @param quantity: The quantity to calculate, identified by GrainQuantity. Expected values: C{B{GRAIN_VALUE_PROJECTED_AREA}}, C{B{GRAIN_VALUE_EQUIV_SQUARE_SIDE}}, C{B{GRAIN_VALUE_EQUIV_DISC_RADIUS}}, C{B{GRAIN_VALUE_SURFACE_AREA}}, C{B{GRAIN_VALUE_MAXIMUM}}, C{B{GRAIN_VALUE_MINIMUM}}, C{B{GRAIN_VALUE_MEAN}}, C{B{GRAIN_VALUE_MEDIAN}}, C{B{GRAIN_VALUE_PIXEL_AREA}}, C{B{GRAIN_VALUE_HALF_HEIGHT_AREA}}, C{B{GRAIN_VALUE_FLAT_BOUNDARY_LENGTH}}, C{B{GRAIN_VALUE_RMS}}, C{B{GRAIN_VALUE_MINIMUM_BOUND_SIZE}}, C{B{GRAIN_VALUE_MINIMUM_BOUND_ANGLE}}, C{B{GRAIN_VALUE_MAXIMUM_BOUND_SIZE}}, C{B{GRAIN_VALUE_MAXIMUM_BOUND_ANGLE}}, C{B{GRAIN_VALUE_CENTER_X}}, C{B{GRAIN_VALUE_CENTER_Y}}, C{B{GRAIN_VALUE_VOLUME_0}}, C{B{GRAIN_VALUE_VOLUME_MIN}}, C{B{GRAIN_VALUE_VOLUME_LAPLACE}}, C{B{GRAIN_VALUE_SLOPE_THETA}}, C{B{GRAIN_VALUE_SLOPE_PHI}}, C{B{GRAIN_VALUE_BOUNDARY_MAXIMUM}}, C{B{GRAIN_VALUE_BOUNDARY_MINIMUM}}, C{B{GRAIN_VALUE_CURVATURE_CENTER_X}}, C{B{GRAIN_VALUE_CURVATURE_CENTER_Y}}, C{B{GRAIN_VALUE_CURVATURE_CENTER_Z}}, C{B{GRAIN_VALUE_CURVATURE1}}, C{B{GRAIN_VALUE_CURVATURE2}}, C{B{GRAIN_VALUE_CURVATURE_ANGLE1}}, C{B{GRAIN_VALUE_CURVATURE_ANGLE2}}, C{B{GRAIN_VALUE_INSCRIBED_DISC_R}}, C{B{GRAIN_VALUE_INSCRIBED_DISC_X}}, C{B{GRAIN_VALUE_INSCRIBED_DISC_Y}}, C{B{GRAIN_VALUE_CONVEX_HULL_AREA}}, C{B{GRAIN_VALUE_CIRCUMCIRCLE_R}}, C{B{GRAIN_VALUE_CIRCUMCIRCLE_X}}, C{B{GRAIN_VALUE_CIRCUMCIRCLE_Y}}, C{B{GRAIN_VALUE_MEAN_RADIUS}}, C{B{GRAIN_VALUE_EQUIV_ELLIPSE_MAJOR}}, C{B{GRAIN_VALUE_EQUIV_ELLIPSE_MINOR}}, C{B{GRAIN_VALUE_EQUIV_ELLIPSE_ANGLE}}, C{B{GRAIN_VALUE_MINIMUM_MARTIN_DIAMETER}}, C{B{GRAIN_VALUE_MINIMUM_MARTIN_ANGLE}}, C{B{GRAIN_VALUE_MAXIMUM_MARTIN_DIAMETER}}, C{B{GRAIN_VALUE_MAXIMUM_MARTIN_ANGLE}}. I{(L{GrainQuantity})}
7933 @param nstats: The number of bins in the histogram. Pass a non-positive value to
7934 determine the number of bins automatically. I{(int)}
7935 @return: The distribution as a data line. I{(L{DataLine})}
7936 """
7937 return None
7938
7941
7943 """
7944 Convenience macro doing L{gwy_serializable_duplicate}() with all the necessary
7945 typecasting.
7946
7947 Use L{DataField.new_alike}() if you don't want to copy data, only
7948 resolutions and units.
7949
7950 @return: I{(L{DataField})}
7951 """
7952 return None
7953
7955 """
7956 Alias for L{DataField.get_dx}().
7957
7958 @return: I{(float)}
7959 """
7960 return None
7961
7963 """
7964 Alias for L{DataField.get_dy}().
7965
7966 @return: I{(float)}
7967 """
7968 return None
7969
7971 """
7972 Gets pointer to data which the data field contains.
7973
7974
7975 @return: integer pointing to the raw data of the data field I{(long)}
7976 """
7977 return None
7978
7979
7981 """
7982 One-dimensional data representation
7983
7984
7985 B{C{DataLine}} represents 1D data arrays in Gwyddion. It is used for most of
7986 the data processing functions connected with 1D data, graphs, etc.
7987
7988 """
7990 """
7991 Creates a new data line.
7992
7993
7994 @param res: Resolution, i.e., the number of samples. I{(int)}
7995 @param real: Real physical dimension. I{(float)}
7996 @param nullme: Whether the data line should be initialized to zeroes. If B{C{False}},
7997 the data will not be initialized. I{(bool)}
7998 @return: A newly created data line. I{(L{DataLine})}
7999 """
8000 return None
8001
8003 """
8004 Checks whether two data lines are compatible.
8005
8006
8007 @param data_line2: Another data line. I{(L{DataLine})}
8008 @param check: The compatibility tests to perform. Expected values: C{B{DATA_COMPATIBILITY_RES}}, C{B{DATA_COMPATIBILITY_REAL}}, C{B{DATA_COMPATIBILITY_MEASURE}}, C{B{DATA_COMPATIBILITY_LATERAL}}, C{B{DATA_COMPATIBILITY_VALUE}}, C{B{DATA_COMPATIBILITY_AXISCAL}}, C{B{DATA_COMPATIBILITY_NCURVES}}, C{B{DATA_COMPATIBILITY_CURVELEN}}, C{B{DATA_COMPATIBILITY_ALL}}. I{(L{DataCompatibilityFlags})}
8009 @return: Zero if all tested properties are compatible. Flags corresponding to failed tests if data lines are not
8010 compatible. I{(DataCompatibilityFlags)}
8011 """
8012 return None
8013
8015 """
8016 Checks whether a data line is compatible with brick Z-profiles.
8017
8018 If B{C{check}} includes B{C{DATA_COMPATIBILITY_REAL}} or B{C{DATA_COMPATIBILITY_LATERAL}} but not
8019 B{C{DATA_COMPATIBILITY_AXISCAL}}, B{C{data_line}} is simply compared to B{C{brick}} in the Z direction.
8020
8021 If you include B{C{DATA_COMPATIBILITY_AXISCAL}} and B{C{brick}} has a Z-calibration data line, then the value range and
8022 units of this data line are compared to B{C{data_line}}. This may not be very useful.
8023
8024 @since: 2.51
8025
8026 @param brick: A three-dimensional data brick. I{(L{Brick})}
8027 @param check: The compatibility tests to perform. Expected values: C{B{DATA_COMPATIBILITY_RES}}, C{B{DATA_COMPATIBILITY_REAL}}, C{B{DATA_COMPATIBILITY_MEASURE}}, C{B{DATA_COMPATIBILITY_LATERAL}}, C{B{DATA_COMPATIBILITY_VALUE}}, C{B{DATA_COMPATIBILITY_AXISCAL}}, C{B{DATA_COMPATIBILITY_NCURVES}}, C{B{DATA_COMPATIBILITY_CURVELEN}}, C{B{DATA_COMPATIBILITY_ALL}}. I{(L{DataCompatibilityFlags})}
8028 @return: Zero if all tested properties are compatible. Flags corresponding to failed tests if the data objects are
8029 not compatible. I{(DataCompatibilityFlags)}
8030 """
8031 return None
8032
8034 """
8035 Fills missing values in a data line using Laplace data correction.
8036
8037 Both data lines must have the same number of values.
8038
8039 For one-dimensional data the missing data interpolation is explicit.
8040 Interior missing segments are filled with linear dependence between the edge
8041 points. Missing segments with one end open are filled with the edge value.
8042
8043 @since: 2.45
8044
8045 @param mask_line: Mask of places to be corrected. I{(L{DataLine})}
8046 @return: B{C{True}} if the line contained any data at all. If there are no data
8047 the B{C{False}} is returned and B{C{data_line}} is filled with zeros. I{(bool)}
8048 """
8049 return None
8050
8052 """
8053 Sets lateral and value units of a data field to match a data line.
8054
8055 @param data_field: A data field to set units of. I{(L{DataField})}
8056 """
8057 pass
8058
8060 """
8061 Creates a new data line similar to an existing one.
8062
8063 Use L{DataLine.duplicate}() if you want to copy a data line including
8064 data.
8065
8066
8067 @param nullme: Whether the data line should be initialized to zeroes. If B{C{False}},
8068 the data will not be initialized. I{(bool)}
8069 @return: A newly created data line. I{(L{DataLine})}
8070 """
8071 return None
8072
8074 """
8075 Emits signal "data_changed" on a data line.
8076
8077 """
8078 pass
8079
8081 """
8082 Creates a new data line by resampling an existing one.
8083
8084 This method is equivalent to L{DataLine.duplicate}() followed by
8085 L{DataLine.resample}(), but it is more efficient.
8086
8087 @since: 2.1
8088
8089 @param res: Desired resolution. I{(int)}
8090 @param interpolation: Interpolation method to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
8091 @return: A newly created data line. I{(L{DataLine})}
8092 """
8093 return None
8094
8096 """
8097 Resamples a data line.
8098
8099 In other words changes the size of one dimensional field related with data
8100 line. The original values are used for resampling using a requested
8101 interpolation alorithm.
8102
8103 @param res: Desired resolution. I{(int)}
8104 @param interpolation: Interpolation method to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
8105 """
8106 pass
8107
8109 """
8110 Resizes (crops) a data line.
8111
8112 Extracts a part of data line in range B{C{from}}..(B{C{to}}-1), recomputing real
8113 sizes.
8114
8115 @param from_: I{(int)}
8116 @param to: Where to finish + 1. I{(int)}
8117 """
8118 pass
8119
8121 """
8122 Extracts a part of a data line to a new data line.
8123
8124
8125 @param from_: I{(int)}
8126 @param len: Length of extracted segment. I{(int)}
8127 @return: The extracted area as a newly created data line. I{(L{DataLine})}
8128 """
8129 return None
8130
8132 """
8133 Copies the contents of a data line to another already allocated data line
8134 of the same size.
8135
8136 @warning:Semantic of method differs from L{DataField.copy}(), it copies
8137 only data. It will be probably changed.
8138
8139 @param target: Destination data line. I{(L{DataLine})}
8140 """
8141 pass
8142
8144 """
8145 Gets the number of data points in a data line.
8146
8147
8148 @return: Resolution (number of data points). I{(int)}
8149 """
8150 return None
8151
8153 """
8154 Gets the physical size of a data line.
8155
8156
8157 @return: Real size of data line. I{(float)}
8158 """
8159 return None
8160
8162 """
8163 Sets the real data line size.
8164
8165 @param real: value to be set I{(float)}
8166 """
8167 pass
8168
8170 """
8171 Gets the offset of data line origin.
8172
8173
8174 @return: Offset value. I{(float)}
8175 """
8176 return None
8177
8179 """
8180 Sets the offset of a data line origin.
8181
8182 Note offsets don't affect any calculation, nor functions like
8183 L{DataLine.rtoi}().
8184
8185 @param offset: New offset value. I{(float)}
8186 """
8187 pass
8188
8190 """
8191 Gets the sample distance (pixel size) of a data line in real units.
8192
8193 The result is the same as
8194 L{DataLine.get_real}(data_line)/L{DataLine.get_res}(data_line).
8195
8196 @since: 2.52
8197
8198 @return: Sampling step size. I{(float)}
8199 """
8200 return None
8201
8203 """
8204 Returns lateral SI unit of a data line.
8205
8206
8207 @return: SI unit corresponding to the lateral (X) dimension of the data
8208 line. Its reference count is not incremented. I{(L{SIUnit})}
8209 """
8210 return None
8211
8213 """
8214 Returns value SI unit of a data line.
8215
8216
8217 @return: SI unit corresponding to the "height" (Z) dimension of the data
8218 line. Its reference count is not incremented. I{(L{SIUnit})}
8219 """
8220 return None
8221
8223 """
8224 Sets the SI unit corresponding to the lateral (X) dimension of a data
8225 line.
8226
8227 It does not assume a reference on B{C{si_unit}}, instead it adds its own
8228 reference.
8229
8230 @param si_unit: SI unit to be set. I{(L{SIUnit})}
8231 """
8232 pass
8233
8235 """
8236 Sets the SI unit corresponding to the "height" (Y) dimension of a data
8237 line.
8238
8239 It does not assume a reference on B{C{si_unit}}, instead it adds its own
8240 reference.
8241
8242 @param si_unit: SI unit to be set. I{(L{SIUnit})}
8243 """
8244 pass
8245
8255
8268
8270 """
8271 Sets lateral and value units of a data line to match another data line.
8272
8273 @since: 2.49
8274
8275 @param target: Destination data line. I{(L{DataLine})}
8276 """
8277 pass
8278
8280 """
8281 Transforms pixel coordinate to real (physical) coordinate.
8282
8283 That is it maps range [0..resolution] to range [0..real-size]. It is not
8284 suitable for conversion of matrix indices to physical coordinates, you
8285 have to use L{DataLine.itor}(B{C{data_line}}, B{C{pixpos}} + 0.5) for that.
8286
8287
8288 @param pixpos: Pixel coordinate. I{(float)}
8289 @return: B{C{pixpos}} in real coordinates. I{(float)}
8290 """
8291 return None
8292
8293 - def rtoi(realpos):
8294 """
8295 Transforms real (physical) coordinate to pixel coordinate.
8296
8297 That is it maps range [0..real-size] to range [0..resolution].
8298
8299
8300 @param realpos: Real coordinate. I{(float)}
8301 @return: B{C{realpos}} in pixel coordinates. I{(float)}
8302 """
8303 return None
8304
8306 """
8307 Gets value at given position in a data line.
8308
8309 Do not access data with this function inside inner loops, it's slow.
8310 Get raw data buffer with L{DataLine.get_data_const}() and access it
8311 directly instead.
8312
8313
8314 @param i: Position in the line (index). I{(int)}
8315 @return: Value at given index. I{(float)}
8316 """
8317 return None
8318
8320 """
8321 Sets the value at given position in a data line.
8322
8323 Do not set data with this function inside inner loops, it's slow. Get raw
8324 data buffer with L{DataLine.get_data}() and write to it directly instead.
8325
8326 @param i: Position in the line (index). I{(int)}
8327 @param value: Value to set. I{(float)}
8328 """
8329 pass
8330
8332 """
8333 Gets interpolated value at arbitrary data line point indexed by pixel
8334 coordinates.
8335
8336 Note pixel values are centered in intervals [B{C{j}}, B{C{j}}+1], so to get the same
8337 value as L{DataLine.get_val}(B{C{data_line}}, B{C{j}}) returns,
8338 it's necessary to add 0.5:
8339 L{DataLine.get_dval}(B{C{data_line}}, B{C{j}}+0.5, B{C{interpolation}}).
8340
8341 See also L{DataLine.get_dval_real}() that does the same, but takes
8342 real coordinates.
8343
8344
8345 @param x: Position in data line in range [0, resolution]. If the value is outside
8346 this range, the nearest border value is returned. I{(float)}
8347 @param interpolation: Interpolation method to use. I{(int)}
8348 @return: Value interpolated in the data line. I{(float)}
8349 """
8350 return None
8351
8353 """
8354 Gets interpolated value at arbitrary data line point indexed by real
8355 coordinates.
8356
8357 See also L{DataLine.get_dval}() for interpolation explanation.
8358
8359
8360 @param x: real coordinates position I{(float)}
8361 @param interpolation: interpolation method used I{(int)}
8362 @return: Value interpolated in the data line. I{(float)}
8363 """
8364 return None
8365
8367 """
8368 Reflects and/or inverts a data line.
8369
8370 In the case of value reflection, it's inverted about mean value.
8371
8372 @param x: Whether to invert data point order. I{(bool)}
8373 @param z: Whether to invert in Z direction (i.e., invert values). I{(bool)}
8374 """
8375 pass
8376
8378 """
8379 Fills a data line with zeroes.
8380
8381 """
8382 pass
8383
8385 """
8386 Fills a data line with specified value.
8387
8388 @param value: Value to fill data line with. I{(float)}
8389 """
8390 pass
8391
8393 """
8394 Multiplies all values in a data line with a specified value.
8395
8396 @param value: Value to multiply data line with. I{(float)}
8397 """
8398 pass
8399
8401 """
8402 Adds a specified value to all values in a data line.
8403
8404 @param value: Value to be added. I{(float)}
8405 """
8406 pass
8407
8409 """
8410 Fills a data line part with zeroes.
8411
8412 @param from_: I{(int)}
8413 @param to: Index the line part ends at + 1. I{(int)}
8414 """
8415 pass
8416
8418 """
8419 Fills specified part of data line with specified number
8420
8421 @param from_: I{(int)}
8422 @param to: Index the line part ends at + 1. I{(int)}
8423 @param value: Value to fill data line part with. I{(float)}
8424 """
8425 pass
8426
8428 """
8429 Multiplies all values in a part of data line by specified value.
8430
8431 @param from_: I{(int)}
8432 @param to: Index the line part ends at + 1. I{(int)}
8433 @param value: Value multiply data line part with. I{(float)}
8434 """
8435 pass
8436
8438 """
8439 Adds specified value to all values in a part of a data line.
8440
8441 @param from_: I{(int)}
8442 @param to: Index the line part ends at + 1. I{(int)}
8443 @param value: Value to be added I{(float)}
8444 """
8445 pass
8446
8448 """
8449 Sums two data lines.
8450
8451 @since: 2.56
8452
8453 @param operand1: First data line operand. I{(L{DataLine})}
8454 @param operand2: Second data line operand. I{(L{DataLine})}
8455 """
8456 pass
8457
8459 """
8460 Subtracts two data lines.
8461
8462 @since: 2.56
8463
8464 @param operand1: First data line operand. I{(L{DataLine})}
8465 @param operand2: Second data line operand. I{(L{DataLine})}
8466 """
8467 pass
8468
8470 """
8471 Multiplies two data lines.
8472
8473 @since: 2.56
8474
8475 @param operand1: First data line operand. I{(L{DataLine})}
8476 @param operand2: Second data line operand. I{(L{DataLine})}
8477 """
8478 pass
8479
8481 """
8482 Computes point-wise general linear combination of two data lines.
8483
8484 @since: 2.61
8485
8486 @param coeff1: Factor to multiply the first operand with. I{(float)}
8487 @param operand1: First data line operand. I{(L{DataLine})}
8488 @param coeff2: Factor to multiply the second operand with. I{(float)}
8489 @param operand2: Second data line operand. I{(L{DataLine})}
8490 @param constant: Constant term to add to the result. I{(float)}
8491 """
8492 pass
8493
8495 """
8496 Sets all the values to B{C{bottom}} or B{C{top}} value
8497 depending on whether the original values are
8498 below or above B{C{threshold}} value
8499
8500
8501 @param threshval: Threshold value. I{(float)}
8502 @param bottom: Lower replacement value. I{(float)}
8503 @param top: Upper replacement value. I{(float)}
8504 @return: total number of values above threshold I{(int)}
8505 """
8506 return None
8507
8509 """
8510 Sets all the values within interval to B{C{bottom}} or B{C{top}} value
8511 depending on whether the original values are
8512 below or above B{C{threshold}} value.
8513
8514
8515 @param from_: I{(int)}
8516 @param to: Index the line part ends at + 1. I{(int)}
8517 @param threshval: Threshold value. I{(float)}
8518 @param bottom: Lower replacement value. I{(float)}
8519 @param top: Upper replacement value. I{(float)}
8520 @return: total number of values above threshold within interval I{(int)}
8521 """
8522 return None
8523
8525 """
8526 Finds line leveling coefficients.
8527
8528 The coefficients can be used for line leveling using relation
8529 data[i] := data[i] - (av + bv*i);
8530
8531 @return: Tuple consisting of 2 values (B{C{av}}, B{C{bv}}). (I{(float)}, I{(float)})
8532 """
8533 return None, None
8534
8536 """
8537 Performs line leveling.
8538
8539 See L{DataLine.get_line_coeffs}() for deails.
8540
8541 @param av: Height coefficient. I{(float)}
8542 @param bv: Slope coefficient. I{(float)}
8543 """
8544 pass
8545
8546 - def rotate(angle, interpolation):
8547 """
8548 Performs line rotation.
8549
8550 This is operation similar to leveling, but it does not change the angles
8551 between line segments (on the other hand it introduces other deformations
8552 due to discretization).
8553
8554 @since: 2.7
8555
8556 @param angle: Angle of rotation (in radians), counterclockwise. I{(float)}
8557 @param interpolation: Interpolation method to use (can be only of two-point type). Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
8558 """
8559 pass
8560
8562 """
8563 Performs line rotation.
8564
8565 Use L{DataLine.rotate}() instead.
8566
8567 @param angle: Angle of rotation (in radians), counterclockwise. I{(float)}
8568 @param interpolation: Interpolation method to use (can be only of two-point type). I{(int)}
8569 """
8570 pass
8571
8573 """
8574 Computes central derivaltion at given index in a data line.
8575
8576
8577 @param i: Pixel coordinate. I{(int)}
8578 @return: Derivation at given position. I{(float)}
8579 """
8580 return None
8581
8583 """
8584 Transforms a distribution in a data line to cummulative distribution.
8585
8586 Each element becomes sum of all previous elements in the line, including
8587 self.
8588
8589 """
8590 pass
8591
8593 """
8594 Applies sqrt() to each element in a data line.
8595
8596 """
8597 pass
8598
8599 - def dwt(wt_coefs, direction, minsize):
8600 """
8601 Performs steps of the wavelet decomposition.
8602
8603 The smallest low pass coefficients block is equal to B{C{minsize}}. Run with
8604 B{C{minsize}} = B{C{dline}}->res/2 to perform one step of decomposition
8605 or B{C{minsize}} = 4 to perform full decomposition (or anything between).
8606
8607
8608 @param wt_coefs: Data line where the wavelet transform coefficients are stored. I{(L{DataLine})}
8609 @param direction: Transform direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
8610 @param minsize: size of minimal transform result block I{(int)}
8611 """
8612 pass
8613
8614 - def fft(isrc, rdest, idest, windowing, direction, interpolation, preserverms, level):
8615 """
8616 Calculates Fast Fourier Transform of a data line.
8617
8618 A windowing or data leveling can be applied if requested.
8619
8620 @param isrc: Imaginary input data line. I{(L{DataLine})}
8621 @param rdest: Real output data line. It will be resized to the size of the input data line. I{(L{DataLine})}
8622 @param idest: Imaginary output data line. It will be resized to the size of the input data line. I{(L{DataLine})}
8623 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
8624 @param direction: FFT direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
8625 @param interpolation: Interpolation type. Ignored since 2.8 as no resampling is performed. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
8626 @param preserverms: B{C{True}} to preserve RMS value while windowing. I{(bool)}
8627 @param level: 0 to perform no leveling, 1 to subtract mean value, 2 to subtract line (the number can be interpreted as
8628 the first polynomial degree to keep, but only the enumerated three values are available). I{(int)}
8629 """
8630 pass
8631
8632 - def part_fft(isrc, rdest, idest, from_, len, windowing, direction, interpolation, preserverms, level):
8633 """
8634 Calculates Fast Fourier Transform of a part of a data line.
8635
8636 A windowing or data leveling can be applied if requested.
8637
8638 @param isrc: Imaginary input data line. Since 2.7 it can be B{C{None}} for real-to-complex transforms. I{(L{DataLine})}
8639 @param rdest: Real output data line, it will be resized to B{C{len}}. I{(L{DataLine})}
8640 @param idest: Imaginary output data line, it will be resized to B{C{len}}. I{(L{DataLine})}
8641 @param from_: I{(int)}
8642 @param len: Lenght of data line part, it must be at least 2. I{(int)}
8643 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
8644 @param direction: FFT direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
8645 @param interpolation: Interpolation type. Ignored since 2.8 as no resampling is performed. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
8646 @param preserverms: B{C{True}} to preserve RMS value while windowing. I{(bool)}
8647 @param level: 0 to perform no leveling, 1 to subtract mean value, 2 to subtract line (the number can be interpreted as
8648 the first polynomial degree to keep, but only the enumerated three values are available). I{(int)}
8649 """
8650 pass
8651
8652 - def fft_raw(isrc, rdest, idest, direction):
8653 """
8654 Calculates Fast Fourier Transform of a data line.
8655
8656 No leveling, windowing nor scaling is performed.
8657
8658 The normalisation of FFT is symmetrical, so transformations in both directions are unitary.
8659
8660 Since 2.8 the dimensions need not to be from the set of sizes returned by L{gwy_fft_find_nice_size}().
8661
8662 @since: 2.1
8663
8664 @param isrc: Imaginary input data line. Since 2.7 it can be B{C{None}} for real-to-complex transform. I{(L{DataLine})}
8665 @param rdest: Real output data line. It will be resized to the size of the input data line. I{(L{DataLine})}
8666 @param idest: Imaginary output data line. It will be resized to the size of the input data line. I{(L{DataLine})}
8667 @param direction: FFT direction. Expected values: C{B{TRANSFORM_DIRECTION_BACKWARD}}, C{B{TRANSFORM_DIRECTION_FORWARD}}. I{(L{TransformDirection})}
8668 """
8669 pass
8670
8671 - def zoom_fft(isrc, rdest, idest, m, f0, f1):
8672 """
8673 Computes Zoom FFT of a data line.
8674
8675 The output is DFTs, but computed for an arbitrary linear sequence of frequencies. The frequencies do not have to
8676 be in any relation to the data sampling step.
8677
8678 The first item of output corresponds exactly to B{C{f0}} and the last exactly to B{C{f1}}. So the frequency sampling step
8679 will be (B{C{f1}} − B{C{f0}})/(B{C{m}} − 1), instead of the more usual division by B{C{m}}. To follow the usual Gwyddion conventions,
8680 the output data line real size will be (B{C{f1}} − B{C{f0}})/(B{C{m}} − 1)*B{C{m}}. If it seems confusing, just take the output as
8681 indexed by integers and work with that.
8682
8683 Frequency step of one corresponds to the normal DFT frequency step. Therefore, passing B{C{f0}}=0, B{C{f1}}=B{C{n}}-1 (where B{C{rsrc}}
8684 has B{C{n}} points) and B{C{m}}=B{C{n}} reproduces the usual DFT, except more slowly. The result is normalised as raw FFT and the
8685 units of the output data lines are unchanged.
8686
8687 The transform direction is always forward. Windowing or other preprocessing need to be done separately beforehand.
8688 They would be usually once, but followed by any number of (Zoom) FFTs.
8689
8690 @since: 2.61
8691
8692 @param isrc: Imaginary input data line. It can be B{C{None}} for real-to-complex transform. I{(L{DataLine})}
8693 @param rdest: Real output data line. It will be resized to B{C{m}} samples. I{(L{DataLine})}
8694 @param idest: Imaginary output data line. It will be resized to B{C{m}} samples. I{(L{DataLine})}
8695 @param m: The number of frequencies to compute. It must be at least 2. I{(int)}
8696 @param f0: The first spatial frequency, measured in DFT frequency steps. I{(float)}
8697 @param f1: The last spatial frequency, measured in DFT frequency steps. I{(float)}
8698 """
8699 pass
8700
8702 """
8703 Performs windowing of a data line in preparation for FFT.
8704
8705 @since: 2.62
8706
8707 @param windowing: Windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
8708 """
8709 pass
8710
8712 """
8713 Finds the maximum value of a data line.
8714
8715
8716 @return: The maximum value. I{(float)}
8717 """
8718 return None
8719
8721 """
8722 Finds the minimum value of a data line.
8723
8724
8725 @return: The minimum value. I{(float)}
8726 """
8727 return None
8728
8730 """
8731 Finds the minimum and maximum values of a data line.
8732
8733 Since 2.42
8734
8735 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
8736 """
8737 return None, None
8738
8740 """
8741 Finds the minimum pixel position of a data line.
8742
8743 For historical reasons the value is returned as double, but it is always
8744 an integer.
8745
8746
8747 @return: The minimum pixel position.
8748
8749 Since 2.48 I{(float)}
8750 """
8751 return None
8752
8754 """
8755 Finds the maximum pixel position of a data line.
8756
8757 For historical reasons the value is returned as double, but it is always
8758 an integer.
8759
8760
8761 @return: The maximum pixel position.
8762
8763 Since 2.48 I{(float)}
8764 """
8765 return None
8766
8768 """
8769 Finds the real minimum position in a data line.
8770
8771
8772 @return: Real position for the minimum.
8773
8774 Since 2.48 I{(float)}
8775 """
8776 return None
8777
8779 """
8780 Finds the real maximum position in a data line.
8781
8782
8783 @return: Real position for the maximum.
8784
8785 Since 2.48 I{(float)}
8786 """
8787 return None
8788
8790 """
8791 Computes average value of a data line.
8792
8793
8794 @return: Average value I{(float)}
8795 """
8796 return None
8797
8799 """
8800 Computes root mean square value of a data line.
8801
8802
8803 @return: Root mean square deviation of values. I{(float)}
8804 """
8805 return None
8806
8808 """
8809 Computes root mean square slope in a data line.
8810
8811 @since: 2.2
8812
8813 @return: Root mean square slope within a given interval. I{(float)}
8814 """
8815 return None
8816
8818 """
8819 Computes the total variation of a data line.
8820
8821 See L{DataLine.part_get_variation}() for definition and discussion.
8822
8823 @since: 2.42
8824
8825 @return: The total variation. I{(float)}
8826 """
8827 return None
8828
8830 """
8831 Computes sum of all values in a data line.
8832
8833
8834 @return: sum of all the values. I{(float)}
8835 """
8836 return None
8837
8839 """
8840 Computes the mean absolute deviation of a data line.
8841
8842 @since: 2.42
8843
8844 @return: The mean absolute deviation of height values. I{(float)}
8845 """
8846 return None
8847
8849 """
8850 Computes the skew of a data line.
8851
8852 @since: 2.42
8853
8854 @return: The skew of height values. I{(float)}
8855 """
8856 return None
8857
8859 """
8860 Computes the kurtosis of a data line.
8861
8862 @since: 2.42
8863
8864 @return: The kurtosis of height values.
8865
8866 Note the kurtosis returned by this function returns is the excess kurtosis
8867 which is zero for the Gaussian distribution (not 3). I{(float)}
8868 """
8869 return None
8870
8872 """
8873 Finds the maximum value of a part of a data line.
8874
8875
8876 @param from_: I{(int)}
8877 @param to: Index the line part ends at + 1. I{(int)}
8878 @return: Maximum within given interval. I{(float)}
8879 """
8880 return None
8881
8883 """
8884 Finds the minimum value of a part of a data line.
8885
8886
8887 @param from_: I{(int)}
8888 @param to: Index the line part ends at + 1. I{(int)}
8889 @return: Minimum within given interval. I{(float)}
8890 """
8891 return None
8892
8894 """
8895 Finds the minimum and maximum values of a part of a data line.
8896
8897 Since 2.42
8898
8899 @param from_: I{(int)}
8900 @param to: Index the line part ends at + 1. I{(int)}
8901 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
8902 """
8903 return None, None
8904
8906 """
8907 Computes mean value of all values in a part of a data line.
8908
8909
8910 @param from_: I{(int)}
8911 @param to: Index the line part ends at + 1. I{(int)}
8912 @return: Average value within given interval. I{(float)}
8913 """
8914 return None
8915
8917 """
8918 Computes root mean square value of a part of a data line.
8919
8920
8921 @param from_: I{(int)}
8922 @param to: Index the line part ends at + 1. I{(int)}
8923 @return: Root mean square deviation of heights within a given interval I{(float)}
8924 """
8925 return None
8926
8928 """
8929 Computes root mean square slope in a part of a data line.
8930
8931 This is the root mean square of value derivatives, it is also proportional
8932 to the second derivative of both HHCF and ACF at zero.
8933
8934 This roughness quantity is also known as Dq.
8935
8936 @since: 2.2
8937
8938 @param from_: I{(int)}
8939 @param to: Index the line part ends at + 1. I{(int)}
8940 @return: Root mean square slope within a given interval. I{(float)}
8941 """
8942 return None
8943
8945 """
8946 Computes the total variation of a part of a data line.
8947
8948 The total variation is estimated as the integral of the absolute value of
8949 local gradient. For one dimensional data, the variation reduces to the
8950 integral of absolute value of the derivative. Its units are thus the same
8951 as the value units of the line. See also
8952 L{DataField.area_get_variation}() for some more discussion.
8953
8954 @since: 2.42
8955
8956 @param from_: I{(int)}
8957 @param to: Index the line part ends at + 1. I{(int)}
8958 @return: The total variation within a given interval. I{(float)}
8959 """
8960 return None
8961
8963 """
8964 Computes sum of all values in a part of a data line.
8965
8966
8967 @param from_: I{(int)}
8968 @param to: Index the line part ends at + 1. I{(int)}
8969 @return: Sum of all values within the interval. I{(float)}
8970 """
8971 return None
8972
8974 """
8975 Computes mean absolute deviation value of a part of a data line.
8976
8977
8978 @param from_: I{(int)}
8979 @param to: Index the line part ends at + 1. I{(int)}
8980 @return: Mean absolute deviation of heights within a given interval. I{(float)}
8981 """
8982 return None
8983
8985 """
8986 Computes skew value of a part of a data line.
8987
8988
8989 @param from_: I{(int)}
8990 @param to: Index the line part ends at + 1. I{(int)}
8991 @return: Skew of heights within a given interval. I{(float)}
8992 """
8993 return None
8994
8996 """
8997 Computes kurtosis value of a part of a data line.
8998
8999 Note the kurtosis returned by this function returns is the excess kurtosis
9000 which is zero for the Gaussian distribution (not 3).
9001
9002
9003 @param from_: I{(int)}
9004 @param to: Index the line part ends at + 1. I{(int)}
9005 @return: Kurtosis of heights within a given interval. I{(float)}
9006 """
9007 return None
9008
9010 """
9011 Finds approximate modus of a data line.
9012
9013 See L{DataLine.part_get_modus}() for details and caveats.
9014
9015
9016 @param histogram_steps: Number of histogram steps used for modus searching,
9017 pass a nonpositive number to autosize. I{(int)}
9018 @return: The modus. I{(float)}
9019 """
9020 return None
9021
9023 """
9024 Finds approximate modus of a data line part.
9025
9026 As each number in the data line is usually unique, this function does not
9027 return modus of the data itself, but modus of a histogram.
9028
9029
9030 @param from_: I{(int)}
9031 @param to: The index in B{C{data_line}} to stop (noninclusive). I{(int)}
9032 @param histogram_steps: Number of histogram steps used for modus searching,
9033 pass a nonpositive number to autosize. I{(int)}
9034 @return: The modus. I{(float)}
9035 """
9036 return None
9037
9047
9059
9061 """
9062 Calculates physical length of a data line.
9063
9064 The length is calculated from approximation by straight segments between
9065 values.
9066
9067
9068 @return: The line length. I{(float)}
9069 """
9070 return None
9071
9073 """
9074 Calculates a peak roughness quantity for a data line.
9075
9076 Depending on B{C{m}} and B{C{k}}, the function can calculate
9077 Average Maximum Profile Peak Height B{C{Rpm}}
9078 or Maximum Profile Peak Height B{C{Rp}}, B{C{Pp}}, B{C{Wp}}.
9079
9080 @since: 2.42
9081
9082 @param m: Number of sampling lengths. I{(int)}
9083 @param k: Number of peaks to consider. I{(int)}
9084 @return: The peak roughness quantity defined by B{C{m}} and B{C{k}}. I{(float)}
9085 """
9086 return None
9087
9089 """
9090 Calculates a valley roughness quantity for a data line.
9091
9092 Depending on B{C{m}} and B{C{k}}, the function can calculate
9093 Average Maximum Profile Valley Depth B{C{Rvm}}
9094 or Maximum Profile Peak Depth B{C{Rv}}, B{C{Pv}}, B{C{Wv}}.
9095
9096 @since: 2.42
9097
9098 @param m: Number of sampling lengths. I{(int)}
9099 @param k: Number of valleys to consider. I{(int)}
9100 @return: The valley roughness quantity defined by B{C{m}} and B{C{k}}. I{(float)}
9101 """
9102 return None
9103
9105 """
9106 Calculates a total roughness quantity for a data line.
9107
9108 The total quantity is just the sum of the corresponding quantities obtained
9109 by L{DataLine.get_xpm}() and L{DataLine.get_xvm}().
9110
9111 @since: 2.42
9112
9113 @param m: Number of sampling lengths. I{(int)}
9114 @param k: Number of peaks and valleys to consider. I{(int)}
9115 @return: The total roughness quantity defined by B{C{m}} and B{C{k}}. I{(float)}
9116 """
9117 return None
9118
9120 """
9121 Counts peaks or valleys defined by thresholds in a data line.
9122
9123 Peak is defined as a part of the profile that extends above the peak
9124 threshold and is separarted by valleys that extend below the valley
9125 threshold. For non-zero thresholds there may be parts between that are
9126 neither peaks not valleys because the local maxima in them are
9127 insignificant.
9128
9129 In either case, values of B{C{pthreshold}} and B{C{vthreshold}} must be non-negative.
9130 Usually one passes the same value for both.
9131
9132 @since: 2.50
9133
9134 @param peaks: B{C{True}} for peaks, B{C{False}} for valleys. If you pass B{C{False}}, swap
9135 the meanings of peaks and valleys in the description. Valley
9136 depths are positive. I{(bool)}
9137 @param pthreshold: Peak height threshold. Peaks must stick above this threshold. I{(float)}
9138 @param vthreshold: Valley depth threshold. Valleys must fall below this
9139 threshold. I{(float)}
9140 @return: The number of peaks found. I{(int)}
9141 """
9142 return None
9143
9144 - def distribution(distribution, ymin, ymax, normalize_to_unity, nstats):
9145 """
9146 Calculates the distribution of data line values.
9147
9148 This function is quite similar to L{DataLine.dh}(), the differences are:
9149 output normalization (chosen to make the integral unity), output units
9150 (again set to make the integral unity), automated binning.
9151
9152 Note the B{C{i}}-th bin is [B{C{i}}*B{C{dx}}+B{C{off}},(B{C{i}}+1)*B{C{dx}}+B{C{off}}] so the central value
9153 you probably want to use for plotting is (B{C{i}}+0.5)*B{C{dx}}+B{C{off}} (where B{C{dx}} is
9154 the B{C{distribution}} data line pixel size, B{C{off}} is its offset).
9155
9156 If all values are equal and B{C{ymin}}, B{C{ymax}} are not explictly specified, the
9157 range is chosen as [B{C{v}}-|B{C{v}}|/2,B{C{v}}+|B{C{v}}/2] where B{C{v}} is the unique value,
9158 except when B{C{v}}=0, in which case the range is set to [-1,1].
9159
9160 @since: 2.8
9161
9162 @param distribution: Data line to put the distribution of B{C{data_line}} values to.
9163 It will be resampled to B{C{nstats}} samples (or the automatically
9164 chosen number of bins). I{(L{DataLine})}
9165 @param ymin: Start of value range, pass B{C{ymin}} = B{C{ymax}} = 0.0 for the full range. I{(float)}
9166 @param ymax: End of value range. I{(float)}
9167 @param normalize_to_unity: B{C{True}} to normalize the integral to unity (including
9168 setting y-units of output to the inverse of x-units),
9169 B{C{False}} to keep plain counts in the output (and set
9170 y-units to none). I{(bool)}
9171 @param nstats: The requested number of histogram bins, pass a non-positive number
9172 to automatically choose a suitable number of bins. I{(int)}
9173 """
9174 pass
9175
9176 - def dh(target_line, ymin, ymax, nsteps):
9177 """
9178 Computes distribution of heights in interval [B{C{ymin}}, B{C{ymax}}).
9179
9180 If the interval is (0, 0) it computes the distribution from
9181 real data minimum and maximum value.
9182
9183 @param target_line: Data line to store height distribution function to.
9184 It will be resized to B{C{nsteps}}. I{(L{DataLine})}
9185 @param ymin: Height distribution minimum value. I{(float)}
9186 @param ymax: Height distribution maximum value. I{(float)}
9187 @param nsteps: Number of histogram steps. I{(int)}
9188 """
9189 pass
9190
9191 - def cdh(target_line, ymin, ymax, nsteps):
9192 """
9193 Computes cumulative distribution of heighs in interval [B{C{ymin}}, B{C{ymax}}).
9194
9195 If the interval is (0, 0) it computes the distribution from
9196 real data minimum and maximum value.
9197
9198 @param target_line: Data line to store height distribution function to.
9199 It will be resized to B{C{nsteps}}. I{(L{DataLine})}
9200 @param ymin: Height distribution minimum value. I{(float)}
9201 @param ymax: Height distribution maximum value. I{(float)}
9202 @param nsteps: Number of histogram steps. I{(int)}
9203 """
9204 pass
9205
9206 - def da(target_line, ymin, ymax, nsteps):
9207 """
9208 Computes distribution of angles in interval [B{C{ymin}}, B{C{ymax}}).
9209
9210 If the interval is (0, 0) it computes the distribution from
9211 real data minimum and maximum angle value.
9212
9213 @param target_line: Data line to store angle distribution function to. I{(L{DataLine})}
9214 @param ymin: Angle distribution minimum value. I{(float)}
9215 @param ymax: Angle distribution maximum value. I{(float)}
9216 @param nsteps: Mumber of angular histogram steps. I{(int)}
9217 """
9218 pass
9219
9220 - def cda(target_line, ymin, ymax, nsteps):
9221 """
9222 Computes cumulative distribution of angles in interval [B{C{ymin}}, B{C{ymax}}).
9223
9224 If the interval is (0, 0) it computes the distribution from
9225 real data minimum and maximum angle value.
9226
9227 @param target_line: Data line to store angle distribution function to.
9228 It will be resized to B{C{nsteps}}. I{(L{DataLine})}
9229 @param ymin: Angle distribution minimum value. I{(float)}
9230 @param ymax: Angle distribution maximum value. I{(float)}
9231 @param nsteps: Number of angular histogram steps. I{(int)}
9232 """
9233 pass
9234
9235 - def acf(target_line):
9236 """
9237 Coputes autocorrelation function and stores the values in
9238 B{C{target_line}}
9239
9240 Up to version 2.53 it did not set the output units properly.
9241
9242 @param target_line: Data line to store autocorrelation function to. It will be
9243 resized to B{C{data_line}} size. I{(L{DataLine})}
9244 """
9245 pass
9246
9247 - def hhcf(target_line):
9248 """
9249 Computes height-height correlation function and stores results in
9250 B{C{target_line}}.
9251
9252 Up to version 2.53 it did not set the output units properly.
9253
9254 @param target_line: Data line to store height-height function to. It will be
9255 resized to B{C{data_line}} size. I{(L{DataLine})}
9256 """
9257 pass
9258
9259 - def psdf(target_line, windowing, interpolation):
9260 """
9261 Calculates the power spectral density function of a data line.
9262
9263 Up to version 2.45 it destroyed the input data and did not set the output
9264 units properly.
9265
9266 @param target_line: Data line to store power spectral density function to.
9267 It will be resized to B{C{data_line}} size. I{(L{DataLine})}
9268 @param windowing: Windowing method to use. I{(int)}
9269 @param interpolation: Interpolation type.
9270 Ignored since 2.8 as no resampling is performed. I{(int)}
9271 """
9272 pass
9273
9275 """
9276 Extract the data of a data line.
9277
9278 The returned list contains a copy of the data. Changing its contents does
9279 not change the data line's data.
9280
9281
9282 @return: List containing extracted data line data. I{(list)}
9283 """
9284 return None
9285
9287 """
9288 Sets the entire contents of a data line.
9289
9290 The length of B{C{data}} must be equal to the number of elements of the data
9291 line.
9292
9293 @param data: Sequence of floating point values. I{(list)}
9294 """
9295 pass
9296
9298 """
9299 Fits a polynomial through a part of a data line.
9300
9301 Please see L{DataLine.fit_polynom}() for more details.
9302
9303
9304 @param n: Polynom degree. I{(int)}
9305 @param from_: I{(int)}
9306 @param to: Index the line part ends at + 1. I{(int)}
9307 @return: The coefficients of the polynomial (B{C{coeffs}} when it was not B{C{None}},
9308 otherwise a newly allocated array). I{(list)}
9309 """
9310 return None
9311
9313 """
9314 Fits a polynomial through a data line.
9315
9316 Note B{C{n}} is polynomial degree, so the size of B{C{coeffs}} is B{C{n}}+1. X-values
9317 are indices in the data line.
9318
9319 For polynomials of degree 0 and 1 it's better to use L{DataLine.get_avg}()
9320 and L{DataLine.get_line_coeffs}() because they are faster.
9321
9322
9323 @param n: Polynom degree. I{(int)}
9324 @return: The coefficients of the polynomial (B{C{coeffs}} when it was not B{C{None}},
9325 otherwise a newly allocated array). I{(list)}
9326 """
9327 return None
9328
9330 """
9331 Subtracts a polynomial from a part of a data line.
9332
9333 @param coeffs: An array of size B{C{n}}+1 with polynomial coefficients to. I{(list)}
9334 @param from_: I{(int)}
9335 @param to: Index the line part ends at + 1. I{(int)}
9336 """
9337 pass
9338
9340 """
9341 Subtracts a polynomial from a data line.
9342
9343 @param coeffs: An array of size B{C{n}}+1 with polynomial coefficients to. I{(list)}
9344 """
9345 pass
9346
9347 - def get_kth_peaks(m, rank, peaks, average, pthreshold, vthreshold):
9348 """
9349 Calculate k-th largers peaks or valleys in a data line split into given
9350 number of sampling lengths.
9351
9352 This is a general function that can be used as the base for various standard
9353 roughness quantities such as Rp, Rpm, Rv, Rvm or R3z. It is assumed
9354 the line is already levelled, the form removed, etc.
9355
9356 See L{DataLine.count_peaks}() for the description what is considered
9357 a peak.
9358
9359 For larger thresholds and/or short lines some sampling lengths may not
9360 contain the requested number of peaks. If there are any peaks at all, the
9361 smallest peak height (even though it is not B{C{rank}}-th) is used. If there
9362 are no peaks, a large negative value is stored in the corresponding
9363 B{C{peakvalues}} item.
9364
9365
9366 @param m: Number of sampling lengths the line is split into. I{(int)}
9367 @param rank: Rank of the peak to find. One means the highest peak, three the
9368 third highers, etc. I{(int)}
9369 @param peaks: B{C{True}} for peaks, B{C{False}} for valleys. If you pass B{C{False}}, swap
9370 the meanings of peaks and valleys in the description. Valley
9371 depths are positive. I{(bool)}
9372 @param average: Calculate the average of the first B{C{rank}} peaks instead of the
9373 height of B{C{rank}}-th peak. I{(bool)}
9374 @param pthreshold: Peak height threshold. Peaks must stick above this threshold. I{(float)}
9375 @param vthreshold: Valley depth threshold. Valleys must fall below this
9376 threshold. The depth is a positive value. I{(float)}
9377 @return: List with B{C{m}} items containing the peak heights. I{(list)}
9378 """
9379 return None
9380
9382 """
9383 Convenience macro doing L{gwy_serializable_duplicate}() with all the necessary
9384 typecasting.
9385
9386 @return: I{(L{DataLine})}
9387 """
9388 return None
9389
9391 """
9392 Gets pointer to data which the data line contains.
9393
9394
9395 @return: integer pointing to the raw data of the data field I{(long)}
9396 """
9397 return None
9398
9399
9402 """
9403 Creates a new data-displaying widget for B{C{data}}.
9404
9405 A newly created B{C{DataView}} doesn't display anything. You have to add
9406 some layers to it, at least a base layer with
9407 L{DataView.set_base_layer}(), and possibly others with
9408 L{DataView.set_alpha_layer}() and L{DataView.set_top_layer}().
9409
9410 The top layer is special. It must be a vector layer and can receive
9411 mouse and keyboard events.
9412
9413 The base layer it also special. It must be always present, and must not be
9414 transparent or vector.
9415
9416
9417 @param data: A B{C{Container}} containing the data to display. I{(L{Container})}
9418 @return: A newly created data view as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
9419 """
9420 return None
9421
9423 """
9424 Returns the base layer this data view currently uses.
9425
9426 A base layer should be always present.
9427
9428
9429 @return: The currently used base layer. I{(L{PixmapLayer})}
9430 """
9431 return None
9432
9434 """
9435 Plugs B{C{layer}} to B{C{data_view}} as the base layer.
9436
9437 If another base layer is present, it's unplugged.
9438
9439 The layer must not be a vector layer. Theoretically, it can be B{C{None}} to
9440 use no base layer, but then B{C{data_view}} will probably display garbage.
9441
9442 @param layer: A layer to be used as the base layer for B{C{data_view}}. I{(L{PixmapLayer})}
9443 """
9444 pass
9445
9447 """
9448 Returns the alpha layer this data view currently uses, or B{C{None}} if none
9449 is present.
9450
9451
9452 @return: The currently used alpha layer. I{(L{PixmapLayer})}
9453 """
9454 return None
9455
9457 """
9458 Plugs B{C{layer}} to B{C{data_view}} as the alpha layer.
9459
9460 If another alpha layer is present, it's unplugged.
9461
9462 The layer must not be a vector layer. It can be B{C{None}}, meaning no alpha
9463 layer is to be used.
9464
9465 @param layer: A layer to be used as the alpha layer for B{C{data_view}}. I{(L{PixmapLayer})}
9466 """
9467 pass
9468
9470 """
9471 Returns the top layer this data view currently uses, or B{C{None}} if none
9472 is present.
9473
9474
9475 @return: The currently used top layer. I{(L{VectorLayer})}
9476 """
9477 return None
9478
9480 """
9481 Plugs B{C{layer}} to B{C{data_view}} as the top layer.
9482
9483 If another top layer is present, it's unplugged.
9484
9485 The layer must be a vector layer. It can be B{C{None}}, meaning no top
9486 layer is to be used.
9487
9488 @param layer: A layer to be used as the top layer for B{C{data_view}}. I{(L{VectorLayer})}
9489 """
9490 pass
9491
9493 """
9494 Gets the prefix for the container data channel that the data view is
9495 currently set to display.
9496
9497
9498 @return: The container data prefix (eg. "/0/data"). I{(string)}
9499 """
9500 return None
9501
9503 """
9504 Sets the prefix for the container data channel to display in a data view.
9505
9506 This function only affects where the data view itself takes parameters
9507 from, it does not affect layer keys.
9508
9509 @param prefix: Container prefix for data (eg. "/0/data"). I{(string)}
9510 """
9511 pass
9512
9514 """
9515 Return the horizontal excess of widget size to data size.
9516
9517 Do not use. Only useful for B{C{DataWindow}} implementation.
9518
9519
9520 @return: The execess. I{(float)}
9521 """
9522 return None
9523
9525 """
9526 Return the vertical excess of widget size to data size.
9527
9528 Do not use. Only useful for B{C{DataWindow}} implementation.
9529
9530
9531 @return: The execess. I{(float)}
9532 """
9533 return None
9534
9536 """
9537 Sets zoom of B{C{data_view}} to B{C{zoom}}.
9538
9539 Zoom greater than 1 means larger image on screen and vice versa.
9540
9541 Note window manager can prevent the window from resize and thus the zoom
9542 from change.
9543
9544 @param zoom: A new zoom value. I{(float)}
9545 """
9546 pass
9547
9549 """
9550 Returns current ideal zoom of a data view.
9551
9552 More precisely the zoom value requested by L{DataView.set_zoom}(), if
9553 it's in use (real zoom may differ a bit due to pixel rounding). If zoom
9554 was set by explicite widget size change, real and requested zoom are
9555 considered to be the same.
9556
9557 When a resize is queued, the new zoom value is returned.
9558
9559 In other words, this is the zoom B{C{data_view}} would like to have. Use
9560 L{DataView.get_real_zoom}() to get the real zoom.
9561
9562
9563 @return: The zoom as a ratio between ideal displayed size and base data
9564 field size. I{(float)}
9565 """
9566 return None
9567
9569 """
9570 Returns current real zoom of a data view.
9571
9572 This is the zoom value a data view may not wish to have, but was imposed
9573 by window manager or other constraints. Unlike ideal zoom set by
9574 L{DataView.set_zoom}(), this value cannot be set.
9575
9576 When a resize is queued, the current (old) value is returned.
9577
9578
9579 @return: The zoom as a ratio between real displayed size and base data
9580 field size. I{(float)}
9581 """
9582 return None
9583
9585 """
9586 Returns the data container used by B{C{data_view}}.
9587
9588
9589 @return: The data as a B{C{Container}}. I{(L{Container})}
9590 """
9591 return None
9592
9594 """
9595 Fixes screen coordinates B{C{xscr}} and B{C{yscr}} to be inside the data-displaying
9596 area (which can be smaller than widget size).
9597
9598 @return: Tuple consisting of 2 values (B{C{xscr}}, B{C{yscr}}). (I{(IntInOutArg)}, I{(IntInOutArg)})
9599 """
9600 return None, None
9601
9603 """
9604 Fixes screen coordinates of line endpoints to be inside the data-displaying
9605 area (which can be smaller than widget size).
9606
9607 @since: 2.11
9608
9609 @return: Tuple consisting of 4 values (B{C{x0scr}}, B{C{y0scr}}, B{C{x1scr}}, B{C{y1scr}}). (I{(IntInOutArg)}, I{(IntInOutArg)}, I{(IntInOutArg)}, I{(IntInOutArg)})
9610 """
9611 return None, None, None, None
9612
9614 """
9615 Recomputes screen coordinates relative to widget origin to physical
9616 coordinates in the sample.
9617
9618 Note that data fields offsets are I{not} taken into
9619 account. Coordinates B{C{xreal}}, B{C{yreal}} are just relative coordinates to the
9620 top left field corner.
9621
9622 @param xscr: A screen x-coordinate relative to widget origin. I{(int)}
9623 @param yscr: A screen y-coordinate relative to widget origin. I{(int)}
9624 @return: Tuple consisting of 2 values (B{C{xreal}}, B{C{yreal}}). (I{(float)}, I{(float)})
9625 """
9626 return None, None
9627
9629 """
9630 Recomputes physical coordinate in the sample to screen coordinate relative
9631 to widget origin.
9632
9633 Note that data fields offsets are I{not} taken into
9634 account. Coordinates B{C{xreal}}, B{C{yreal}} are just relative coordinates to the
9635 top left field corner.
9636
9637 @param xreal: A physical x-coordinate in the data sample. I{(float)}
9638 @param yreal: A physical y-coordinate in the data sample. I{(float)}
9639 @return: Tuple consisting of 2 values (B{C{xscr}}, B{C{yscr}}). (I{(int)}, I{(int)})
9640 """
9641 return None, None
9642
9644 """
9645 Recomputes physical coordinate in the sample to screen coordinate relative
9646 to widget origin, keeping them as floating point values.
9647
9648 Note that data fields offsets are I{not} taken into
9649 account. Coordinates B{C{xreal}}, B{C{yreal}} are just relative coordinates to the
9650 top left field corner.
9651
9652 @since: 2.45
9653
9654 @param xreal: A physical x-coordinate in the data sample. I{(float)}
9655 @param yreal: A physical y-coordinate in the data sample. I{(float)}
9656 @return: Tuple consisting of 2 values (B{C{xscr}}, B{C{yscr}}). (I{(float)}, I{(float)})
9657 """
9658 return None, None
9659
9661 """
9662 Returns the ratio between horizontal physical lengths and horizontal
9663 screen lengths in pixels.
9664
9665
9666 @return: The horizontal measure. I{(float)}
9667 """
9668 return None
9669
9671 """
9672 Returns the ratio between vertical physical lengths and horizontal
9673 screen lengths in pixels.
9674
9675
9676 @return: The vertical measure. I{(float)}
9677 """
9678 return None
9679
9681 """
9682 Obtains pixel dimensions of data displayed by a data view.
9683
9684 This is a convenience method, the same values could be obtained
9685 by L{DataField.get_xres}() and L{DataField.get_yres}() of the data
9686 field displayed by the base layer.
9687
9688 @return: Tuple consisting of 2 values (B{C{xres}}, B{C{yres}}). (I{(int)}, I{(int)})
9689 """
9690 return None, None
9691
9693 """
9694 Obtains physical dimensions of data displayed by a data view.
9695
9696 Physical coordinates are always taken from data field displayed by the base
9697 layer. This is a convenience method, the same values could be obtained
9698 by L{DataField.get_xreal}() and L{DataField.get_yreal}() of the data
9699 field displayed by the base layer.
9700
9701 @return: Tuple consisting of 2 values (B{C{xreal}}, B{C{yreal}}). (I{(float)}, I{(float)})
9702 """
9703 return None, None
9704
9706 """
9707 Obtains physical offsets of data displayed by a data view.
9708
9709 Physical coordinates are always taken from data field displayed by the base
9710 layer. This is a convenience method, the same values could be obtained
9711 by L{DataField.get_xoffset}() and L{DataField.get_yoffset}() of the data
9712 field displayed by the base layer.
9713
9714 @since: 2.16
9715
9716 @return: Tuple consisting of 2 values (B{C{xoffset}}, B{C{yoffset}}). (I{(float)}, I{(float)})
9717 """
9718 return None, None
9719
9721 """
9722 Creates and returns a pixbuf from the data view.
9723
9724 If the data is not square, the resulting pixbuf is also nonsquare.
9725 The returned pixbuf also never has an alpha channel.
9726
9727
9728 @param max_width: Pixbuf width that should not be exceeeded. Value smaller than
9729 1 means unlimited size. I{(int)}
9730 @param max_height: Pixbuf height that should not be exceeeded. Value smaller than
9731 1 means unlimited size. I{(int)}
9732 @return: The pixbuf as a newly created B{C{GdkPixbuf}}, it should be freed
9733 when no longer needed. It is never larger than the actual data
9734 size, as B{C{max_width}} and B{C{max_height}} are only upper limits. I{(L{gdk.Pixbuf})}
9735 """
9736 return None
9737
9739 """
9740 Exports data view to a pixbuf.
9741
9742
9743 @param zoom: Zoom to export data with (unrelated to data view zoom). I{(float)}
9744 @param draw_alpha: B{C{True}} to draw alpha layer (mask). I{(bool)}
9745 @param draw_top: B{C{True}} to draw top layer (selection). I{(bool)}
9746 @return: A newly created pixbuf, it must be freed by caller. I{(L{gdk.Pixbuf})}
9747 """
9748 return None
9749
9751 """
9752 Fills metric matrix for a data view.
9753
9754 The metric matrix essentially transforms distances in physical coordinates
9755 to screen distances. It is to be used with functions like
9756 L{gwy_math_find_nearest_point}() and L{gwy_math_find_nearest_line}() when the
9757 distance should be screen-Euclidean.
9758
9759 @return: I{(list)}
9760 """
9761 return None
9766 """
9767 Emits a "plugged" singal on a layer.
9768
9769 Primarily intended for B{C{DataView}} implementation.
9770
9771 """
9772 pass
9773
9775 """
9776 Emits a "unplugged" singal on a layer.
9777
9778 Primarily intended for B{C{DataView}} implementation.
9779
9780 """
9781 pass
9782
9784 """
9785 Emits a "updated" singal on a layer.
9786
9787 """
9788 pass
9789
9791 """
9792 Tells a data view layer its parent was realized and it can create
9793 display-specific resources.
9794
9795 """
9796 pass
9797
9799 """
9800 Tells a data view layer its parent was unrealized and it should destroy
9801 display-specific resources.
9802
9803 """
9804 pass
9809 """
9810 Creates a new data displaying window.
9811
9812
9813 @param data_view: A B{C{DataView}} containing the data-displaying widget to show. I{(L{DataView})}
9814 @return: A newly created widget, as B{C{GtkWidget}}. I{(L{gtk.Widget})}
9815 """
9816 return None
9817
9819 """
9820 Returns the data view widget a data window currently shows.
9821
9822
9823 @return: The currently shown data view. I{(L{DataView})}
9824 """
9825 return None
9826
9828 """
9829 Returns the color axis widget displayed by a data window.
9830
9831
9832 @return: The color axis. I{(L{gtk.Widget})}
9833 """
9834 return None
9835
9837 """
9838 Returns the data for the data view a data window currently shows.
9839
9840
9841 @return: The data as B{C{Container}}. I{(L{Container})}
9842 """
9843 return None
9844
9846 """
9847 Sets the zoom of a data window to B{C{izoom}}.
9848
9849 When B{C{izoom}} is -1 it zooms out; when B{C{izoom}} is 1 it zooms out.
9850 Otherwise the new zoom value is set to B{C{izoom}}/10000.
9851
9852 @param izoom: The new zoom value (as an integer). I{(int)}
9853 """
9854 pass
9855
9857 """
9858 Sets the zoom of data windows's data view in an attempt to make the window
9859 fit to the screen.
9860
9861 @since: 2.56
9862
9863 """
9864 pass
9865
9867 """
9868 Gets the data name part of a data window's title.
9869
9870
9871 @return: The data name as a string owned by the window. I{(string)}
9872 """
9873 return None
9874
9876 """
9877 Sets the data name of a data window.
9878
9879 The data name is used in the window's title.
9880
9881 @param data_name: New data name. I{(string)}
9882 """
9883 pass
9884
9894
9907 """
9908 Creates graph widget based on information in model.
9909
9910
9911 @param gmodel: A graph model. I{(L{GraphModel})}
9912 @return: new graph widget. I{(L{gtk.Widget})}
9913 """
9914 return None
9915
9917 """
9918 Gets a graph axis.
9919
9920
9921 @param type: Axis orientation I{(GtkPositionType)}
9922 @return: The axis (of given orientation) within the graph widget. I{(L{Axis})}
9923 """
9924 return None
9925
9927 """
9928 Sets the visibility of graph axis of given orientation. Visibility
9929 can be set also directly using Axis API.
9930
9931 @param type: Axis orientation I{(GtkPositionType)}
9932 @param is_visible: set/unset axis visibility within graph widget I{(bool)}
9933 """
9934 pass
9935
9937 """
9938 Gets the area widget of a graph.
9939
9940
9941 @return: The graph area widget within the graph. I{(L{gtk.Widget})}
9942 """
9943 return None
9944
9946 """
9947 Changes the model a graph displays.
9948
9949 Everything in graph widgets will be reset to reflect the new data.
9950
9951 @param gmodel: New graph model I{(L{GraphModel})}
9952 """
9953 pass
9954
9956 """
9957 Gets the model of a graph.
9958
9959
9960 @return: The graph model this graph widget displays. I{(L{GraphModel})}
9961 """
9962 return None
9963
9965 """
9966 Sets the status of a graph widget.
9967
9968 The status determines how the graph reacts on mouse events.
9969 This includes point or area selection and zooming.
9970
9971 @param status: graph status Expected values: C{B{GRAPH_STATUS_PLAIN}}, C{B{GRAPH_STATUS_XSEL}}, C{B{GRAPH_STATUS_YSEL}}, C{B{GRAPH_STATUS_POINTS}}, C{B{GRAPH_STATUS_ZOOM}}, C{B{GRAPH_STATUS_XLINES}}, C{B{GRAPH_STATUS_YLINES}}. I{(L{GraphStatusType})}
9972 """
9973 pass
9974
9976 """
9977 Get the status of a graph widget.
9978
9979 See L{Graph.set_status}() for more.
9980
9981
9982 @return: The current graph status. I{(GraphStatusType)}
9983 """
9984 return None
9985
9994
9996 """
9997 Renders a graph widget into a pixbuf.
9998
9999
10000 @param export_title: B{C{True}} to export graph title. Currently unimplemented. I{(bool)}
10001 @param export_axis: B{C{True}} to export graph axes. Currently unimplemented. I{(bool)}
10002 @param export_labels: B{C{True}} to export graph labels. Currently unimplemented. I{(bool)}
10003 @return: A newly created pixbuf. I{(L{gdk.Pixbuf})}
10004 """
10005 return None
10006
10007 - def export_postscript(export_title, export_axis, export_labels):
10008 """
10009 Approximately renders a graph widget in PostScript.
10010
10011
10012 @param export_title: B{C{True}} to export graph title. Currently unimplemented. I{(bool)}
10013 @param export_axis: B{C{True}} to export graph axes. Currently unimplemented. I{(bool)}
10014 @param export_labels: B{C{True}} to export graph labels. Currently unimplemented. I{(bool)}
10015 @return: Tuple consisting of 2 values (B{C{value}}, B{C{str}}). (I{(string)}, I{(SkipArg)})
10016 """
10017 return None, None
10018
10020 """
10021 Creates a new window showing B{C{graph}}.
10022
10023
10024 @return: A newly created graph window as B{C{GtkWidget}}. I{(L{gtk.Widget})}
10025 """
10026 return None
10031 """
10032 Creates a new graph area widget.
10033
10034
10035 @return: Newly created graph area as B{C{GtkWidget}}. I{(L{gtk.Widget})}
10036 """
10037 return None
10038
10040 """
10041 Gets the label inside a graph area.
10042
10043
10044 @return: The graph label widget within the graph area. I{(L{gtk.Widget})}
10045 """
10046 return None
10047
10049 """
10050 Sets the graph model of a graph area.
10051
10052 @param gmodel: New graph model. I{(L{GraphModel})}
10053 """
10054 pass
10055
10057 """
10058 Gets the model of a graph area.
10059
10060
10061 @return: The graph model this graph area widget displays. I{(L{GraphModel})}
10062 """
10063 return None
10064
10066 """
10067 Gets mouse cursor related values within a graph area.
10068
10069 @return: Tuple consisting of 2 values (B{C{x_cursor}}, B{C{y_cursor}}). (I{(float)}, I{(float)})
10070 """
10071 return None, None
10072
10074 """
10075 Sets the horizontal range a graph area displays.
10076
10077 @param x_min: The minimum x value, in real coodrinates. I{(float)}
10078 @param x_max: The maximum x value, in real coodrinates. I{(float)}
10079 """
10080 pass
10081
10083 """
10084 Sets the vertical range a graph area displays.
10085
10086 @param y_min: The minimum y value, in real coodrinates. I{(float)}
10087 @param y_max: The maximum y value, in real coodrinates. I{(float)}
10088 """
10089 pass
10090
10092 """
10093 Gets the selection object corresponding to a status of a graph area.
10094
10095 A selection object exists even for inactive status types (selection modes),
10096 therefore also selections for other modes than the currently active one can
10097 be requested.
10098
10099
10100 @param status_type: Graph status. Value B{C{GRAPH_STATUS_PLAIN}} mode (which has
10101 no selection associated) stands for the currentl selection
10102 mode. Expected values: C{B{GRAPH_STATUS_PLAIN}}, C{B{GRAPH_STATUS_XSEL}}, C{B{GRAPH_STATUS_YSEL}}, C{B{GRAPH_STATUS_POINTS}}, C{B{GRAPH_STATUS_ZOOM}}, C{B{GRAPH_STATUS_XLINES}}, C{B{GRAPH_STATUS_YLINES}}. I{(L{GraphStatusType})}
10103 @return: The requested selection. It is B{C{None}} only if B{C{status_type}} is
10104 B{C{GRAPH_STATUS_PLAIN}} and the current selection mode is
10105 B{C{GRAPH_STATUS_PLAIN}}. I{(L{Selection})}
10106 """
10107 return None
10108
10110 """
10111 Sets the status of a graph area.
10112
10113 When the area is inside a B{C{Graph}}, use L{Graph.set_status}() instead
10114 (also see this function for details).
10115
10116 @param status_type: New graph area status. Expected values: C{B{GRAPH_STATUS_PLAIN}}, C{B{GRAPH_STATUS_XSEL}}, C{B{GRAPH_STATUS_YSEL}}, C{B{GRAPH_STATUS_POINTS}}, C{B{GRAPH_STATUS_ZOOM}}, C{B{GRAPH_STATUS_XLINES}}, C{B{GRAPH_STATUS_YLINES}}. I{(L{GraphStatusType})}
10117 """
10118 pass
10119
10121 """
10122 Gets the status of a grap area.
10123
10124 See L{Graph.area_set_status}().
10125
10126
10127 @return: The current graph area status. I{(GraphStatusType)}
10128 """
10129 return None
10130
10132 """
10133 Draws a graph area to a Gdk drawable.
10134
10135 @param drawable: a B{C{GdkDrawable}} (destination for graphics operations) I{(L{gdk.Drawable})}
10136 @param gc: Graphics context.
10137 It is modified by this function unpredictably. I{(L{gdk.GC})}
10138 @param x: X position in B{C{drawable}} where the graph area should be drawn I{(int)}
10139 @param y: Y position in B{C{drawable}} where the graph area should be drawn I{(int)}
10140 @param width: width of the graph area on the drawable I{(int)}
10141 @param height: height of the graph area on the drawable I{(int)}
10142 """
10143 pass
10144
10146 """
10147 Creates PostScript representation of a graph area.
10148
10149
10150 @param x: Bounding box origin X-coordinate. I{(int)}
10151 @param y: Bounding box origin Y-coordinate. I{(int)}
10152 @param width: Bounding box width. I{(int)}
10153 @param height: Bounding box height. I{(int)}
10154 @return: A fragment of PostScript code representing the the graph area
10155 as a newly allocated B{C{GString}}. I{(string)}
10156 """
10157 return None
10158
10170
10172 """
10173 Enables/disables selection editing using mouse.
10174
10175 When selection editing is disabled the graph area status type determines
10176 the selection type that can be drawn on the area. However, the user cannot
10177 modify it.
10178
10179 @since: 2.45
10180
10181 @param setting: B{C{True}} to enable selection editing, B{C{False}} to disable it. I{(bool)}
10182 """
10183 pass
10184
10186 """
10187 Invokes the curve property dialog for a curve.
10188
10189 If the dialog is already displayed, it is switched to the requested curve.
10190
10191 @since: 2.5
10192
10193 @param id: The index of the curve to edit properties of. I{(int)}
10194 """
10195 pass
10196
10198 """
10199 Sets the grid data on the x-axis of a graph area
10200
10201 @param grid_data: Array of grid line positions on the x-axis (in real values,
10202 not pixels). I{(list)}
10203 """
10204 pass
10205
10207 """
10208 Sets the grid data on the y-axis of a graph area
10209
10210 @param grid_data: Array of grid line positions on the y-axis (in real values,
10211 not pixels). I{(list)}
10212 """
10213 pass
10214
10216 """
10217 Gets the grid data on the x-axis of a graph area.
10218
10219
10220 @return: Array of grid line positions (in real values, not pixels) owned
10221 by the graph area. I{(list)}
10222 """
10223 return None
10224
10226 """
10227 Gets the grid data on the y-axis of a graph area.
10228
10229
10230 @return: Array of grid line positions (in real values, not pixels) owned
10231 by the graph area. I{(list)}
10232 """
10233 return None
10238 """
10239 Creates a new graph corner.
10240
10241
10242 @return: A new graph corner as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
10243 """
10244 return None
10249 """
10250 Creates a new graph curve model.
10251
10252
10253 @return: New empty graph curve model as a B{C{GObject}}. I{(L{GraphCurveModel})}
10254 """
10255 return None
10256
10258 """
10259 Creates new graph curve model object that has the same settings as B{C{gcmodel}}.
10260
10261 Curve data are not duplicated.
10262
10263
10264 @return: New graph curve model. I{(L{GraphCurveModel})}
10265 """
10266 return None
10267
10269 """
10270 Sets graph curve model data from a data line.
10271
10272 The range of import can be modified using parameters B{C{from_index}} and B{C{to_index}} that are interpreted directly as
10273 data indices within the B{C{DataLine}}. In the case that B{C{from_index}} == B{C{to_index}}, the full B{C{DataLine}} is used.
10274
10275 If there were calibration data in the former B{C{gcmodel}}, they are removed.
10276
10277 @param dline: A data line. I{(L{DataLine})}
10278 @param from_index: Data line index where to start. I{(int)}
10279 @param to_index: Data line index where to stop. I{(int)}
10280 """
10281 pass
10282
10284 """
10285 Ensures curve model data points are ordered by abscissa in ascending order.
10286
10287 The function reorders the data points currently present in the model. It does not prevent functions such as
10288 L{Graph.curve_model_set_data}() from disrupting the order again. See its documentation for further remarks.
10289
10290 The "data-changed" signal is emitted if the data order actually changes.
10291
10292 @since: 2.45
10293
10294 """
10295 pass
10296
10298 """
10299 Checks if a curve model data points are ordered by abscissa in ascending order.
10300
10301 If the curve model has less than two points it is considered ordered by abscissa. Two points with the same
10302 abscissa are considered correctly ordered in both orders.
10303
10304 See L{Graph.curve_model_enforce_order}() for fixing the point order.
10305
10306 @since: 2.46
10307
10308 @return: B{C{True}} if the graph curve model points are sorted by abscissa, B{C{False}} when they are not. I{(bool)}
10309 """
10310 return None
10311
10313 """
10314 Gets the number of points in a graph curve model.
10315
10316
10317 @return: number of data points within the curve data I{(int)}
10318 """
10319 return None
10320
10322 """
10323 Gets the abscissa range of a graph curve.
10324
10325 The values are cached in the curve model therefore repeated calls to this function (with unchanged data) are cheap.
10326
10327 If there are no data points in the curve, B{C{x_min}} and B{C{x_max}} are untouched and the function returns B{C{False}}.
10328
10329 See also L{Graph.curve_model_get_ranges}() for a more high-level function.
10330
10331
10332 @return: Tuple consisting of 3 values (B{C{value}}, B{C{x_min}}, B{C{x_max}}). (I{(bool)}, I{(float)}, I{(float)})
10333 """
10334 return None, None, None
10335
10337 """
10338 Gets the ordinate range of a graph curve.
10339
10340 The values are cached in the curve model therefore repeated calls to this function (with unchanged data) are cheap.
10341
10342 If there are no data points in the curve, B{C{x_min}} and B{C{x_max}} are untouched and the function returns B{C{False}}.
10343
10344 See also L{Graph.curve_model_get_ranges}() for a more high-level function.
10345
10346
10347 @return: Tuple consisting of 3 values (B{C{value}}, B{C{y_min}}, B{C{y_max}}). (I{(bool)}, I{(float)}, I{(float)})
10348 """
10349 return None, None, None
10350
10352 """
10353 Gets the log-scale suitable range minima of a graph curve.
10354
10355 Parameters B{C{x_logscale}} and B{C{y_logscale}} determine which axis or axes are intended to use logarithmical scale. The
10356 range of displayble values for an axis generally depends on the other axis too as it acts as a filter. When both
10357 B{C{x_logscale}} and B{C{y_logscale}} are B{C{False}}, the returned minima are identical to those returned by
10358 L{Graph.curve_model_get_x_range}() and L{Graph.curve_model_get_y_range}().
10359
10360 The return values are cached in the curve model therefore repeated calls to this function (with unchanged data) are
10361 cheap.
10362
10363 If there are no data points that would be displayable with the intended logarithmical scale setup, the output
10364 arguments are untouched and B{C{False}} is returned.
10365
10366 @since: 2.8
10367
10368 @param x_logscale: B{C{True}} if logarithmical scale is intended for the abscissa. I{(bool)}
10369 @param y_logscale: B{C{True}} if logarithmical scale is intended for the ordinate. I{(bool)}
10370 @return: Tuple consisting of 5 values (B{C{value}}, B{C{x_min}}, B{C{x_max}}, B{C{y_min}}, B{C{y_max}}). (I{(bool)}, I{(float)}, I{(float)}, I{(float)}, I{(float)})
10371 """
10372 return None, None, None, None, None
10373
10375 """
10376 Gets y data points of a graph curve model.
10377
10378 The returned data are owned by the and cannot be modified nor freed. The returned pointer is valid only so long as
10379 the curve model exists and its data do not change.
10380
10381
10382 @return: X data points, owned by the curve model. I{(list)}
10383 """
10384 return None
10385
10387 """
10388 Gets y data points of a graph curve model.
10389
10390 The returned data are owned by the and cannot be modified nor freed. The returned pointer is valid only so long as
10391 the curve model exists and its data do not change.
10392
10393
10394 @return: Y data points, owned by the curve model. I{(list)}
10395 """
10396 return None
10397
10399 """
10400 Sets curve model data from separated X and Y arrays.
10401
10402 If there were calibration data in the former B{C{gcmodel}}, they are removed.
10403
10404 @warning:The points should be ordered in ascending abscissa order, meaning B{C{xdata}} values ordered from smallest to
10405 largest. It is not enforced and you can create graphs of data the do not satisfy this condition. However, various
10406 graph functionality may be unavailable or degraded then. You also can use L{Graph.curve_model_enforce_order}()
10407 afterwards to ensure the recommended data point order.
10408
10409 @param xdata: X data points (array of size B{C{n}}). I{(list)}
10410 @param ydata: Y data points (array of size B{C{n}}). I{(list)}
10411 """
10412 pass
10413
10415 """
10416 Sets curve model data from an interleaved array.
10417
10418 The array should contain interleaved abscissa and ordinate values: x0, y0, x1, y1, x2, y2, etc. You can also
10419 typecast an array of B{C{XY}} structs and pass it as B{C{xydata}}.
10420
10421 If there were calibration data in the former B{C{gcmodel}}, they are removed.
10422
10423 @warning:The points should be ordered in ascending abscissa order, meaning B{C{xdata}} values ordered from smallest to
10424 largest. It is not enforced and you can create graphs of data the do not satisfy this condition. However, various
10425 graph functionality may be unavailable or degraded then. You also can use L{Graph.curve_model_enforce_order}()
10426 afterwards to ensure the recommended data point order.
10427
10428 @since: 2.45
10429
10430 @param xydata: X and Y data points (array of size 2*B{C{n}}). I{(list)}
10431 """
10432 pass
10433
10435 """
10436 Convenience macro doing L{gwy_serializable_duplicate}() with all the necessary typecasting.
10437
10438 @return: I{(L{GraphCurveModel})}
10439 """
10440 return None
10445 """
10446 Creates graph curve list widget based on information in graph model.
10447
10448 The B{C{GtkTreeModel}} and the columns follow the graph model and must not be
10449 changed manually.
10450
10451 @since: 2.5
10452
10453 @param gmodel: A graph model. It can be B{C{None}}. I{(L{GraphModel})}
10454 @return: A new graph curve list. I{(L{gtk.Widget})}
10455 """
10456 return None
10457
10459 """
10460 Changes the graph model a graph curve list.
10461
10462 @since: 2.5
10463
10464 @param gmodel: New graph model. I{(L{GraphModel})}
10465 """
10466 pass
10467
10469 """
10470 Gets the graph model a graph curve list displays.
10471
10472 @since: 2.5
10473
10474 @return: The graph model associated with this B{C{GraphCurves}} widget. I{(L{GraphModel})}
10475 """
10476 return None
10481 """
10482 Creates graph_data widget based on information in graph model.
10483
10484 The B{C{GtkTreeModel}} and the columns follow the graph model and must not be
10485 changed manually.
10486
10487
10488 @param gmodel: A graph_data model. It can be B{C{None}}. I{(L{GraphModel})}
10489 @return: A new graph_data widget. I{(L{gtk.Widget})}
10490 """
10491 return None
10492
10494 """
10495 Changes the graph model a graph data table displays.
10496
10497 @param gmodel: New graph_data model. I{(L{GraphModel})}
10498 """
10499 pass
10500
10502 """
10503 Gets the graph model a graph data table displays.
10504
10505
10506 @return: The graph model associated with this B{C{GraphData}} widget. I{(L{GraphModel})}
10507 """
10508 return None
10513 """
10514 Creates a new graph label.
10515
10516
10517 @return: A new graph label widget as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
10518 """
10519 return None
10520
10522 """
10523 Sets new model of a graph label.
10524
10525 @param gmodel: New graph model. I{(L{GraphModel})}
10526 """
10527 pass
10528
10530 """
10531 Gets the model of a graph key.
10532
10533
10534 @return: The graph model this graph label takes curve properties and
10535 descriptions from. I{(L{GraphModel})}
10536 """
10537 return None
10538
10546
10548 """
10549 draws a graph label on a drawable
10550
10551 @param drawable: the B{C{GdkDrawable}} I{(L{gdk.Drawable})}
10552 @param gc: Graphics context.
10553 It is modified by this function unpredictably. I{(L{gdk.GC})}
10554 @param layout: pango layout I{(PangoLayout*)}
10555 @param x: x position where label is to be drawn I{(int)}
10556 @param y: y position where label is to be drawn I{(int)}
10557 @param width: width of the label I{(int)}
10558 @param height: hieght of the label I{(int)}
10559 """
10560 pass
10561
10563 """
10564 Creates PostScript representation of a graph label.
10565
10566
10567 @param x: x position of the graph label I{(int)}
10568 @param y: y position of the graph label I{(int)}
10569 @param width: width of the graph label I{(int)}
10570 @param height: hieght of the graph label I{(int)}
10571 @param fontsize: fontsize of the label I{(int)}
10572 @return: A fragment of PostScript code representing the the graph label
10573 as a newly allocated B{C{GString}}. I{(string)}
10574 """
10575 return None
10580 """
10581 Creates a new graph model.
10582
10583
10584 @return: New graph model as a B{C{GObject}}. I{(L{GraphModel})}
10585 """
10586 return None
10587
10589 """
10590 Creates new graph model object that has the same settings as B{C{gmodel}}.
10591
10592 This includes axis/label visibility, actual plotting range, etc.
10593 Curves are not duplicated or referenced.
10594
10595
10596 @return: New graph model. I{(L{GraphModel})}
10597 """
10598 return None
10599
10601 """
10602 Reports the number of curves in a graph model.
10603
10604
10605 @return: Number of curves in graph model. I{(int)}
10606 """
10607 return None
10608
10610 """
10611 Adds a new curve to a graph model.
10612
10613
10614 @param curve: A B{C{GraphCurveModel}} representing the curve to add. I{(L{GraphCurveModel})}
10615 @return: The index of the added curve in B{C{gmodel}}. I{(int)}
10616 """
10617 return None
10618
10620 """
10621 Removes all the curves having same description string as B{C{description}}.
10622
10623
10624 @param description: Curve description (label). I{(string)}
10625 @return: The number of removed curves. I{(int)}
10626 """
10627 return None
10628
10630 """
10631 Removes the curve having given index.
10632
10633 @param cindex: Curve index in graph model. I{(int)}
10634 """
10635 pass
10636
10638 """
10639 Finds a graph curve model in a graph model by its description.
10640
10641
10642 @param description: Curve description (label). I{(string)}
10643 @return: The first curve that has description (label) given by B{C{description}}
10644 (no reference is added). I{(L{GraphCurveModel})}
10645 """
10646 return None
10647
10649 """
10650 Gets a graph curve model in a graph model by its index.
10651
10652
10653 @param cindex: Curve index in graph model. I{(int)}
10654 @return: The curve with index B{C{cindex}} (no reference is added). I{(L{GraphCurveModel})}
10655 """
10656 return None
10657
10659 """
10660 Finds the index of a graph model curve.
10661
10662
10663 @param curve: A curve model present in B{C{gmodel}} to find. I{(L{GraphCurveModel})}
10664 @return: The index of B{C{curve}} in B{C{gmodel}}, -1 if it is not present there. I{(int)}
10665 """
10666 return None
10667
10669 """
10670 Replaces a curve in a graph model.
10671
10672 @since: 2.51
10673
10674 @param cindex: Curve index in graph model. I{(int)}
10675 @param curve: A curve model to put into B{C{gmodel}} at position B{C{cindex}}. I{(L{GraphCurveModel})}
10676 """
10677 pass
10678
10680 """
10681 Removes all the curves from graph model
10682
10683 """
10684 pass
10685
10687 """
10688 Appends all curves from another graph model to a graph model.
10689
10690 The colors of the curves can be updated, presumably to continue a preset
10691 color sequence. This is controlled by argument B{C{colorstep}}. When B{C{colorstep}}
10692 is zero no curve color modification is done. When it is positive, a block
10693 of curves of size B{C{colorstep}} is always given the same color, the first color
10694 being the first preset color corresponding to the number of curves already
10695 in B{C{gmodel}}. So pass B{C{colorstep}}=1 for individual curves, B{C{colorstep}}=2 for
10696 couples of curves (e.g. data and fit) that should have the same color, etc.
10697
10698 @since: 2.41
10699
10700 @param source: Graph model containing the curves to append. I{(L{GraphModel})}
10701 @param colorstep: Block size for curve color updating. I{(int)}
10702 """
10703 pass
10704
10706 """
10707 Sets x and y graph model units to match a data line.
10708
10709 @param data_line: A data line to take units from. I{(L{DataLine})}
10710 """
10711 pass
10712
10714 """
10715 Sets x and y graph model units to units derived from a data field.
10716
10717 @since: 2.51
10718
10719 @param data_field: A data field. I{(L{DataField})}
10720 @param power_xy_in_x: Power of field's lateral units to appear in graph's abscissa
10721 units. I{(int)}
10722 @param power_z_in_x: Power of field's value units to appear in graph's abscissa
10723 units. I{(int)}
10724 @param power_xy_in_y: Power of field's lateral units to appear in graph's ordinate
10725 units. I{(int)}
10726 @param power_z_in_y: Power of field's value units to appear in graph's ordinate
10727 units. I{(int)}
10728 """
10729 pass
10730
10732 """
10733 Checks if the units of two graph models are compatible.
10734
10735 This function is useful namely as a pre-check for moving curves between
10736 graphs.
10737
10738 @since: 2.41
10739
10740 @param othergmodel: Another graph model. I{(L{GraphModel})}
10741 @return: B{C{True}} if the abscissa and ordinate units of the two graphs are
10742 compatible. I{(bool)}
10743 """
10744 return None
10745
10747 """
10748 Checks whehter x axis can be lograrithmed.
10749
10750
10751 @return: True if all x-values are greater than zero (thus logarithmic
10752 display of x-data is feasible). I{(bool)}
10753 """
10754 return None
10755
10757 """
10758 Checks whehter y axis can be lograrithmed.
10759
10760
10761 @return: True if all y-values are greater than zero (thus logarithmic
10762 display of y-data is feasible). I{(bool)}
10763 """
10764 return None
10765
10767 """
10768 Sets one axis label of a graph model.
10769
10770 @param pos: Axis position. I{(GtkPositionType)}
10771 @param label: The new label. I{(string)}
10772 """
10773 pass
10774
10776 """
10777 Gets the label of a one graph model axis.
10778
10779
10780 @param pos: Axis position. I{(GtkPositionType)}
10781 @return: The label as a string owned by the model. I{(string)}
10782 """
10783 return None
10784
10786 """
10787 Gets the abscissa range of a graph.
10788
10789 Explicitly set minimum and maximum range properties take precedence over
10790 values calculated from curve abscissa ranges.
10791
10792
10793 @return: Tuple consisting of 3 values (B{C{value}}, B{C{x_min}}, B{C{x_max}}). (I{(bool)}, I{(float)}, I{(float)})
10794 """
10795 return None, None, None
10796
10798 """
10799 Gets the ordinate range of a graph.
10800
10801 Explicitly set minimum and maximum range properties take precedence over
10802 values calculated from curve ordinate ranges.
10803
10804
10805 @return: Tuple consisting of 3 values (B{C{value}}, B{C{y_min}}, B{C{y_max}}). (I{(bool)}, I{(float)}, I{(float)})
10806 """
10807 return None, None, None
10808
10810 """
10811 Gets the log-scale suitable range minima of a graph curve.
10812
10813 See L{Graph.curve_model_get_ranges}() for discussion.
10814
10815 @since: 2.8
10816
10817 @param x_logscale: B{C{True}} if logarithmical scale is intended for the abscissa. I{(bool)}
10818 @param y_logscale: B{C{True}} if logarithmical scale is intended for the ordinate. I{(bool)}
10819 @return: Tuple consisting of 5 values (B{C{value}}, B{C{x_min}}, B{C{x_max}}, B{C{y_min}}, B{C{y_max}}). (I{(bool)}, I{(float)}, I{(float)}, I{(float)}, I{(float)})
10820 """
10821 return None, None, None, None, None
10822
10823 - def export_ascii(export_units, export_labels, export_metadata, export_style):
10824 """
10825 Exports a graph model data to a string.
10826
10827 The export format is specified by parameter B{C{export_style}}.
10828
10829
10830 @param export_units: B{C{True}} to export units in the column header. I{(bool)}
10831 @param export_labels: B{C{True}} to export labels in the column header. I{(bool)}
10832 @param export_metadata: B{C{True}} to export all graph metadata within file header. I{(bool)}
10833 @param export_style: File format subtype to export to (e. g. plain, csv, gnuplot,
10834 etc.). Expected values: C{B{GRAPH_MODEL_EXPORT_ASCII_PLAIN}}, C{B{GRAPH_MODEL_EXPORT_ASCII_GNUPLOT}}, C{B{GRAPH_MODEL_EXPORT_ASCII_CSV}}, C{B{GRAPH_MODEL_EXPORT_ASCII_ORIGIN}}, C{B{GRAPH_MODEL_EXPORT_ASCII_IGORPRO}}, C{B{GRAPH_MODEL_EXPORT_ASCII_POSIX}}, C{B{GRAPH_MODEL_EXPORT_ASCII_MERGED}}. I{(L{GraphModelExportStyle})}
10835 @return: Tuple consisting of 2 values (B{C{value}}, B{C{string}}). (I{(string)}, I{(SkipArg)})
10836 """
10837 return None, None
10838
10840 """
10841 Convenience macro doing L{gwy_serializable_duplicate}() with all the necessary
10842 typecasting.
10843
10844 @return: I{(L{GraphModel})}
10845 """
10846 return None
10851 """
10852 Gets the graph widget a graph window currently shows.
10853
10854
10855 @return: The currently shown B{C{Graph}}. I{(L{gtk.Widget})}
10856 """
10857 return None
10858
10860 """
10861 Gets the graph data widget of a graph window.
10862
10863 @since: 2.5
10864
10865 @return: The B{C{GraphData}} widget of this graph window. Its model and
10866 column layout must be considered private. I{(L{gtk.Widget})}
10867 """
10868 return None
10869
10871 """
10872 Gets the graph curves widget of a graph window.
10873
10874 @since: 2.5
10875
10876 @return: The B{C{GraphCurves}} widget of this graph window. Its model and
10877 column layout must be considered private. I{(L{gtk.Widget})}
10878 """
10879 return None
10883 """
10884 Ordered item inventory, indexed by both name and
10885 position.
10886
10887
10888 B{C{Inventory}} is a uniform container that offers both hash table and array
10889 (sorted or unsorted) interfaces. Both types of read access are fast,
10890 operations that modify it may be slower. Inventory can also maintain a
10891 notion of default item.
10892
10893 B{C{Inventory}} can be used both as an actual container for some data, or just
10894 wrap a static array with a the same interface so the actual storage is
10895 opaque to inventory user. The former kind of inventories can be created
10896 with L{Inventory.new}() or L{Inventory.new_filled}(); constant inventory
10897 is created with L{Inventory.new_from_array}(). Contantess of an inventory
10898 can be tested with L{Inventory.is_const}().
10899
10900 Possible operations with data items stored in an inventory are specified
10901 upon inventory creation with B{C{InventoryItemType}} structure. Not all
10902 fields are mandatory, with items allowing more operations the inventory is
10903 more capable too. For example, if items offer a method to make copies,
10904 L{Inventory.new_item}() can be used to directly create new items in the
10905 inventory (this capability can be tested with
10906 L{Inventory.can_make_copies}()).
10907
10908 Item can have `traits', that is data that can be obtained generically. They
10909 are similar to B{C{GObject}} properties. Actually, if items are objects, they
10910 should simply map object properties to traits. But it is possible to define
10911 traits for simple structures too.
10912
10913 """
10915 """
10916 Creates a new inventory.
10917
10918
10919 @param itype: Type of items the inventory will contain. I{(const-InventoryItemType*)}
10920 @return: The newly created inventory. I{(L{Inventory})}
10921 """
10922 return None
10923
10925 """
10926 Returns the number of items in an inventory.
10927
10928
10929 @return: The number of items. I{(int)}
10930 """
10931 return None
10932
10934 """
10935 Returns whether an inventory can create new items itself.
10936
10937 The prerequistie is that item type is a serializable object. It enables
10938 functions like L{Inventory.new_item}().
10939
10940
10941 @return: B{C{True}} if inventory can create new items itself. I{(bool)}
10942 """
10943 return None
10944
10946 """
10947 Finds position of an item in an inventory.
10948
10949
10950 @param name: Item name. I{(string)}
10951 @return: Item position, or (guint)-1 if there is no such item. I{(int)}
10952 """
10953 return None
10954
10955 - def foreach(function, user_data):
10956 """
10957 Calls a function on each item of an inventory, in order.
10958
10959 B{C{function}}'s first argument is item position (transformed with
10960 GUINT_TO_POINTER()), second is item pointer, and the last is B{C{user_data}}.
10961
10962 @param function: A function to call on each item. It must not modify B{C{inventory}}. I{(GHFunc)}
10963 @param user_data: Data passed to B{C{function}}. I{(gpointer)}
10964 """
10965 pass
10966
10967 - def find(predicate, user_data):
10968 """
10969 Finds an inventory item using user-specified predicate function.
10970
10971 B{C{predicate}} is called for each item in B{C{inventory}} (in order) until it returns
10972 B{C{True}}. Its arguments are the same as in L{Inventory.foreach}().
10973
10974
10975 @param predicate: A function testing some item property. It must not modify
10976 B{C{inventory}}. I{(GHRFunc)}
10977 @param user_data: Data passed to B{C{predicate}}. I{(gpointer)}
10978 @return: The item for which B{C{predicate}} returned B{C{True}}. If there is no
10979 such item in the inventory, B{C{None}} is returned. I{(gpointer)}
10980 """
10981 return None
10982
10984 """
10985 Sets the default of an inventory.
10986
10987 Item B{C{name}} must already exist in the inventory.
10988
10989 @param name: Item name, pass B{C{None}} to unset default item. I{(string)}
10990 """
10991 pass
10992
10994 """
10995 Returns the name of the default item of an inventory.
10996
10997
10998 @return: The default item name, B{C{None}} if no default name is set.
10999 Item of this name may or may not exist in the inventory. I{(string)}
11000 """
11001 return None
11002
11004 """
11005 Notifies inventory an item was updated.
11006
11007 This function makes sense primarily for non-object items, as object items
11008 can notify inventory via signals.
11009
11010 @param name: Item name. I{(string)}
11011 """
11012 pass
11013
11015 """
11016 Notifies inventory item on given position was updated.
11017
11018 This function makes sense primarily for non-object items, as object items
11019 can provide B{C{watchable_signal}}.
11020
11021 @param n: Item position. I{(int)}
11022 """
11023 pass
11024
11026 """
11027 Assures an inventory is sorted.
11028
11029 """
11030 pass
11031
11033 """
11034 Forces an inventory to be unsorted.
11035
11036 Item positions don't change, but future L{Inventory.insert_item}() won't
11037 try to insert items in order.
11038
11039 """
11040 pass
11041
11043 """
11044 Deletes an item from an inventory.
11045
11046
11047 @param name: Name of item to delete. I{(string)}
11048 @return: B{C{True}} if item was deleted. I{(bool)}
11049 """
11050 return None
11051
11053 """
11054 Deletes an item on given position from an inventory.
11055
11056
11057 @param n: Position of B{C{item}} to delete. I{(int)}
11058 @return: B{C{True}} if item was deleted. I{(bool)}
11059 """
11060 return None
11061
11063 """
11064 Creates a new B{C{GtkTreeModel}} wrapper around a B{C{Inventory}}.
11065
11066
11067 @return: The newly created inventory store. I{(L{InventoryStore})}
11068 """
11069 return None
11070
11072 """
11073 Looks up an item in an inventory.
11074
11075
11076 @param name: Item name. I{(string)}
11077 @return: Item called B{C{name}}, or B{C{None}} if there is no such item. I{(L{gobject.GObject})}
11078 """
11079 return None
11080
11082 """
11083 Looks up an item in an inventory, eventually falling back to default.
11084
11085 The lookup order is: item of requested name, default item (if set), any
11086 inventory item, B{C{None}} (can happen only when inventory is empty).
11087
11088
11089 @param name: Item name. I{(string)}
11090 @return: Item called B{C{name}}, or default item. I{(L{gobject.GObject})}
11091 """
11092 return None
11093
11095 """
11096 Returns item on given position in an inventory.
11097
11098
11099 @param n: Item position. It must be between zero and the number of items in
11100 inventory, inclusive. If it is equal to the number of items, B{C{None}}
11101 is returned. In other words, inventory behaves like a B{C{None}}-terminated
11102 array, you can simply iterate over it until L{Inventory.get_nth_item}()
11103 returns B{C{None}}. I{(int)}
11104 @return: Item at given position. I{(L{gobject.GObject})}
11105 """
11106 return None
11107
11109 """
11110 Returns the default item of an inventory.
11111
11112
11113 @return: The default item. If there is no default item, B{C{None}} is returned. I{(L{gobject.GObject})}
11114 """
11115 return None
11116
11118 """
11119 Inserts an item into an inventory.
11120
11121 Item of the same name must not exist yet.
11122
11123 If the inventory is sorted, item is inserted to keep order. If the
11124 inventory is unsorted, item is simply added to the end.
11125
11126
11127 @param object: I{(L{gobject.GObject})}
11128 """
11129 pass
11130
11132 """
11133 Inserts an item to an explicit position in an inventory.
11134
11135 Item of the same name must not exist yet.
11136
11137
11138 @param object: I{(L{gobject.GObject})}
11139 @param n: Position to insert B{C{item}} to. I{(int)}
11140 """
11141 pass
11142
11144 """
11145 Renames an inventory item.
11146
11147 If an item of name B{C{newname}} is already present in B{C{inventory}}, the rename
11148 will fail.
11149
11150
11151 @param name: Name of item to rename. I{(string)}
11152 @param newname: New name of item. I{(string)}
11153 """
11154 pass
11155
11157 """
11158 Creates a new item as a copy of existing one and inserts it to inventory.
11159
11160 The newly created item can be called differently than B{C{newname}} if that
11161 already exists.
11162
11163
11164 @param name: Name of item to duplicate, may be B{C{None}} to use default item (the
11165 same happens when B{C{name}} does not exist). I{(string)}
11166 @param newname: Name of new item, it must not exist yet. It may be B{C{None}}, the
11167 new name is based on B{C{name}} then. I{(string)}
11168 @return: The newly added item. I{(L{gobject.GObject})}
11169 """
11170 return None
11171
11172
11175 """
11176 Gets the inventory a inventory store wraps.
11177
11178
11179 @return: The underlying inventory (its reference count is not increased). I{(L{Inventory})}
11180 """
11181 return None
11182
11184 """
11185 Gets tree model column corresponding to a trait name.
11186
11187 The underlying inventory must support trait names, except for B{C{name}} C{"item"} which always works
11188 (and always maps to 0).
11189
11190
11191 @param name: Trait (column) name. I{(string)}
11192 @return: The underlying inventory (its reference count is not increased). I{(int)}
11193 """
11194 return None
11198 """
11199 Three-dimensional data representation
11200
11201
11202 B{C{Lawn}} represents 3D data arrays in Gwyddion. It is typically useful for different volume data obtained from
11203 SPMs, like in force volume measurements.
11204
11205 """
11206 - def __init__(xres, yres, xreal, yreal, ncurves, nsegments):
11207 """
11208 Creates a new data lawn.
11209
11210 @since: 2.60
11211
11212 @param xres: X resolution, i.e., the number of samples in x direction I{(int)}
11213 @param yres: Y resolution, i.e., the number of samples in y direction I{(int)}
11214 @param xreal: Real physical dimension in x direction. I{(float)}
11215 @param yreal: Real physical dimension in y direction. I{(float)}
11216 @param ncurves: The number of curves at each sample. I{(int)}
11217 @param nsegments: The number of curve segments. I{(int)}
11218 @return: A newly created data lawn. I{(L{Lawn})}
11219 """
11220 return None
11221
11223 """
11224 Checks whether two data lawns are compatible.
11225
11226 Dimensions are checked only in the plane. To check if the curve lengths match, use the
11227 B{C{DATA_COMPATIBILITY_CURVELEN}} flag. Use B{C{DATA_COMPATIBILITY_NCURVES}} to check if the two lawns have the
11228 same number of curves.
11229
11230 @since: 2.60
11231
11232 @param lawn2: Another data lawn. I{(L{Lawn})}
11233 @param check: The compatibility tests to perform. Expected values: C{B{DATA_COMPATIBILITY_RES}}, C{B{DATA_COMPATIBILITY_REAL}}, C{B{DATA_COMPATIBILITY_MEASURE}}, C{B{DATA_COMPATIBILITY_LATERAL}}, C{B{DATA_COMPATIBILITY_VALUE}}, C{B{DATA_COMPATIBILITY_AXISCAL}}, C{B{DATA_COMPATIBILITY_NCURVES}}, C{B{DATA_COMPATIBILITY_CURVELEN}}, C{B{DATA_COMPATIBILITY_ALL}}. I{(L{DataCompatibilityFlags})}
11234 @return: Zero if all tested properties are compatible. Flags corresponding to failed tests if lawns are not
11235 compatible. I{(DataCompatibilityFlags)}
11236 """
11237 return None
11238
11240 """
11241 Creates a new data lawn similar to an existing one.
11242
11243 Use L{Lawn.duplicate}() if you want to copy a data lawn including
11244 data.
11245
11246 @since: 2.60
11247
11248 @return: A newly created data lawn. I{(L{Lawn})}
11249 """
11250 return None
11251
11252 - def new_part(xpos, ypos, xres, yres, keep_offsets):
11253 """
11254 Creates a new data lawn as a part of existing one.
11255
11256 Use L{Lawn.duplicate}() if you want to copy a whole data lawn.
11257
11258 @since: 2.60
11259
11260 @param xpos: x position where to start from I{(int)}
11261 @param ypos: y position where to start from I{(int)}
11262 @param xres: x resolution (width) to be extracted I{(int)}
11263 @param yres: y resolution (height) to be extracted I{(int)}
11264 @param keep_offsets: keep offsets of data during extraction I{(bool)}
11265 @return: A newly created data lawn. I{(L{Lawn})}
11266 """
11267 return None
11268
11270 """
11271 Emits signal "data_changed" on a data lawn.
11272
11273 @since: 2.60
11274
11275 """
11276 pass
11277
11278 - def copy(dest, nondata_too):
11279 """
11280 Copies the contents of an already allocated lawn to a lawn of the same size.
11281
11282 @param dest: Destination lawn. I{(L{Lawn})}
11283 @param nondata_too: Whether non-data (units, labels, segment information) should be copied too. I{(bool)}
11284 """
11285 pass
11286
11288 """
11289 Gets the x resolution of a data lawn.
11290
11291 @since: 2.60
11292
11293 @return: Resolution (number of data points). I{(int)}
11294 """
11295 return None
11296
11298 """
11299 Gets the y resolution of a data lawn.
11300
11301 @since: 2.60
11302
11303 @return: Resolution (number of data points). I{(int)}
11304 """
11305 return None
11306
11308 """
11309 Gets the physical size of a data lawn in the x direction.
11310
11311 @since: 2.60
11312
11313 @return: Real size of a data lawn the x direction. I{(float)}
11314 """
11315 return None
11316
11318 """
11319 Gets the physical size of a data lawn in the y direction.
11320
11321 @since: 2.60
11322
11323 @return: Real size of a data lawn the y direction. I{(float)}
11324 """
11325 return None
11326
11328 """
11329 Gets the offset of data lawn origin in x direction.
11330
11331 @since: 2.60
11332
11333 @return: Offset value. I{(float)}
11334 """
11335 return None
11336
11338 """
11339 Gets the offset of data lawn origin in y direction.
11340
11341 @since: 2.60
11342
11343 @return: Offset value. I{(float)}
11344 """
11345 return None
11346
11348 """
11349 Gets the number of curves at each sample.
11350
11351 @since: 2.60
11352
11353 @return: Number of curves. I{(int)}
11354 """
11355 return None
11356
11358 """
11359 Sets the real x dimension of a lawn.
11360
11361 @since: 2.60
11362
11363 @param xreal: New real x dimensions value I{(float)}
11364 """
11365 pass
11366
11368 """
11369 Sets the real y dimension of a lawn.
11370
11371 @since: 2.60
11372
11373 @param yreal: New real y dimensions value I{(float)}
11374 """
11375 pass
11376
11378 """
11379 Sets the offset of a data lawn origin in the x direction.
11380
11381 Note offsets don't affect any calculation.
11382
11383 @since: 2.60
11384
11385 @param xoffset: New offset value. I{(float)}
11386 """
11387 pass
11388
11390 """
11391 Sets the offset of a data lawn origin in the y direction.
11392
11393 Note offsets don't affect any calculation.
11394
11395 @since: 2.60
11396
11397 @param yoffset: New offset value. I{(float)}
11398 """
11399 pass
11400
11402 """
11403 Gets the horizontal (X) pixel size of a lawn in real units.
11404
11405 The result is the same as L{Lawn.get_xreal}(lawn)/L{Lawn.get_xres}(lawn).
11406
11407 @since: 2.60
11408
11409 @return: Horizontal pixel size. I{(float)}
11410 """
11411 return None
11412
11414 """
11415 Gets the vertical (Y) pixel size of a lawn in real units.
11416
11417 The result is the same as L{Lawn.get_yreal}(lawn)/L{Lawn.get_yres}(lawn).
11418
11419 @since: 2.60
11420
11421 @return: Vertical pixel size. I{(float)}
11422 """
11423 return None
11424
11426 """
11427 Returns x- and y-direction SI unit of a data lawn.
11428
11429 @since: 2.60
11430
11431 @return: SI unit corresponding to the lateral (X) dimension of the data lawn. Its reference count is not
11432 incremented. I{(L{SIUnit})}
11433 """
11434 return None
11435
11437 """
11438 Returns value SI unit of the n-th curve of a data lawn.
11439
11440 @since: 2.60
11441
11442 @param n: Index of a curve in B{C{lawn}}. I{(int)}
11443 @return: SI unit corresponding to the "value" of the data lawn. Its reference count is not incremented. I{(L{SIUnit})}
11444 """
11445 return None
11446
11448 """
11449 Sets the SI unit corresponding to the lateral (X, Y) dimensions of a data lawn.
11450
11451 It does not assume a reference on B{C{si_unit}}, instead it adds its own reference.
11452
11453 @since: 2.60
11454
11455 @param si_unit: SI unit to be set. I{(L{SIUnit})}
11456 """
11457 pass
11458
11460 """
11461 Sets the SI unit corresponding of the n-th curve of a data lawn.
11462
11463 It does not assume a reference on B{C{si_unit}}, instead it adds its own reference.
11464
11465 @since: 2.60
11466
11467 @param n: Index of a curve in B{C{lawn}}. I{(int)}
11468 @param si_unit: SI unit to be set. I{(L{SIUnit})}
11469 """
11470 pass
11471
11473 """
11474 Sets lateral and curve units of a data lawn to match another data lawn.
11475
11476 @since: 2.60
11477
11478 @param target: Target data lawn. I{(L{Lawn})}
11479 """
11480 pass
11481
11483 """
11484 Sets the label of a curve in data lawn.
11485
11486 @since: 2.60
11487
11488 @param n: Index of a curve in B{C{lawn}}. I{(int)}
11489 @param label: New curve label. I{(string)}
11490 """
11491 pass
11492
11494 """
11495 Gets the label of a curve in data lawn.
11496
11497 @since: 2.60
11498
11499 @param n: Index of a curve in B{C{lawn}}. I{(int)}
11500 @return: Curve label, as a string owned by B{C{lawn}}. It may be B{C{None}}. I{(string)}
11501 """
11502 return None
11503
11514
11517
11519 """
11520 Gets the length of the curves at given position in a data lawn.
11521
11522 @since: 2.60
11523
11524 @param col: Position in the lawn (column index). I{(int)}
11525 @param row: Position in the lawn (row index). I{(int)}
11526 @return: The curves length at given index. I{(int)}
11527 """
11528 return None
11529
11531 """
11532 Gets the number of segments marked in curves in a data lawn.
11533
11534 All curves have the same number of segments, even empty curves. Empty curves simply have the corresponding number
11535 of trivial zero-length segments.
11536
11537 @since: 2.60
11538
11539 @return: The number of segments. Zero is returned if no segments are marked. I{(int)}
11540 """
11541 return None
11542
11544 """
11545 Gets the label of a curve segment in data lawn.
11546
11547 @since: 2.60
11548
11549 @param segment: Index of a curve segment in B{C{lawn}}. I{(int)}
11550 @return: Segment label, as a string owned by B{C{lawn}}. It may be B{C{None}}. I{(string)}
11551 """
11552 return None
11553
11555 """
11556 Sets the label of a curve segment in data lawn.
11557
11558 Since all curves in B{C{lawn}} are segmented into the same segments the segments share labels. The first segment label
11559 corresponds to the first segment in all the curves.
11560
11561 @since: 2.60
11562
11563 @param segment: Index of a curve segment in B{C{lawn}}. I{(int)}
11564 @param label: New segment label. I{(string)}
11565 """
11566 pass
11567
11569 """
11570 Removes curve data at all samples (curve number, units, and labels preserved).
11571
11572 @since: 2.60
11573
11574 """
11575 pass
11576
11578 """
11579 Creates a new data lawn by rotating a data lawn by 90 degrees.
11580
11581 @since: 2.60
11582
11583 @param clockwise: B{C{True}} to rotate clocwise, B{C{False}} to rotate anti-clockwise. I{(bool)}
11584 @return: A newly created data lawn. I{(L{Lawn})}
11585 """
11586 return None
11587
11588 - def invert(xflipped, yflipped):
11589 """
11590 Flips a data lawn in place.
11591
11592 Since real sizes cannot go backward, flipping an axis results in the corresponding offset being reset (the real
11593 dimension stays positive).
11594
11595 Note that the axis parameter convention is different from the confusing one of L{DataField.invert}(). Here
11596 parameters simply correspond to directions that should be flipped.
11597
11598 @since: 2.60
11599
11600 @param xflipped: B{C{True}} to reflect X, i.e. rows. I{(bool)}
11601 @param yflipped: B{C{True}} to reflect Y, i.e. columns. I{(bool)}
11602 """
11603 pass
11604
11605
11608 """
11609 Gets the index of the currently selected marker in a marker
11610 box.
11611
11612
11613 @return: The index of currently selected marker, -1 when none is
11614 selected. I{(int)}
11615 """
11616 return None
11617
11619 """
11620 Selects a marker in a marker box.
11621
11622 @param i: The index of marker to select. Pass -1 to unselect. I{(int)}
11623 """
11624 pass
11625
11627 """
11628 Gets the position of a marker in a marker box.
11629
11630
11631 @param i: The index of marker to get position of. I{(int)}
11632 @return: The marker position, in the range [0.0, 1.0]. I{(float)}
11633 """
11634 return None
11635
11637 """
11638 Moves a marker in a marker box.
11639
11640
11641 @param i: Index of marker to move. I{(int)}
11642 @param pos: The new marker position, in the range [0.0, 1.0]. I{(float)}
11643 @return: B{C{True}} on success. If the move does not validate, B{C{False}} is returned
11644 and the marker position does not change. I{(bool)}
11645 """
11646 return None
11647
11649 """
11650 Adds a marker to a marker box.
11651
11652
11653 @param i: Index to insert marker at. I{(int)}
11654 @param pos: Position to insert marker to, in the range [0.0, 1.0]. I{(float)}
11655 @return: On success, the index the marker was added at. If the insertion
11656 does not validate, -1 is returned and no marker is added. I{(int)}
11657 """
11658 return None
11659
11661 """
11662 Removes a marker from a marker box.
11663
11664
11665 @param i: Index of marker to remove. I{(int)}
11666 @return: B{C{True}} on success. If the removal does not validate, B{C{False}} is
11667 returned and the marker is kept. I{(bool)}
11668 """
11669 return None
11670
11672 """
11673 Gets the number of markers in a marker box.
11674
11675
11676 @return: The number of markers. I{(int)}
11677 """
11678 return None
11679
11681 """
11682 Sets whether a marker box is drawn upside down.
11683
11684 @param flipped: B{C{True}} to draw markers upside down. I{(bool)}
11685 """
11686 pass
11687
11689 """
11690 Returns whether a marker box is drawn upside down.
11691
11692
11693 @return: B{C{True}} if markers are drawn upside down. I{(bool)}
11694 """
11695 return None
11696
11698 """
11699 Sets whether a marker box highlights selected marker.
11700
11701 @param highlight: B{C{True}} to visually differentiate selected marker, B{C{False}} to
11702 draw markers uniformly. I{(bool)}
11703 """
11704 pass
11705
11707 """
11708 Returns whether a marker box highlights selected marker.
11709
11710
11711 @return: B{C{True}} if selected marker is visually differentiated, B{C{False}} if
11712 markers are drawn uniformly. I{(bool)}
11713 """
11714 return None
11715
11717 """
11718 Gets all markers in a marker box.
11719
11720
11721 @return: The markers as an array of positions, owned by B{C{mbox}}. It must
11722 not be modified nor freed by caller and it's valid only until
11723 next marker change. I{(list)}
11724 """
11725 return None
11726
11728 """
11729 Sets positions of all markers in a marker box.
11730
11731 No validation is performed, even if validator is set. It's up to caller to
11732 set markers that do not logically conflict with the validator.
11733
11734 @param markers: Markers position. I{(list)}
11735 """
11736 pass
11741 """
11742 Creates a new horizontal marker box.
11743
11744
11745 @return: The new horizontal marker box as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
11746 """
11747 return None
11752 """
11753 Creates a new B{C{GtkTreeModel}} wrapper around nothing.
11754
11755
11756 @param n: The initial number of rows. I{(int)}
11757 @return: The newly created null store. I{(L{NullStore})}
11758 """
11759 return None
11760
11762 """
11763 Gets the number of imaginary rows in a null store.
11764
11765 This is a convenience function, the same information can be obtained with gtk_tree_model_iter_n_children().
11766
11767
11768 @return: The number of rows. I{(int)}
11769 """
11770 return None
11771
11773 """
11774 Sets the number of imaginary rows in a null store.
11775
11776 If the new number of rows is larger than the current one, rows will be sequentially and virtually appended to the
11777 end of the store until the requested number of rows is reached.
11778
11779 Similarly, if the new number of rows is smaller then the current one, rows will be sequentially and virtually
11780 deleted from the end of the store until the requested number of rows is reached.
11781
11782 Note for radical changes it is usually more useful to disconnect the model from its view(s), change the number of
11783 rows, and then reconnect.
11784
11785 @param n: The new number of rows. I{(int)}
11786 """
11787 pass
11788
11790 """
11791 Gets the model pointer of a null store.
11792
11793
11794 @return: The pointer set with L{NullStore.set_model}(). I{(gpointer)}
11795 """
11796 return None
11797
11799 """
11800 Sets the model pointer of a null store.
11801
11802 While the virtual integers in B{C{NullStore}} can be used directly, a null store typically serves as an adaptor for
11803 array-like structures and its rows are used as indices to these structures. This helper method provides means to
11804 attach such a structure to a null store in the common case.
11805
11806 The store itself does not interpret nor access the attached data by any means. No signals are emitted in response
11807 to the model pointer change either, particularly because it is expected to be set only once upon creation (null
11808 stores are cheap).
11809
11810 You are free to keep the model pointer at B{C{None}} if these functions do not suit your needs.
11811
11812 @param model: Model pointer. I{(gpointer)}
11813 @param destroy: Function to call on B{C{model}} when it is replaced or the store is destroyed. I{(GDestroyNotify)}
11814 """
11815 pass
11816
11818 """
11819 Emits "GtkTreeModel::row-changed" signal on a null store.
11820
11821 This is a convenience method, with a bit more work the same effect can be achieved with
11822 gtk_tree_model_row_changed().
11823
11824 @param i: A row to emit "row-changed" on. I{(int)}
11825 """
11826 pass
11827
11829 """
11830 Emits "GtkTreeModel::row-changed" signal on a block of rows in a null store.
11831
11832 This is a convenience method, with a bit more work the same effect can be achieved with
11833 gtk_tree_model_row_changed().
11834
11835 It is possible to pass B{C{ifrom}} larger than B{C{ito}}. The signal is then emitted for the same rows, but in the opposite
11836 order.
11837
11838 @since: 2.62
11839
11840 @param ifrom: The first row to emit "row-changed" on. I{(int)}
11841 @param ito: The last row to emit "row-changed" on (inclusive). I{(int)}
11842 """
11843 pass
11848 """
11849 Checks whether a pixmap layer wants repaint.
11850
11851
11852 @return: B{C{True}} if the the layer wants repaint itself, B{C{False}} otherwise. I{(bool)}
11853 """
11854 return None
11855
11857 """
11858 Returns a pixbuf with painted pixmap layer.
11859
11860 This method does not enforce repaint. If the layer doesn't think it needs
11861 to repaint the pixbuf, it simply returns the current one. To enforce
11862 update, emit "data-changed" signal on corresponding data field.
11863
11864
11865 @return: The pixbuf. It should not be modified or freed. If the data field
11866 to draw is not present in the container, B{C{None}} is returned. I{(L{gdk.Pixbuf})}
11867 """
11868 return None
11869
11871 """
11872 Sets the data field to display by a pixmap layer.
11873
11874 @param key: Container string key identifying the data field to display. I{(string)}
11875 """
11876 pass
11877
11879 """
11880 Gets the key identifying data field this pixmap layer displays.
11881
11882
11883 @return: The string key, or B{C{None}} if it isn't set. I{(string)}
11884 """
11885 return None
11886
11888 """
11889 Creates or resizes pixmap layer B{C{GdkPixbuf}} to match its data field.
11890
11891 This method is intended for pixmap layer implementation.
11892
11893 @param has_alpha: Whether pixbuf should have alpha channel. I{(bool)}
11894 """
11895 pass
11900 """
11901 Creates a new mask layer.
11902
11903 By default, is uses a transparent color (thus not displaying anything).
11904
11905
11906 @return: The newly created layer. I{(L{PixmapLayer})}
11907 """
11908 return None
11909
11911 """
11912 Sets the container key of colour components of a mask layer.
11913
11914 @param prefix: Prefix of keys identifying mask color components, "/red", "/green",
11915 "/blue", and "/alpha" is appended to it to get the individual
11916 keys. I{(string)}
11917 """
11918 pass
11919
11921 """
11922 Gets prefix identifying color components.
11923
11924
11925 @return: The prefix, or B{C{None}} if it isn't set. I{(string)}
11926 """
11927 return None
11928
11930 """
11931 Returns the color used by a mask layer.
11932
11933
11934 @return: The color as B{C{RGBA}}. I{(RGBA)}
11935 """
11936 return None
11941 """
11942 Creates a new basic data displaying layer.
11943
11944
11945 @return: The newly created layer. I{(L{PixmapLayer})}
11946 """
11947 return None
11948
11950 """
11951 Gets the range colors are mapped from in current mode.
11952
11953 This function does not take presentations into account. It always returns
11954 ther range corresponding to the underlying data even if a presentation is
11955 shown instead.
11956
11957 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
11958 """
11959 return None, None
11960
11962 """
11963 Gets the current color mapping mode.
11964
11965 @since: 2.7
11966
11967 @return: The current color mapping mode. I{(LayerBasicRangeType)}
11968 """
11969 return None
11970
11972 """
11973 Sets the container key of the colour gradient to use to visualize data.
11974
11975 @param key: Container string key identifying the color gradient to use. I{(string)}
11976 """
11977 pass
11978
11980 """
11981 Gets key identifying color gradient.
11982
11983
11984 @return: The string key, or B{C{None}} if it isn't set. I{(string)}
11985 """
11986 return None
11987
11989 """
11990 Sets the container key of the data field to actually display by a basic
11991 layer.
11992
11993 The data field set with L{PixmapLayer.get_data_key}() is used to obtain
11994 values, it determines physical dimensions, etc. When a data field is set
11995 with this method, it is displayed instead of the actual data.
11996
11997 @param key: Container string key identifying the data field to actually display. I{(string)}
11998 """
11999 pass
12000
12002 """
12003 Gets the key identifying data field this pixmap layer actually displays.
12004
12005 See L{LayerBasic.set_presentation_key}() for details.
12006
12007
12008 @return: The string key, or B{C{None}} if it isn't set. I{(string)}
12009 """
12010 return None
12011
12013 """
12014 Tests whether a basic layer displays a presentation instead of the data.
12015
12016
12017 @return: B{C{True}} if the layer has a presentation, B{C{False}} it it displays the
12018 data. I{(bool)}
12019 """
12020 return None
12021
12023 """
12024 Sets basic layer fixed range minimum and maximum.
12025
12026 @param prefix: Prefix of keys identifying minimum and maximum values for fixed
12027 range, "/min" and "/max" is appended to it to get the individual
12028 minimum and maximum keys. I{(string)}
12029 """
12030 pass
12031
12033 """
12034 Gets prefix identifying fixed range minimum and maximum.
12035
12036
12037 @return: The prefix, or B{C{None}} if it isn't set. I{(string)}
12038 """
12039 return None
12040
12042 """
12043 Sets the container key of the color range mapping type to use to visualize
12044 data.
12045
12046 @param key: Container string key identifying the range type to use. I{(string)}
12047 """
12048 pass
12049
12051 """
12052 Gets key identifying color range mapping type.
12053
12054
12055 @return: The string key, or B{C{None}} if it isn't set. I{(string)}
12056 """
12057 return None
12089 """
12090 Built-in and/or user supplied application resources
12091
12092
12093 B{C{Resource}} is a base class for various application resources. It defines common interface: questioning resource
12094 name (L{Resource.get_name}()), modifiability (L{Resource.get_is_modifiable}()), loading resources from files and
12095 saving them.
12096
12097 """
12099 """
12100 Returns resource name.
12101
12102
12103 @return: Name of B{C{resource}}. The string is owned by B{C{resource}} and must not
12104 be modfied or freed. I{(string)}
12105 """
12106 return None
12107
12109 """
12110 Returns whether a resource is modifiable.
12111
12112
12113 @return: B{C{True}} if resource is modifiable, B{C{False}} if it's fixed (system)
12114 resource. I{(bool)}
12115 """
12116 return None
12117
12119 """
12120 Returns whether a resource is preferred.
12121
12122
12123 @return: B{C{True}} if resource is preferred, B{C{False}} otherwise. I{(bool)}
12124 """
12125 return None
12126
12128 """
12129 Sets preferability of a resource.
12130
12131 @param is_preferred: B{C{True}} to make B{C{resource}} preferred, B{C{False}} to make it not preferred. I{(bool)}
12132 """
12133 pass
12134
12136 """
12137 Starts using a resource.
12138
12139 Call to this function is necessary to use a resource properly. It makes the resource to create any auxiliary
12140 structures that consume considerable amount of memory and perform other initialization to ready-to-use form.
12141
12142 When a resource is no longer used, it should be released with L{Resource.release}().
12143
12144 In addition, it calls g_object_ref() on the resource.
12145
12146 Resources usually exist through almost whole program lifetime from B{C{GObject}} perspective, but from the viewpoint of
12147 use this method is the constructor and L{Resource.release}() is the destructor.
12148
12149 """
12150 pass
12151
12153 """
12154 Releases a resource.
12155
12156 When the number of resource uses drops to zero, it frees all auxiliary data and returns back to `latent' form. In
12157 addition, it calls g_object_unref() on it. See L{Resource.use}() for more.
12158
12159 """
12160 pass
12161
12163 """
12164 Tells whether a resource is currently in use.
12165
12166 See L{Resource.use}() for details.
12167
12168
12169 @return: B{C{True}} if resource is in use, B{C{False}} otherwise. I{(bool)}
12170 """
12171 return None
12172
12174 """
12175 Emits signal "data-changed" on a resource.
12176
12177 It can be called only on non-constant resources. The default handler sets B{C{is_modified}} flag on the resource.
12178
12179 Mostly useful in resource implementation.
12180
12181 """
12182 pass
12183
12185 """
12186 Clears B{C{is_modified}} flag of a resource.
12187
12188 @since: 2.8
12189
12190 """
12191 pass
12192
12194 """
12195 Builds file name a resource should be saved to.
12196
12197 If the resource has not been newly created, renamed, or system it was probably loaded from file of the same name.
12198
12199
12200 @return: Resource file name as a newly allocated string that must be freed by caller. I{(string)}
12201 """
12202 return None
12203
12205 """
12206 Dumps a resource to a textual (human readable) form.
12207
12208
12209 @return: Textual resource representation. I{(string)}
12210 """
12211 return None
12212
12214 """
12215 Renames a resource, including renaming it on disk.
12216
12217 The method renames the resource both in the inventory and on disk. The renaming must not conflict with an existing
12218 resource, constant resources cannot be renamed, etc. It is OK to rename a resource to the same name (nothing
12219 happens then).
12220
12221 @since: 2.51
12222
12223 @param newname: New resource name. I{(string)}
12224 @return: B{C{True}} if the renaming succeeded. I{(bool)}
12225 """
12226 return None
12227
12229 """
12230 Deletes a resource, including removal from disk.
12231
12232 The method deletes the resource both in the inventory and on disk. Constant resources cannot be deleted.
12233
12234 @since: 2.51
12235
12236 @return: B{C{True}} if the removal succeeded. I{(bool)}
12237 """
12238 return None
12239
12241 """
12242 Saves a resource to disk.
12243
12244 Only non-constant resources can be saved. The file name is determined by L{Resource.build_filename}(). The
12245 resource data are saved even if the modified flag is not set. Upon successful save, the modified flag is cleared.
12246
12247 Instead of saving individual resources, consider also using L{Resource.class_save_modified}().
12248
12249 @since: 2.62
12250
12251 @return: B{C{True}} if resource was saved to disk, B{C{False}} otherwise. I{(bool)}
12252 """
12253 return None
12254
12255
12258 """
12259 Calculates preset function value in a single point with given parameters.
12260
12261
12262 @param x: The point to compute value at. I{(float)}
12263 @param params: Preset parameter values. I{(const-gdouble*)}
12264 @param fres: Set to B{C{True}} if succeeds, B{C{False}} on failure. I{(gboolean*)}
12265 @return: The function value. I{(float)}
12266 """
12267 return None
12268
12277
12279 """
12280 Return the number of parameters of B{C{preset}}.
12281
12282
12283 @return: The number of function parameters. I{(int)}
12284 """
12285 return None
12286
12288 """
12289 Gets the name of a fitting parameter of a fitter preset.
12290
12291 The name may contain Pango markup.
12292
12293
12294 @param param: A parameter number. I{(int)}
12295 @return: The name of parameter @param. I{(string)}
12296 """
12297 return None
12298
12300 """
12301 Derives the SI unit of a fitting parameter from the units of abscissa and
12302 ordinate.
12303
12304 @since: 2.5
12305
12306 @param param: A parameter number. I{(int)}
12307 @param siunit_x: SI unit of abscissa. I{(L{SIUnit})}
12308 @param siunit_y: SI unit of ordinate. I{(L{SIUnit})}
12309 @return: A newly created B{C{SIUnit}} with the units of the parameter @param.
12310 If the units of @param are not representable as B{C{SIUnit}},
12311 the result is unitless (i.e. it will be presented as a mere
12312 number). I{(L{SIUnit})}
12313 """
12314 return None
12315
12316 - def fit(fitter, n_dat, x, y, params, err, fixed_param):
12317 """
12318 Performs a nonlinear fit with a preset.
12319
12320 See L{gwy_math_nlfit_fit_full}() for details.
12321
12322
12323 @param fitter: A Marquardt-Levenberg nonlinear fitter already initialized for
12324 B{C{preset}}'s function, or B{C{None}}. I{(MathNLFit*)}
12325 @param n_dat: The number of data points (number of items in B{C{x}} and B{C{y}}). I{(int)}
12326 @param x: Abscissa points. I{(const-gdouble*)}
12327 @param y: Ordinate points. I{(const-gdouble*)}
12328 @param params: Initial parameter estimate (the number of parameters depends on
12329 the fitted preset and it can be obtained with
12330 L{gwy_nlfit_preset_get_nparams}()). I{(gdouble*)}
12331 @param err: Array to store parameter errros to, may be B{C{None}}. I{(gdouble*)}
12332 @param fixed_param: Which parameters should be treated as fixed (set
12333 corresponding element to B{C{True}} for them). May be B{C{None}} if
12334 all parameters are variable. I{(const-gboolean*)}
12335 @return: Either B{C{fitter}} itself, or a newly created fitter if it was B{C{None}}. I{(MathNLFit*)}
12336 """
12337 return None
12341 """
12342 A map from numbers to RGBA colors
12343
12344
12345 Gradient is a map from interval [0,1] to RGB(A) color space. Each gradient
12346 is defined by an ordered set of color points, the first of them is always at
12347 0.0, the last at 1.0 (thus each gradient must consist of at least two
12348 points). Between them, the color is interpolated. Color points of
12349 modifiable gradients (see B{C{Resource}}) can be edited with functions like
12350 L{Gradient.insert_point}(), L{Gradient.set_point_color}(), or
12351 L{Gradient.set_points}().
12352
12353 Gradient objects can be obtained from L{gwy_gradients_get_gradient}(). New
12354 gradients can be created with L{Inventory.new_item}() on the B{C{Inventory}}
12355 returned by L{gwy_gradients}().
12356
12357 """
12359 """
12360 Computes the color at a given position of a color gradient.
12361
12362 @param x: Position in gradient, in range 0..1. I{(float)}
12363 @param color: Color to fill with interpolated color at position B{C{x}}. I{(L{RGBA})}
12364 """
12365 pass
12366
12368 """
12369 Samples a color gradient to a provided pixbuf.
12370
12371 Unlike L{Gradient.sample}() which simply takes samples at equidistant
12372 points this method uses supersampling and thus it gives a bit better
12373 looking gradient presentation.
12374
12375 @param pixbuf: A pixbuf to sample gradient to (in horizontal direction). I{(L{gdk.Pixbuf})}
12376 """
12377 pass
12378
12380 """
12381 Returns the number of points in a color gradient.
12382
12383
12384 @return: The number of points in B{C{gradient}}. I{(int)}
12385 """
12386 return None
12387
12389 """
12390 Returns the point at given index of a color gradient.
12391
12392
12393 @param index_: Color point index in B{C{gradient}}. I{(int)}
12394 @return: Color point at B{C{index_}}. I{(GradientPoint)}
12395 """
12396 return None
12397
12399 """
12400 Sets a single color point in a color gradient.
12401
12402 It is an error to try to move points beyond its neighbours, or to move first
12403 (or last) point from 0 (or 1).
12404
12405 @param index_: Color point index in B{C{gradient}}. I{(int)}
12406 @param point: Color point to replace current point at B{C{index_}} with. I{(const-GradientPoint*)}
12407 """
12408 pass
12409
12411 """
12412 Sets the color of a color gradient point without moving it.
12413
12414 @param index_: Color point index in B{C{gradient}}. I{(int)}
12415 @param color: Color to set the point to. I{(const-RGBA*)}
12416 """
12417 pass
12418
12420 """
12421 Deletes a point at given index in a color gradient.
12422
12423 It is not possible to delete points in gradients with less than 3 points.
12424 First and last points should not be deleted unless there's another point
12425 with B{C{x}} = 0 or B{C{x}} = 1 present.
12426
12427 @param index_: Color point index in B{C{gradient}}. I{(int)}
12428 """
12429 pass
12430
12432 """
12433 Resets a gradient to the default two-point gray scale state.
12434
12435 """
12436 pass
12437
12439 """
12440 Returns the complete set of color points of a gradient.
12441
12442
12443 @return: Tuple consisting of 2 values (B{C{value}}, B{C{npoints}}). (I{(const-GradientPoint*)}, I{(int)})
12444 """
12445 return None, None
12446
12448 """
12449 Sets the complete color gradient definition to a given set of points.
12450
12451 The point positions should be ordered, and first point should start at 0.0,
12452 last end at 1.0. There should be no redundant points.
12453
12454 @param npoints: The length of B{C{points}}. I{(int)}
12455 @param points: Color points to set as new gradient definition. I{(const-GradientPoint*)}
12456 """
12457 pass
12458
12460 """
12461 Reconstructs a color gradient definition from sampled colors.
12462
12463 The result is usually approximate.
12464
12465 @param nsamples: Number of samples, it must be at least one. I{(int)}
12466 @param samples: Sampled color gradient in B{C{GdkPixbuf}}-like RRGGBBAA form. I{(string)}
12467 @param threshold: Maximum allowed difference (for color components in range 0..1).
12468 When negative, default value 1/80 suitable for most purposes
12469 is used. I{(float)}
12470 """
12471 pass
12472
12473
12475 """
12476 OpenGL material representation
12477
12478
12479 B{C{GLMaterial}} represents an OpenGL material. Its properties directly map
12480 to corresponding OpenGL material characteristics, all are in the range
12481 [0,1].
12482
12483 Gradient objects can be obtained from L{gwy_gl_materials_get_gl_material}().
12484 New GL materials can be created with L{Inventory.new_item}() on the
12485 B{C{Inventory}} returned by L{gwy_gl_materials}().
12486
12487 """
12489 """
12490 Gets the ambient reflectance of a GL material.
12491
12492
12493 @return: Ambient reflectance (owned by GL material, must not be modified
12494 nor freed). I{(const-RGBA*)}
12495 """
12496 return None
12497
12499 """
12500 Sets the ambient reflectance of a GL material.
12501
12502 @param ambient: Ambient reflectance. I{(const-RGBA*)}
12503 """
12504 pass
12505
12507 """
12508 Gets the diffuse reflectance of a GL material.
12509
12510
12511 @return: Diffuse reflectance (owned by GL material, must not be modified
12512 nor freed). I{(const-RGBA*)}
12513 """
12514 return None
12515
12517 """
12518 Sets the diffuse reflectance of a GL material.
12519
12520 @param diffuse: Diffuse reflectance. I{(const-RGBA*)}
12521 """
12522 pass
12523
12525 """
12526 Gets the specular reflectance of a GL material.
12527
12528
12529 @return: Specular reflectance (owned by GL material, must not be modified
12530 nor freed). I{(const-RGBA*)}
12531 """
12532 return None
12533
12535 """
12536 Sets the specular reflectance of a GL material.
12537
12538 @param specular: Specular reflectance. I{(const-RGBA*)}
12539 """
12540 pass
12541
12543 """
12544 Gets the emission component of a GL material.
12545
12546
12547 @return: Emission component (owned by GL material, must not be modified
12548 nor freed). I{(const-RGBA*)}
12549 """
12550 return None
12551
12553 """
12554 Sets the emission component of a GL material.
12555
12556 @param emission: Emission component. I{(const-RGBA*)}
12557 """
12558 pass
12559
12561 """
12562 Gets the shininess value of a GL material.
12563
12564
12565 @return: The shininess value (in range 0..1, not 0..128). I{(float)}
12566 """
12567 return None
12568
12570 """
12571 Sets the shininess value of a GL material.
12572
12573 @param shininess: Shinniness value (in range 0..1, not 0..128). I{(float)}
12574 """
12575 pass
12576
12578 """
12579 Samples GL material to a provided pixbuf.
12580
12581 @param pixbuf: A pixbuf to sample gl_material to (in horizontal direction). I{(L{gdk.Pixbuf})}
12582 """
12583 pass
12584
12586 """
12587 Resets a GL material to default values.
12588
12589 """
12590 pass
12591
12592
12595 """
12596 Return cdline name (its unique identifier).
12597
12598
12599 @return: The cdline name. I{(string)}
12600 """
12601 return None
12602
12604 """
12605 Gets the name of the image file with critical dimension evaluator
12606 description.
12607
12608
12609 @return: The cdline function definition. I{(string)}
12610 """
12611 return None
12612
12614 """
12615 Returns the name of a critical dimension evaluator parameter.
12616
12617 The name may contain Pango markup.
12618
12619
12620 @param param: A parameter number. I{(int)}
12621 @return: The name of parameter @param. I{(string)}
12622 """
12623 return None
12624
12626 """
12627 Returns a constant default parameter value.
12628
12629
12630 @param param: A parameter number. I{(int)}
12631 @return: The default parameter value, unrelated to the actual data fitted.
12632 It is worthless. I{(float)}
12633 """
12634 return None
12635
12637 """
12638 Derives the SI unit of a critical dimension parameter from the units of
12639 abscissa and ordinate.
12640
12641 @since: 2.5
12642
12643 @param param: A parameter number. I{(int)}
12644 @param siunit_x: SI unit of abscissa. I{(L{SIUnit})}
12645 @param siunit_y: SI unit of ordinate. I{(L{SIUnit})}
12646 @return: A newly created B{C{SIUnit}} with the units of the parameter @param.
12647 If the units of @param are not representable as B{C{SIUnit}},
12648 the result is unitless (i.e. it will be presented as a mere
12649 number). I{(L{SIUnit})}
12650 """
12651 return None
12652
12654 """
12655 Return the number of parameters of B{C{cdline}}.
12656
12657
12658 @return: The number of function parameters. I{(int)}
12659 """
12660 return None
12661
12663 """
12664 Performs a critical dimension evaulation (fit).
12665
12666 @param x: Abscissa points. I{(list)}
12667 @param y: Ordinate points. I{(list)}
12668 @return: Tuple consisting of 2 values (B{C{params}}, B{C{err}}). (I{(list)}, I{(list)})
12669 """
12670 return None, None
12671
12673 """
12674 Calculates critical dimension function value in a single point with given
12675 parameters.
12676
12677
12678 @param x: The point to compute value at. I{(float)}
12679 @param params: Evaluator parameter values. I{(list)}
12680 @return: Tuple consisting of 2 values (B{C{value}}, B{C{fres}}). (I{(float)}, I{(BooleanOutArg)})
12681 """
12682 return None, None
12687 """
12688 Gets the currently edited resource.
12689
12690 It is an error to call this method when no resource is being edited.
12691
12692
12693 @return: The currently edited resource. I{(L{Resource})}
12694 """
12695 return None
12696
12698 """
12699 Queues commit of resource changes, marking the currently edited resource
12700 `dirty'.
12701
12702 Call this method in particular resource editor subclass whenever user
12703 changes some editor property.
12704
12705 To flush pending commit, call L{Resource.editor_commit}(). To immediately
12706 commit a change, call this method and then L{Resource.editor_commit}().
12707
12708 """
12709 pass
12710
12712 """
12713 Commits pending resource changes, if there are any.
12714
12715 It calls B{C{apply_changes}} method first (if it exists), then saves resource to
12716 disk.
12717
12718 Changes are always immediately committed (if there are any pending): before
12719 the editor is destroyed, when a resource stops being edited, before a
12720 resource is deleted, before a resource is renamed. When a resource is newly
12721 created, it is immediately created on disk too.
12722
12723
12724 @return: Always B{C{False}} (to be usable as B{C{GSourceFunc}}). I{(bool)}
12725 """
12726 return None
12727
12729 """
12730 Sets up particular resource editor.
12731
12732 Helper method only intended for resource editor implementation.
12733 To be called in particular resource initialization methods.
12734
12735 """
12736 pass
12740 - def set_range(lower, upper, position, max_size):
12741 """
12742 Sets range and current value of a ruler.
12743
12744 @param lower: Lower limit of the ruler. I{(float)}
12745 @param upper: Upper limit of the ruler. I{(float)}
12746 @param position: Current position of the mark on the ruler. I{(float)}
12747 @param max_size: Maximum value used for calculating size of text labels. I{(float)}
12748 """
12749 pass
12750
12752 """
12753 Draws a position marker.
12754
12755 This method is intended primarily for subclass implementation.
12756
12757 """
12758 pass
12759
12761 """
12762 Retrieves values indicating the range and current position of a B{C{Ruler}}.
12763 See L{Ruler.set_range}().
12764
12765 @return: Tuple consisting of 4 values (B{C{lower}}, B{C{upper}}, B{C{position}}, B{C{max_size}}). (I{(float)}, I{(float)}, I{(float)}, I{(float)})
12766 """
12767 return None, None, None, None
12768
12770 """
12771 Sets the base units a ruler displays.
12772
12773 Setting units to B{C{None}} effectively disables them.
12774
12775 @param units: The base units this ruler should display. I{(L{SIUnit})}
12776 """
12777 pass
12778
12780 """
12781 Returns the base units a ruler uses.
12782
12783
12784 @return: The units the rules uses. I{(L{SIUnit})}
12785 """
12786 return None
12787
12789 """
12790 Gets current units placement of ruler B{C{ruler}}.
12791
12792
12793 @return: The units placement. I{(UnitsPlacement)}
12794 """
12795 return None
12796
12798 """
12799 Sets whether and where units should be placed on the ruler.
12800
12801 @param placement: Units placement specification. Expected values: C{B{UNITS_PLACEMENT_NONE}}, C{B{UNITS_PLACEMENT_AT_ZERO}}. I{(L{UnitsPlacement})}
12802 """
12803 pass
12808 """
12809 Creates a new B{C{HRuler}}.
12810
12811
12812 @return: The new ruler as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
12813 """
12814 return None
12818 """
12819 SI unit representation, physical quantitiy formatting
12820
12821
12822 B{C{SIUnit}} object represents a physical SI unit (or any other unit), it can be created from a unit string with
12823 L{SIUnit.new}().
12824
12825 SIUnit is also responsible for prefixes selection and generally formatting of physical quantities (see also
12826 gwymath for pure number formatting functions). There are several functions computing value format (as
12827 a B{C{SIValueFormat}} structure) with given resolution -- L{SIUnit.get_format_with_resolution}(), or number of
12828 significant digits -- L{SIUnit.get_format_with_digits}().
12829
12830 """
12832 """
12833 Creates a new SI unit from string representation.
12834
12835 Unit string represents unit with no prefixes (e. g. "m", "N", "A", etc.)
12836
12837
12838 @param unit_string: Unit string (it can be B{C{None}} for an empty unit). I{(string)}
12839 @return: A new SI unit. I{(L{SIUnit})}
12840 """
12841 return None
12842
12844 """
12845 Sets string that represents unit.
12846
12847 It must be base unit with no prefixes (e. g. "m", "N", "A", etc.).
12848
12849 @param unit_string: Unit string to set B{C{siunit}} from (it can be B{C{None}} for an empty unit). I{(string)}
12850 """
12851 pass
12852
12854 """
12855 Changes an SI unit according to string representation.
12856
12857 This is a more powerful version of L{SIUnit.set_from_string}(), please see L{SIUnit.new_parse}() for some
12858 discussion.
12859
12860 @param unit_string: Unit string to set B{C{siunit}} from (it can be B{C{None}} for an empty
12861 unit). I{(string)}
12862 @return: Value B{C{power10}}. (I{(int)})
12863 """
12864 return None
12865
12867 """
12868 Obtains string representing a SI unit.
12869
12870
12871 @param style: Unit format style. Expected values: C{B{SI_UNIT_FORMAT_NONE}}, C{B{SI_UNIT_FORMAT_PLAIN}}, C{B{SI_UNIT_FORMAT_MARKUP}}, C{B{SI_UNIT_FORMAT_VFMARKUP}}, C{B{SI_UNIT_FORMAT_TEX}}, C{B{SI_UNIT_FORMAT_VFTEX}}, C{B{SI_UNIT_FORMAT_UNICODE}}, C{B{SI_UNIT_FORMAT_VFUNICODE}}. I{(L{SIUnitFormatStyle})}
12872 @return: A newly allocated string that represents the base unit (with no prefixes). I{(string)}
12873 """
12874 return None
12875
12877 """
12878 Multiplies two SI units.
12879
12880
12881 @param siunit2: An SI unit. I{(L{SIUnit})}
12882 @param result: An SI unit to set to product of B{C{siunit1}} and B{C{siunit2}}. It is safe to pass one of B{C{siunit1}}, B{C{siunit2}}. It
12883 can be B{C{None}} too, a new SI unit is created then and returned. I{(L{SIUnit})}
12884 @return: When B{C{result}} is B{C{None}}, a newly created SI unit that has to be dereferenced when no longer used later.
12885 Otherwise B{C{result}} itself is simply returned, its reference count is NOT increased. I{(L{SIUnit})}
12886 """
12887 return None
12888
12889 - def divide(siunit2, result):
12890 """
12891 Divides two SI units.
12892
12893
12894 @param siunit2: An SI unit. I{(L{SIUnit})}
12895 @param result: An SI unit to set to quotient of B{C{siunit1}} and B{C{siunit2}}. It is safe to pass one of B{C{siunit1}}, B{C{siunit2}}. It
12896 can be B{C{None}} too, a new SI unit is created then and returned. I{(L{SIUnit})}
12897 @return: When B{C{result}} is B{C{None}}, a newly created SI unit that has to be dereferenced when no longer used later.
12898 Otherwise B{C{result}} itself is simply returned, its reference count is NOT increased. I{(L{SIUnit})}
12899 """
12900 return None
12901
12902 - def power(power, result):
12903 """
12904 Computes a power of an SI unit.
12905
12906
12907 @param power: Power to raise B{C{siunit}} to. I{(int)}
12908 @param result: An SI unit to set to power of B{C{siunit}}. It is safe to pass B{C{siunit}} itself. It can be B{C{None}} too, a new SI
12909 unit is created then and returned. I{(L{SIUnit})}
12910 @return: When B{C{result}} is B{C{None}}, a newly created SI unit that has to be dereferenced when no longer used later.
12911 Otherwise B{C{result}} itself is simply returned, its reference count is NOT increased. I{(L{SIUnit})}
12912 """
12913 return None
12914
12916 """
12917 Calulates n-th root of an SI unit.
12918
12919 This operation fails if the result would have fractional powers that are not representable by B{C{SIUnit}}.
12920
12921 @since: 2.5
12922
12923 @param ipower: The root to take: 2 means a quadratic root, 3 means cubic root, etc. I{(int)}
12924 @param result: An SI unit to set to power of B{C{siunit}}. It is safe to pass B{C{siunit}} itself. It can be B{C{None}} too, a new SI
12925 unit is created then and returned. I{(L{SIUnit})}
12926 @return: On success: When B{C{result}} is B{C{None}}, a newly created SI unit that has to be dereferenced when no longer used
12927 later, otherwise B{C{result}} itself is simply returned, its reference count is NOT increased. On failure B{C{None}}
12928 is always returned. I{(L{SIUnit})}
12929 """
12930 return None
12931
12933 """
12934 Computes the product of two SI units raised to arbitrary powers.
12935
12936 This is the most complex SI unit arithmetic function. It can be easily chained when more than two units are to be
12937 multiplied.
12938
12939 @since: 2.4
12940
12941 @param power1: Power to raise B{C{siunit1}} to. I{(int)}
12942 @param siunit2: An SI unit. I{(L{SIUnit})}
12943 @param power2: Power to raise B{C{siunit2}} to. I{(int)}
12944 @param result: An SI unit to set to B{C{siunit1}}^B{C{power1}}*B{C{siunit2}}^B{C{power2}}. It is safe to pass B{C{siunit1}} or B{C{siunit2}}. It can
12945 be B{C{None}} too, a new SI unit is created then and returned. I{(L{SIUnit})}
12946 @return: When B{C{result}} is B{C{None}}, a newly created SI unit that has to be dereferenced when no longer used later.
12947 Otherwise B{C{result}} itself is simply returned, its reference count is NOT increased. I{(L{SIUnit})}
12948 """
12949 return None
12950
12952 """
12953 Checks whether two SI units are equal.
12954
12955
12956 @param siunit2: Second unit. I{(L{SIUnit})}
12957 @return: B{C{True}} if the units are equal. I{(bool)}
12958 """
12959 return None
12960
12962 """
12963 Checks whether an SI unit corresponds to given string.
12964
12965 Any power-of-ten prefixes are ignored. This function is mostly useful for quick commensurability checks with
12966 simple units such as "m" and for checking whether a unit is non-empty (by comparing with B{C{None}} or an empty string).
12967
12968 @since: 2.49
12969
12970 @param unit_string: Unit string (it can be B{C{None}} for an empty unit). I{(string)}
12971 @return: B{C{True}} if the units is equivalent to the given string. I{(bool)}
12972 """
12973 return None
12974
12990
13008
13025
13042
13044 """
13045 Convenience macro doing L{gwy_serializable_duplicate}() with all the necessary typecasting.
13046
13047 @return: I{(L{SIUnit})}
13048 """
13049 return None
13050
13051
13054 """
13055 Creates a new scientific text entry.
13056
13057
13058 @return: A newly created scientific text entry. I{(L{gtk.Widget})}
13059 """
13060 return None
13061
13063 """
13064 Gets the text in a scientific text entry.
13065
13066 The text is already in UTF-8 with all entities converted.
13067
13068
13069 @return: The text as a newly allocated string. It should be freed when no
13070 longer used. I{(string)}
13071 """
13072 return None
13073
13074 - def set_text(new_text):
13075 """
13076 Sets the text a scientific text widget displays.
13077
13078 It can contain both UTF-8 and entities. UTF-8 characters corresponding to
13079 known entities are converted to entities, other characters are left as they
13080 are.
13081
13082 @param new_text: The text to display. I{(string)}
13083 """
13084 pass
13085
13087 """
13088 Tests the display of a preview in a scientific text entry.
13089
13090
13091 @return: B{C{True}} if there is a preview, B{C{False}} if preview is not shown. I{(bool)}
13092 """
13093 return None
13094
13095 - def set_has_preview(has_preview):
13096 """
13097 Sets the display of a preview in a scientific text entry.
13098
13099 @param has_preview: B{C{True}} to display a preview, B{C{False}} to disable it. I{(bool)}
13100 """
13101 pass
13102
13104 """
13105 Gets the entry widget of a scientific text entry.
13106
13107
13108 @return: The entry widget, no reference is added. I{(L{gtk.Widget})}
13109 """
13110 return None
13114 """
13115 Data selection base class
13116
13117
13118 B{C{Selection}} is an abstract class representing data selections. Particular selection types are defined by vector
13119 layer modules.
13120
13121 Selections behave as flat arrays of coordinates. They are however logically split into selection objects (points,
13122 lines, rectangles), characteristic for each selection type. For example, to describe a horizontal line one needs
13123 only one coordinate, for a point two coordinates are needed, rectangle or arbitrary line need four.
13124 L{Selection.get_object_size}() can be used to generically determine the number of coordinates used to describe
13125 a one selection object.
13126
13127 The number of selection objects in a selection can vary, L{Selection.set_max_objects}() sets the maximum possible
13128 number. Functions for getting and setting individual selection objects (L{Selection.get_object}(),
13129 L{Selection.set_object}()) or complete selection (L{Selection.get_data}(), L{Selection.set_data}()) are
13130 available. The method L{Selection.set_data}() with B{C{None}} second argument is also used to determine the number of
13131 selected object.
13132
13133 """
13135 """
13136 Gets the number of coordinates that make up a one selection object.
13137
13138
13139 @return: The number of coordinates in one selection object. I{(int)}
13140 """
13141 return None
13142
13144 """
13145 Clears a selection.
13146
13147 """
13148 pass
13149
13151 """
13152 Deletes a one selection object.
13153
13154 Since there cannot be holes in the object list, the rest of selection objects is moved to close the gap.
13155
13156 @param i: Index of object to delete. I{(int)}
13157 """
13158 pass
13159
13161 """
13162 Gets the maximum number of selected objects.
13163
13164
13165 @return: The maximum number of selected objects; I{(int)}
13166 """
13167 return None
13168
13170 """
13171 Sets the maximum number of objects allowed to select.
13172
13173 When selection reaches this number of selected objects, it emits "finished" signal.
13174
13175 @param max_objects: The maximum number of objects allowed to select. Note particular selection types may allow only
13176 specific values. I{(int)}
13177 """
13178 pass
13179
13181 """
13182 Checks whether the maximum number of objects is selected.
13183
13184
13185 @return: B{C{True}} when the maximum possible number of objects is selected, B{C{False}} otherwise. I{(bool)}
13186 """
13187 return None
13188
13189 - def crop(xmin, ymin, xmax, ymax):
13190 """
13191 Limits objects in a selection to a rectangle.
13192
13193 Objects that are fully outside specified rectangle are removed. Objects partially outside may be removed or cut,
13194 depending on what makes sense for the specific selection type. If the selection class does not implement this
13195 method then all objects are removed.
13196
13197 @since: 2.16
13198
13199 @param xmin: Minimum x-coordinate. I{(float)}
13200 @param ymin: Minimum y-coordinate. I{(float)}
13201 @param xmax: Maximum x-coordinate. I{(float)}
13202 @param ymax: Maximum y-coordinate. I{(float)}
13203 """
13204 pass
13205
13206 - def move(vx, vy):
13207 """
13208 Moves entire selection in plane by given vector.
13209
13210 If a selection class does not implement this operation the selection remains unchanged. Bult-in selection classes
13211 generally implement this operation if it is meaningful. For some, such as SelectionLattice, it is not
13212 meaningful and moving SelectionLattice thus does not do anything.
13213
13214 @since: 2.43
13215
13216 @param vx: Value to add to all x-coordinates. I{(float)}
13217 @param vy: Value to add to all y-coordinates. I{(float)}
13218 """
13219 pass
13220
13222 """
13223 Removes selection objects matching certain criteria.
13224
13225 @since: 2.16
13226
13227 @param filter: Function returning B{C{True}} for objects that should be kept, B{C{False}} for objects that should be removed. I{(SelectionFilterFunc)}
13228 @param data: User data passed to B{C{filter}}. I{(gpointer)}
13229 """
13230 pass
13231
13233 """
13234 Emits "changed" signal on a selection.
13235
13236 @param i: Index of object that changed. Use -1 when not applicable, e.g., when complete selection was changed, cleared,
13237 or truncated. I{(int)}
13238 """
13239 pass
13240
13242 """
13243 Emits "finished" signal on a selection.
13244
13245 """
13246 pass
13247
13249 """
13250 Get selection coordinates as single flat list.
13251
13252
13253 @return: a list of selected data I{(list)}
13254 """
13255 return None
13256
13258 """
13259 Gets one selection object.
13260
13261
13262 @param i: Index of object to get. I{(int)}
13263 @return: B{C{True}} if there was such an object and B{C{data}} was filled. I{(list)}
13264 """
13265 return None
13266
13268 """
13269 Sets selection data.
13270
13271 @param data: Selection data, that is an array B{C{nselected}} * L{Selection.get_object_size}() long with selected object
13272 coordinates. I{(list)}
13273 """
13274 pass
13275
13277 """
13278 Sets one selection object.
13279
13280 This method can be also used to append objects (if the maximum number is not exceeded). Since there cannot be
13281 holes in the object list, B{C{i}} must be then equal to either the number of selected objects or special value -1
13282 meaning append to end.
13283
13284
13285 @param i: Index of object to set. I{(int)}
13286 @param data: Object selection data. It's an array of coordinates whose precise meaning is defined by particular selection
13287 types. I{(list)}
13288 """
13289 pass
13290
13292 """
13293 Convenience macro doing L{gwy_serializable_duplicate}() with all the necessary typecasting.
13294
13295 @return: I{(L{Selection})}
13296 """
13297 return None
13298
13299
13302 """
13303 Creates a new area-wise graph selection.
13304
13305 @since: 2.1
13306
13307 @return: A new selection object. I{(L{Selection})}
13308 """
13309 return None
13314 """
13315 Creates a new line-wise graph selection.
13316
13317 @since: 2.1
13318
13319 @return: A new selection object. I{(L{Selection})}
13320 """
13321 return None
13326 """
13327 Creates a new point-wise graph selection.
13328
13329 @since: 2.1
13330
13331 @return: A new selection object. I{(L{Selection})}
13332 """
13333 return None
13338 """
13339 Creates a new zoom-wise graph selection.
13340
13341 @since: 2.1
13342
13343 @return: A new selection object. I{(L{Selection})}
13344 """
13345 return None
13350 """
13351 Creates a new flag-based widget sensitivity group.
13352
13353
13354 @return: The newly created sensitivity group. It starts with zero state. I{(L{SensitivityGroup})}
13355 """
13356 return None
13357
13374
13376 """
13377 Sets the state of a widget flag sensitivity group.
13378
13379 Widget sensitivity states are then updated accordingly.
13380
13381 More precisely, widget will be made sensitive when all bits in its B{C{mask}} are
13382 set in current B{C{sensgroup}} state, insensitive otherwise. This means when
13383 B{C{mask}} is zero, widget will be always sensitive.
13384
13385 @param affected_mask: Which bits in B{C{state}} to copy to B{C{sensgroup}} state.
13386 1's in B{C{affected_mask}} causes corresponding bits in
13387 B{C{sensgroup}} state to be set to the value of corresponding
13388 bit in B{C{state}}.
13389 0's in B{C{affected_mask}} cause corresponding state bits to be
13390 kept on their current value. I{(int)}
13391 @param state: The new state of B{C{sensgroup}} (masked with B{C{affected_mask}}). I{(int)}
13392 """
13393 pass
13394
13396 """
13397 Gets the current state of a widget flag sensitivity group.
13398
13399
13400 @return: The current state as set with L{SensitivityGroup.set_state}(). I{(int)}
13401 """
13402 return None
13403
13411
13422
13432
13447 """
13448 Creates a new spherical shader.
13449
13450 The widget takes up all the space allocated for it.
13451
13452
13453 @param gradient: Name of gradient to color the spehere with. Can be B{C{None}} to
13454 use the default gradient. I{(string)}
13455 @return: The new shader as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
13456 """
13457 return None
13458
13460 """
13461 Returns the theta coordinate of a shader.
13462
13463
13464 @return: The theta coordinate, in radians. Theta coordinate is angle from
13465 sphere's north pole. I{(float)}
13466 """
13467 return None
13468
13470 """
13471 Returns the phi coordinate of a shader.
13472
13473
13474 @return: The phi coordinate, in radians. Phi coordinate is orientation
13475 in horizontal plane, measured from x axis, counterclockwise. I{(float)}
13476 """
13477 return None
13478
13480 """
13481 Sets the theta coordinate of a shader.
13482
13483 @param theta: The theta coordinate to set. See L{Shader.get_theta}() for
13484 description. I{(float)}
13485 """
13486 pass
13487
13489 """
13490 Sets the phi coordinate of a shader.
13491
13492 @param phi: The phi coordinate to set. See L{Shader.get_phi}() for description. I{(float)}
13493 """
13494 pass
13495
13497 """
13498 Sets the spherical angle of a shader.
13499
13500 @param theta: The theta coordinate to set. See L{Shader.get_theta}() for
13501 description. I{(float)}
13502 @param phi: The phi coordinate to set. See L{Shader.get_phi}() for description. I{(float)}
13503 """
13504 pass
13505
13507 """
13508 Returns the name of color gradient a shader uses.
13509
13510
13511 @return: The gradient name. It must not be modified or freed. It may
13512 differ the name that was used on initialization or set with
13513 L{Shader.set_gradient}(), if the gradient didn't exist or
13514 was renamed meanwhile. I{(string)}
13515 """
13516 return None
13517
13519 """
13520 Sets the gradient a shader uses.
13521
13522 @param gradient: Name of gradient B{C{shader}} should use. It should exist. I{(string)}
13523 """
13524 pass
13525
13527 """
13528 Returns the update policy of a shader.
13529
13530
13531 @return: The update policy. I{(GtkUpdateType)}
13532 """
13533 return None
13534
13536 """
13537 Sets the update policy of a shader.
13538
13539 @param update_policy: The update policy B{C{shader}} should use. I{(GtkUpdateType)}
13540 """
13541 pass
13546 """
13547 Reports if a 3D geometrical shape fitter preset requires the same lateral and value units.
13548
13549 For instance, fitting a sphere is meaningless if the horizontal and vertical radii would be different physical
13550 quantities.
13551
13552 @since: 2.47
13553
13554 @return: B{C{True}} if the function requires the same lateral and value units. I{(bool)}
13555 """
13556 return None
13557
13559 """
13560 Reports the number of parameters of a 3D geometrical shape fitter preset.
13561
13562 @since: 2.47
13563
13564 @return: The number of function parameters. I{(int)}
13565 """
13566 return None
13567
13569 """
13570 Gets the name of a fitting parameter of a 3D geometrical shape fitter preset.
13571
13572 The name may contain Pango markup.
13573
13574 @since: 2.47
13575
13576 @param i: Parameter number. I{(int)}
13577 @return: The name of the B{C{i}}-th parameter. I{(string)}
13578 """
13579 return None
13580
13582 """
13583 Gets the description of a fitting parameter of a 3D geometrical shape fitter preset.
13584
13585 The description may contain Pango markup. It may also be B{C{None}} if the parameter is currently undescribed.
13586
13587 @since: 2.61
13588
13589 @param i: Parameter number. I{(int)}
13590 @return: The description of the B{C{i}}-th parameter, possibly B{C{None}}. I{(string)}
13591 """
13592 return None
13593
13595 """
13596 Gets the properties of a fitting parameter of a 3D geometrical shape fitter preset.
13597
13598 @since: 2.47
13599
13600 @param i: Parameter number. I{(int)}
13601 @return: The flags of the B{C{i}}-th parameter. I{(NLFitParamFlags)}
13602 """
13603 return None
13604
13606 """
13607 Derives the SI unit of a fitting parameter from the units of abscissa and ordinate.
13608
13609 Note that angle parameters are by default in radians and thus unitless. If you want to convert them to degrees for
13610 presentation to the user you must do it explicitly.
13611
13612 @since: 2.47
13613
13614 @param i: Parameter number. I{(int)}
13615 @param siunit_xy: SI unit of lateral coordinates. I{(L{SIUnit})}
13616 @param siunit_z: SI unit of values. I{(L{SIUnit})}
13617 @return: A newly created B{C{SIUnit}} with the units of the B{C{i}}-th parameter. I{(L{SIUnit})}
13618 """
13619 return None
13620
13622 """
13623 Gets the power of abscissa units in a shape fitting parameter.
13624
13625 Usually it is easier to let L{ShapeFitPreset.get_param_units}() derive the parameter units.
13626
13627 @since: 2.50
13628
13629 @param i: Parameter number. I{(int)}
13630 @return: The power of abscissa in the parameter. I{(int)}
13631 """
13632 return None
13633
13635 """
13636 Gets the power of ordinate units in a shape fitting parameter.
13637
13638 Usually it is easier to let L{ShapeFitPreset.get_param_units}() derive the parameter units.
13639
13640 @since: 2.50
13641
13642 @param i: Parameter number. I{(int)}
13643 @return: The power of ordinate in the parameter. I{(int)}
13644 """
13645 return None
13646
13648 """
13649 Reports the number of secondary (derived) quantities of a 3D geometrical shape fitter preset.
13650
13651 @since: 2.47
13652
13653 @return: The number of secondary quantities. I{(int)}
13654 """
13655 return None
13656
13658 """
13659 Gets the name of a secondary (derived) quantity of a 3D geometrical shape fitter preset.
13660
13661 The name may contain Pango markup.
13662
13663 @since: 2.47
13664
13665 @param i: Secondary quantity number. I{(int)}
13666 @return: The name of the B{C{i}}-th secondary quantity. I{(string)}
13667 """
13668 return None
13669
13671 """
13672 Gets the description of a secondary quantity of a 3D geometrical shape fitter preset.
13673
13674 The description may contain Pango markup. It may also be B{C{None}} if the quantity is currently undescribed.
13675
13676 @since: 2.61
13677
13678 @param i: Secondary quantity number. I{(int)}
13679 @return: The description of the B{C{i}}-th secondary quantity, possibly B{C{None}}. I{(string)}
13680 """
13681 return None
13682
13684 """
13685 Gets the properties of a secondary (derived) quantity of a 3D geometrical shape fitter preset.
13686
13687 @since: 2.47
13688
13689 @param i: Secondary quantity number. I{(int)}
13690 @return: The flags of the B{C{i}}-th secondary quantity. I{(NLFitParamFlags)}
13691 """
13692 return None
13693
13695 """
13696 Derives the SI unit of a secondary (derived) quantity from the units of abscissa and ordinate.
13697
13698 Note that angle parameters are by default in radians and thus unitless. If you want to convert them to degrees for
13699 presentation to the user you must do it explicitly.
13700
13701 @since: 2.47
13702
13703 @param i: Secondary quantity number. I{(int)}
13704 @param siunit_xy: SI unit of lateral coordinates. I{(L{SIUnit})}
13705 @param siunit_z: SI unit of values. I{(L{SIUnit})}
13706 @return: A newly created B{C{SIUnit}} with the units of the B{C{i}}-th secondary quantity. I{(L{SIUnit})}
13707 """
13708 return None
13709
13711 """
13712 Gets the power of abscissa units in a shape fitting secondary (derived) quantity.
13713
13714 Usually it is easier to let L{ShapeFitPreset.get_secondary_units}() derive the quantity units.
13715
13716 @since: 2.50
13717
13718 @param i: Secondary quantity number. I{(int)}
13719 @return: The power of abscissa in the secondary quantity. I{(int)}
13720 """
13721 return None
13722
13724 """
13725 Gets the power of ordinate units in a shape fitting secondary (derived) quantity.
13726
13727 Usually it is easier to let L{ShapeFitPreset.get_secondary_units}() derive the quantity units.
13728
13729 @since: 2.50
13730
13731 @param i: Secondary quantity number. I{(int)}
13732 @return: The power of ordinate in the secondary quantity. I{(int)}
13733 """
13734 return None
13735
13736 - def setup(points, n, params):
13737 """
13738 Initialises parameter values of a 3D geometrical shape fitter preset.
13739
13740 The parameters are quickly set to reasonable values that roughly correspond to the ranges of the data points. They
13741 may serve as starting values for manual experimentation but often will not be good enough as initial parameter
13742 estimates for the fit. See also L{ShapeFitPreset.guess}().
13743
13744 @since: 2.47
13745
13746 @param points: Array of XYZ data to fit. I{(const-XYZ*)}
13747 @param n: Number of data points. I{(int)}
13748 @param params: The array to fill with initialised parameter values. I{(gdouble*)}
13749 """
13750 pass
13751
13753 """
13754 Calculates the value of a 3D geometrical shape fitter preset in a single point.
13755
13756 If you want multiple values you should use either L{ShapeFitPreset.calculate_z}() or
13757 L{ShapeFitPreset.calculate_xyz}() instead of calling this function in a cycle.
13758
13759 @since: 2.47
13760
13761 @param x: X-coordinate. I{(float)}
13762 @param y: Y-coordinate. I{(float)}
13763 @param params: Fitting parameter values. I{(const-gdouble*)}
13764 @return: The calculated function value in (B{C{x}},B{C{y}}). I{(float)}
13765 """
13766 return None
13767
13768 - def fit(fitter, points, n, params, fixed_param, rss):
13769 """
13770 Performs a non-linear least-squares fit with a 3D geometrical shape fitter.
13771
13772 If you pass B{C{None}} B{C{fitter}} the function creates one for you and immediately performs the fit. If you want to modify
13773 the fitter settings beforehand or set callback functions create it using L{ShapeFitPreset.create_fitter}() and
13774 pass to this function. The fitter must be created for the same preset.
13775
13776 Additional quantities such as parameter errors or the correlation matrix can be obtained from the fitter. See
13777 L{gwy_math_nlfit_fit_full}() for details.
13778
13779 @since: 2.47
13780
13781 @param fitter: A Marquardt-Levenberg nonlinear fitter already initialized for B{C{preset}}'s function, or B{C{None}}. I{(MathNLFit*)}
13782 @param points: Array of B{C{n}} XYZ data defining the lateral coordinates and values to fit. I{(const-XYZ*)}
13783 @param n: Number of items in B{C{points}}. I{(int)}
13784 @param params: Fitting parameters filled with initial estimates (the fitting starts from the provided values). I{(gdouble*)}
13785 @param fixed_param: Which parameters should be treated as fixed (set corresponding element to B{C{True}} for them). May be
13786 B{C{None}} if all parameters are free. I{(const-gboolean*)}
13787 @param rss: Location to store the residual sum of squares, as returned by L{gwy_math_nlfit_fit_idx}(), may be B{C{None}}. I{(gdouble*)}
13788 @return: Either B{C{fitter}} itself, or a newly created fitter if it was B{C{None}}. I{(MathNLFit*)}
13789 """
13790 return None
13794 """
13795 Collection of dataline representing point spectra.
13796
13797
13798 B{C{Spectra}} contains an array of B{C{DataLines}} and coordinates
13799 representing where in a data field the spectrum was acquired.
13800
13801 """
13803 """
13804 Creates a new Spectra object containing zero spectra.
13805
13806 @since: 2.7
13807
13808 @return: A newly created spectra. I{(L{Spectra})}
13809 """
13810 return None
13811
13813 """
13814 Creates a new Spectra object similar to an existing one, but containing zero
13815 spectra.
13816
13817 Use L{Spectra.duplicate}() if you want to copy a spectra object including
13818 the spectra in it.
13819
13820 @since: 2.7
13821
13822 @return: A newly created Spectra object. I{(L{Spectra})}
13823 """
13824 return None
13825
13827 """
13828 Emits signal "data_changed" on a spectra object.
13829
13830 @since: 2.7
13831
13832 """
13833 pass
13834
13836 """
13837 Gets SI unit used for the location co-ordinates of spectra.
13838
13839 @since: 2.7
13840
13841 @return: SI unit corresponding to the the location co-ordinates of spectra
13842 object. Its reference count is not incremented. I{(L{SIUnit})}
13843 """
13844 return None
13845
13847 """
13848 Sets the SI unit corresponding to the location co-ordinates of the spectra
13849 object.
13850
13851 It does not assume a reference on B{C{si_unit}}, instead it adds its own
13852 reference.
13853
13854 @since: 2.7
13855
13856 @param si_unit: SI unit to be set. I{(L{SIUnit})}
13857 """
13858 pass
13859
13861 """
13862 Gets the coordinates of one spectrum.
13863
13864 @since: 2.7
13865
13866 @param i: Index of a spectrum. I{(int)}
13867 @return: Tuple consisting of 2 values (B{C{x}}, B{C{y}}). (I{(float)}, I{(float)})
13868 """
13869 return None, None
13870
13872 """
13873 Finds the index of the spectrum closest to the location specified by
13874 the coordinates x and y.
13875
13876 @since: 2.7
13877
13878 @param x: The x coordinate of the location of the spectrum. I{(float)}
13879 @param y: The y coordinate of the location of the spectrum. I{(float)}
13880 @return: The index of the nearest spectrum. If there are no curves in the
13881 spectra, -1 is returned. I{(int)}
13882 """
13883 return None
13884
13886 """
13887 Sets the location coordinates of a spectrum.
13888
13889 @since: 2.7
13890
13891 @param i: The index of a spectrum. I{(int)}
13892 @param x: The new x coordinate of the location of the spectrum. I{(float)}
13893 @param y: The new y coordinate of the location of the spectrum. I{(float)}
13894 """
13895 pass
13896
13898 """
13899 Gets the number of spectra in a spectra object.
13900
13901 @since: 2.7
13902
13903 @return: The number of spectra. I{(int)}
13904 """
13905 return None
13906
13908 """
13909 Gets a dataline that contains the spectrum at index i.
13910
13911 @since: 2.7
13912
13913 @param i: Index of a spectrum I{(int)}
13914 @return: A B{C{DataLine}} containing the spectrum, owned by B{C{spectra}}. I{(L{DataLine})}
13915 """
13916 return None
13917
13919 """
13920 Replaces the ith spectrum in the spectra object with a the
13921 supplied spectrum, new_spectrum. It takes its own reference
13922 to the New_Spectrum dataline.
13923
13924 @since: 2.7
13925
13926 @param i: Index of a spectrum to replace I{(int)}
13927 @param new_spectrum: A B{C{DataLine}} Object containing the new spectrum. I{(L{DataLine})}
13928 """
13929 pass
13930
13932 """
13933 Sets selected state of a spectrum in a spectra object.
13934
13935 @since: 2.7
13936
13937 @param i: Index of a spectrum. I{(int)}
13938 @param selected: B{C{True}} to make the spectrum selected, B{C{False}} to deselect it. I{(bool)}
13939 """
13940 pass
13941
13943 """
13944 Gets the selected state of a spectrum in a spectra object.
13945
13946 @since: 2.7
13947
13948 @param i: Index of a spectrum. I{(int)}
13949 @return: B{C{True}} if spectrum is selected. I{(bool)}
13950 """
13951 return None
13952
13954 """
13955 Appends a new_spectrum to the spectra collection with a position of x, y.
13956 L{Spectra.add} takes a refference to the supplied spectrum.
13957
13958 @since: 2.7
13959
13960 @param new_spectrum: A DataLine containing the spectrum to append. I{(L{DataLine})}
13961 @param x: The physical x coordinate of the location of the spectrum. I{(float)}
13962 @param y: The physical y coordinate of the location of the spectrum. I{(float)}
13963 """
13964 pass
13965
13967 """
13968 Removes the ith spectrum from the Spectra collection. The subsequent
13969 spectra are moved down one place.
13970
13971 @since: 2.7
13972
13973 @param i: Index of spectrum to remove. I{(int)}
13974 """
13975 pass
13976
13978 """
13979 Gets the title of spectra.
13980
13981 @since: 2.7
13982
13983 @return: A pointer to the title string (owned by the spectra object). I{(string)}
13984 """
13985 return None
13986
13988 """
13989 Sets the title of the spectra collection.
13990
13991 @since: 2.7
13992
13993 @param title: The new title string. I{(string)}
13994 """
13995 pass
13996
13998 """
13999 Gets the spectrum abscissa label of a spectra object.
14000
14001 @since: 2.40
14002
14003 @return: The abscissa label. The string is owned by B{C{spectra}} and must not
14004 be modified nor freed. I{(string)}
14005 """
14006 return None
14007
14009 """
14010 Sets the spectrum abscissa label of a spectra object.
14011
14012 @since: 2.40
14013
14014 @param label: New abscissa label. I{(string)}
14015 """
14016 pass
14017
14019 """
14020 Gets the spectrum ordinate label of a spectra object.
14021
14022 @since: 2.40
14023
14024 @return: The ordinate label. The string is owned by B{C{spectra}} and must not
14025 be modified nor freed. I{(string)}
14026 """
14027 return None
14028
14030 """
14031 Sets the spectrum ordinate label of a spectra object.
14032
14033 @since: 2.40
14034
14035 @param label: New ordinate label. I{(string)}
14036 """
14037 pass
14038
14040 """
14041 Removes all spectra from the collection.
14042
14043 @since: 2.7
14044
14045 """
14046 pass
14047
14049 """
14050 Gets the list of the indices to spectra ordered by their distance from a
14051 given point.
14052
14053 List positions
14054
14055 @since: 2.7
14056
14057 @param x: Point x-coordinate. I{(float)}
14058 @param y: Point y-coordinate. I{(float)}
14059 @param n: Number of indices to find. Array B{C{ilist}} must have at least this
14060 number of items. I{(int)}
14061 @return: I{(list)}
14062 """
14063 return None
14064
14066 """
14067 Convenience macro doing L{gwy_serializable_duplicate}() with all the necessary
14068 typecasting.
14069
14070 @since: 2.7
14071
14072 @return: I{(L{Spectra})}
14073 """
14074 return None
14075
14076
14079 """
14080 Creates a new Gwyddion statusbar.
14081
14082 Gwyddion statusbar differs from B{C{GtkStatusbar}} only in one thing: the
14083 messages can contain Pango markup.
14084
14085
14086 @return: The newly created statusbar, as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
14087 """
14088 return None
14089
14091 """
14092 Sets the text to display in a status bar.
14093
14094 This method is intended for simple status bars that do not have stacks and
14095 do not need contexts. It does not mix with gtk_statusbar_push(). You can
14096 use either this simple interface or the full stacks-and-contexts API with
14097 B{C{Statusbar}}, but not both in the same status bar.
14098
14099 @param markup: Text message to display in the statusbar. It can contain Pango
14100 markup. I{(string)}
14101 """
14102 pass
14106 """
14107 A string list object wrapper
14108
14109
14110 B{C{StringList}} object represents a reference-counted, serializable list of
14111 strings. The current interface is very minimal, more methods may be added
14112 later as needed.
14113
14114 """
14116 """
14117 Creates a new string list.
14118
14119
14120 @return: A new empty string list. I{(L{StringList})}
14121 """
14122 return None
14123
14125 """
14126 Appends a string to the end of a string list.
14127
14128 @param string: A string to add. I{(string)}
14129 """
14130 pass
14131
14133 """
14134 Appends a string to the end of a string list, taking ownership of the string.
14135
14136 @since: 2.35
14137
14138 @param string: A string to add. I{(string)}
14139 """
14140 pass
14141
14143 """
14144 Gets the number of strings in a string list.
14145
14146
14147 @return: The number of strings in B{C{strlist}}. I{(int)}
14148 """
14149 return None
14150
14152 """
14153 Gets a string from a string list by position.
14154
14155
14156 @param i: The position of string to get. I{(int)}
14157 @return: The string, owned by B{C{strlist}}. It is valid only until B{C{strlist}}
14158 changes. I{(string)}
14159 """
14160 return None
14161
14163 """
14164 Clears the contents of a string list, removing all strings.
14165
14166 @since: 2.35
14167
14168 """
14169 pass
14170
14172 """
14173 Convenience macro doing L{gwy_serializable_duplicate}() with all the necessary
14174 typecasting.
14175
14176 @return: I{(L{StringList})}
14177 """
14178 return None
14179
14180
14182 """
14183 General two-dimensional data
14184
14185
14186 B{C{Surface}} represents general, i.e. possibly unevenly spaced, two-dimensional data, also called XYZ data.
14187
14188 Surface points are stored in a flat array B{C{Surface}}-struct.data of B{C{XYZ}} values.
14189
14190 Unlike B{C{DataField}}, a surface can also be empty, i.e. contain zero points.
14191
14192 """
14194 """
14195 Creates a new empty surface.
14196
14197 The surface will not contain any points. This parameterless constructor exists mainly for language bindings,
14198 L{Surface.new_from_data}() is usually more useful.
14199
14200 @since: 2.45
14201
14202 @return: A new empty surface. I{(L{Surface})}
14203 """
14204 return None
14205
14207 """
14208 Creates a new empty surface similar to another surface.
14209
14210 The units of the new surface will be identical to those of B{C{model}} but the new surface will not contain any points.
14211 Use L{Surface.duplicate}() to completely duplicate a surface including data.
14212
14213 @since: 2.45
14214
14215 @return: A new empty surface. I{(L{Surface})}
14216 """
14217 return None
14218
14219 - def new_part(xfrom, xto, yfrom, yto):
14220 """
14221 Creates a new surface as a part of another surface.
14222
14223 The new surface consits of data with lateral coordinates within the specified ranges (inclusively). It may be
14224 empty.
14225
14226 Data are physically copied, i.e. changing the new surface data does not change B{C{surface}}'s data and vice versa.
14227
14228 @since: 2.45
14229
14230 @param xfrom: Minimum x-coordinate value. I{(float)}
14231 @param xto: Maximum x-coordinate value. I{(float)}
14232 @param yfrom: Minimum y-coordinate value. I{(float)}
14233 @param yto: Maximum y-coordinate value. I{(float)}
14234 @return: A new surface. I{(L{Surface})}
14235 """
14236 return None
14237
14239 """
14240 Gets the raw XYZ data array of a surface.
14241
14242 The returned buffer is not guaranteed to be valid through whole data surface life time.
14243
14244 This function invalidates any cached information, use L{Surface.get_data_const}() if you are not going to change
14245 the data.
14246
14247 See L{Surface.invalidate}() for some discussion.
14248
14249 @since: 2.45
14250
14251 @return: The surface XYZ data as a pointer to an array of L{Surface.get_npoints}() items. I{(L{XYZ})}
14252 """
14253 return None
14254
14256 """
14257 Gets the number of points in an XYZ surface.
14258
14259 @since: 2.45
14260
14261 @return: The number of points. I{(int)}
14262 """
14263 return None
14264
14266 """
14267 Emits signal Surface::data-changed on a surface.
14268
14269 @since: 2.45
14270
14271 """
14272 pass
14273
14275 """
14276 Copies the data of a surface to another surface of the same dimensions.
14277
14278 Only the data points are copied. To make a surface completely identical to another, including units and change of
14279 dimensions, you can use L{Surface.clone}().
14280
14281 @since: 2.45
14282
14283 @param dest: Destination surface. I{(L{Surface})}
14284 """
14285 pass
14286
14288 """
14289 Invalidates cached surface statistics.
14290
14291 Cached statistics include ranges returned by L{Surface.get_xrange}(), L{Surface.get_yrange}() and
14292 L{Surface.get_min_max}(), the fingerprint for L{Surface.xy_is_compatible}() and and possibly other
14293 characteristics in the future.
14294
14295 See L{DataField.invalidate}() for discussion of invalidation and examples.
14296
14297 @since: 2.45
14298
14299 """
14300 pass
14301
14303 """
14304 Fills the data of a surface from a data field.
14305
14306 The number of points in the new surface will be equal to the number of points in the field. Lateral coordinates
14307 will be equal to the corresponding B{C{data_field}} coordinates; values will be created in regular grid according to
14308 B{C{data_field}}'s physical size and offset.
14309
14310 Lateral and value units will correspond to B{C{data_field}}'s units. This means the field needs to have identical B{C{x}}
14311 and B{C{y}} units.
14312
14313 @since: 2.45
14314
14315 @param data_field: A two-dimensional data field. I{(L{DataField})}
14316 """
14317 pass
14318
14320 """
14321 Fills the data of a surface from a data field, possibly using masking.
14322
14323 @since: 2.46
14324
14325 @param data_field: A two-dimensional data field. I{(L{DataField})}
14326 @param mask: Mask of pixels to include from/exclude, or B{C{None}} I{(L{DataField})}
14327 @param masking: Masking mode to use. Expected values: C{B{MASK_EXCLUDE}}, C{B{MASK_INCLUDE}}, C{B{MASK_IGNORE}}. I{(L{MaskingType})}
14328 """
14329 pass
14330
14332 """
14333 Returns lateral SI unit of a surface.
14334
14335 @since: 2.45
14336
14337 @return: SI unit corresponding to the lateral (XY) dimensions of the surface. Its reference count is not
14338 incremented. I{(L{SIUnit})}
14339 """
14340 return None
14341
14343 """
14344 Returns value SI unit of a surface.
14345
14346 @since: 2.45
14347
14348 @return: SI unit corresponding to the "height" (Z) dimension of the surface. Its reference count is not
14349 incremented. I{(L{SIUnit})}
14350 """
14351 return None
14352
14354 """
14355 Sets the SI unit corresponding to the lateral (XY) dimensions of a surface.
14356
14357 It does not assume a reference on B{C{si_unit}}, instead it adds its own reference.
14358
14359 @since: 2.45
14360
14361 @param si_unit: SI unit to be set. I{(L{SIUnit})}
14362 """
14363 pass
14364
14366 """
14367 Sets the SI unit corresponding to the "height" (Z) dimension of a surface.
14368
14369 It does not assume a reference on B{C{si_unit}}, instead it adds its own reference.
14370
14371 @since: 2.45
14372
14373 @param si_unit: SI unit to be set. I{(L{SIUnit})}
14374 """
14375 pass
14376
14387
14398
14400 """
14401 Sets lateral and value units of a surface to match another surface.
14402
14403 @since: 2.49
14404
14405 @param target: Target surface. I{(L{Surface})}
14406 """
14407 pass
14408
14410 """
14411 Sets lateral and value units of a data field to match a surface.
14412
14413 @since: 2.46
14414
14415 @param data_field: A two-dimensional data field. I{(L{DataField})}
14416 """
14417 pass
14418
14420 """
14421 Obtains a single surface point.
14422
14423 This function exists I{only for language bindings} as it is very slow compared to simply
14424 accessing B{C{data}} in B{C{Surface}} directly in C.
14425
14426 @since: 2.45
14427
14428 @param pos: Position in B{C{surface}}. I{(int)}
14429 @return: The point at B{C{pos}}. I{(XYZ)}
14430 """
14431 return None
14432
14434 """
14435 Gets the range of X coordinates of a surface.
14436
14437 This information is cached.
14438
14439 @since: 2.45
14440
14441 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
14442 """
14443 return None, None
14444
14446 """
14447 Gets the range of Y coordinates of a surface.
14448
14449 This information is cached.
14450
14451 @since: 2.45
14452
14453 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
14454 """
14455 return None, None
14456
14458 """
14459 Gets the range of Z values of a surface.
14460
14461 This information is cached.
14462
14463 @since: 2.45
14464
14465 @return: Tuple consisting of 2 values (B{C{min}}, B{C{max}}). (I{(float)}, I{(float)})
14466 """
14467 return None, None
14468
14470 """
14471 Puts back values from a flat array to an entire data surface.
14472
14473 If you do not have an array of B{C{XYZ}} and want to fill the data sequentially, use L{Surface.resize}() and
14474 L{Surface.get_data}().
14475
14476 See L{Surface.get_data_full}() for a discussion.
14477
14478 @since: 2.45
14479
14480 @param points: Data points to copy to the surface. They replace whatever points are in B{C{surface}} now. I{(const-XYZ*)}
14481 @param n: The number of points in B{C{data}}. I{(int)}
14482 """
14483 pass
14484
14486 """
14487 Checks whether the XY positions of two surfaces are compatible.
14488
14489 Compatible XY positions mean the XY units are the same and the points are the same. Two surfaces that have the
14490 same set of XY points but in different orders are I{not} considered compatible. This is because
14491 the points at the same index in B{C{data}} are different and thus calculations involving data from the two surfaces are
14492 impossible. It is necessary to match the points order in the two surfaces to make this possible.
14493
14494 This information is cached.
14495
14496 @since: 2.45
14497
14498 @param othersurface: Another surface. I{(L{Surface})}
14499 @return: B{C{True}} if the surfaces are XY-position compatible, B{C{False}} if they are not. I{(bool)}
14500 """
14501 return None
14502
14504 """
14505 Creates a similar surface with smaller number of points.
14506
14507 The functions attempts to choose points from the original surface to cover its full area, even though points from
14508 dense regions are still more likely to be found in the result than points from sparse regions. As the main purpose
14509 to enable quick rough operations that may take long time with the full surface, the focus is on speed not fidelity.
14510
14511 The function may employ random selection and thus be be non-deterministic.
14512
14513 @since: 2.48
14514
14515 @param npoints: Requested number of points in the reduced surface. If it is not smaller than the number of points in
14516 B{C{surface}} then the function behaves like L{Surface.duplicate}(). I{(int)}
14517 @return: A newly created B{C{Surface}} with reduced number of points. I{(L{Surface})}
14518 """
14519 return None
14520
14522 """
14523 Changes the number of points in a surface.
14524
14525 If the number of points decreases then the first B{C{npoints}} points will be kept. If the number of points increases
14526 the new points will be uninitialised. Although usually you would overwrite all the points after using this
14527 function.
14528
14529 Use L{Surface.set_data_full}() if you already have an array of B{C{XYZ}} to fill the surface data with.
14530
14531 @since: 2.61
14532
14533 @param npoints: New number of points in the surface. I{(int)}
14534 """
14535 pass
14536
14537 - def set(pos, point):
14538 """
14539 Sets a single surface value.
14540
14541 This function exists I{only for language bindings} as it is very slow compared to simply
14542 accessing B{C{data}} in B{C{Surface}} directly in C.
14543
14544 @since: 2.45
14545
14546 @param pos: Position in B{C{surface}}. I{(int)}
14547 @param point: Point to store at given position. I{(const-XYZ*)}
14548 """
14549 pass
14550
14552 """
14553 Duplicates a surface.
14554
14555 This is a convenience wrapper of L{gwy_serializable_duplicate}().
14556
14557 @since: 2.45
14558
14559 @return: I{(L{Surface})}
14560 """
14561 return None
14562
14563
14566 """
14567 Creates a new B{C{VRuler}}.
14568
14569
14570 @return: The new ruler as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
14571 """
14572 return None
14577 """
14578 Sets the selection object to use by a vector layer.
14579
14580 @param key: Container string key identifying the selection object. I{(string)}
14581 """
14582 pass
14583
14585 """
14586 Gets the key identifying selection this vector layer displays.
14587
14588
14589 @return: The string key, or B{C{None}} if it isn't set. I{(string)}
14590 """
14591 return None
14592
14594 """
14595 Ensures a vector layer's selection exist in data container.
14596
14597 This method can be called only when layer is plugged into a data view and it
14598 has a selection key set. If the data container contains a selection under
14599 the specified key the selection is returned. If there is none,
14600 a selection of appropriate type is created and put to the container first.
14601
14602 Provided the above conditions are met this method is suitable for just
14603 obtaining the selection object a vector layer uses too.
14604
14605
14606 @return: The layer's selection (no reference is added). I{(L{Selection})}
14607 """
14608 return None
14609
14611 """
14612 Gets focused object index.
14613
14614
14615 @return: Focued object index, or -1 if no object is focused. I{(int)}
14616 """
14617 return None
14618
14620 """
14621 Focues on one selection object.
14622
14623 When a selection object is focused, it becomes the only one user can
14624 interact with. More precisely, "object-chosen" signal is emitted only
14625 for this object, and if the layer is editable only this object can be
14626 modified by the user.
14627
14628
14629 @param focus: Index of object to focus on, use -1 to unfocus (allow interaction
14630 with any object). I{(int)}
14631 @return: B{C{True}} if the object was focused, B{C{False}} on failure. Failure can
14632 be caused by user currently moving another object, wrong object
14633 index, or the feature being unimplemented in B{C{layer}}. I{(bool)}
14634 """
14635 return None
14636
14638 """
14639 Gets editability of a vector layer.
14640
14641
14642 @return: B{C{True}} if layer is edtiable, B{C{False}} if it is not editable. I{(bool)}
14643 """
14644 return None
14645
14647 """
14648 Sets a vector layer editability.
14649
14650 It is an error to attempt to set a layer non-editabile while it is being
14651 edited.
14652
14653 When a layer is set noneditable, the user cannot change the selection.
14654 However, "object-chosen" signal is still emitted.
14655
14656 @param editable: B{C{True}} to set layer editable, B{C{False}} to set it noneditable. I{(bool)}
14657 """
14658 pass
14659
14660 - def draw(drawable, target):
14661 """
14662 Draws B{C{layer}} on given drawable (which should be a B{C{DataView}} window).
14663
14664 @param drawable: A drawable to draw on. I{(L{gdk.Drawable})}
14665 @param target: Rendering target. Expected values: C{B{RENDERING_TARGET_SCREEN}}, C{B{RENDERING_TARGET_PIXMAP_IMAGE}}. I{(L{RenderingTarget})}
14666 """
14667 pass
14668
14670 """
14671 Emits "object-chosen" signal on a vector layer.
14672
14673 This function is primarily intended for layer implementations.
14674
14675 @param id: Index of the chosen object. I{(int)}
14676 """
14677 pass
14678
14680 """
14681 Gets the selection type of a vector layer.
14682
14683 This is a convenience wrapper around
14684 L{VectorLayer.class_get_selection_type}().
14685
14686 @return: I{(GType)}
14687 """
14688 return None
14692 """
14693 Representation of Cartesian coordinates in plane.
14694
14695 @since: 2.45
14696
14697 """
14699 """
14700 Creates Cartesian coordinates in plane.
14701
14702 This is mostly useful for language bindings.
14703
14704 @since: 2.47
14705
14706 @param x: X-coordinate. I{(float)}
14707 @param y: Y-coordinate. I{(float)}
14708 @return: New XY structure. The result must be freed using L{XY.free}(), not g_free(). I{(L{XY})}
14709 """
14710 return None
14711
14713 """
14714 Copies Cartesian coordinates in plane.
14715
14716 @since: 2.45
14717
14718 @return: A copy of B{C{xy}}. The result must be freed using L{XY.free}(), not g_free(). I{(L{XY})}
14719 """
14720 return None
14721
14723 """
14724 Frees Cartesian coordinates in plane created with L{XY.copy}().
14725
14726 @since: 2.45
14727
14728 """
14729 pass
14730
14731
14733 """
14734 Representation of Cartesian coordinates in space.
14735
14736 @since: 2.45
14737
14738 """
14740 """
14741 Creates Cartesian coordinates in space.
14742
14743 This is mostly useful for language bindings.
14744
14745 @since: 2.47
14746
14747 @param x: X-coordinate. I{(float)}
14748 @param y: Y-coordinate. I{(float)}
14749 @param z: Z-coordinate. I{(float)}
14750 @return: New XYZ structure. The result must be freed using L{XY.free}(), not g_free(). I{(L{XYZ})}
14751 """
14752 return None
14753
14755 """
14756 Copies Cartesian coordinates in space.
14757
14758 @since: 2.45
14759
14760 @return: A copy of B{C{xyz}}. The result must be freed using L{XY.free}(), not g_free(). I{(L{XYZ})}
14761 """
14762 return None
14763
14765 """
14766 Frees Cartesian coordinates in space created with L{XY.copy}().
14767
14768 @since: 2.45
14769
14770 """
14771 pass
14772
14773
14775 """
14776 Bit depth independet RGBA colors
14777
14778
14779 B{C{RGBA}} is a bit depth independent representation of an RGB or RGBA color,
14780 using floating point values from the [0,1] interval.
14781
14782 B{C{RGBA}} is not an object, but a simple struct that can be allocated on
14783 stack on created with g_new() or malloc(). Helper functions for conversion
14784 between B{C{RGBA}} and B{C{GdkColor}} (L{RGBA.to_gdk_color}(),
14785 L{RGBA.from_gdk_color}()) and for B{C{Container}} storage by component
14786 (L{RGBA.store_to_container}(), L{RGBA.get_from_container}()) are provided.
14787
14788 """
14790 """
14791 Creates RGBA colour specification.
14792
14793 This is mostly useful for language bindings.
14794
14795 @since: 2.47
14796
14797 @param r: The red component. I{(float)}
14798 @param g: The green component. I{(float)}
14799 @param b: The blue component. I{(float)}
14800 @param a: The alpha (opacity) value. I{(float)}
14801 @return: New RGBA colour structure. The result must be freed with
14802 L{RGBA.free}(), not g_free(). I{(L{RGBA})}
14803 """
14804 return None
14805
14807 """
14808 Makes a copy of a rgba structure. The result must be freed using
14809 L{RGBA.free}().
14810
14811
14812 @return: A copy of B{C{rgba}}. I{(L{RGBA})}
14813 """
14814 return None
14815
14817 """
14818 Frees an rgba structure created with L{RGBA.copy}().
14819
14820 """
14821 pass
14822
14824 """
14825 Converts a rgba to a Gdk opacity value.
14826
14827
14828 @return: The opacity value as a 16bit integer. I{(guint16)}
14829 """
14830 return None
14831
14833 """
14834 Linearly interpolates two colors, including alpha blending.
14835
14836 Correct blending of two not fully opaque colors is tricky. Always use
14837 this function, not simple independent interpolation of r, g, b, and a.
14838
14839 @param src2: Color at point B{C{x}} = 1.0. I{(const-RGBA*)}
14840 @param x: Point in interval 0..1 to take color from. I{(float)}
14841 @param rgba: A B{C{RGBA}} to store the result to. I{(L{RGBA})}
14842 """
14843 pass
14844
14846 """
14847 Gets RGBA color components from a container.
14848
14849 This is a convenience function to get the components in the common
14850 arrangement.
14851
14852
14853 @param container: A B{C{Container}} to get the color components from. I{(L{Container})}
14854 @param prefix: Prefix in B{C{container}}, e.g. "/0/mask" (it would try to fetch
14855 "/0/mask/red", "/0/mask/green", etc. then). I{(string)}
14856 @return: Whether all B{C{rgba}} components were successfully found and set. I{(bool)}
14857 """
14858 return None
14859
14861 """
14862 Stores RGBA color components to a container.
14863
14864 This is a convenience function to store the components in the common
14865 arrangement.
14866
14867 @param container: A B{C{Container}} to store the color components to. I{(L{Container})}
14868 @param prefix: Prefix in B{C{container}}, e.g. "/0/mask" (it will store
14869 "/0/mask/red", "/0/mask/green", etc. then). I{(string)}
14870 """
14871 pass
14872
14874 """
14875 Sets foreground color of a Gdk graphics context from a RGBA color.
14876
14877 This is a convenience wrapper around gdk_gc_set_rgb_fg_color(), see its
14878 documentation for details and caveats.
14879
14880 @param gc: A Gdk graphics context to set forgeground color of. I{(L{gdk.GC})}
14881 """
14882 pass
14883
14885 """
14886 Sets foreground color of a Gdk graphics context from a RGBA color.
14887
14888 This is a convenience wrapper around gdk_gc_set_rgb_bg_color(), see its
14889 documentation for details and caveats.
14890
14891 @param gc: A Gdk graphics context to set forgeground color of. I{(L{gdk.GC})}
14892 """
14893 pass
14894
14896 """
14897 Formats the R, G and B components of a RGBA color to hexadecimal string.
14898
14899 The component order is R, G and B. The output has always exactly 6 bytes
14900 and does not include any "#" prefix which is used in some contexts.
14901
14902 @since: 2.32
14903
14904 @param hexout: Buffer at least seven character long where the hexadecimal
14905 representation (e.g. "ff0000" for red) will be stored. I{(string)}
14906 """
14907 pass
14908
14910 """
14911 Formats all components of a RGBA color to hexadecimal string.
14912
14913 The component order is A, R, G and B. Note that while this order is a
14914 common it is by no means universal. The output has always exactly 8 bytes
14915 and does not include any "#" prefix which is used in some contexts.
14916
14917 @since: 2.32
14918
14919 @param hexout: Buffer at least nine character long where the hexadecimal
14920 representation (e.g. "ffff0000" for opaque red) will be stored. I{(string)}
14921 """
14922 pass
14923
14925 """
14926 Converts a RGBA color to pixbuf pixel.
14927
14928 The returned pixel value includes opacity. If B{C{rgba}} is partially
14929 transparent, so is the pixel.
14930
14931 @since: 2.49
14932
14933 @return: The pixel value as a 32-bit integer. I{(guint32)}
14934 """
14935 return None
14936
14938 """
14939 Converts a pixbuf pixel value to a RGBA color.
14940
14941 The conversion includes opacity. If the opacity channel is undefined or
14942 should be ignored, you need to either set the lowest byte of B{C{pixel}} to 0xff
14943 or fix B{C{rgba}} afterwards.
14944
14945 @since: 2.49
14946
14947 @param pixel: Pixbuf pixel value as a 32-bit integer. I{(guint32)}
14948 """
14949 pass
14950
14951
14953 """
14954 Auxiliary structure representing one data item in an open file.
14955
14956 The data container number can be obtained with L{gwy_app_data_browser_get}() and used to look up the container with
14957 L{gwy_app_data_browser_get_number}().
14958
14959 @since: 2.41
14960
14961 """
14963 """
14964 Creates a new data identifier on heap.
14965
14966 This is mostly useful for language bindings.
14967
14968 @since: 2.47
14969
14970 @param datano: Numeric identifier of data container. Zero is used for none. I{(int)}
14971 @param id: Numeric identifier of a specific data item, such as channel or graph number. Value -1 is used for none. I{(int)}
14972 @return: Newly allocated data id. It must be freed with L{AppDataId.free}(). I{(L{AppDataId})}
14973 """
14974 return None
14975
14977 """
14978 Creates a copy of data identifier.
14979
14980 This is mostly useful for language bindings.
14981
14982 @since: 2.47
14983
14984 @return: Newly allocated data id. It must be freed with L{AppDataId.free}(). I{(L{AppDataId})}
14985 """
14986 return None
14987
14989 """
14990 Frees a data identifier.
14991
14992 This is mostly useful for language bindings.
14993
14994 @since: 2.47
14995
14996 """
14997 pass
14998
15000 """
15001 Checks if numerical channel identifiers correspond to an existing channel.
15002
15003 If either the data contained referenced in B{C{id}} or the channel does not exist the structure is cleared to
15004 B{C{APP_DATA_ID_NONE}} and the function returns B{C{False}}. If it represents an existing channel it is kept intact and
15005 the function returns B{C{True}}.
15006
15007 @since: 2.41
15008
15009 @return: Whether B{C{id}} refers to an existing channel now. I{(bool)}
15010 """
15011 return None
15012
15014 """
15015 Checks if numerical graph identifiers correspond to an existing graph.
15016
15017 If either the data contained referenced in B{C{id}} or the graph model does not exist the structure is cleared to
15018 B{C{APP_DATA_ID_NONE}} and the function returns B{C{False}}. If it represents an existing graph it is kept intact and
15019 the function returns B{C{True}}.
15020
15021 @since: 2.41
15022
15023 @return: Whether B{C{id}} refers to an existing graph now. I{(bool)}
15024 """
15025 return None
15026
15028 """
15029 Checks if numerical volume data identifiers correspond to existing volume data.
15030
15031 If either the data contained referenced in B{C{id}} or the volume data does not exist the structure is cleared to
15032 B{C{APP_DATA_ID_NONE}} and the function returns B{C{False}}. If it represents existing volume data it is kept intact and
15033 the function returns B{C{True}}.
15034
15035 @since: 2.41
15036
15037 @return: Whether B{C{id}} refers to existing volume data now. I{(bool)}
15038 """
15039 return None
15040
15042 """
15043 Checks if numerical XYZ data identifiers correspond to existing XYZ data.
15044
15045 If either the data contained referenced in B{C{id}} or the XYZ data does not exist the structure is cleared to
15046 B{C{APP_DATA_ID_NONE}} and the function returns B{C{False}}. If it represents existing XYZ data it is kept intact and
15047 the function returns B{C{True}}.
15048
15049 @since: 2.46
15050
15051 @return: Whether B{C{id}} refers to existing XYZ data now. I{(bool)}
15052 """
15053 return None
15054
15056 """
15057 Checks if numerical curve map data identifiers correspond to existing curve map data.
15058
15059 If either the data contained referenced in B{C{id}} or the curve map data does not exist the structure is cleared to
15060 B{C{APP_DATA_ID_NONE}} and the function returns B{C{False}}. If it represents existing curve map data it is kept intact
15061 and the function returns B{C{True}}.
15062
15063 @since: 2.46
15064
15065 @return: Whether B{C{id}} refers to existing curve map data now. I{(bool)}
15066 """
15067 return None
15068
15070 """
15071 Checks if numerical spectra identifiers correspond to existing spectra.
15072
15073 If either the data contained referenced in B{C{id}} or the spectra does not exist the structure is cleared to
15074 B{C{APP_DATA_ID_NONE}} and the function returns B{C{False}}. If it represents existing spectra it is kept intact and the
15075 function return B{C{True}}.
15076
15077 @since: 2.41
15078
15079 @return: Whether B{C{id}} refers to existing spectra now. I{(bool)}
15080 """
15081 return None
15082
15083
15109
15110
15112 """
15113 Graph peak analyser
15114
15115
15116 One B{C{Peaks}} analyser can be used repeatedly to find and characterise peaks in several data sets.
15117
15118 Feed the curve data to the analyser using functions such as L{Peaks.analyze}(), L{Peaks.analyze_dataline}() or
15119 L{Peaks.analyze_xy}(). It will process the data, locate peaks and remember their various characteristics that you
15120 can subsequently obtain using L{Peaks.get_quantity}(). The results are static; if you change the analyser
15121 settings (or the curve data) you need to re-run the analysis function.
15122
15123 """
15125 """
15126 Creates a new empty peak analyser.
15127
15128 @since: 2.46
15129
15130 @return: A new peak analyser. I{(L{Peaks})}
15131 """
15132 return None
15133
15135 """
15136 Creates a copy of a peak analyser.
15137
15138 This is mostly useful for language bindings.
15139
15140 @since: 2.47
15141
15142 @return: A newly created peak analyser. I{(L{Peaks})}
15143 """
15144 return None
15145
15147 """
15148 Frees a peak analyser and all associated data.
15149
15150 @since: 2.46
15151
15152 """
15153 pass
15154
15156 """
15157 Sets the background type a peak analyser will use.
15158
15159 The default background is B{C{PEAK_BACKGROUND_MMSTEP}}. Note that the new background type will only be used in
15160 future analyses; it does not change the results of the already performed analysis.
15161
15162 @since: 2.46
15163
15164 @param background: Background type to use in future analyses. Expected values: C{B{PEAK_BACKGROUND_ZERO}}, C{B{PEAK_BACKGROUND_MMSTEP}}. I{(L{PeakBackgroundType})}
15165 """
15166 pass
15167
15169 """
15170 Sets the order type a peak analyser will use.
15171
15172 The default order is B{C{PEAK_ORDER_ABSCISSA}}. Note that the new order will only be effective in future analyses;
15173 it does not change the results of the already performed analysis.
15174
15175 @since: 2.46
15176
15177 @param order: Order type to use in future analyses. Expected values: C{B{PEAK_ORDER_ABSCISSA}}, C{B{PEAK_ORDER_PROMINENCE}}. I{(L{PeakOrderType})}
15178 """
15179 pass
15180
15182 """
15183 Finds peaks a graph curve given as XY data.
15184
15185 The peaks are remembered by the analyser and their properties can be subsequently requested using
15186 L{Peaks.get_quantity}().
15187
15188 @since: 2.46
15189
15190 @param xydata: Curve points (array with B{C{n}} items) that must be ordered by B{C{x}} values in ascending order. I{(const-XY*)}
15191 @param n: Number of data points in the curve. I{(int)}
15192 @param maxpeaks: Maximum number of the most prominent peaks to locate. I{(int)}
15193 @return: The number of peaks found. I{(int)}
15194 """
15195 return None
15196
15198 """
15199 Finds peaks a graph curve given as DataLine.
15200
15201 The peaks are remembered by the analyser and their properties can be subsequently requested using
15202 L{Peaks.get_quantity}().
15203
15204 @since: 2.46
15205
15206 @param dline: Curve data as a data line. I{(L{DataLine})}
15207 @param maxpeaks: Maximum number of the most prominent peaks to locate. I{(int)}
15208 @return: The number of peaks found. I{(int)}
15209 """
15210 return None
15211
15213 """
15214 Gets the current number of peaks of a peak analyser.
15215
15216 @since: 2.46
15217
15218 @return: The currently remembered number of peaks. I{(int)}
15219 """
15220 return None
15221
15222 - def analyze(xdata, ydata, maxpeaks):
15223 """
15224 Finds peaks a graph curve given as separated B{C{x}} and B{C{y}} data.
15225
15226 The peaks are remembered by the analyser and their properties can be subsequently requested using
15227 L{Peaks.get_quantity}().
15228
15229 @since: 2.46
15230
15231 @param xdata: Abscissa values (array with B{C{n}} items), must be ordered in ascending order. I{(list)}
15232 @param ydata: Ordinate values corresponding to B{C{xdata}}. I{(list)}
15233 @param maxpeaks: Maximum number of the most prominent peaks to locate. I{(int)}
15234 @return: Value B{C{npeaks}}. (I{(int)})
15235 """
15236 return None
15237
15239 """
15240 Obtaines values of a given quantity for all found peaks.
15241
15242 @since: 2.46
15243
15244 @param quantity: Peak property to return. Expected values: C{B{PEAK_PROMINENCE}}, C{B{PEAK_ABSCISSA}}, C{B{PEAK_HEIGHT}}, C{B{PEAK_AREA}}, C{B{PEAK_WIDTH}}. I{(L{PeakQuantity})}
15245 @return: I{(list)}
15246 """
15247 return None
15248
15249
15252 """
15253 Creates a new empty spline curve.
15254
15255 You need to set the curve points using L{Spline.set_points}() before any
15256 sampling along the curve. Alternatively, use L{Spline.new_from_points}()
15257 to construct the spline already with some points.
15258
15259 @since: 2.45
15260
15261 @return: A newly created spline curve. I{(L{Spline})}
15262 """
15263 return None
15264
15266 """
15267 Frees a spline curve and all associated resources.
15268
15269 @since: 2.45
15270
15271 """
15272 pass
15273
15275 """
15276 Creates a copy of a spline curve.
15277
15278 @since: 2.49
15279
15280 @return: A newly created spline curve. I{(L{Spline})}
15281 """
15282 return None
15283
15285 """
15286 Gets the number of points of a spline curve.
15287
15288 @since: 2.45
15289
15290 @return: The number of XY points defining the curve. I{(int)}
15291 """
15292 return None
15293
15295 """
15296 Gets the slackness parameter of a spline curve.
15297
15298 See L{Spline.set_slackness}() for discussion.
15299
15300 @since: 2.45
15301
15302 @return: The slackness parameter value. I{(float)}
15303 """
15304 return None
15305
15307 """
15308 Reports whether a spline curve is closed or not.
15309
15310 See L{Spline.set_closed}() for discussion.
15311
15312 @since: 2.45
15313
15314 @return: B{C{True}} if B{C{spline}} is closed, B{C{False}} if it is open-ended. I{(bool)}
15315 """
15316 return None
15317
15319 """
15320 Sets the coordinates of XY points a spline curve should pass through.
15321
15322 It is possible to pass B{C{n}}=0 to make the spline empty (B{C{xy}} can be B{C{None}} then)
15323 but such spline may not be sampled using L{Spline.sample_uniformly}().
15324
15325 The coordinates should be device-scaled, i.e. they should data field rows
15326 and columns, or screen or image pixels. Generally, the unit length should
15327 be about the smallest distinguishable distance.
15328
15329 This is important namely for L{Spline.sample_naturally}() that stops
15330 refining the curve when the details become too tiny, even though there may
15331 be sharp changes of direction. It is also important if the physical X and Y
15332 scales differ.
15333
15334 Using unscaled physical coordinates may produce odd results.
15335
15336 @since: 2.45
15337
15338 @param xy: Array of points in plane the curve will pass through. I{(const-XY*)}
15339 @param n: Number of points in B{C{xy}}. I{(int)}
15340 """
15341 pass
15342
15344 """
15345 Sets the slackness parameter of a spline curve.
15346
15347 The slackness parameter determines how taut or slack the curve is.
15348
15349 The curve always passes through the given XY points. For zero slackness
15350 the curve is maximally taut, i.e. the shortest possible passing
15351 through the points. Such curve is formed by straight segments. For
15352 slackness of 1 the curve is a ‘free’ spline. Values smaller than 1 mean
15353 tensile stress while values larger than 1 compressive stres. The default
15354 value is 1/sqrt(2).
15355
15356 @since: 2.45
15357
15358 @param slackness: New slackness parameter value from the range [0, B{C{glib.SQRT2}}]. I{(float)}
15359 """
15360 pass
15361
15363 """
15364 Sets whether a spline curve is closed or open.
15365
15366 In closed curve the last point is connected smoothly with the first point,
15367 forming a cycle. Note you should not repeat the point in the B{C{xy}} array.
15368 When a closed curve is sampled, the sampling starts from the first point
15369 and continues beyond the last point until it gets close to the first point
15370 again.
15371
15372 An open curve begins with the first point and ends with the last point. It
15373 has zero curvature at these two points.
15374
15375 @since: 2.45
15376
15377 @param closed: B{C{True}} to make B{C{spline}} closed, B{C{False}} to make it open-ended. I{(bool)}
15378 """
15379 pass
15380
15382 """
15383 Calculates the length of a spline curve.
15384
15385 This is useful when you want to sample the curve with a specific step
15386 (at least approximately).
15387
15388 Note L{Spline.sample_uniformly}() also returns the length.
15389
15390 @since: 2.45
15391
15392 @return: The curve length. I{(float)}
15393 """
15394 return None
15395
15397 """
15398 Gets the coordinates of spline curve points.
15399
15400 If the spline is empty (there are no points) the function returns B{C{None}}.
15401
15402 @since: 2.45
15403
15404 @return: Coordinates of the XY points defining the curve. The returned
15405 array is owned by B{C{spline}}, must not be modified and is only
15406 guaranteed to exist so long as the spline is not modified nor
15407 destroyed. I{(list)}
15408 """
15409 return None
15410
15412 """
15413 Gets tangents to the curve in its defining points.
15414
15415 See L{Spline.sample_uniformly}() for discussion.
15416
15417 If the spline is empty (there are no points) the function returns B{C{None}}.
15418
15419 @since: 2.45
15420
15421 @return: Tangents to the spline in the XY points defining the curve. The
15422 returned array is owned by B{C{spline}}, must not be modified and is
15423 only guaranteed to exist so long as the spline is not modified nor
15424 destroyed. I{(list)}
15425 """
15426 return None
15427
15429 """
15430 Samples efficiently a spline curve.
15431
15432 This function calculates coordinates of points that lie on the spline curve
15433 and are sufficient for a good approximation by straight lines. This is
15434 particularly useful for drawing the curve.
15435
15436 See L{Spline.sample_uniformly}() for some discussion of closed versus open
15437 curves and corner case handling.
15438
15439 @since: 2.45
15440
15441 @return: Coordinates of the XY points defining the sampled curve. The
15442 returned array is owned by B{C{spline}}, must not be modified and is
15443 only guaranteed to exist so long as the spline is not modified nor
15444 destroyed. I{(list)}
15445 """
15446 return None
15447
15482 """
15483 Globally disables drawing of 3D view axes.
15484
15485 If axis drawing is disabled, axes are never drawn. If it is not disabled, their rendering depends on the 3D view
15486 setup.
15487
15488 This function is a hack and exists to work around various GL implementations that crash on pixmap drawing
15489 operations.
15490
15491 @since: 2.14
15492
15493 @param disable: B{C{True}} to disable 3D view axes globally, B{C{False}} to enable them. I{(bool)}
15494 """
15495 pass
15496
15507
15526
15528 """
15529 Puts the curves of a graph to another graph if possible, or adds the graph as new.
15530
15531 If the units of B{C{gmodel}} are compatible with the units of the graph identified by B{C{target_graph}} the curves are
15532 copied to the target graph with L{Graph.model_append_curves}().
15533
15534 In all other cases, including when B{C{target_graph}} does not refer to any existing graph, the graph model is added to
15535 B{C{data}} as a new graph.
15536
15537 Either way, the caller usually need to release its own reference afterwards.
15538
15539 This function is useful particularly in modules that create graphs and can be run non-interactively.
15540
15541 @since: 2.41
15542
15543 @param gmodel: A graph model with curves to add. I{(L{GraphModel})}
15544 @param data: Data container where the graph would be added. I{(L{Container})}
15545 @param target_graph: Graph where curves would be added. I{(const-AppDataId*)}
15546 @param colorstep: Curve block size as in L{Graph.model_append_curves}(). I{(int)}
15547 @return: The numerical identifier of the newly-created graph of one was created. Value -1 is returned if curves
15548 were added to B{C{target_graph}}. I{(int)}
15549 """
15550 return None
15551
15553 """
15554 Adds main (global) application accelerator group to a window.
15555
15556 This includes accelerators for terminating Gwyddion, opening files, etc.
15557
15558 @param window: A window. I{(L{gtk.Window})}
15559 """
15560 pass
15561
15563 """
15564 Constructs the application I{Curve Maps} menu.
15565
15566 The menu is created from curve map data processing functions registered by modules, therefore module registration
15567 has to be done first for this function to make sense.
15568
15569 @since: 2.60
15570
15571 @param accel_group: Acceleration group to be associated with the menu. I{(L{gtk.AccelGroup})}
15572 @return: A newly ceated curve map data processing menu (a B{C{GtkMenu}}). I{(L{gtk.Widget})}
15573 """
15574 return None
15575
15577 """
15578 Constructs the application I{Graph} menu.
15579
15580 The menu is created from graph functions registered by modules, therefore module registration has to be done first
15581 for this function to make sense.
15582
15583
15584 @param accel_group: Acceleration group to be associated with the menu. I{(L{gtk.AccelGroup})}
15585 @return: A newly ceated graph menu (a B{C{GtkMenu}}). I{(L{gtk.Widget})}
15586 """
15587 return None
15588
15590 """
15591 Constructs the application I{Data Process} menu.
15592
15593 The menu is created from data processing functions registered by modules, therefore module registration has to be
15594 done first for this function to make sense.
15595
15596
15597 @param accel_group: Acceleration group to be associated with the menu. I{(L{gtk.AccelGroup})}
15598 @return: A newly ceated data processing menu (a B{C{GtkMenu}}). I{(L{gtk.Widget})}
15599 """
15600 return None
15601
15603 """
15604 Constructs the application I{Volume Data} menu.
15605
15606 The menu is created from volume data processing functions registered by modules, therefore module registration has
15607 to be done first for this function to make sense.
15608
15609 @since: 2.32
15610
15611 @param accel_group: Acceleration group to be associated with the menu. I{(L{gtk.AccelGroup})}
15612 @return: A newly ceated volume data processing menu (a B{C{GtkMenu}}). I{(L{gtk.Widget})}
15613 """
15614 return None
15615
15617 """
15618 Constructs the application I{XYZ Data} menu.
15619
15620 The menu is created from XYZ data processing functions registered by modules, therefore module registration has to
15621 be done first for this function to make sense.
15622
15623 @since: 2.45
15624
15625 @param accel_group: Acceleration group to be associated with the menu. I{(L{gtk.AccelGroup})}
15626 @return: A newly ceated XYZ data processing menu (a B{C{GtkMenu}}). I{(L{gtk.Widget})}
15627 """
15628 return None
15629
15631 """
15632 Adds an entry to the log of the current data processing operations for a channel.
15633
15634 This simplified variant of L{gwy_app_channel_log_add}() takes the currently running data processing function name and
15635 constructs the qualified function name from that.
15636
15637 @since: 2.38
15638
15639 @param data: A data container. I{(L{Container})}
15640 @param previd: Identifier of the previous (source) data channel in the container.
15641 Pass -1 for a no-source (or unclear source) operation. I{(int)}
15642 @param newid: Identifier of the new (target) data channel in the container. I{(int)}
15643 """
15644 pass
15645
15647 """
15648 Creates a mask corresponding to not-a-number and infinite values in a data
15649 field.
15650
15651 NaNs and infinities are not normally allowed in Gwyddion so this function
15652 should be used upon import if the source file format can represent such
15653 values.
15654
15655 The invalid values can be automatically removed using the same method as
15656 L{gwy_app_channel_remove_bad_data}().
15657
15658 @since: 2.38
15659
15660 @param dfield: A data field possibly containing NaNs and infinities. I{(L{DataField})}
15661 @param removebad: Automatically remove the invalid values. I{(bool)}
15662 @return: A newly created data field with 1.0 in pixels corresponding to a
15663 NaN or infinity in B{C{dfield}}. If no such pixels are present, B{C{None}}
15664 is returned. I{(L{DataField})}
15665 """
15666 return None
15667
15669 """
15670 Replaces bad data points with some neutral values.
15671
15672 Since Gwyddion has no concept of bad data points, they are usually marked
15673 with a mask and replaced with some neutral values upon import, leaving the
15674 user to decide how to proceed further. This helper function performs such
15675 replacement.
15676
15677 @since: 2.14
15678
15679 @param dfield: A data field. The values of bad data points are ignored and might
15680 be even left uninitialized. I{(L{DataField})}
15681 @param mfield: A mask field containing 1.0 in place of good data points, 0.0 in
15682 place of bad points. It will be inverted to become the mask of
15683 bad points. I{(L{DataField})}
15684 @return: The number of bad data points replaced. If zero is returned, all
15685 points are good and there is no need for masking. I{(int)}
15686 """
15687 return None
15688
15690 """
15691 Adds a channel title based on data field units.
15692
15693 The guess is very simple, but probably better than `Unknown channel' in
15694 most cases. If there already is a title it is left intact, making use of
15695 this function as a fall-back easier.
15696
15697 @since: 2.3
15698
15699 @param data: A data container. I{(L{Container})}
15700 @param id: Data channel id. I{(int)}
15701 @return: B{C{True}} if the title was set (either by this function or before). I{(bool)}
15702 """
15703 return None
15704
15718
15734
15736 """
15737 Adds an entry to the log of the current B{C{Lawn}} curve map processing operations for B{C{Lawn}} curve map.
15738
15739 This simplified variant of L{gwy_app_curve_map_log_add}() takes the currently running function B{C{Lawn}} curve map
15740 processing name and constructs the qualified function name from that.
15741
15742 @since: 2.60
15743
15744 @param data: A data container. I{(L{Container})}
15745 @param previd: Identifier of the previous (source) B{C{Lawn}} curve map in the container.
15746 Pass -1 for a no-source (or unclear source) operation. I{(int)}
15747 @param newid: Identifier of the new (target) B{C{Lawn}} curve map in the container. I{(int)}
15748 """
15749 pass
15750
15752 """
15753 Adds a data container to the application data browser.
15754
15755 The data browser takes a reference on the container so you can release yours.
15756
15757 @param data: A data container. I{(L{Container})}
15758 """
15759 pass
15760
15762 """
15763 Adds a volume data brick to a data container.
15764
15765 The data browser takes a reference to B{C{brick}} (and B{C{preview}} if given) so usually you will want to release your
15766 reference, especially when done as the ‘create output’ step of a module function.
15767
15768 @since: 2.32
15769
15770 @param brick: A data brick to add. I{(L{Brick})}
15771 @param preview: Preview data field. It may be B{C{None}} to create a
15772 preview automatically. If non-B{C{None}}, its dimensions
15773 should match those of brick planes. You must
15774 I{not} pass a field which already represents a
15775 channel. If you want a to show the same field as an existing
15776 channel you must create a copy with L{DataField.duplicate}(). I{(L{DataField})}
15777 @param data: A data container to add B{C{brick}} to. It can be B{C{None}} to add the data field to current data container. I{(L{Container})}
15778 @param showit: B{C{True}} to display it immediately, B{C{False}} to just add it. I{(bool)}
15779 @return: The id of the data brick in the container. I{(int)}
15780 """
15781 return None
15782
15784 """
15785 Adds a data field to a data container.
15786
15787 The data browser takes a reference to B{C{dfield}} so usually you will want to release your reference, especially when
15788 done as the ‘create output’ step of a module function.
15789
15790
15791 @param dfield: A data field to add. I{(L{DataField})}
15792 @param data: A data container to add B{C{dfield}} to. It can be B{C{None}} to add the data field to current data container. I{(L{Container})}
15793 @param showit: B{C{True}} to display it immediately, B{C{False}} to just add it. I{(bool)}
15794 @return: The id of the data field in the container. I{(int)}
15795 """
15796 return None
15797
15799 """
15800 Adds a graph model to a data container.
15801
15802 The data browser takes a reference to B{C{gmodel}} so usually you will want to release your reference, especially when
15803 done as the ‘create output’ step of a module function.
15804
15805
15806 @param gmodel: A graph model to add. I{(L{GraphModel})}
15807 @param data: A data container to add B{C{gmodel}} to.
15808 It can be B{C{None}} to add the graph model to current data container. I{(L{Container})}
15809 @param showit: B{C{True}} to display it immediately, B{C{False}} to just add it. I{(bool)}
15810 @return: The id of the graph model in the container. I{(int)}
15811 """
15812 return None
15813
15815 """
15816 Adds B{C{Lawn}} curve map data to a data container.
15817
15818 The data browser takes a reference to B{C{lawn}} so usually you will want to release your reference, especially when
15819 done as the ‘create output’ step of a module function.
15820
15821 @since: 2.60
15822
15823 @param lawn: B{C{Lawn}} to add. I{(L{Lawn})}
15824 @param preview: Preview data field. It may be B{C{None}} to create a
15825 preview automatically. If non-B{C{None}}, its dimensions
15826 should match those of lawn planes. You must
15827 I{not} pass a field which already represents a
15828 channel. If you want a to show the same field as an existing
15829 channel you must create a copy with L{DataField.duplicate}(). I{(L{DataField})}
15830 @param data: A data container to add B{C{lawn}} to.
15831 It can be B{C{None}} to add the data field to current data container. I{(L{Container})}
15832 @param showit: B{C{True}} to display it immediately, B{C{False}} to just add it. I{(bool)}
15833 @return: The id of the data lawn in the container. I{(int)}
15834 """
15835 return None
15836
15838 """
15839 Adds a spectra object to a data container.
15840
15841 The data browser takes a reference to B{C{spectra}} so usually you will want to release your reference, especially when
15842 done as the ‘create output’ step of a module function.
15843
15844 @since: 2.7
15845
15846 @param spectra: A spectra object to add. I{(L{Spectra})}
15847 @param data: A data container to add B{C{gmodel}} to. It can be B{C{None}} to add the spectra to current data container. I{(L{Container})}
15848 @param showit: B{C{True}} to display it immediately, B{C{False}} to just add it. I{(bool)}
15849 @return: The id of the spectra object in the container. I{(int)}
15850 """
15851 return None
15852
15854 """
15855 Adds XYZ surface data to a data container.
15856
15857 The data browser takes a reference to B{C{surface}} so usually you will want to release your reference, especially when
15858 done as the ‘create output’ step of a module function.
15859
15860 @since: 2.45
15861
15862 @param surface: XYZ surface data to add. I{(L{Surface})}
15863 @param data: A data container to add B{C{surface}} to. It can be B{C{None}} to add the data field to current data container. I{(L{Container})}
15864 @param showit: B{C{True}} to display it immediately, B{C{False}} to just add it. I{(bool)}
15865 @return: The id of the data surface in the container. I{(int)}
15866 """
15867 return None
15868
15870 """
15871 Copies a channel including all auxiliary data.
15872
15873
15874 @param source: Source container. I{(L{Container})}
15875 @param id: Data channel id. I{(int)}
15876 @param dest: Target container (may be identical to source). I{(L{Container})}
15877 @return: The id of the copy. I{(int)}
15878 """
15879 return None
15880
15882 """
15883 Copies B{C{Lawn}} curve map data including all auxiliary data.
15884
15885 @since: 2.60
15886
15887 @param source: Source container. I{(L{Container})}
15888 @param id: B{C{Lawn}} curve map data id. I{(int)}
15889 @param dest: Target container (may be identical to source). I{(L{Container})}
15890 @return: The id of the copy. I{(int)}
15891 """
15892 return None
15893
15895 """
15896 Copies volume brick data including all auxiliary data.
15897
15898 @since: 2.32
15899
15900 @param source: Source container. I{(L{Container})}
15901 @param id: Volume data brick id. I{(int)}
15902 @param dest: Target container (may be identical to source). I{(L{Container})}
15903 @return: The id of the copy. I{(int)}
15904 """
15905 return None
15906
15908 """
15909 Copies XYZ surface data including all auxiliary data.
15910
15911 @since: 2.45
15912
15913 @param source: Source container. I{(L{Container})}
15914 @param id: XYZ surface data id. I{(int)}
15915 @param dest: Target container (may be identical to source). I{(L{Container})}
15916 @return: The id of the copy. I{(int)}
15917 """
15918 return None
15919
15921 """
15922 Gets the list of all channels in a data container whose titles match the specified pattern.
15923
15924 The function originally could be used only for data containers managed by the data browser. Since version 2.49 it
15925 can be used for all file-like data containers.
15926
15927 @since: 2.21
15928
15929 @param data: A data container. I{(L{Container})}
15930 @param titleglob: Pattern, as used by B{C{GPatternSpec}}, to match the channel titles against. I{(string)}
15931 @return: A newly allocated array with channel ids, -1 terminated. I{(list)}
15932 """
15933 return None
15934
15936 """
15937 Gets the list of all graphs in a data container whose titles match the specified pattern.
15938
15939 The function originally could be used only for data containers managed by the data browser. Since version 2.49 it
15940 can be used for all file-like data containers.
15941
15942 @since: 2.21
15943
15944 @param data: A data container. I{(L{Container})}
15945 @param titleglob: Pattern, as used by B{C{GPatternSpec}}, to match the graph titles against. I{(string)}
15946 @return: A newly allocated array with graph ids, -1 terminated. I{(list)}
15947 """
15948 return None
15949
15951 """
15952 Gets the list of all spectra in a data container whose titles match the specified pattern.
15953
15954 The function originally could be used only for data containers managed by the data browser. Since version 2.49 it
15955 can be used for all file-like data containers.
15956
15957 @since: 2.21
15958
15959 @param data: A data container. I{(L{Container})}
15960 @param titleglob: Pattern, as used by B{C{GPatternSpec}}, to match the spectra titles against. I{(string)}
15961 @return: A newly allocated array with spectra ids, -1 terminated. I{(list)}
15962 """
15963 return None
15964
15966 """
15967 Gets the list of all volume data in a data container whose titles match the specified pattern.
15968
15969 The function originally could be used only for data containers managed by the data browser. Since version 2.49 it
15970 can be used for all file-like data containers.
15971
15972 @since: 2.45
15973
15974 @param data: A data container. I{(L{Container})}
15975 @param titleglob: Pattern, as used by B{C{GPatternSpec}}, to match the volume data titles against. I{(string)}
15976 @return: A newly allocated array with volume data ids, -1 terminated. I{(list)}
15977 """
15978 return None
15979
15981 """
15982 Gets the list of all XYZ data in a data container whose titles match the specified pattern.
15983
15984 The function originally could be used only for data containers managed by the data browser. Since version 2.49 it
15985 can be used for all file-like data containers.
15986
15987 @since: 2.45
15988
15989 @param data: A data container. I{(L{Container})}
15990 @param titleglob: Pattern, as used by B{C{GPatternSpec}}, to match the XYZ data titles against. I{(string)}
15991 @return: A newly allocated array with XYZ data ids, -1 terminated. I{(list)}
15992 """
15993 return None
15994
15996 """
15997 Calls a function for each data container managed by data browser.
15998
15999 @param function: Function to run on each data container. I{(AppDataForeachFunc)}
16000 @param user_data: Data to pass as second argument of B{C{function}}. I{(gpointer)}
16001 """
16002 pass
16003
16005 """
16006 Gets the data corresponding to a numerical identifier.
16007
16008 The identifier can be obtained with L{gwy_app_data_browser_get_number}(). See its documentation for discussion.
16009
16010 @since: 2.41
16011
16012 @param number: Numerical identifier of open data managed by the data browser, or
16013 zero. I{(int)}
16014 @return: The corresponding data container. B{C{None}} is returned if B{C{number}} does not identify any existing data. I{(L{Container})}
16015 """
16016 return None
16017
16019 """
16020 Get list of containers of current data browser.
16021
16022
16023 @return: list of containers L{Container} object I{(list)}
16024 """
16025 return None
16026
16028 """
16029 Get current data item of given type.
16030
16031 Depending on what you request, the function can return data object
16032 themselves, integer keys, ids, ...
16033
16034
16035 @param obj_type: Data item type. I{(L{AppWhat})} Expected values: C{B{APP_CONTAINER}}, C{B{APP_DATA_VIEW}}, C{B{APP_GRAPH}}, C{B{APP_DATA_FIELD}}, C{B{APP_DATA_FIELD_KEY}}, C{B{APP_DATA_FIELD_ID}}, C{B{APP_MASK_FIELD}}, C{B{APP_MASK_FIELD_KEY}}, C{B{APP_SHOW_FIELD}}, C{B{APP_SHOW_FIELD_KEY}}, C{B{APP_GRAPH_MODEL}}, C{B{APP_GRAPH_MODEL_KEY}}, C{B{APP_GRAPH_MODEL_ID}}, C{B{APP_SPECTRA}}, C{B{APP_SPECTRA_KEY}}, C{B{APP_SPECTRA_ID}}, C{B{APP_VOLUME_VIEW}}, C{B{APP_BRICK}}, C{B{APP_BRICK_KEY}}, C{B{APP_BRICK_ID}}, C{B{APP_CONTAINER_ID}}, C{B{APP_XYZ_VIEW}}, C{B{APP_SURFACE}}, C{B{APP_SURFACE_KEY}}, C{B{APP_SURFACE_ID}}, C{B{APP_PAGE}}, C{B{APP_LAWN}}, C{B{APP_LAWN_KEY}}, C{B{APP_LAWN_ID}}, C{B{APP_CURVE_MAP_VIEW}}. I{(L{AppWhat})}
16036 @return: The current object or None. I{(any)}
16037 """
16038 return None
16039
16041 """
16042 Gets the list of all channels in a data container (presumably representing
16043 a file).
16044
16045
16046 @param container: A data container. I{(L{Container})}
16047 @return: List of channel ids. I{(list)}
16048 """
16049 return None
16050
16052 """
16053 Gets the list of all graphs in a data container (presumably representing
16054 a file).
16055
16056
16057 @param container: A data container. I{(L{Container})}
16058 @return: List of graph ids. I{(list)}
16059 """
16060 return None
16061
16063 """
16064 Reports whether creation of windows by the data-browser is enabled.
16065
16066 @since: 2.21
16067
16068 @return: B{C{True}} if the data-browser is permitted to create windows, B{C{False}} if it is not. I{(bool)}
16069 """
16070 return None
16071
16073 """
16074 Gets data browser behaviour for inaccessible data.
16075
16076
16077 @param data: A data container. I{(L{Container})}
16078 @return: See L{gwy_app_data_browser_set_keep_invisible}(). I{(bool)}
16079 """
16080 return None
16081
16083 """
16084 Gets the numerical identifier of data.
16085
16086 Each time a data container is added with L{gwy_app_data_browser_add}() it is assigned a new unique numerical
16087 identifier. This number can be used in multi-data modules to remember and restore secondary data.
16088
16089 Note, however, that the number is only guaranteed to be unique within one process. It does not persist across
16090 different program invocations and it does not make sense to store it to the settings or other kinds of permanent
16091 storage.
16092
16093 @since: 2.41
16094
16095 @param data: A data container managed by the data browser. For convenience, B{C{None}} is also permitted. I{(L{Container})}
16096 @return: A positive numerical identifier of B{C{data}}. Zero is returned if B{C{data}} is B{C{None}}. I{(int)}
16097 """
16098 return None
16099
16101 """
16102 Gets the list of all spectra in a data container (presumably representing
16103 a file).
16104
16105
16106 @param container: A data container. I{(L{Container})}
16107 @return: List of spectra ids. I{(list)}
16108 """
16109 return None
16110
16112 """
16113 Gets the list of all volume data in a data container (presumably
16114 representing a file).
16115
16116
16117 @param container: A data container. I{(L{Container})}
16118 @return: List of volume data ids. I{(list)}
16119 """
16120 return None
16121
16123 """
16124 Gets the list of all XYZ data in a data container (presumably representing
16125 a file).
16126
16127
16128 @param container: A data container. I{(L{Container})}
16129 @return: List of XYZ data ids. I{(list)}
16130 """
16131 return None
16132
16134 """
16135 Merges the data from a data container to the current one.
16136
16137 @since: 2.7
16138
16139 @param data: A data container, not managed by the data browser. I{(L{Container})}
16140 """
16141 pass
16142
16144 """
16145 Removed a data container from the application data browser.
16146
16147 @param data: A data container. I{(L{Container})}
16148 """
16149 pass
16150
16152 """
16153 Removes a channel watch function.
16154
16155 @since: 2.21
16156
16157 @param id: Watch function id, as returned by L{gwy_app_data_browser_add_channel_watch}(). I{(gulong)}
16158 """
16159 pass
16160
16162 """
16163 Removes a curve map data watch function.
16164
16165 @since: 2.60
16166
16167 @param id: Watch function id, as returned by L{gwy_app_data_browser_add_curve_map_watch}(). I{(gulong)}
16168 """
16169 pass
16170
16172 """
16173 Removes a graph watch function.
16174
16175 @since: 2.41
16176
16177 @param id: Watch function id, as returned by L{gwy_app_data_browser_add_graph_watch}(). I{(gulong)}
16178 """
16179 pass
16180
16182 """
16183 Removes a volume data watch function.
16184
16185 @since: 2.60
16186
16187 @param id: Watch function id, as returned by L{gwy_app_data_browser_add_volume_watch}(). I{(gulong)}
16188 """
16189 pass
16190
16192 """
16193 Removes an XYZ data watch function.
16194
16195 @since: 2.60
16196
16197 @param id: Watch function id, as returned by L{gwy_app_data_browser_add_xyz_watch}(). I{(gulong)}
16198 """
16199 pass
16200
16202 """
16203 Resets visibility of all data objects in a container.
16204
16205
16206 @param data: A data container. I{(L{Container})}
16207 @param reset_type: Type of visibility reset. Expected values: C{B{VISIBILITY_RESET_DEFAULT}}, C{B{VISIBILITY_RESET_RESTORE}}, C{B{VISIBILITY_RESET_SHOW_ALL}}, C{B{VISIBILITY_RESET_HIDE_ALL}}. I{(L{VisibilityResetType})}
16208 @return: B{C{True}} if anything is visible after the reset. I{(bool)}
16209 """
16210 return None
16211
16213 """
16214 Restores the data browser window.
16215
16216 The data browser window is always created (if it does not exist). If it should be visible according to settings, is
16217 shown at the saved position. Otherwise it is kept hidden until L{gwy_app_data_browser_show}().
16218
16219 """
16220 pass
16221
16223 """
16224 Makes a brick (volume data) current in the data browser.
16225
16226 @warning:This function does not do what you might expect. Selecting a data object which is not displayed in any
16227 view makes it just possible to delete or duplicate in the data browser. Module functions can be only run on
16228 visible data.
16229
16230 @since: 2.61
16231
16232 @param data: The container to select. I{(L{Container})}
16233 @param id: Number (id) of the brick in B{C{data}} to select. I{(int)}
16234 """
16235 pass
16236
16238 """
16239 Switches application data browser to display container of data and selects B{C{data_view}}'s curve_map data in the graph
16240 list.
16241
16242 @since: 2.60
16243
16244 @param data_view: A data view widget showing a preview of curve_map data. I{(L{DataView})}
16245 """
16246 pass
16247
16249 """
16250 Makes a data field (image) current in the data browser.
16251
16252 @warning:This function does not do what you might expect. Selecting a data object which is not displayed in any
16253 view makes it just possible to delete or duplicate in the data browser. Module functions can be only run on
16254 visible data.
16255
16256 @param data: The container to select. I{(L{Container})}
16257 @param id: Number (id) of the data field in B{C{data}} to select. I{(int)}
16258 """
16259 pass
16260
16262 """
16263 Switches application data browser to display container of B{C{data_view}}'s data and selects B{C{data_view}}'s data in the
16264 channel list.
16265
16266 @param data_view: A data view widget. I{(L{DataView})}
16267 """
16268 pass
16269
16271 """
16272 Switches application data browser to display container of B{C{graph}}'s data and selects B{C{graph}}'s data in the graph
16273 list.
16274
16275 @param graph: A graph widget. I{(L{Graph})}
16276 """
16277 pass
16278
16280 """
16281 Makes a graph model current in the data browser.
16282
16283 @warning:This function does not do what you might expect. Selecting a data object which is not displayed in any
16284 view makes it just possible to delete or duplicate in the data browser. Module functions can be only run on
16285 visible data.
16286
16287 @param data: The container to select. I{(L{Container})}
16288 @param id: Number (id) of the graph model in B{C{data}} to select. I{(int)}
16289 """
16290 pass
16291
16293 """
16294 Makes a lawn (curve map) current in the data browser.
16295
16296 @warning:This function does not do what you might expect. Selecting a data object which is not displayed in any
16297 view makes it just possible to delete or duplicate in the data browser. Module functions can be only run on
16298 visible data.
16299
16300 @since: 2.61
16301
16302 @param data: The container to select. I{(L{Container})}
16303 @param id: Number (id) of the lawn in B{C{data}} to select. I{(int)}
16304 """
16305 pass
16306
16308 """
16309 Switches application data browser to display container of B{C{spectra}}'s data and selects B{C{spectra}}'s data in the graph
16310 list.
16311
16312 However, it is not actually supposed to work with spectra from a different container than those of the currently
16313 active channel, so do not try that for now.
16314
16315 @since: 2.7
16316
16317 @param spectra: A spectra object. I{(L{Spectra})}
16318 """
16319 pass
16320
16322 """
16323 Makes a surface (XYZ data) current in the data browser.
16324
16325 @warning:This function does not do what you might expect. Selecting a data object which is not displayed in any
16326 view makes it just possible to delete or duplicate in the data browser. Module functions can be only run on
16327 visible data.
16328
16329 @since: 2.61
16330
16331 @param data: The container to select. I{(L{Container})}
16332 @param id: Number (id) of the surface in B{C{data}} to select. I{(int)}
16333 """
16334 pass
16335
16337 """
16338 Switches application data browser to display container of data and selects B{C{data_view}}'s volume data in the graph
16339 list.
16340
16341 @since: 2.32
16342
16343 @param data_view: A data view widget showing a preview of volume data. I{(L{DataView})}
16344 """
16345 pass
16346
16348 """
16349 Switches application data browser to display container of data and selects B{C{data_view}}'s XYZ data in the graph list.
16350
16351 @since: 2.45
16352
16353 @param data_view: A data view widget showing a preview of XYZ data. I{(L{DataView})}
16354 """
16355 pass
16356
16358 """
16359 Globally enables or disables creation of widgets by the data-browser.
16360
16361 By default, the data-browser creates windows for data objects automatically, for instance when reconstructing view
16362 of a loaded file, after a module function creates a new channel or graph or when it is explicitly asked so by
16363 L{gwy_app_data_browser_show_3d}(). Non-GUI applications that run module functions usually wish to disable GUI.
16364
16365 If GUI is disabled the data browser never creates windows showing data objects and also L{gwy_app_data_browser_show}()
16366 becomes no-op.
16367
16368 Disabling GUI after widgets have been already created is a bad idea. Hence you should do so before loading files or
16369 calling module functions.
16370
16371 @since: 2.21
16372
16373 @param setting: B{C{True}} to enable creation of widgets by the data-browser, B{C{False}} to disable it. I{(bool)}
16374 """
16375 pass
16376
16378 """
16379 Sets data browser behaviour for inaccessible data.
16380
16381 Normally, when all visual objects belonging to a file are closed the container is removed from the data browser and
16382 dereferenced, leading to its finalization. By setting B{C{keep_invisible}} to B{C{True}} the container can be made to sit in
16383 the browser indefinitely.
16384
16385 @param data: A data container. I{(L{Container})}
16386 @param keep_invisible: B{C{True}} to retain B{C{data}} in the browser even when it becomes inaccessible, B{C{False}} to dispose of it. I{(bool)}
16387 """
16388 pass
16389
16391 """
16392 Shows the data browser window.
16393
16394 If the window does not exist, it is created.
16395
16396 """
16397 pass
16398
16400 """
16401 Shows a 3D window displaying a channel.
16402
16403 If a 3D window of the specified channel already exists, it is just presented to the user. If it does not exist, it
16404 is created.
16405
16406 The caller must ensure 3D display is available, for example by checking L{gwy_app_gl_is_ok}().
16407
16408 @param data: A data container. I{(L{Container})}
16409 @param id: Channel id. I{(int)}
16410 """
16411 pass
16412
16414 """
16415 Releases data browser resources and saves its state.
16416
16417 """
16418 pass
16419
16421 """
16422 Clears all selections associated with a data channel.
16423
16424 This is the preferred selection handling after changes in data geometry as they have generally unpredictable
16425 effects on selections. Selection should not be removed because this is likely to make the current tool stop
16426 working.
16427
16428 @param data: A data container. I{(L{Container})}
16429 @param id: Data channel id. I{(int)}
16430 """
16431 pass
16432
16434 """
16435 Runs mask color selector on a data view.
16436
16437 This is a convenience function to run L{gwy_color_selector_for_mask}(), possibly taking the initial color from
16438 settings.
16439
16440 @param data_view: A data view (of application's data window). It must have a mask. I{(L{DataView})}
16441 """
16442 pass
16443
16445 """
16446 Closes the current file file (very high-level app function).
16447
16448 @since: 2.45
16449
16450 """
16451 pass
16452
16454 """
16455 Asks for file overwrite for a file save chooser.
16456
16457
16458 @param chooser: A file chooser for save action. I{(L{gtk.Widget})}
16459 @return: B{C{True}} if it is OK to overwrite the file, B{C{False}} when user cancelled
16460 it or there was other problem. I{(bool)}
16461 """
16462 return None
16463
16465 """
16466 Loads a file into application (a high-level function).
16467
16468 At least one of B{C{filename_utf8}}, B{C{filename_sys}} must be non-B{C{None}}.
16469
16470 The file is loaded in interactive mode, modules can ask for user input. Upon a successful load all necessary setup
16471 tasks are performed. If the load fails, an error dialog is presented.
16472
16473
16474 @param filename_utf8: Name of file to load, in UTF-8. I{(string)}
16475 @param name: File type to open file as, but normally B{C{None}} to automatically detect from file contents. I{(string)}
16476 @return: Tuple consisting of 2 values (B{C{value}}, B{C{filename_sys}}). (I{(L{Container})}, I{(SkipArg)})
16477 """
16478 return None, None
16479
16481 """
16482 Merges a user-selected file (very high-level app function).
16483
16484 @since: 2.7
16485
16486 """
16487 pass
16488
16490 """
16491 Opens a user-selected file (very high-level app function).
16492
16493 """
16494 pass
16495
16497 """
16498 Saves current data to a file (very high-level app function).
16499
16500 May fall back to L{gwy_app_file_save_as}() when current data has no file name associated with it, or the format it was
16501 loaded from is not saveable.
16502
16503 """
16504 pass
16505
16507 """
16508 Saves current data to a user-selected file (very high-level app function).
16509
16510 """
16511 pass
16512
16514 """
16515 Writes container to a file (a high-level function).
16516
16517 At least one of B{C{filename_utf8}}, B{C{filename_sys}} must be non-B{C{None}}.
16518
16519 The file is saved in interactive mode, modules can ask for user input. If the write fails, an error dialog is
16520 presented.
16521
16522
16523 @param data: Data to write. I{(L{Container})}
16524 @param filename_utf8: Name of file to write data to, in UTF-8. I{(string)}
16525 @param name: File type to save file as, but normally B{C{None}} to automatically detect from file name. I{(string)}
16526 @return: Tuple consisting of 2 values (B{C{value}}, B{C{filename_sys}}). (I{(bool)}, I{(SkipArg)})
16527 """
16528 return None, None
16529
16531 """
16532 Finds the window displaying a data channel.
16533
16534
16535 @param data: A data container to find window for. I{(L{Container})}
16536 @param id: Data channel id. It can be -1 to find any data window displaying a channel from B{C{data}}. I{(int)}
16537 @return: The window if found, B{C{None}} if no data window displays the requested channel. I{(L{gtk.Window})}
16538 """
16539 return None
16540
16542 """
16543 Finds the window displaying given curve map.
16544
16545 @since: 2.60
16546
16547 @param data: A data container to find window for. I{(L{Container})}
16548 @param id: curve map id. It can be -1 to find any data window displaying curve map from B{C{data}}. I{(int)}
16549 @return: The window if found, B{C{None}} if no data window displays the requested curve map. I{(L{gtk.Window})}
16550 """
16551 return None
16552
16554 """
16555 Finds the window displaying a graph model.
16556
16557 @since: 2.45
16558
16559 @param data: A data container to find window for. I{(L{Container})}
16560 @param id: Graph model id. It can be -1 to find any graph window displaying a graph model from B{C{data}}. I{(int)}
16561 @return: The window if found, B{C{None}} if no graph window displays the requested channel. I{(L{gtk.Window})}
16562 """
16563 return None
16564
16566 """
16567 Finds the window displaying given volume data.
16568
16569 @since: 2.42
16570
16571 @param data: A data container to find window for. I{(L{Container})}
16572 @param id: Volume data id. It can be -1 to find any data window displaying volume data from B{C{data}}. I{(int)}
16573 @return: The window if found, B{C{None}} if no data window displays the requested volume data. I{(L{gtk.Window})}
16574 """
16575 return None
16576
16578 """
16579 Finds the window displaying given XYZ data.
16580
16581 @since: 2.45
16582
16583 @param data: A data container to find window for. I{(L{Container})}
16584 @param id: XYZ data id. It can be -1 to find any data window displaying XYZ data from B{C{data}}. I{(int)}
16585 @return: The window if found, B{C{None}} if no data window displays the requested XYZ data. I{(L{gtk.Window})}
16586 """
16587 return None
16588
16590 """
16591 Calculates data brick quark identifier from its id.
16592
16593 @since: 2.32
16594
16595 @param id: Numerical id of a data brick in file (container). I{(int)}
16596 @return: The quark key identifying data brick with number B{C{id}}. I{(int)}
16597 """
16598 return None
16599
16610
16612 """
16613 Calculates data brick palette quark identifier from its id.
16614
16615 @since: 2.43
16616
16617 @param id: Numerical id of a data brick in file (container). I{(int)}
16618 @return: The quark key identifying string name palette of data brick with number B{C{id}}. I{(int)}
16619 """
16620 return None
16621
16623 """
16624 Calculates data brick preview quark identifier from its id.
16625
16626 @since: 2.43
16627
16628 @param id: Numerical id of a data brick in file (container). I{(int)}
16629 @return: The quark key identifying preview data field of data brick with number B{C{id}}. I{(int)}
16630 """
16631 return None
16632
16634 """
16635 Gets a volume data brick title.
16636
16637 @since: 2.32
16638
16639 @param data: A data container. I{(L{Container})}
16640 @param id: Volume data brick id. I{(int)}
16641 @return: The brick title as a newly allocated string. I{(string)}
16642 """
16643 return None
16644
16646 """
16647 Calculates data brick title quark identifier from its id.
16648
16649 @since: 2.43
16650
16651 @param id: Numerical id of a data brick in file (container). I{(int)}
16652 @return: The quark key identifying string title of data brick with number B{C{id}}. I{(int)}
16653 """
16654 return None
16655
16657 """
16658 Creates a channel thumbnail.
16659
16660
16661 @param data: A data container. I{(L{Container})}
16662 @param id: Data channel id. I{(int)}
16663 @param max_width: Maximum width of the created pixbuf, it must be at least 2. I{(int)}
16664 @param max_height: Maximum height of the created pixbuf, it must be at least 2. I{(int)}
16665 @return: A newly created pixbuf with channel thumbnail. It keeps the aspect
16666 ratio of the data field while not exceeding B{C{max_width}} and
16667 B{C{max_height}}. I{(L{gdk.Pixbuf})}
16668 """
16669 return None
16670
16672 """
16673 Returns what the app uses as `current directory'.
16674
16675 Warning: This function is probably temporary.
16676
16677
16678 @return: A string in GLib file name encoding that should not be modified neither freed, valid only until next call
16679 to L{gwy_app_set_current_directory}(). It ends with a B{C{glib.DIR_SEPARATOR_S}}. I{(string)}
16680 """
16681 return None
16682
16684 """
16685 Creates a curve map thumbnail.
16686
16687 @since: 2.60
16688
16689 @param data: A data container. I{(L{Container})}
16690 @param id: Volume data id. I{(int)}
16691 @param max_width: Maximum width of the created pixbuf, it must be at least 2. I{(int)}
16692 @param max_height: Maximum height of the created pixbuf, it must be at least 2. I{(int)}
16693 @return: A newly created pixbuf with curve map data thumbnail. It keeps the aspect ratio of the lawn preview while
16694 not exceeding B{C{max_width}} and B{C{max_height}}. I{(L{gdk.Pixbuf})}
16695 """
16696 return None
16697
16699 """
16700 Calculates data field base visualisation quark identifier from its id.
16701
16702 This is the common prefix for range and palette key. It is not useful alone because it is only prefix.
16703
16704 @since: 2.59
16705
16706 @param id: Numerical id of a image in file (container). I{(int)}
16707 @return: The quark key identifying base string prefix of image with number B{C{id}}. I{(int)}
16708 """
16709 return None
16710
16712 """
16713 Gets a data channel title.
16714
16715 This function should return a reasonable title for untitled channels, channels with old titles, channels with and
16716 without a file, etc.
16717
16718
16719 @param data: A data container. I{(L{Container})}
16720 @param id: Data channel id. I{(int)}
16721 @return: The channel title as a newly allocated string. I{(string)}
16722 """
16723 return None
16724
16726 """
16727 Calculates data field quark identifier from its id.
16728
16729
16730 @param id: Numerical id of a channel in file (container). I{(int)}
16731 @return: The quark key identifying channel data field with number B{C{id}}. I{(int)}
16732 """
16733 return None
16734
16745
16747 """
16748 Calculates data field palette quark identifier from its id.
16749
16750 @since: 2.43
16751
16752 @param id: Numerical id of a image in file (container). I{(int)}
16753 @return: The quark key identifying string name palette of image with number B{C{id}}. I{(int)}
16754 """
16755 return None
16756
16758 """
16759 Calculates data field fixed range maximum quark identifier from its id.
16760
16761 @since: 2.43
16762
16763 @param id: Numerical id of a image in file (container). I{(int)}
16764 @return: The quark key identifying floating fixed false colour range maximum of image with number B{C{id}}. I{(int)}
16765 """
16766 return None
16767
16769 """
16770 Calculates data field fixed range minimum quark identifier from its id.
16771
16772 @since: 2.43
16773
16774 @param id: Numerical id of a image in file (container). I{(int)}
16775 @return: The quark key identifying floating fixed false colour range minimum of image with number B{C{id}}. I{(int)}
16776 """
16777 return None
16778
16780 """
16781 Calculates data field range type quark identifier from its id.
16782
16783 @since: 2.43
16784
16785 @param id: Numerical id of a image in file (container). I{(int)}
16786 @return: The quark key identifying B{C{LayerBasicRangeType}} false colour mapping type of image with number B{C{id}}. I{(int)}
16787 """
16788 return None
16789
16791 """
16792 Calculates data field real-square quark identifier from its id.
16793
16794 @since: 2.60
16795
16796 @param id: Numerical id of a image in file (container). I{(int)}
16797 @return: The quark key identifying boolean controlling real-square setting of image with number B{C{id}}. I{(int)}
16798 """
16799 return None
16800
16802 """
16803 Calculates data field title quark identifier from its id.
16804
16805 @since: 2.43
16806
16807 @param id: Numerical id of a image in file (container). I{(int)}
16808 @return: The quark key identifying string title of image with number B{C{id}}. I{(int)}
16809 """
16810 return None
16811
16813 """
16814 Calculates graph model quark identifier from its id.
16815
16816 @since: 2.7
16817
16818 @param id: Numerical id of a graph in file (container). I{(int)}
16819 @return: The quark key identifying graph model with number B{C{id}}. I{(int)}
16820 """
16821 return None
16822
16824 """
16825 Creates a graph thumbnail.
16826
16827 Note this function needs the GUI running (unlike the other thumbnail functions). It cannot be used in a console
16828 program.
16829
16830 @since: 2.45
16831
16832 @param data: A data container. I{(L{Container})}
16833 @param id: Graph model data id. I{(int)}
16834 @param max_width: Maximum width of the created pixbuf, it must be at least 2. I{(int)}
16835 @param max_height: Maximum height of the created pixbuf, it must be at least 2. I{(int)}
16836 @return: A newly created pixbuf with graph thumbnail. Since graphs do not have natural width and height, its size
16837 will normally be exactly B{C{max_width}} and B{C{max_height}}. I{(L{gdk.Pixbuf})}
16838 """
16839 return None
16840
16842 """
16843 Calculates B{C{Lawn}} curve map quark identifier from its id.
16844
16845 @since: 2.60
16846
16847 @param id: Numerical id of a B{C{Lawn}} curve map in file (container). I{(int)}
16848 @return: The quark key identifying B{C{Lawn}} curve map with number B{C{id}}. I{(int)}
16849 """
16850 return None
16851
16862
16864 """
16865 Calculates B{C{Lawn}} curve map palette quark identifier from its id.
16866
16867 @since: 2.60
16868
16869 @param id: Numerical id of a B{C{Lawn}} curve map in file (container). I{(int)}
16870 @return: The quark key identifying string name palette of B{C{Lawn}} curve map with number B{C{id}}. I{(int)}
16871 """
16872 return None
16873
16875 """
16876 Calculates B{C{Lawn}} curve map preview quark identifier from its id.
16877
16878 @since: 2.60
16879
16880 @param id: Numerical id of a B{C{Lawn}} curve map in file (container). I{(int)}
16881 @return: The quark key identifying preview data field of B{C{Lawn}} curve map with number B{C{id}}. I{(int)}
16882 """
16883 return None
16884
16886 """
16887 Calculates B{C{Lawn}} curve map real-square quark identifier from its id.
16888
16889 @since: 2.60
16890
16891 @param id: Numerical id of a B{C{Lawn}} curve map in file (container). I{(int)}
16892 @return: The quark key identifying boolean controlling real-square setting of B{C{Lawn}} curve map with number B{C{id}}. I{(int)}
16893 """
16894 return None
16895
16897 """
16898 Gets a B{C{Lawn}} curve map data title.
16899
16900 @since: 2.60
16901
16902 @param data: A data container. I{(L{Container})}
16903 @param id: XYZ data lawn id. I{(int)}
16904 @return: The lawn title as a newly allocated string. I{(string)}
16905 """
16906 return None
16907
16909 """
16910 Calculates B{C{Lawn}} curve map title quark identifier from its id.
16911
16912 @since: 2.60
16913
16914 @param id: Numerical id of a B{C{Lawn}} curve map in file (container). I{(int)}
16915 @return: The quark key identifying string title of B{C{Lawn}} curve map with number B{C{id}}. I{(int)}
16916 """
16917 return None
16918
16920 """
16921 Obtains a text buffer with program log messages.
16922
16923 This functions may only be called after L{gwy_app_setup_logging}() and,
16924 obviously, after GTK+ was intialised.
16925
16926 The text buffer is owned by the library and must not be modified nor
16927 destroyed. It will be already filled with messages occurring between
16928 L{gwy_app_setup_logging}() and this function call. New messages will be
16929 appended to the buffer as they arrive.
16930
16931 @since: 2.45
16932
16933 @return: Text buffer with the program log messages. I{(L{gtk.TextBuffer})}
16934 """
16935 return None
16936
16938 """
16939 Calculates mask field quark identifier from its id.
16940
16941
16942 @param id: Numerical id of a channel in file (container). I{(int)}
16943 @return: The quark key identifying mask data field with number B{C{id}}. I{(int)}
16944 """
16945 return None
16946
16948 """
16949 Calculates presentation field quark identifier from its id.
16950
16951
16952 @param id: Numerical id of a channel in file (container). I{(int)}
16953 @return: The quark key identifying presentation data field with number B{C{id}}. I{(int)}
16954 """
16955 return None
16956
16958 """
16959 Calculates spectra quark identifier from its id.
16960
16961 @since: 2.7
16962
16963 @param id: Numerical id of a spectra set in file (container). I{(int)}
16964 @return: The quark key identifying spectra with number B{C{id}}. I{(int)}
16965 """
16966 return None
16967
16969 """
16970 Calculates XYZ surface quark identifier from its id.
16971
16972 @since: 2.45
16973
16974 @param id: Numerical id of an XYZ surface in file (container). I{(int)}
16975 @return: The quark key identifying XYZ surface with number B{C{id}}. I{(int)}
16976 """
16977 return None
16978
16989
16991 """
16992 Calculates XYZ surface palette quark identifier from its id.
16993
16994 @since: 2.45
16995
16996 @param id: Numerical id of an XYZ surface in file (container). I{(int)}
16997 @return: The quark key identifying string name palette of XYZ surface with number B{C{id}}. I{(int)}
16998 """
16999 return None
17000
17002 """
17003 Calculates XYZ surface preview quark identifier from its id.
17004
17005 @since: 2.46
17006
17007 @param id: Numerical id of an XYZ surface in file (container). I{(int)}
17008 @return: The quark key identifying preview data field of XYZ surface with number B{C{id}}. I{(int)}
17009 """
17010 return None
17011
17013 """
17014 Gets an XYZ surface data title.
17015
17016 @since: 2.45
17017
17018 @param data: A data container. I{(L{Container})}
17019 @param id: XYZ data surface id. I{(int)}
17020 @return: The surface title as a newly allocated string. I{(string)}
17021 """
17022 return None
17023
17025 """
17026 Calculates data surface title quark identifier from its id.
17027
17028 @since: 2.45
17029
17030 @param id: Numerical id of a data surface in file (container). I{(int)}
17031 @return: The quark key identifying string title of data surface with number B{C{id}}. I{(int)}
17032 """
17033 return None
17034
17046
17048 """
17049 Creates a volume thumbnail.
17050
17051 @since: 2.33
17052
17053 @param data: A data container. I{(L{Container})}
17054 @param id: Volume data id. I{(int)}
17055 @param max_width: Maximum width of the created pixbuf, it must be at least 2. I{(int)}
17056 @param max_height: Maximum height of the created pixbuf, it must be at least 2. I{(int)}
17057 @return: A newly created pixbuf with volume data thumbnail. It keeps the aspect ratio of the brick preview while
17058 not exceeding B{C{max_width}} and B{C{max_height}}. I{(L{gdk.Pixbuf})}
17059 """
17060 return None
17061
17063 """
17064 Creates an XYZ data thumbnail.
17065
17066 @since: 2.45
17067
17068 @param data: A data container. I{(L{Container})}
17069 @param id: XYZ surface data id. I{(int)}
17070 @param max_width: Maximum width of the created pixbuf, it must be at least 2. I{(int)}
17071 @param max_height: Maximum height of the created pixbuf, it must be at least 2. I{(int)}
17072 @return: A newly created pixbuf with XYZ data thumbnail. It keeps the aspect ratio of the brick preview while not
17073 exceeding B{C{max_width}} and B{C{max_height}}. I{(L{gdk.Pixbuf})}
17074 """
17075 return None
17076
17078 """
17079 Returns OpenGL availability.
17080
17081
17082 @return: The return value is the same as the return value of L{gwy_app_gl_init}() which needs to be called prior to
17083 this function (until then, the return value is always B{C{False}}). I{(bool)}
17084 """
17085 return None
17086
17088 """
17089 Creates or presents OpenGL material editor.
17090
17091 Material editor is singleton, therefore if it doesn't exist, this function
17092 creates and displays it. If it already exists, it simply calls
17093 gtk_window_present() on the existing instance. It exists until it's closed
17094 by user.
17095
17096 """
17097 pass
17098
17100 """
17101 Creates or presents color gradient editor.
17102
17103 Gradient editor is singleton, therefore if it doesn't exist, this function
17104 creates and displays it. If it already exists, it simply calls
17105 gtk_window_present() on the existing instance. It exists until it's closed
17106 by user.
17107
17108 """
17109 pass
17110
17112 """
17113 Initializes internationalization.
17114
17115 Normally not needed to call explicitly.
17116
17117 """
17118 pass
17119
17128
17130 """
17131 Shows a simple log browser for a channel.
17132
17133 If the log browser is already shown for this channel it is just raised and given focus. Otherwise, a new window is
17134 created.
17135
17136 @since: 2.35
17137
17138 @param data: A data container. I{(L{Container})}
17139 @param id: Id of a channel in B{C{data}} to show log for. I{(int)}
17140 @return: The log browser (owned by the library). Usually, you can ignore the return value. I{(L{gtk.Widget})}
17141 """
17142 return None
17143
17145 """
17146 Shows a simple log browser for B{C{Lawn}} curve map.
17147
17148 If the log browser is already shown for this B{C{Lawn}} curve map it is just raised and given focus. Otherwise,
17149 a new window is created.
17150
17151 @since: 2.60
17152
17153 @param data: A data container. I{(L{Container})}
17154 @param id: Id of B{C{Lawn}} curve map in B{C{data}} to show log for. I{(int)}
17155 @return: The log browser (owned by the library). Usually, you can ignore the return value. I{(L{gtk.Widget})}
17156 """
17157 return None
17158
17160 """
17161 Shows a simple log browser for volume data.
17162
17163 If the log browser is already shown for this volume data it is just raised and given focus. Otherwise, a new
17164 window is created.
17165
17166 @since: 2.35
17167
17168 @param data: A data container. I{(L{Container})}
17169 @param id: Id of volume data in B{C{data}} to show log for. I{(int)}
17170 @return: The log browser (owned by the library). Usually, you can ignore the return value. I{(L{gtk.Widget})}
17171 """
17172 return None
17173
17175 """
17176 Shows a simple log browser for XYZ data.
17177
17178 If the log browser is already shown for this XYZ data it is just raised and given focus. Otherwise, a new window
17179 is created.
17180
17181 @since: 2.45
17182
17183 @param data: A data container. I{(L{Container})}
17184 @param id: Id of XYZ data in B{C{data}} to show log for. I{(int)}
17185 @return: The log browser (owned by the library). Usually, you can ignore the return value. I{(L{gtk.Widget})}
17186 """
17187 return None
17188
17190 """
17191 Returns Gwyddion main application window (toolbox).
17192
17193
17194 @return: The Gwyddion toolbox. I{(L{gtk.Widget})}
17195 """
17196 return None
17197
17199 """
17200 Sets the main application window.
17201
17202 This function is probably only useful in Gwyddion itself and should be ignored.
17203
17204 It needs to be called exactly once at Gwyddion startup. It restores the toolbox position and makes
17205 L{gwy_app_main_window_get}() work.
17206
17207 @param window: A window, presumably the Gwyddion toolbox. I{(L{gtk.Widget})}
17208 """
17209 pass
17210
17212 """
17213 Gets the application recent files menu.
17214
17215 The menu is initially empty and can be updated with L{gwy_app_menu_recent_files_update}(). This function is
17216 essentially useful only for toolbox construction.
17217
17218
17219 @return: The recent files menu (a B{C{GtkMenu}}). I{(L{gtk.Widget})}
17220 """
17221 return None
17222
17237
17252
17267
17282
17284 """
17285 Saves application data processing function statistics.
17286
17287 """
17288 pass
17289
17291 """
17292 Adds I{Re-show Last} and I{Repeat Last} items to application data
17293 process menu.
17294
17295 This function is essentially useful only for toolbox construction.
17296
17297 @param menu: Menu created with L{gwy_app_build_process_menu}(). I{(L{gtk.Widget})}
17298 """
17299 pass
17300
17302 """
17303 Quits the application.
17304
17305 This function may present a confirmation dialog to the user and it may let the application to continue running. If
17306 it quits the application, it performs some shutdown actions and then quits the Gtk+ main loop with gtk_main_quit().
17307
17308
17309 @return: Always B{C{True}} to be usable as an event handler. However, if the application is actually terminated, this
17310 function does not return. I{(bool)}
17311 """
17312 return None
17313
17315 """
17316 Gets thumbnail of a recently open file.
17317
17318
17319 @param filename_utf8: Name of a recent file, in UTF-8 encoding. I{(string)}
17320 @return: The thumbnail as a new pixbuf or a pixbuf with a new reference.
17321 The caller must unreference it but not modify it. If not
17322 thumbnail can not be obtained, a fully transparent pixbuf is
17323 returned. I{(L{gdk.Pixbuf})}
17324 """
17325 return None
17326
17328 """
17329 Loads list of recently open files from B{C{filename}}.
17330
17331 Cannot be called more than once (at least not without doing L{gwy_app_recent_file_list_free}() first). Must be called
17332 before any other document history function can be used, even if on a nonexistent file: use B{C{None}} as B{C{filename}} in
17333 that case.
17334
17335
17336 @param filename: Name of file containing list of recently open files. I{(string)}
17337 @return: B{C{True}} if the file was read successfully, B{C{False}} otherwise. I{(bool)}
17338 """
17339 return None
17340
17342 """
17343 Saves list of recently open files to B{C{filename}}.
17344
17345
17346 @param filename: Name of file to save the list of recently open files to. I{(string)}
17347 @return: B{C{True}} if the file was written successfully, B{C{False}} otherwise. I{(bool)}
17348 """
17349 return None
17350
17352 """
17353 Moves B{C{filename_utf8}} to the first position in document history, possibly adding it if not present yet.
17354
17355 At least one of B{C{filename_utf8}}, B{C{filename_sys}} should be set.
17356
17357 @param data: A data container corresponding to the file. I{(L{Container})}
17358 @param filename_utf8: A recent file to insert or move to the first position in document history, in UTF-8. I{(string)}
17359 @param filename_sys: A recent file to insert or move to the first position in document history, in GLib encoding. I{(string)}
17360 @param hint: Preferred channel id to use for thumbnail, pass 0 if no channel is specificaly preferred. I{(int)}
17361 """
17362 pass
17363
17365 """
17366 Restores a window position and/or size from settings.
17367
17368 Unlike L{gwy_app_save_window_position}(), this function has no B{C{position}} and B{C{size}} arguments, it simply restores all
17369 attributes that were saved.
17370
17371 Note to restore position (not size) it should be called twice for each window to accommodate sloppy window
17372 managers: once before the window is shown, second time immediately after showing the window.
17373
17374 Some sanity checks are included, therefore if saved window position and/or size is too suspicious, it is not
17375 restored.
17376
17377 @param window: A window to restore position of. I{(L{gtk.Window})}
17378 @param prefix: Unique prefix in settings to get the information from (the same as
17379 in L{gwy_app_save_window_position}()). I{(string)}
17380 @param grow_only: B{C{True}} to only attempt set the window default size bigger than it
17381 requests, never smaller. I{(bool)}
17382 """
17383 pass
17384
17386 """
17387 Runs a curve map processing function on the current data.
17388
17389 From the run modes function B{C{name}} supports, the most interactive one is selected.
17390
17391 @since: 2.45
17392
17393 @param name: A curve map processing function name. I{(string)}
17394 @return: The actually used mode (nonzero), or 0 on failure. I{(RunType)}
17395 """
17396 return None
17397
17399 """
17400 Runs a curve map processing function on current data in specified mode.
17401
17402 @since: 2.45
17403
17404 @param name: A curve map processing function name. I{(string)}
17405 @param run: A run mode. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
17406 """
17407 pass
17408
17410 """
17411 Runs a graph function on the current graph.
17412
17413 @param name: A graph function name. I{(string)}
17414 """
17415 pass
17416
17418 """
17419 Runs a data processing function on the current data.
17420
17421 From the run modes function B{C{name}} supports, the most interactive one is
17422 selected.
17423
17424
17425 @param name: A data processing function name. I{(string)}
17426 @return: The actually used mode (nonzero), or 0 on failure. I{(RunType)}
17427 """
17428 return None
17429
17431 """
17432 Runs a data processing function on current data in specified mode.
17433
17434 @param name: A data processing function name. I{(string)}
17435 @param run: A run mode. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
17436 """
17437 pass
17438
17440 """
17441 Runs a volume data processing function on the current data.
17442
17443 From the run modes function B{C{name}} supports, the most interactive one is selected.
17444
17445 @since: 2.32
17446
17447 @param name: A volume data processing function name. I{(string)}
17448 @return: The actually used mode (nonzero), or 0 on failure. I{(RunType)}
17449 """
17450 return None
17451
17453 """
17454 Runs a volume data processing function on current data in specified mode.
17455
17456 @since: 2.32
17457
17458 @param name: A volume data processing function name. I{(string)}
17459 @param run: A run mode. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
17460 """
17461 pass
17462
17464 """
17465 Runs a XYZ data processing function on the current data.
17466
17467 From the run modes function B{C{name}} supports, the most interactive one is selected.
17468
17469 @since: 2.45
17470
17471 @param name: A XYZ data processing function name. I{(string)}
17472 @return: The actually used mode (nonzero), or 0 on failure. I{(RunType)}
17473 """
17474 return None
17475
17477 """
17478 Runs a XYZ data processing function on current data in specified mode.
17479
17480 @since: 2.45
17481
17482 @param name: A XYZ data processing function name. I{(string)}
17483 @param run: A run mode. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
17484 """
17485 pass
17486
17488 """
17489 Saves position and/or size of a window to settings.
17490
17491 Some sanity checks are included, therefore if window position and/or size is too suspicious, it is not saved.
17492
17493 @param window: A window to save position of. I{(L{gtk.Window})}
17494 @param prefix: Unique prefix in settings to store the information under. I{(string)}
17495 @param position: B{C{True}} to save position information. I{(bool)}
17496 @param size: B{C{True}} to save size information. I{(bool)}
17497 """
17498 pass
17499
17511
17513 """
17514 Gets the application-wide widget sensitvity group.
17515
17516 The flags to be used with this sensitvity group are defined in B{C{MenuSensFlags}}.
17517
17518
17519 @return: The global sensitvity group instead. No reference is added, you can add yours, but the returned object
17520 will exist to the end of program anyway. I{(L{SensitivityGroup})}
17521 """
17522 return None
17523
17525 """
17526 Sets the state of application-wide widget sensitvity group.
17527
17528 The semantics of this function is the same as L{SensitivityGroup.set_state}() (in fact, it's a simple wrapper
17529 around it).
17530
17531 @param affected_mask: Which bits in B{C{state}} to copy to state. Expected values: C{B{MENU_FLAG_DATA}}, C{B{MENU_FLAG_UNDO}}, C{B{MENU_FLAG_REDO}}, C{B{MENU_FLAG_GRAPH}}, C{B{MENU_FLAG_LAST_PROC}}, C{B{MENU_FLAG_LAST_GRAPH}}, C{B{MENU_FLAG_DATA_MASK}}, C{B{MENU_FLAG_DATA_SHOW}}, C{B{MENU_FLAG_3D}}, C{B{MENU_FLAG_FILE}}, C{B{MENU_FLAG_VOLUME}}, C{B{MENU_FLAG_XYZ}}, C{B{MENU_FLAG_CURVE_MAP}}, C{B{MENU_FLAG_GRAPH_CURVE}}, C{B{MENU_FLAG_MASK}}. I{(L{MenuSensFlags})}
17532 @param state: The new state (masked with B{C{affected_mask}}). Expected values: C{B{MENU_FLAG_DATA}}, C{B{MENU_FLAG_UNDO}}, C{B{MENU_FLAG_REDO}}, C{B{MENU_FLAG_GRAPH}}, C{B{MENU_FLAG_LAST_PROC}}, C{B{MENU_FLAG_LAST_GRAPH}}, C{B{MENU_FLAG_DATA_MASK}}, C{B{MENU_FLAG_DATA_SHOW}}, C{B{MENU_FLAG_3D}}, C{B{MENU_FLAG_FILE}}, C{B{MENU_FLAG_VOLUME}}, C{B{MENU_FLAG_XYZ}}, C{B{MENU_FLAG_CURVE_MAP}}, C{B{MENU_FLAG_GRAPH_CURVE}}, C{B{MENU_FLAG_MASK}}. I{(L{MenuSensFlags})}
17533 """
17534 pass
17535
17537 """
17538 Sets volume data title.
17539
17540 @since: 2.32
17541
17542 @param data: A data container. I{(L{Container})}
17543 @param id: The volume data brick id. I{(int)}
17544 @param name: The title to set. It can be B{C{None}} to use somthing like "Untitled". The id will be appended to it or
17545 (replaced in it if it already ends with digits). I{(string)}
17546 """
17547 pass
17548
17550 """
17551 Sets what the app should use as `current directory'.
17552
17553 Warning: This function is probably temporary.
17554
17555 @param directory: The directory to set, or a filename to take directory part from, it must be an absolute path. In GLib
17556 file name encoding. I{(string)}
17557 """
17558 pass
17559
17561 """
17562 Sets channel title.
17563
17564 @param data: A data container. I{(L{Container})}
17565 @param id: The data channel id. I{(int)}
17566 @param name: The title to set. It can be B{C{None}} to use somthing like "Untitled". The id will be appended to it or
17567 (replaced in it if it already ends with digits). I{(string)}
17568 """
17569 pass
17570
17572 """
17573 Sets B{C{Lawn}} curve map data title.
17574
17575 @since: 2.60
17576
17577 @param data: A data container. I{(L{Container})}
17578 @param id: The B{C{Lawn}} curve map data channel id. I{(int)}
17579 @param name: The title to set. It can be B{C{None}} to use somthing like "Untitled". The id will be appended to it or
17580 (replaced in it if it already ends with digits). I{(string)}
17581 """
17582 pass
17583
17585 """
17586 Sets XYZ surface data title.
17587
17588 @since: 2.45
17589
17590 @param data: A data container. I{(L{Container})}
17591 @param id: The XYZ surface data channel id. I{(int)}
17592 @param name: The title to set. It can be B{C{None}} to use somthing like "Untitled". The id will be appended to it or
17593 (replaced in it if it already ends with digits). I{(string)}
17594 """
17595 pass
17596
17598 """
17599 Create gwyddion config directory.
17600
17601
17602 @return: Whether it succeeded (also returns B{C{True}} if the directory already
17603 exists). I{(bool)}
17604 """
17605 return None
17606
17608 """
17609 Returns error domain for application settings operations.
17610
17611 See and use B{C{APP_SETTINGS_ERROR}}.
17612
17613
17614 @return: The error domain. I{(int)}
17615 """
17616 return None
17617
17619 """
17620 Gets the Gwyddion settings.
17621
17622 The program settings are a B{C{Container}} automatically loaded at program startup and saved ad its exit. For
17623 storing persistent module data manually you should use C{"/module/YOUR_MODULE_NAME/"} prefix.
17624 However, in common cases you should use B{C{ParamDef}} and B{C{Params}} which can handle the dirty work themselves.
17625
17626
17627 @return: The settings as a B{C{Container}}. I{(L{Container})}
17628 """
17629 return None
17630
17632 """
17633 Returns a suitable log file name.
17634
17635
17636 @return: The file name as a newly allocated string. I{(string)}
17637 """
17638 return None
17639
17641 """
17642 Returns a suitable recent file list file name.
17643
17644
17645 @return: The file name as a newly allocated string. I{(string)}
17646 """
17647 return None
17648
17650 """
17651 Returns a suitable human-readable settings file name.
17652
17653
17654 @return: The file name as a newly allocated string. I{(string)}
17655 """
17656 return None
17657
17659 """
17660 Loads settings file.
17661
17662
17663 @param filename: A filename to read settings from. I{(string)}
17664 @return: Whether it succeeded. In either case you can call L{gwy_app_settings_get}() then to obtain either the loaded
17665 settings or the old ones (if failed), or an empty B{C{Container}}. I{(bool)}
17666 """
17667 return None
17668
17670 """
17671 Saves the settings.
17672
17673 Use L{gwy_app_settings_get_settings_filename}() to obtain a suitable default filename.
17674
17675
17676 @param filename: A filename to save the settings to. I{(string)}
17677 @return: Whether it succeeded. I{(bool)}
17678 """
17679 return None
17680
17682 """
17683 Sets up Gwyddion GLib log handler.
17684
17685 The log handler sends the messages to a log file or console, as Gwyddion
17686 usually does. This function may not be useful in Gwyddion-based programs
17687 unless they try to emulate Gwyddion behaviour closely.
17688
17689 @since: 2.45
17690
17691 @param flags: Flags controlling how messages are handled. Expected values: C{B{APP_LOGGING_TO_FILE}}, C{B{APP_LOGGING_TO_CONSOLE}}. I{(L{AppLoggingFlags})}
17692 """
17693 pass
17694
17706
17708 """
17709 Synchronizes auxiliary image data items between data containers.
17710
17711 @param source: Source container. I{(L{Container})}
17712 @param dest: Target container (may be identical to source). I{(L{Container})}
17713 @param from_id: Data number to copy items from. I{(int)}
17714 @param to_id: Data number to copy items to. I{(int)}
17715 @param delete_too: B{C{True}} to delete items in target if source does not contain
17716 them, B{C{False}} to copy only. I{(bool)}
17717 @param items: I{(list)}
17718 """
17719 pass
17720
17722 """
17723 Create a point in the undo history it is possible to return to.
17724
17725 In addition to what L{gwy_undo_checkpoint}() does, this function takes care
17726 of updating application controls state.
17727
17728
17729 @param container: I{(L{Container})}
17730 @param keys: I{(StringArray*)}
17731 @return: Undo level id (zero if undo/redo is disabled). Not useful (yet). I{(gulong)}
17732 """
17733 return None
17734
17736 """
17737 Removes undo/redo information for a data container.
17738
17739 In addition to what L{gwy_undo_container_remove}() does, this function takes
17740 care of updating application controls state.
17741
17742 @since: 2.23
17743
17744 @param data: A data container managed by the data-browser. I{(L{Container})}
17745 @param prefix: Prefix to remove undo/redo information under. Pass B{C{None}} to remove
17746 undo/redo information altogether. I{(string)}
17747 """
17748 pass
17749
17751 """
17752 Create a point in the undo history it is possible to return to.
17753
17754 In addition to what L{gwy_undo_checkpoint}() does, this function takes care
17755 of updating application controls state.
17756
17757
17758 @param container: I{(L{Container})}
17759 @param keys: I{(list)}
17760 @return: Undo level id. Not useful (yet). I{(gulong)}
17761 """
17762 return None
17763
17765 """
17766 Performs undo on a data container.
17767
17768 It must have redo available.
17769
17770 In addition to what L{gwy_undo_redo_container}() does, this function takes care
17771 of updating application controls state.
17772
17773 @param data: A data container. I{(L{Container})}
17774 """
17775 pass
17776
17778 """
17779 Performs undo on a data container.
17780
17781 It must have undo available.
17782
17783 In addition to what L{gwy_undo_undo_container}() does, this function takes care
17784 of updating application controls state.
17785
17786 @param data: A data container. I{(L{Container})}
17787 """
17788 pass
17789
17791 """
17792 Adds an entry to the log of the current volume data processing operations for volume data.
17793
17794 This simplified variant of L{gwy_app_volume_log_add}() takes the currently running function volume data processing
17795 name and constructs the qualified function name from that.
17796
17797 @since: 2.38
17798
17799 @param data: A data container. I{(L{Container})}
17800 @param previd: Identifier of the previous (source) volume data in the container.
17801 Pass -1 for a no-source (or unclear source) operation. I{(int)}
17802 @param newid: Identifier of the new (target) volume data in the container. I{(int)}
17803 """
17804 pass
17805
17807 """
17808 Resets the cursor for a window.
17809
17810 This function lets the Gtk+ main loop to run.
17811
17812 If the window cursor was non-default before L{gwy_app_wait_cursor_start}(), it is not restored and has to be set
17813 manually. This limitation is due to the nonexistence of a method to obtain the current cursor.
17814
17815 @since: 2.3
17816
17817 @param window: A window. I{(L{gtk.Window})}
17818 """
17819 pass
17820
17822 """
17823 Changes the cursor for a window to indicate work.
17824
17825 This function lets the Gtk+ main loop to run.
17826
17827 @since: 2.3
17828
17829 @param window: A window. I{(L{gtk.Window})}
17830 """
17831 pass
17832
17834 """
17835 Finishes waiting, closing the dialog.
17836
17837 No function like L{gwy_app_wait_set_message}() should be call after that.
17838
17839 This function must be called even if user cancelled the operation.
17840
17841 """
17842 pass
17843
17845 """
17846 Reports whether progress reporting is globally enabled.
17847
17848 @since: 2.48
17849
17850 @return: B{C{True}} if progress reporting is enabled, B{C{False}} if it is disabled. I{(bool)}
17851 """
17852 return None
17853
17855 """
17856 Helper function for progressive animated preview.
17857
17858 This is a wrapper for L{gwy_app_wait_set_preview_widget}() which creates a simple image preview displaying B{C{dfield}}.
17859 Call L{DataField.data_changed}() on it to redraw the preview.
17860
17861 No preview is created if progress bars are disabled, see L{gwy_app_wait_set_enabled}().
17862
17863 @since: 2.59
17864
17865 @param dfield: A data field used for preview. I{(L{DataField})}
17866 @param data: Data container with source image (or B{C{None}}). I{(L{Container})}
17867 @param id: Source image id (or -1). I{(int)}
17868 @return: The created B{C{DataView}} with the preview (possibly B{C{None}} if not preview was actually created). Usually
17869 you can ignore it. I{(L{gtk.Widget})}
17870 """
17871 return None
17872
17874 """
17875 Globally enables or disables progress reporting.
17876
17877 This function may not be used when a waiting dialog is currently being shown.
17878
17879 By default, progress reporting is enabled. Non-GUI applications that run module functions may wish to disable it
17880 to avoid GTK+ calls or just showing the progress dialogs.
17881
17882 If progress reporting is disabled then functions such as L{gwy_app_wait_set_message}() and L{gwy_app_wait_set_fraction}()
17883 become no-op and always return B{C{True}} as nothing can be cancelled by the user. Functions
17884 L{gwy_app_wait_cursor_start}() and L{gwy_app_wait_cursor_finish}() still work but may be called with B{C{None}} arguments.
17885
17886 @since: 2.48
17887
17888 @param setting: B{C{True}} to enable progress reporting, B{C{False}} to disable it. I{(bool)}
17889 """
17890 pass
17891
17893 """
17894 Sets the amount of progress the progress bar on the dialog displays.
17895
17896 This function may let the Gtk+ main loop to run. It used to let the main loop to run always. Since version 2.46
17897 it performs automated rate-limiting and only does so if sufficient time has passed since the last main loop
17898 invocation. Therefore, you can call it 10000 times per second without fearing that the program will spend all time
17899 updating the GUI and no time in the calculation.
17900
17901 It must not be called again once the operation is cancelled, i.e. after any of the progress reporting functions
17902 return B{C{False}}.
17903
17904
17905 @param fraction: The progress of the operation, as a number from 0 to 1. I{(float)}
17906 @return: B{C{True}} if the operation can continue, B{C{False}} if user cancelled it meanwhile. You must always check the
17907 return value and cancel the operation if it is B{C{False}}. I{(bool)}
17908 """
17909 return None
17910
17912 """
17913 Sets the message shown on the progress dialog.
17914
17915 See also L{gwy_app_wait_set_message_prefix}() which makes this function more usable directly as a callback.
17916
17917 This function lets the Gtk+ main loop to run.
17918
17919 It must not be called again once the operation is cancelled, i.e. after any of the progress reporting functions
17920 return B{C{False}}.
17921
17922
17923 @param message: A mesage to show in the progress dialog. I{(string)}
17924 @return: B{C{True}} if the operation can continue, B{C{False}} if user cancelled it meanwhile. You must always check the
17925 return value and cancel the operation if it is B{C{False}}. I{(bool)}
17926 """
17927 return None
17928
17930 """
17931 Sets prefix for the messages shown in the progress dialog.
17932
17933 The prefix will take effect in the next L{gwy_app_wait_set_message}() call.
17934
17935 This function lets the Gtk+ main loop to run.
17936
17937 It must not be called again once the operation is cancelled, i.e. after any of the progress reporting functions
17938 return B{C{False}}.
17939
17940
17941 @param prefix: The prefix for new messages. I{(string)}
17942 @return: B{C{True}} if the operation can continue, B{C{False}} if user cancelled it meanwhile. You must always check the
17943 return value and cancel the operation if it is B{C{False}}. I{(bool)}
17944 """
17945 return None
17946
17958
17960 """
17961 Starts waiting for a window B{C{window}}, creating a dialog with a progress bar.
17962
17963 Waiting is global, there can be only one at a time.
17964
17965 Do not forget to call L{gwy_app_wait_finish}() when the computation is finished (or cancelled). You should also call
17966 L{gwy_app_wait_set_fraction}() or L{gwy_app_wait_set_message}() regularly to leave the GUI responsive.
17967
17968 @param window: A window. I{(L{gtk.Window})}
17969 @param message: A message to show in the wait dialog. I{(string)}
17970 """
17971 pass
17972
17974 """
17975 Checks if a progress dialog was cancelled.
17976
17977 Calling this function is only meaningful between L{gwy_app_wait_start}() and L{gwy_app_wait_finish}(). It returns B{C{True}}
17978 if the computation was cancelled by the user. This may be occasionaly useful in complex multi-level calculations.
17979 Usually, the return values of L{gwy_app_wait_set_fraction}() and L{gwy_app_wait_set_message}() are sufficient.
17980
17981 @since: 2.49
17982
17983 @return: B{C{True}} if the currently running calculation was cancelled. I{(bool)}
17984 """
17985 return None
17986
17988 """
17989 Adds an entry to the log of the current XYZ data processing operations for XYZ data.
17990
17991 This simplified variant of L{gwy_app_xyz_log_add}() takes the currently running function XYZ data processing name and
17992 constructs the qualified function name from that.
17993
17994 @since: 2.45
17995
17996 @param data: A data container. I{(L{Container})}
17997 @param previd: Identifier of the previous (source) XYZ data in the container.
17998 Pass -1 for a no-source (or unclear source) operation. I{(int)}
17999 @param newid: Identifier of the new (target) XYZ data in the container. I{(int)}
18000 """
18001 pass
18002
18004 """
18005 Adds a XYZ data title based on surface value units.
18006
18007 The guess is very simple, but probably better than `Unknown channel' in
18008 most cases. If there already is a title it is left intact, making use of
18009 this function as a fall-back easier.
18010
18011 @since: 2.45
18012
18013 @param data: A data container. I{(L{Container})}
18014 @param id: XYZ surface data id. I{(int)}
18015 @return: B{C{True}} if the title was set (either by this function or before). I{(bool)}
18016 """
18017 return None
18018
18020 """
18021 Canonicalizes an angle to requested interval.
18022
18023 For B{C{positive}}=B{C{False}}, B{C{oriented}}=B{C{False}} the output interval is [-π/2,π/2].
18024
18025 For B{C{positive}}=B{C{False}}, B{C{oriented}}=B{C{True}} the output interval is [-π,π].
18026
18027 For B{C{positive}}=B{C{True}}, B{C{oriented}}=B{C{False}} the output interval is [0,π).
18028
18029 For B{C{positive}}=B{C{True}}, B{C{oriented}}=B{C{True}} the output interval is [0,2π).
18030
18031 @since: 2.50
18032
18033 @param phi: Angle to canonicalize, in radians. I{(float)}
18034 @param positive: B{C{True}} if a positive angle is requested, B{C{False}} for outputs symmetrical around zero. I{(bool)}
18035 @param oriented: B{C{True}} for direction of a vector, B{C{False}} for the direction of a line (i.e. with no distinction between
18036 forward and backward direction). I{(bool)}
18037 @return: Canonicalized angle, equivalent (in given sense) to B{C{phi}}. I{(float)}
18038 """
18039 return None
18040
18042 """
18043 Canonicalizes a filesystem path.
18044
18045 Particularly it makes the path absolute, resolves `..' and `.', and fixes slash sequences to single slashes. On
18046 Win32 it also converts all backslashes to slashes along the way.
18047
18048 Note this function does NOT resolve symlinks, use g_file_read_link() for that.
18049
18050
18051 @param path: A filesystem path. I{(string)}
18052 @return: The canonical path, as a newly created string. I{(string)}
18053 """
18054 return None
18055
18057 """
18058 Gets inventory with all the critical dimension evaluators.
18059
18060
18061 @return: Critical dimension evaluator inventory. I{(L{Inventory})}
18062 """
18063 return None
18064
18066 """
18067 Gets the flag value associated with a check box.
18068
18069 @since: 2.51
18070
18071 @param checkbox: A check box belonging to a group created by
18072 L{gwy_check_boxes_create}() or L{gwy_check_boxes_createl}(). I{(L{gtk.Widget})}
18073 @return: The flag value corresponding to B{C{button}}. I{(int)}
18074 """
18075 return None
18076
18078 """
18079 Creates a new color axis.
18080
18081
18082 @param orientation: The orientation of the axis. I{(GtkOrientation)}
18083 @param min: The minimum. I{(float)}
18084 @param max: The maximum. I{(float)}
18085 @return: The newly created color axis as a B{C{GtkWidget}}. I{(L{gtk.Widget})}
18086 """
18087 return None
18088
18098
18100 """
18101 Creates and runs a color selector dialog for a mask.
18102
18103 See L{gwy_mask_color_selector_run}() for details.
18104
18105 @param dialog_title: Title of the color selection dialog (B{C{None}} to use default). I{(string)}
18106 @param color_button: Color button to update on color change (or B{C{None}}). I{(L{ColorButton})}
18107 @param container: Container to initialize the color from and save it to. I{(L{Container})}
18108 @param prefix: Prefix in B{C{container}} (normally "/0/mask"). I{(string)}
18109 """
18110 pass
18111
18113 """
18114 Creates an enum combo box with curves from a graph model.
18115
18116 This function is intended for selection of curves from static graphs in graph modules. The graph model is not
18117 permitted to change.
18118
18119 @since: 2.45
18120
18121 @param gmodel: A graph model. I{(L{GraphModel})}
18122 @param current: Index of currently selected curve. I{(int)}
18123 @return: The newly created combo box as B{C{GtkWidget}}. I{(L{gtk.Widget})}
18124 """
18125 return None
18126
18128 """
18129 Creates an enum combo box with SI power of 10 multiplies.
18130
18131 The integer value is the power of 10.
18132
18133
18134 @param from_: I{(int)}
18135 @param to: The exponent of 10 the menu should end at (a multiple of 3, will be rounded upward if isn't). I{(int)}
18136 @param unit: The unit to be prefixed. I{(L{SIUnit})}
18137 @param active: The power of 10 to show as currently selected (a multiple of 3). I{(int)}
18138 @return: The newly created combo box as B{C{GtkWidget}}. I{(L{gtk.Widget})}
18139 """
18140 return None
18141
18143 """
18144 Changes the unit selection displayed by a metric unit combo box.
18145
18146 @since: 2.5
18147
18148 @param combo: A combo box which was created with L{gwy_combo_box_metric_unit_new}(). I{(L{gtk.ComboBox})}
18149 @param from_: I{(int)}
18150 @param to: The exponent of 10 the menu should end at (a multiple of 3, will be rounded upward if isn't). I{(int)}
18151 @param unit: The unit to be prefixed. I{(L{SIUnit})}
18152 """
18153 pass
18154
18157
18159 """
18160 Restores a container from is text representation.
18161
18162
18163 @param text: Text containing serialized container contents as dumped by
18164 L{Container.serialize_to_text}(). I{(string)}
18165 @return: The restored container, or B{C{None}} on failure. I{(L{Container})}
18166 """
18167 return None
18168
18170 """
18171 Creates the typical data processing dialog hbox with a preview.
18172
18173 The box is added to the dialog.
18174
18175 @since: 2.59
18176
18177 @param dialog: A data processing dialog. I{(L{gtk.Dialog})}
18178 @param dataview: Preview data view, usually created by L{gwy_create_preview}(). I{(L{DataView})}
18179 @param pack_end: B{C{True}} to pack the data view to the end; B{C{False}} to pack it to the start. I{(bool)}
18180 @return: A new B{C{GtkBox}} widget. I{(L{gtk.Widget})}
18181 """
18182 return None
18183
18185 """
18186 Creates and sets up a preview widget for use in modules.
18187
18188 @since: 2.59
18189
18190 @param data: Data container with images to preview. I{(L{Container})}
18191 @param id: Data id of preview image in B{C{data}}. I{(int)}
18192 @param size: Preview size. Prefrably one of the standard sizes. I{(int)}
18193 @param have_mask: B{C{True}} if the preview will have mask and should be set up so. I{(bool)}
18194 @return: A new data view widget with the preview. I{(L{gtk.Widget})}
18195 """
18196 return None
18197
18199 """
18200 Creates and sets up a vector layer for use in module previews.
18201
18202 The selection's key will have the form "/0/select/lcname", where B{C{lcname}} is the lowercase version of B{C{name}}. You
18203 can query the layer using B{C{DataView}} functions.
18204
18205 Parameters B{C{max_objects}} and B{C{editable}} exist for convenience. The corresponding properties can be modified later.
18206
18207 In typical scenarios this function is also suitable for switching vector layers in the preview. Simply create
18208 a different layer and the current one will be discarded – this assumes you do not keep the old layer object around.
18209 Selections are kept in B{C{dataview}}'s data, so they will be automatically restored when switching back and forth.
18210
18211 @since: 2.61
18212
18213 @param dataview: Preview data view, usually created by L{gwy_create_preview}(). I{(L{DataView})}
18214 @param id: Data id of preview image in B{C{dataview}}'s data. I{(int)}
18215 @param name: Layer/selection type name, without the Layer/Selection prefix. So usually "Point", "Line" or
18216 "Rectangle". I{(string)}
18217 @param max_objects: Maximum number of objects in the selection. I{(int)}
18218 @param editable: B{C{True}} for a user-editable selection, B{C{False}} to disable editing. I{(bool)}
18219 @return: The layer's selection. No reference is added; use g_object_ref() if you want to keep the selection
18220 around after the preview is destroyed. I{(L{Selection})}
18221 """
18222 return None
18223
18225 """
18226 Obtains the name of currently running curve map processing function.
18227
18228 If no curve map processing function is currently running, B{C{None}} is returned.
18229
18230 If multiple nested functions are running (which is not usual but technically possible), the innermost function name
18231 is returned.
18232
18233 @since: 2.60
18234
18235 @return: The name of currently running curve map processing function or B{C{None}}. I{(string)}
18236 """
18237 return None
18238
18240 """
18241 Checks whether a curve map processing function exists.
18242
18243 @since: 2.60
18244
18245 @param name: Curve map data processing function name. I{(string)}
18246 @return: B{C{True}} if function B{C{name}} exists, B{C{False}} otherwise. I{(bool)}
18247 """
18248 return None
18249
18251 """
18252 Returns the menu path of a curve map processing function.
18253
18254 The returned menu path is only the tail part registered by the function, i.e., without any leading "/Curve Map".
18255
18256 @since: 2.60
18257
18258 @param name: Curve map data processing function name. I{(string)}
18259 @return: The menu path. The returned string is owned by the module. I{(string)}
18260 """
18261 return None
18262
18264 """
18265 Returns run modes supported by a curve map processing function.
18266
18267 @since: 2.60
18268
18269 @param name: Curve map data processing function name. I{(string)}
18270 @return: The run mode bit mask. I{(RunType)}
18271 """
18272 return None
18273
18275 """
18276 Gets menu sensititivy mask for a curve map processing function.
18277
18278 @since: 2.60
18279
18280 @param name: Curve map data processing function name. I{(string)}
18281 @return: The menu item sensitivity mask (a combination of B{C{MenuSensFlags}} flags). I{(int)}
18282 """
18283 return None
18284
18286 """
18287 Gets stock icon id of a curve map processing function.
18288
18289 @since: 2.60
18290
18291 @param name: Curve map data processing function name. I{(string)}
18292 @return: The stock icon id. The returned string is owned by the module. I{(string)}
18293 """
18294 return None
18295
18306
18308 """
18309 Runs a curve map processing function identified by B{C{name}}.
18310
18311 @since: 2.60
18312
18313 @param name: Curve map data processing function name. I{(string)}
18314 @param data: Data (a B{C{Container}}). I{(L{Container})}
18315 @param run: How the function should be run. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
18316 """
18317 pass
18318
18321
18323 """
18324 Creates a data chooser for data channels.
18325
18326
18327 @return: A new channel chooser. Nothing may be assumed about the type and properties of the returned widget as
18328 they can change in the future. I{(L{gtk.Widget})}
18329 """
18330 return None
18331
18333 """
18334 Creates a data chooser for curve map data.
18335
18336 @since: 2.60
18337
18338 @return: A new curve map data chooser. Nothing may be assumed about the type and properties of the returned widget
18339 as they can change in the future. I{(L{gtk.Widget})}
18340 """
18341 return None
18342
18344 """
18345 Creates a data chooser for graphs.
18346
18347 @since: 2.41
18348
18349 @return: A new graph chooser. Nothing may be assumed about the type and properties of the returned widget as they
18350 can change in the future. I{(L{gtk.Widget})}
18351 """
18352 return None
18353
18355 """
18356 Creates a data chooser for volume data.
18357
18358 @since: 2.33
18359
18360 @return: A new volume chooser. Nothing may be assumed about the type and properties of the returned widget as they
18361 can change in the future. I{(L{gtk.Widget})}
18362 """
18363 return None
18364
18366 """
18367 Creates a data chooser for XYZ data.
18368
18369 @since: 2.45
18370
18371 @return: A new XYZ data chooser. Nothing may be assumed about the type and properties of the returned widget as
18372 they can change in the future. I{(L{gtk.Widget})}
18373 """
18374 return None
18375
18377 """
18378 Destroys a correlation iterator, freeing all resources.
18379
18380 @param state: Correlation iterator. I{(ComputationState*)}
18381 """
18382 pass
18383
18385 """
18386 Performs one iteration of correlation.
18387
18388 An iterator can be created with L{DataField.correlate_init}(). When iteration ends, either by finishing or being
18389 aborted, L{DataField.correlate_finalize}() must be called to release allocated resources.
18390
18391 @param state: Correlation iterator. I{(ComputationState*)}
18392 """
18393 pass
18394
18396 """
18397 Destroys a cross-correlation iterator, freeing all resources.
18398
18399 @param state: Cross-correlation iterator. I{(ComputationState*)}
18400 """
18401 pass
18402
18404 """
18405 Performs one iteration of cross-correlation.
18406
18407 Cross-correlation matches two different images of the same object under changes.
18408
18409 It does not use any special features for matching. It simply searches for all points (with their neighbourhood) of
18410 B{C{data_field1}} within B{C{data_field2}}. Parameters B{C{search_width}} and B{C{search_height}} determine maimum area where to search
18411 for points. The area is cenetered in the B{C{data_field2}} at former position of points at B{C{data_field1}}.
18412
18413 A cross-correlation iterator can be created with L{DataField.crosscorrelate_init}(). When iteration ends, either
18414 by finishing or being aborted, L{DataField.crosscorrelate_finalize}() must be called to release allocated
18415 resources.
18416
18417 @param state: Cross-correlation iterator. I{(ComputationState*)}
18418 """
18419 pass
18420
18422 """
18423 Sets the weight function to be used within iterative cross-correlation algorithm.
18424
18425 By default (not setting it), rectangular windowing is used. This function should be called before running first
18426 iteration to get consistent results.
18427
18428 @param state: Cross-correlation iterator. I{(ComputationState*)}
18429 @param type: Set windowing type to be set as correlation weight, see B{C{WindowingType}} for details. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
18430 """
18431 pass
18432
18434 """
18435 Computes fractal dimension by cube counting method from log-log plot data.
18436
18437 The B{C{xresult}} and B{C{yresult}} data lines are usually calculated by L{DataField.fractal_cubecounting}().
18438
18439
18440 @param xresult: Log-log fractal data (x values). I{(L{DataLine})}
18441 @param yresult: Log-log fractal data (y values). I{(L{DataLine})}
18442 @return: Tuple consisting of 3 values (B{C{value}}, B{C{a}}, B{C{b}}). (I{(float)}, I{(float)}, I{(float)})
18443 """
18444 return None, None, None
18445
18447 """
18448 Computes fractal dimension by partitioning method from log-log plot data.
18449
18450 The B{C{xresult}} and B{C{yresult}} data lines are usually calculated by L{DataField.fractal_partitioning}().
18451
18452
18453 @param xresult: Log-log fractal data (x values). I{(L{DataLine})}
18454 @param yresult: Log-log fractal data (y values). I{(L{DataLine})}
18455 @return: Tuple consisting of 3 values (B{C{value}}, B{C{a}}, B{C{b}}). (I{(float)}, I{(float)}, I{(float)})
18456 """
18457 return None, None, None
18458
18460 """
18461 Computes fractal dimension by spectral density function method from log-log plot data.
18462
18463 The B{C{xresult}} and B{C{yresult}} data lines are usually calculated by L{DataField.fractal_psdf}().
18464
18465
18466 @param xresult: Log-log fractal data (x values). I{(L{DataLine})}
18467 @param yresult: Log-log fractal data (y values). I{(L{DataLine})}
18468 @return: Tuple consisting of 3 values (B{C{value}}, B{C{a}}, B{C{b}}). (I{(float)}, I{(float)}, I{(float)})
18469 """
18470 return None, None, None
18471
18473 """
18474 Computes fractal dimension by triangulation method from log-log plot data.
18475
18476 The B{C{xresult}} and B{C{yresult}} data lines are usually calculated by L{DataField.fractal_triangulation}().
18477
18478
18479 @param xresult: Log-log fractal data (x values). I{(L{DataLine})}
18480 @param yresult: Log-log fractal data (y values). I{(L{DataLine})}
18481 @return: Tuple consisting of 3 values (B{C{value}}, B{C{a}}, B{C{b}}). (I{(float)}, I{(float)}, I{(float)})
18482 """
18483 return None, None, None
18484
18486 """
18487 Calculates an upper bound of the number of samples in a circular region.
18488
18489
18490 @param radius: Circular area radius (in pixels). I{(float)}
18491 @return: The number of pixels in a circular region with given rectangular bounds (or its upper bound). I{(int)}
18492 """
18493 return None
18494
18496 """
18497 Calculates an upper bound of the number of samples in an elliptic region.
18498
18499 This function is useful for elliptic areas more or less contained within the data field. Otherwise the returned
18500 size can be overestimated a lot. Use L{DataField.get_elliptic_intersection}() for elliptic areas intersecting the
18501 data field in arbitrary manner.
18502
18503
18504 @param width: Bounding box width. I{(int)}
18505 @param height: Bounding box height. I{(int)}
18506 @return: The number of pixels in an elliptic region with given rectangular bounds (or its upper bound). I{(int)}
18507 """
18508 return None
18509
18511 """
18512 Destroys a watershed iterator, freeing all resources.
18513
18514 @param state: Watershed iterator. I{(ComputationState*)}
18515 """
18516 pass
18517
18519 """
18520 Performs one iteration of the watershed algorithm.
18521
18522 Fields B{C{state}} and progress B{C{fraction}} of watershed state are updated
18523 (fraction is calculated for each phase individually). Once B{C{state}}
18524 becomes B{C{WATERSHED_STATE_FINISHED}}, the calculation is finised.
18525
18526 A watershed iterator can be created with
18527 L{DataField.grains_watershed_init}(). When iteration ends, either
18528 by finishing or being aborted, L{DataField.grains_watershed_finalize}()
18529 must be called to release allocated resources.
18530
18531 @param state: Watershed iterator. I{(ComputationState*)}
18532 """
18533 pass
18534
18537
18539 """
18540 Finds rotation corrections.
18541
18542 Rotation correction is computed for for all symmetry types.
18543 In addition an estimate is made about the prevalent one.
18544
18545
18546 @param derdist: Angular derivation distribution (normally obrained from
18547 L{DataField.slope_distribution}()). I{(L{DataLine})}
18548 @return: Tuple consisting of 2 values (B{C{value}}, B{C{correction}}). (I{(PlaneSymmetry)}, I{(list)})
18549 """
18550 return None, None
18551
18562
18582
18584 """
18585 Returns B{C{True}}.
18586
18587 Use gtk_true() instead.
18588
18589
18590 @return: B{C{True}}. I{(bool)}
18591 """
18592 return None
18593
18595 """
18596 Maps ordinate values to interval [0,1] as
18597 L{gwy_pixbuf_draw_data_field_adaptive}() would do.
18598
18599 This is useful to find out which positions in the false colour gradient
18600 correspond to specific values.
18601
18602 @since: 2.39
18603
18604 @param data_field: A data field to draw. I{(L{DataField})}
18605 @param z: Array of B{C{n}} data values to map. I{(list)}
18606 @return: I{(list)}
18607 """
18608 return None
18609
18611 """
18612 Makes libgwydraw types safe for deserialization and performs other
18613 initialization. You have to call this function before using objects
18614 from libgwydraw.
18615
18616 Calls L{gwy_process_type_init}() first to make sure libgwyprocess is
18617 initialized.
18618
18619 It is safe to call this function more than once, subsequent calls are no-op.
18620
18621 """
18622 pass
18623
18625 """
18626 Fills resampled or nely allocated data line with wavelet coefficients.
18627
18628
18629 @param dline: Data line to store wavelet coefficients to (or B{C{None}} to allocate
18630 a new one). I{(L{DataLine})}
18631 @param type: Wavelet type. Expected values: C{B{DWT_HAAR}}, C{B{DWT_DAUB4}}, C{B{DWT_DAUB6}}, C{B{DWT_DAUB8}}, C{B{DWT_DAUB12}}, C{B{DWT_DAUB20}}. I{(L{DWTType})}
18632 @return: resampled or newly allocated DataLine with wavelet coefficients. I{(L{DataLine})}
18633 """
18634 return None
18635
18637 """
18638 Returns a constant inventory with all available entities.
18639
18640
18641 @return: The entities as a B{C{Inventory}}. I{(L{Inventory})}
18642 """
18643 return None
18644
18646 """
18647 Converts a single named entity B{C{entity}} to UTF-8 representation.
18648
18649 The string passed to this function should be a bare entity name, i.e. it
18650 should not contain the ampersand and semicolon.
18651
18652
18653 @param entity: A single entity name, as a nul-delimited string. I{(string)}
18654 @return: B{C{entity}} if the name was not recognized, or a valid UTF-8 string.
18655 If the returned string is not equal to B{C{entities}}, it's owned by
18656 entities and must not be freed nor modified. I{(string)}
18657 """
18658 return None
18659
18661 """
18662 Converts entities in a text to UTF-8.
18663
18664
18665 @param text: A nul-delimited string. I{(string)}
18666 @return: A newly allocated nul-delimited string containing the converted
18667 text. I{(string)}
18668 """
18669 return None
18670
18672 """
18673 Gets the enum value corresponding to currently active combo box item.
18674
18675
18676 @param combo: A combo box which was created with L{gwy_enum_combo_box_new}(). I{(L{gtk.ComboBox})}
18677 @return: The selected enum value. I{(int)}
18678 """
18679 return None
18680
18682 """
18683 Sets the active combo box item by corresponding enum value.
18684
18685 @param combo: A combo box which was created with L{gwy_enum_combo_box_new}(). I{(L{gtk.ComboBox})}
18686 @param active: The enum value to show as currently selected. I{(int)}
18687 """
18688 pass
18689
18691 """
18692 Convenience callback keeping an integer synchronized with selected enum combo box value.
18693
18694 @param combo: A combo box which was created with L{gwy_enum_combo_box_new}(). I{(L{gtk.ComboBox})}
18695 @return: Value B{C{integer}}. (I{(int)})
18696 """
18697 return None
18698
18700 """
18701 Makes sure an enum value is valid.
18702
18703
18704 @param enumval: An enum value. I{(int)}
18705 @param enum_type: B{C{GType}} of a registered enum type. I{(GType)}
18706 @return: Either B{C{enumval}} itself if it's valid, or some valid enum value. When B{C{enumval}} is invalid and larger than
18707 all valid values the largest valid value is returned. Likewise if it's smaller the smallest valid value is
18708 returned. If it's in range but invalid, the first enum value is returned. I{(int)}
18709 """
18710 return None
18711
18713 """
18714 Returns error domain for expression parsin and evaluation.
18715
18716 See and use B{C{EXPR_ERROR}}.
18717
18718
18719 @return: The error domain. I{(int)}
18720 """
18721 return None
18722
18724 """
18725 Gets inventory with all the FD curve presets.
18726
18727 @since: 2.7
18728
18729 @return: FD curve preset inventory. I{(L{Inventory})}
18730 """
18731 return None
18732
18734 """
18735 Finds a nice-for-FFT array size.
18736
18737 Here ‘nice’ means three properties are guaranteed: it is greater than or equal to B{C{size}}; it can be directly used
18738 with current FFT backend without scaling (since 2.8 this is true for any size); and the transform is fast, i.e. the
18739 number is highly factorable.
18740
18741 To be compatible with Gwyddion <= 2.7 one has to pass only data fields and lines with sizes returned by this
18742 function to raw integral transforms. Otherwise this function is mainly useful if you extend and pad the input data
18743 for other reasons and thus have the freedom to choose a convenient transform size.
18744
18745
18746 @param size: Transform size. I{(int)}
18747 @return: A nice FFT array size. I{(int)}
18748 """
18749 return None
18750
18752 """
18753 Multiplies data by given window.
18754
18755 @param data: Data values. I{(list)}
18756 @param windowing: Method used for windowing. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
18757 @return: I{(list)}
18758 """
18759 return None
18760
18762 """
18763 Performs windowing of a data field in given direction.
18764
18765 This is an old alias for L{DataField.fft_window_1d}().
18766
18767 @param dfield: A data field. I{(L{DataField})}
18768 @param orientation: Windowing orientation (the same as corresponding FFT orientation). Expected values: C{B{ORIENTATION_HORIZONTAL}}, C{B{ORIENTATION_VERTICAL}}. I{(L{Orientation})}
18769 @param windowing: The windowing type to use. Expected values: C{B{WINDOWING_NONE}}, C{B{WINDOWING_HANN}}, C{B{WINDOWING_HAMMING}}, C{B{WINDOWING_BLACKMANN}}, C{B{WINDOWING_LANCZOS}}, C{B{WINDOWING_WELCH}}, C{B{WINDOWING_RECT}}, C{B{WINDOWING_NUTTALL}}, C{B{WINDOWING_FLAT_TOP}}, C{B{WINDOWING_KAISER25}}. I{(L{WindowingType})}
18770 """
18771 pass
18772
18774 """
18775 Frees or unmmaps memory allocated by L{gwy_file_get_contents}().
18776
18777
18778 @param buffer: Buffer with file contents as created by L{gwy_file_get_contents}(). I{(guchar*)}
18779 @param size: Buffer size. I{(gsize)}
18780 @return: Whether it succeeded. Since 2.22 it always return B{C{True}}. I{(bool)}
18781 """
18782 return None
18783
18785 """
18786 Logs the import of a channel from third-party file.
18787
18788 This is a convenience wrapper for L{gwy_app_channel_log_add}(). The source id
18789 will be set to -1. The file name will be added to function arguments.
18790
18791 @since: 2.35
18792
18793 @param data: A data container. I{(L{Container})}
18794 @param id: Data channel id. I{(int)}
18795 @param filetype: File type, i.e. the name of the function importing the data
18796 (without any "file::" prefix). Since 2.38 it is possible to
18797 pass B{C{None}} to fill the name of the currently running file type
18798 function automatically. I{(string)}
18799 @param filename: Name of the imported file. If it is not valid UTF-8, it will be
18800 converted to UTF-8 using g_filename_to_utf8(). Failing even
18801 that, non-ASCII characters will be escaped. I{(string)}
18802 """
18803 pass
18804
18806 """
18807 Logs the import of volume data from third-party file.
18808
18809 This is a convenience wrapper for L{gwy_app_curve_map_log_add}(). The source id
18810 will be set to -1. The file name will be added to function arguments.
18811
18812 @since: 2.60
18813
18814 @param data: A data container. I{(L{Container})}
18815 @param id: Volume data id. I{(int)}
18816 @param filetype: File type, i.e. the name of the function importing the data
18817 (without any "file::" prefix). Since 2.38 it is possible to
18818 pass B{C{None}} to fill the name of the currently running file type
18819 function automatically. I{(string)}
18820 @param filename: Name of the imported file. If it is not valid UTF-8, it will be
18821 converted to UTF-8 using g_filename_to_utf8(). Failing even
18822 that, non-ASCII characters will be escaped. I{(string)}
18823 """
18824 pass
18825
18827 """
18828 Detects the type of a file.
18829
18830
18831 @param filename: A file name to detect type of. I{(string)}
18832 @param only_name: Whether to use only file name for a guess, or try to actually
18833 access the file. I{(bool)}
18834 @param operations: The file operations the file type must support (it must
18835 support all of them to be considered). Expected values: C{B{FILE_OPERATION_DETECT}}, C{B{FILE_OPERATION_LOAD}}, C{B{FILE_OPERATION_SAVE}}, C{B{FILE_OPERATION_EXPORT}}, C{B{FILE_OPERATION_MASK}}. I{(L{FileOperationType})}
18836 @return: The type name (i.e., the same name as passed to
18837 e.g. L{gwy_file_func_run_load}()) of most probable type of B{C{filename}},
18838 or B{C{None}} if there's no probable one. I{(string)}
18839 """
18840 return None
18841
18843 """
18844 Detects the type of a file and gives the score.
18845
18846 @since: 2.1
18847
18848 @param filename: A file name to detect type of. I{(string)}
18849 @param only_name: Whether to use only file name for a guess, or try to actually I{(bool)}
18850 @param operations: The file operations the file type must support (it must Expected values: C{B{FILE_OPERATION_DETECT}}, C{B{FILE_OPERATION_LOAD}}, C{B{FILE_OPERATION_SAVE}}, C{B{FILE_OPERATION_EXPORT}}, C{B{FILE_OPERATION_MASK}}. I{(L{FileOperationType})}
18851 @return: Tuple consisting of 2 values (B{C{value}}, B{C{score}}). (I{(string)}, I{(int)})
18852 """
18853 return None, None
18854
18856 """
18857 Obtains the name of currently running file type function.
18858
18859 Detection routines are not included, only load, save and export functions.
18860
18861 If no file type function is currently running, B{C{None}} is returned.
18862
18863 If multiple nested functions are running (which is not usual but technically
18864 possible), the innermost function name is returned.
18865
18866 @since: 2.38
18867
18868 @return: The name of currently running file type function or B{C{None}}. I{(string)}
18869 """
18870 return None
18871
18873 """
18874 Checks whether a file type function exists.
18875
18876
18877 @param name: File type function name. I{(string)}
18878 @return: B{C{True}} if function B{C{name}} exists, B{C{False}} otherwise. I{(bool)}
18879 """
18880 return None
18881
18883 """
18884 Gets file function description.
18885
18886 That is, the B{C{description}} argument of L{gwy_file_func_register}() .
18887
18888
18889 @param name: File type function name. I{(string)}
18890 @return: File function description, as a string owned by module loader. I{(string)}
18891 """
18892 return None
18893
18895 """
18896 Returns if the file format is reasonably detectable.
18897
18898 This is B{C{True}} for all file types that define a detection method unless they
18899 explicitly call L{gwy_file_func_set_is_detectable}() to set the file format
18900 non-detectable in spite of providing a detection method.
18901
18902 If files that can be actually loaded as a given type form a subset of files
18903 that are detected as this format, which is normaly the case, it makes no
18904 sense to let the user explicitly choose between these formats. Hence,
18905 detectable formats normally are not explicitly offered.
18906
18907 @since: 2.18
18908
18909 @param name: File type function name. I{(string)}
18910 @return: If the file format is detectable. I{(bool)}
18911 """
18912 return None
18913
18915 """
18916 Returns operations supported by a file type function.
18917
18918
18919 @param name: File type function name. I{(string)}
18920 @return: The file operation bit mask, zero if B{C{name}} does not exist. I{(FileOperationType)}
18921 """
18922 return None
18923
18925 """
18926 Runs a file type detection function identified by B{C{name}}.
18927
18928 Value of B{C{only_name}} should be B{C{True}} if the file doesn't exist (is to be
18929 written) so its contents can't be used for file type detection.
18930
18931 This is a low-level function, consider using L{gwy_file_detect}() if you
18932 simply want to detect a file type.
18933
18934
18935 @param name: A file type function name. I{(string)}
18936 @param filename: A file name to detect. I{(string)}
18937 @param only_name: Whether to use only file name for a guess, or try to actually
18938 access the file. I{(bool)}
18939 @return: An integer score expressing the likehood of the file being
18940 loadable as this type. A basic scale is 20 for a good extension,
18941 100 for good magic header, more for more thorough tests. I{(int)}
18942 """
18943 return None
18944
18946 """
18947 Runs a file export function identified by B{C{name}}.
18948
18949 It guarantees the container lifetime spans through the actual file saving,
18950 so the module function doesn't have to care about it.
18951
18952 This is a low-level function, consider using L{gwy_file_save}() if you
18953 simply want to save a file.
18954
18955
18956 @param name: A file save function name. I{(string)}
18957 @param data: A B{C{Container}} to save. I{(L{Container})}
18958 @param filename: A file name to save B{C{data}} as. I{(string)}
18959 @param mode: Run mode. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
18960 @return: B{C{True}} if file save succeeded, B{C{False}} otherwise. I{(bool)}
18961 """
18962 return None
18963
18965 """
18966 Runs a file load function identified by B{C{name}}.
18967
18968 This is a low-level function, consider using L{gwy_file_load}() if you
18969 simply want to load a file.
18970
18971
18972 @param name: A file load function name. I{(string)}
18973 @param filename: A file name to load data from. I{(string)}
18974 @param mode: Run mode. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
18975 @return: A new B{C{Container}} with data from B{C{filename}}, or B{C{None}}. I{(L{Container})}
18976 """
18977 return None
18978
18980 """
18981 Runs a file save function identified by B{C{name}}.
18982
18983 It guarantees the container lifetime spans through the actual file saving,
18984 so the module function doesn't have to care about it.
18985
18986 This is a low-level function, consider using L{gwy_file_save}() if you
18987 simply want to save a file.
18988
18989
18990 @param name: A file save function name. I{(string)}
18991 @param data: A B{C{Container}} to save. I{(L{Container})}
18992 @param filename: A file name to save B{C{data}} as. I{(string)}
18993 @param mode: Run mode. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
18994 @return: B{C{True}} if file save succeeded, B{C{False}} otherwise. I{(bool)}
18995 """
18996 return None
18997
18999 """
19000 Sets the detectability status of a file format.
19001
19002 See L{gwy_file_func_get_is_detectable}() for details. The only rare case when
19003 it makes sense to call this function is when a detection function is
19004 provided for some reason, however, this function is not really able to
19005 detect the format. For instance, the fallback detection method of the
19006 Gwyddion rawfile module.
19007
19008 @since: 2.18
19009
19010 @param name: File type function name. I{(string)}
19011 @param is_detectable: B{C{True}} to define format as detectable, B{C{False}} as
19012 non-detectable. I{(bool)}
19013 """
19014 pass
19015
19017 """
19018 Gets the file name corresponding to a data container.
19019
19020 The file name is set on two ocasions: file load and successful file save.
19021 File export does not set it.
19022
19023 @since: 2.36
19024
19025 @param data: A B{C{Container}}. I{(L{Container})}
19026 @return: File name of B{C{data}} (in GLib encoding), or B{C{None}}. The returned
19027 string is owned by module system and is valid only until the
19028 container is destroyed or saved again. I{(string)}
19029 """
19030 return None
19031
19033 """
19034 Loads a data file, autodetecting its type.
19035
19036
19037 @param filename: A file name to load data from, in GLib encoding. I{(string)}
19038 @param mode: Run mode. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
19039 @return: A new B{C{Container}} with data from B{C{filename}}, or B{C{None}}. I{(L{Container})}
19040 """
19041 return None
19042
19044 """
19045 Saves a data file, deciding to save as what type from the file name.
19046
19047 It tries to find a module implementing B{C{FILE_OPERATION_SAVE}} first, when
19048 it does not succeed, it falls back to B{C{FILE_OPERATION_EXPORT}}.
19049
19050
19051 @param data: A B{C{Container}} to save. I{(L{Container})}
19052 @param filename: A file name to save the data as, in GLib encoding. I{(string)}
19053 @param mode: Run mode. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
19054 @return: The save operation that was actually realized on success, zero
19055 on failure. I{(FileOperationType)}
19056 """
19057 return None
19058
19060 """
19061 Logs the import of volume data from third-party file.
19062
19063 This is a convenience wrapper for L{gwy_app_volume_log_add}(). The source id
19064 will be set to -1. The file name will be added to function arguments.
19065
19066 @since: 2.35
19067
19068 @param data: A data container. I{(L{Container})}
19069 @param id: Volume data id. I{(int)}
19070 @param filetype: File type, i.e. the name of the function importing the data
19071 (without any "file::" prefix). Since 2.38 it is possible to
19072 pass B{C{None}} to fill the name of the currently running file type
19073 function automatically. I{(string)}
19074 @param filename: Name of the imported file. If it is not valid UTF-8, it will be
19075 converted to UTF-8 using g_filename_to_utf8(). Failing even
19076 that, non-ASCII characters will be escaped. I{(string)}
19077 """
19078 pass
19079
19081 """
19082 Logs the import of xyz data from third-party file.
19083
19084 This is a convenience wrapper for L{gwy_app_xyz_log_add}(). The source id
19085 will be set to -1. The file name will be added to function arguments.
19086
19087 @since: 2.45
19088
19089 @param data: A data container. I{(L{Container})}
19090 @param id: XYZ surface data id. I{(int)}
19091 @param filetype: File type, i.e. the name of the function importing the data
19092 (without any "file::" prefix). It is possible to
19093 pass B{C{None}} to fill the name of the currently running file type
19094 function automatically. I{(string)}
19095 @param filename: Name of the imported file. If it is not valid UTF-8, it will be
19096 converted to UTF-8 using g_filename_to_utf8(). Failing even
19097 that, non-ASCII characters will be escaped. I{(string)}
19098 """
19099 pass
19100
19102 """
19103 Checks whether file should be ignored.
19104
19105 This function checks for common file names indicating files that should be normally ignored. Currently it means
19106 backup files (ending with ~ or .bak) and Unix hidden files (starting with a dot).
19107
19108
19109 @param filename_sys: File name in GLib encoding. I{(string)}
19110 @return: B{C{True}} to ignore this file, B{C{False}} otherwise. I{(bool)}
19111 """
19112 return None
19113
19115 """
19116 Finds a system Gwyddion directory.
19117
19118 On Unix, a compiled-in path is returned, unless it's overriden with environment variables (see gwyddion manual
19119 page).
19120
19121 On Win32, the directory where the libgwyddion DLL from which this function was called resides is taken as the base
19122 and the location of other Gwyddion directories is calculated from it.
19123
19124 The returned value is not actually tested for existence, it's up to caller.
19125
19126 To obtain the Gwyddion user directory see L{gwy_get_user_dir}().
19127
19128
19129 @param dirname: A gwyddion directory name:
19130 C{"modules"},
19131 C{"plugins"},
19132 C{"pixmaps"},
19133 C{"locale"}, or
19134 C{"data"}. I{(string)}
19135 @return: The path as a newly allocated string. I{(string)}
19136 """
19137 return None
19138
19140 """
19141 A wrapper for the stdio fopen() function. The fopen() function opens a file and associates a new stream with it.
19142
19143 Because file descriptors are specific to the C library on Windows, and a file descriptor is part of the FILE
19144 struct, the FILE* returned by this function makes sense only to functions in the same C library. Thus if the
19145 GLib-using code uses a different C library than GLib does, the FILE* returned by this function cannot be passed to
19146 C library functions like fprintf() or fread().
19147
19148 See your C library manual for more details about fopen().
19149
19150 @since: 2.43
19151
19152 @param filename: a pathname in the GLib file name encoding (UTF-8 on Windows) I{(string)}
19153 @param mode: a string describing the mode in which the file should be opened I{(string)}
19154 @return: A FILE* if the file was successfully opened, or B{C{None}} if an error occurred. I{(FILE*)}
19155 """
19156 return None
19157
19159 """
19160 Gets the n-th most function from a function statistics.
19161
19162
19163 @param functions: Function use statistics. I{(FunctionUse*)}
19164 @param i: Position in the top used functions (starting from 0). I{(int)}
19165 @return: The function name, or B{C{None}} if there are not more functions with
19166 use statistics records than B{C{i}}. I{(string)}
19167 """
19168 return None
19169
19171 """
19172 Gets the (preferred) name for a file to store function use statistics to.
19173
19174
19175 @param type: Function type, that is an identifier of the type of statistics
19176 gathered. It must be a valid identifier. I{(string)}
19177 @return: The file name as a newly allocated string. I{(string)}
19178 """
19179 return None
19180
19183
19185 """
19186 Returns home directory, or temporary directory as a fallback.
19187
19188 Under normal circumstances the same string as g_get_home_dir() would return is returned. But on MS Windows,
19189 something like "C:\Windows\Temp" can be returned too, as it is as good as anything else (we can write there).
19190
19191
19192 @return: Something usable as user home directory. It may be silly, but never B{C{None}} or empty. I{(string)}
19193 """
19194 return None
19195
19197 """
19198 Returns the directory where Gwyddion user settings and data should be stored.
19199
19200 On Unix this is usually a dot-directory in user's home directory. On modern Win32 the returned directory resides
19201 in user's Documents and Settings. On silly platforms or silly occasions, silly locations (namely a temporary
19202 directory) can be returned as fallback.
19203
19204 To obtain a Gwyddion system directory see L{gwy_find_self_dir}().
19205
19206
19207 @return: The directory as a constant string that should not be freed. I{(string)}
19208 """
19209 return None
19210
19212 """
19213 Gets the name of currently selected GL material of a selection button.
19214
19215
19216 @param selection: GL material selection button. I{(L{gtk.Widget})}
19217 @return: Name as a string owned by the selected GL material. I{(string)}
19218 """
19219 return None
19220
19222 """
19223 Creates a GL material selection button.
19224
19225
19226 @param active: GL material name to be shown as currently selected
19227 (or B{C{None}} for default). I{(string)}
19228 @return: The newly created GL material selection button as B{C{GtkWidget}}. I{(L{gtk.Widget})}
19229 """
19230 return None
19231
19233 """
19234 Sets the currently selected GL material of a selection button.
19235
19236 @param selection: GL material selection button. I{(L{gtk.Widget})}
19237 @param active: GL material name to be shown as currently selected. I{(string)}
19238 """
19239 pass
19240
19242 """
19243 Creates a tree view with GL material list.
19244
19245
19246 @param active: GL material name to be shown as currently selected
19247 (or B{C{None}} for default). I{(string)}
19248 @return: The newly created GL material tree view as B{C{GtkWidget}}. I{(L{gtk.Widget})}
19249 """
19250 return None
19251
19253 """
19254 Selects a GL material in a GL material list and scrolls to make it visible.
19255
19256
19257 @param treeview: A GL material selector tree view. I{(L{gtk.Widget})}
19258 @param active: GL material name to be shown as currently selected. I{(string)}
19259 @return: B{C{True}} if B{C{active}} was selected, B{C{False}} if there is no such
19260 GL material. I{(bool)}
19261 """
19262 return None
19263
19265 """
19266 Gets inventory with all the GL materials.
19267
19268
19269 @return: GL material inventory. I{(L{Inventory})}
19270 """
19271 return None
19272
19274 """
19275 Convenience function to get a GL material from L{gwy_gl_materials}() by name.
19276
19277
19278 @param name: GL material name. May be B{C{None}} to get the default GL material. I{(string)}
19279 @return: GL material identified by B{C{name}} or the default GL material if B{C{name}}
19280 does not exist. I{(L{GLMaterial})}
19281 """
19282 return None
19283
19285 """
19286 Gets the name of currently selected gradient of a selection button.
19287
19288
19289 @param selection: Gradient selection button. I{(L{gtk.Widget})}
19290 @return: Name as a string owned by the selected gradient. I{(string)}
19291 """
19292 return None
19293
19295 """
19296 Creates a gradient selection button.
19297
19298
19299 @param active: Gradient name to be shown as currently selected
19300 (or B{C{None}} for default). I{(string)}
19301 @return: The newly created gradient selection button as B{C{GtkWidget}}. I{(L{gtk.Widget})}
19302 """
19303 return None
19304
19306 """
19307 Sets the currently selected gradient of a selection button.
19308
19309 @param selection: Gradient selection button. I{(L{gtk.Widget})}
19310 @param active: Gradient name to be shown as currently selected. I{(string)}
19311 """
19312 pass
19313
19315 """
19316 Creates a tree view with gradient list.
19317
19318
19319 @param active: Gradient name to be shown as currently selected
19320 (or B{C{None}} for default). I{(string)}
19321 @return: The newly created gradient tree view as B{C{GtkWidget}}. I{(L{gtk.Widget})}
19322 """
19323 return None
19324
19326 """
19327 Selects a gradient in a gradient list and scrolls to make it visible.
19328
19329
19330 @param treeview: A gradient selector tree view. I{(L{gtk.Widget})}
19331 @param active: Gradient name to be shown as currently selected. I{(string)}
19332 @return: B{C{True}} if B{C{active}} was selected, B{C{False}} if there is no such
19333 gradient. I{(bool)}
19334 """
19335 return None
19336
19338 """
19339 Gets inventory with all the gradients.
19340
19341
19342 @return: Gradient inventory. I{(L{Inventory})}
19343 """
19344 return None
19345
19347 """
19348 Convenience function to get a gradient from L{gwy_gradients}() by name.
19349
19350
19351 @param name: Gradient name. May be B{C{None}} to get the default gradient. I{(string)}
19352 @return: Gradient identified by B{C{name}} or the default gradient if B{C{name}} does
19353 not exist. I{(L{Gradient})}
19354 """
19355 return None
19356
19358 """
19359 Draws a line segment on a drawable.
19360
19361 @param drawable: A drawable. I{(L{gdk.Drawable})}
19362 @param gc: Graphics context.
19363 It is modified by this function unpredictably. I{(L{gdk.GC})}
19364 @param x_from: x coordinate of the start point of the line I{(int)}
19365 @param y_from: y coordinate of the start point of the line I{(int)}
19366 @param x_to: x coordinate of the end point of the line I{(int)}
19367 @param y_to: y coordinate of the end point of the line I{(int)}
19368 @param line_style: graph line style I{(GdkLineStyle)}
19369 @param size: point size I{(int)}
19370 @param color: point color I{(const-RGBA*)}
19371 """
19372 pass
19373
19375 """
19376 Draws a point on a drawable.
19377
19378 @param drawable: A drawable. I{(L{gdk.Drawable})}
19379 @param gc: Graphics context.
19380 It is modified by this function unpredictably. I{(L{gdk.GC})}
19381 @param x: X coordinate of the point. I{(int)}
19382 @param y: Y coordinate of the point. I{(int)}
19383 @param type: graph point type Expected values: C{B{GRAPH_POINT_SQUARE}}, C{B{GRAPH_POINT_CROSS}}, C{B{GRAPH_POINT_CIRCLE}}, C{B{GRAPH_POINT_STAR}}, C{B{GRAPH_POINT_TIMES}}, C{B{GRAPH_POINT_TRIANGLE_UP}}, C{B{GRAPH_POINT_TRIANGLE_DOWN}}, C{B{GRAPH_POINT_DIAMOND}}, C{B{GRAPH_POINT_FILLED_SQUARE}}, C{B{GRAPH_POINT_DISC}}, C{B{GRAPH_POINT_FILLED_CIRCLE}}, C{B{GRAPH_POINT_FILLED_TRIANGLE_UP}}, C{B{GRAPH_POINT_FILLED_TRIANGLE_DOWN}}, C{B{GRAPH_POINT_FILLED_DIAMOND}}, C{B{GRAPH_POINT_TRIANGLE_LEFT}}, C{B{GRAPH_POINT_FILLED_TRIANGLE_LEFT}}, C{B{GRAPH_POINT_TRIANGLE_RIGHT}}, C{B{GRAPH_POINT_FILLED_TRIANGLE_RIGHT}}, C{B{GRAPH_POINT_ASTERISK}}. I{(L{GraphPointType})}
19384 @param size: point size I{(int)}
19385 @param color: point color I{(const-RGBA*)}
19386 """
19387 pass
19388
19390 """
19391 Obtains the name of currently running graph function.
19392
19393 If no graph function is currently running, B{C{None}} is returned.
19394
19395 If multiple nested functions are running (which is not usual but technically
19396 possible), the innermost function name is returned.
19397
19398 @since: 2.38
19399
19400 @return: The name of currently running graph function or B{C{None}}. I{(string)}
19401 """
19402 return None
19403
19405 """
19406 Checks whether a graph function exists.
19407
19408
19409 @param name: Graph function name. I{(string)}
19410 @return: B{C{True}} if function B{C{name}} exists, B{C{False}} otherwise. I{(bool)}
19411 """
19412 return None
19413
19415 """
19416 Gets menu path of a graph function.
19417
19418 The returned menu path is only the tail part registered by the function,
19419 i.e., without any leading "/Graph".
19420
19421
19422 @param name: Graph function name. I{(string)}
19423 @return: The menu path. The returned string is owned by the module. I{(string)}
19424 """
19425 return None
19426
19428 """
19429 Gets menu sensititivy mask for a graph function.
19430
19431
19432 @param name: Graph function name. I{(string)}
19433 @return: The menu item sensitivity mask (a combination of B{C{MenuSensFlags}}
19434 flags). I{(int)}
19435 """
19436 return None
19437
19439 """
19440 Gets stock icon id of a graph function.
19441
19442
19443 @param name: Graph function name. I{(string)}
19444 @return: The stock icon id. The returned string is owned by the module. I{(string)}
19445 """
19446 return None
19447
19457
19459 """
19460 Runs a graph function identified by B{C{name}}.
19461
19462 @param name: Graph function name. I{(string)}
19463 @param graph: Graph (a B{C{Graph}}). I{(L{Graph})}
19464 """
19465 pass
19466
19468 """
19469 Gets the number of distinct colors L{Graph.get_preset_color}() can return.
19470
19471
19472 @return: The number of distinct colors. I{(int)}
19473 """
19474 return None
19475
19477 """
19478 Gets a preset graph color.
19479
19480 Preset colors are a set of selected colors one can use to distingush graph
19481 curves when there is no reason to prefer a particular color. Note they
19482 can occasionally change between version, even their number can change.
19483
19484
19485 @param i: Color number, starting from 0 which is always black. It can be any
19486 number but colors start to repeat after
19487 L{Graph.get_n_preset_colors}() colors. I{(int)}
19488 @return: A constant color that must not be neither modified nor freed. I{(const-RGBA*)}
19489 """
19490 return None
19491
19502
19522
19524 """
19525 Adds help to a curve map data processing function dialog.
19526
19527 Note the help button will not be added if no help URI is found for the currently running function or help is not
19528 available.
19529
19530 @since: 2.60
19531
19532 @param dialog: Main dialog for a curve map data processing function. I{(L{gtk.Dialog})}
19533 @param flags: Flags allowing to modify the help setup. Expected values: C{B{HELP_DEFAULT}}, C{B{HELP_NO_BUTTON}}. I{(L{HelpFlags})}
19534 """
19535 pass
19536
19538 """
19539 Adds help to a file function dialog.
19540
19541 Note the help button will not be added if no help URI is found for the currently running function or help is not
19542 available.
19543
19544 @since: 2.38
19545
19546 @param dialog: Main dialog for a file function. I{(L{gtk.Dialog})}
19547 @param flags: Flags allowing to modify the help setup. Expected values: C{B{HELP_DEFAULT}}, C{B{HELP_NO_BUTTON}}. I{(L{HelpFlags})}
19548 """
19549 pass
19550
19552 """
19553 Adds help to a graph function dialog.
19554
19555 Note the help button will not be added if no help URI is found for the currently running function or help is not
19556 available.
19557
19558 @since: 2.38
19559
19560 @param dialog: Main dialog for a graph function. I{(L{gtk.Dialog})}
19561 @param flags: Flags allowing to modify the help setup. Expected values: C{B{HELP_DEFAULT}}, C{B{HELP_NO_BUTTON}}. I{(L{HelpFlags})}
19562 """
19563 pass
19564
19566 """
19567 Adds help to a data processing function dialog.
19568
19569 Note the help button will not be added if no help URI is found for the currently running function or help is not
19570 available.
19571
19572 @since: 2.38
19573
19574 @param dialog: Main dialog for a data processing function. I{(L{gtk.Dialog})}
19575 @param flags: Flags allowing to modify the help setup. Expected values: C{B{HELP_DEFAULT}}, C{B{HELP_NO_BUTTON}}. I{(L{HelpFlags})}
19576 """
19577 pass
19578
19580 """
19581 Adds help to a volume data processing function dialog.
19582
19583 Note the help button will not be added if no help URI is found for the currently running function or help is not
19584 available.
19585
19586 @since: 2.38
19587
19588 @param dialog: Main dialog for a volume data processing function. I{(L{gtk.Dialog})}
19589 @param flags: Flags allowing to modify the help setup. Expected values: C{B{HELP_DEFAULT}}, C{B{HELP_NO_BUTTON}}. I{(L{HelpFlags})}
19590 """
19591 pass
19592
19594 """
19595 Adds help to a window pointing to the user guide.
19596
19597 If the window is a B{C{GtkDialog}} a help button will be added by default (this can be modified with B{C{flags}}). Normal
19598 windows do not get help buttons. No help may be added if help is not available.
19599
19600 This is a relatively low-level function and should not be necessary in modules. An exception may be modules with
19601 multiple user interfaces described in different parts of the guide – but this should be rare.
19602
19603 It is a suitable functions for adding help to base application windows, such as channel or volume windows.
19604
19605 @since: 2.38
19606
19607 @param window: A window. I{(L{gtk.Window})}
19608 @param filename: Base file name in the user guide without any path or extensions, for instance "statistical-analysis". I{(string)}
19609 @param fragment: Fragment identifier (without "#"), or possibly B{C{None}}. I{(string)}
19610 @param flags: Flags allowing to modify the help setup. Expected values: C{B{HELP_DEFAULT}}, C{B{HELP_NO_BUTTON}}. I{(L{HelpFlags})}
19611 """
19612 pass
19613
19615 """
19616 Adds help to a window pointing to an arbitrary URI.
19617
19618 If the window is a B{C{GtkDialog}} a help button will be added by default (this can be modified with B{C{flags}}). Normal
19619 windows do not get help buttons. No help may be added if help is not available.
19620
19621 This function should not be necessary anywhere within Gwyddion itself. Use the functions pointing to the user guide
19622 instead as they can handle language versions or changing the user guide base location.
19623
19624 It may be useful for third-party modules if they wish to add a help facility behaving similarly to built-in
19625 modules.
19626
19627 @since: 2.38
19628
19629 @param window: A window. I{(L{gtk.Window})}
19630 @param uri: Full URI pointing to the help for B{C{window}}. I{(string)}
19631 @param flags: Flags allowing to modify the help setup. Expected values: C{B{HELP_DEFAULT}}, C{B{HELP_NO_BUTTON}}. I{(L{HelpFlags})}
19632 """
19633 pass
19634
19636 """
19637 Adds help to a XYZ data processing function dialog.
19638
19639 Note the help button will not be added if no help URI is found for the currently running function or help is not
19640 available.
19641
19642 @since: 2.45
19643
19644 @param dialog: Main dialog for a XYZ data processing function. I{(L{gtk.Dialog})}
19645 @param flags: Flags allowing to modify the help setup. Expected values: C{B{HELP_DEFAULT}}, C{B{HELP_NO_BUTTON}}. I{(L{HelpFlags})}
19646 """
19647 pass
19648
19650 """
19651 Check whether help is available.
19652
19653 This is a weak check that finds if we have any help-showing backend that might work at all, have the user guide
19654 module map, and if the user guide locations is a local directory it checks whether it exists. If it returns B{C{True}}
19655 it does not guarantee help will work. If it returns B{C{False}}, however, it means help will not work.
19656
19657 @since: 2.38
19658
19659 @return: B{C{True}} if help seems available, B{C{False}} if it is not. I{(bool)}
19660 """
19661 return None
19662
19664 """
19665 Immediately shows a specific help location.
19666
19667 This function should be rarely needed. It may fail if help is not available.
19668
19669 @since: 2.38
19670
19671 @param filename: Base file name in the user guide without any path or extensions, for instance "statistical-analysis". I{(string)}
19672 @param fragment: Fragment identifier (without "#"), or possibly B{C{None}}. I{(string)}
19673 """
19674 pass
19675
19677 """
19678 This function uses two-point interpolation
19679 methods to get interpolated value between
19680 two arbitrary data points.
19681
19682
19683 @param x: requested value coordinate I{(float)}
19684 @param x1_: x coordinate of first value I{(float)}
19685 @param y1_: y coordinate of first value I{(float)}
19686 @param x2_: x coordinate of second value I{(float)}
19687 @param y2_: y coordinate of second value I{(float)}
19688 @param interpolation: interpolation type Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19689 @return: interpolated value I{(float)}
19690 """
19691 return None
19692
19694 """
19695 Computes interpolated value from 2 or 4 equidistant values.
19696
19697 For B{C{INTERPOLATION_NONE}} no B{C{data}} value is actually used, and zero is
19698 returned.
19699
19700 For B{C{INTERPOLATION_ROUND}} or B{C{INTERPOLATION_LINEAR}}
19701 it is enough to set middle two B{C{data}} values, that to use B{C{data}} in format
19702 {0, data[i], data[i+1], 0} and function computes value at data[i+x]
19703 (the outer values are not used).
19704
19705 For four value interpolations you have to prepare B{C{data}} as
19706 {data[i-1], data[i], data[i+1], data[i+2]} and function again
19707 returns value at data[i+x].
19708
19709 Interpolation with non-interpolating bases are silently replaced with an
19710 interpolating function with the same support size. See
19711 L{gwy_interpolation_interpolate_1d}() for a function interpolating from
19712 interpolation coefficients.
19713
19714
19715 @param x: Possibily noninteger position in B{C{data}} to get value at. I{(float)}
19716 @param data: Array of 4 values to interpolate between (see below). I{(list)}
19717 @param interpolation: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19718 @return: Value B{C{result}}. (I{(float)})
19719 """
19720 return None
19721
19723 """
19724 Obtains the basis support size for an interpolation type.
19725
19726 @since: 2.2
19727
19728 @param interpolation: Interpolation type. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19729 @return: The length of the support interval of the interpolation basis. I{(int)}
19730 """
19731 return None
19732
19734 """
19735 Obtains the interpolating basis property of an inteprolation type.
19736
19737 Interpolation types with inteprolating basis directly use data values
19738 for interpolation. For these types L{gwy_interpolation_resolve_coeffs_1d}()
19739 and L{gwy_interpolation_resolve_coeffs_2d}() are no-op.
19740
19741 Generalized interpolation types (with non-interpolation basis) require to
19742 preprocess the data values to obtain interpolation coefficients first. On
19743 the ohter hand they typically offer much higher interpolation quality.
19744
19745 @since: 2.2
19746
19747 @param interpolation: Interpolation type. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19748 @return: B{C{True}} if the inteprolation type has interpolating basis,
19749 B{C{False}} if data values cannot be directly used for interpolation
19750 of this type. I{(bool)}
19751 """
19752 return None
19753
19755 """
19756 Interpolates a signle data point in one dimension.
19757
19758 The interpolation basis support size can be obtained generically with
19759 L{gwy_interpolation_get_support_size}().
19760
19761 @since: 2.2
19762
19763 @param x: Position in interval [0,1) to get value at. I{(float)}
19764 @param coeff: Array of support-length size with interpolation coefficients
19765 (that are equal to data values for an interpolating basis). I{(list)}
19766 @param interpolation: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19767 @return: Value B{C{result}}. (I{(float)})
19768 """
19769 return None
19770
19772 """
19773 Interpolates a signle data point in two dimensions.
19774
19775 @since: 2.2
19776
19777 @param x: X-position in interval [0,1) to get value at. I{(float)}
19778 @param y: Y-position in interval [0,1) to get value at. I{(float)}
19779 @param rowstride: Row stride of B{C{coeff}}. I{(int)}
19780 @param coeff: Array of support-length-squared size with interpolation coefficients
19781 (that are equal to data values for an interpolating basis). I{(list)}
19782 @param interpolation: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19783 @return: Value B{C{result}}. (I{(float)})
19784 """
19785 return None
19786
19788 """
19789 Resamples a one-dimensional data array.
19790
19791 This is a primitive operation, in most cases methods such as
19792 L{DataLine.new_resampled}() provide more convenient interface.
19793
19794 @since: 2.2
19795
19796 @param data: Data block to resample. I{(list)}
19797 @param newlength: Requested length after resampling. I{(int)}
19798 @param interpolation: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19799 @return: I{(list)}
19800 """
19801 return None
19802
19804 """
19805 Resamples a two-dimensional data array.
19806
19807 This is a primitive operation, in most cases methods such as
19808 L{DataField.new_resampled}() provide more convenient interface.
19809
19810 @since: 2.2
19811
19812 @param data: Data block to resample. I{(list)}
19813 @param width: Number of columns in B{C{data}}. I{(int)}
19814 @param height: Number of rows in B{C{data}}. I{(int)}
19815 @param rowstride: Total row length (including B{C{width}}). I{(int)}
19816 @param newwidth: Requested number of columns after resampling. I{(int)}
19817 @param newheight: Requested number of rows after resampling. I{(int)}
19818 @param newrowstride: Requested total row length after resampling (including
19819 B{C{newwidth}}). I{(int)}
19820 @param interpolation: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19821 @return: I{(list)}
19822 """
19823 return None
19824
19826 """
19827 Transforms data values in a one-dimensional array to interpolation
19828 coefficients.
19829
19830 This function is no-op for interpolation types with finite-support
19831 interpolating function. Therefore you can also omit it and use the data
19832 array directly for these interpolation types.
19833
19834 @since: 2.2
19835
19836 @param data: An array of data values. It will be rewritten with the coefficients. I{(list)}
19837 @param interpolation: Interpolation type to prepare B{C{data}} for. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19838 @return: I{(list)}
19839 """
19840 return None
19841
19843 """
19844 Transforms data values in a two-dimensional array to interpolation
19845 coefficients.
19846
19847 This function is no-op for interpolation types with finite-support
19848 interpolating function. Therefore you can also omit it and use the data
19849 array directly for these interpolation types.
19850
19851 @since: 2.2
19852
19853 @param width: Number of columns in B{C{data}}. I{(int)}
19854 @param height: Number of rows in B{C{data}}. I{(int)}
19855 @param rowstride: Total row length (including B{C{width}}). I{(int)}
19856 @param data: An array of data values. It will be rewritten with the coefficients. I{(list)}
19857 @param interpolation: Interpolation type to prepare B{C{data}} for. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19858 @return: I{(list)}
19859 """
19860 return None
19861
19863 """
19864 Shifts a one-dimensional data block by a possibly non-integer offset.
19865
19866 The B{C{EXTERIOR_LAPLACE}} exterior type cannot be used with this function.
19867
19868 @since: 2.2
19869
19870 @param data: Data block to shift. I{(list)}
19871 @param offset: The shift, in corrective sense. Shift value of 1.0 means the
19872 zeroth value of B{C{newdata}} will be set to the first value of B{C{data}}. I{(float)}
19873 @param interpolation: Interpolation type to use. Expected values: C{B{INTERPOLATION_NONE}}, C{B{INTERPOLATION_ROUND}}, C{B{INTERPOLATION_LINEAR}}, C{B{INTERPOLATION_BILINEAR}}, C{B{INTERPOLATION_KEY}}, C{B{INTERPOLATION_BSPLINE}}, C{B{INTERPOLATION_OMOMS}}, C{B{INTERPOLATION_NNA}}, C{B{INTERPOLATION_SCHAUM}}. I{(L{InterpolationType})}
19874 @param exterior: Exterior pixels handling. Expected values: C{B{EXTERIOR_UNDEFINED}}, C{B{EXTERIOR_BORDER_EXTEND}}, C{B{EXTERIOR_MIRROR_EXTEND}}, C{B{EXTERIOR_PERIODIC}}, C{B{EXTERIOR_FIXED_VALUE}}, C{B{EXTERIOR_LAPLACE}}. I{(L{ExteriorType})}
19875 @param fill_value: The value to use with B{C{EXTERIOR_FIXED_VALUE}}. I{(float)}
19876 @return: I{(list)}
19877 """
19878 return None
19879
19881 """
19882 Convert string representation of key to numerical.
19883
19884
19885 @param name: String representation of key. I{(string)}
19886 @return: Corresponding numerical key. I{(int)}
19887 """
19888 return None
19889
19891 """
19892 Creates a bold, left aligned label.
19893
19894 The purpose of this function is to avoid propagation of too much markup to
19895 translations (and to reduce code clutter by avoiding dummy constructor and
19896 left-aligning automatically).
19897
19898
19899 @param text: Text to put into the label. It must be a valid markup and it will
19900 be made bold by adding appropriate markup around it. I{(string)}
19901 @return: A newly created B{C{GtkLabel}}. I{(L{gtk.Widget})}
19902 """
19903 return None
19904
19906 """
19907 Registeres a layer function (layer type).
19908
19909
19910 @param type: Layer type in GObject type system. That is the return value of
19911 L{gwy_layer_foo_get_type}(). I{(GType)}
19912 @return: Normally B{C{True}}; B{C{False}} on failure. I{(bool)}
19913 """
19914 return None
19915
19917 """
19918 Reports whether logging of data processing operations is globally enabled.
19919
19920 @since: 2.35
19921
19922 @return: B{C{True}} if logging is enabled, B{C{False}} if it is disabled. I{(bool)}
19923 """
19924 return None
19925
19927 """
19928 Globally enables or disables logging of data processing operations.
19929
19930 By default, logging is enabled. Non-GUI applications that run module functions may wish to disable it. Of course,
19931 the log will presist only if the data container is saved into a GWY file.
19932
19933 If logging is disabled logging functions such as L{gwy_app_channel_log_add}() become no-op. It is possible to run the
19934 log viewer with L{gwy_app_log_browser_for_channel}() to see log entries created when logging was enabled.
19935
19936 @since: 2.35
19937
19938 @param setting: B{C{True}} to enable logging, B{C{False}} to disable it. I{(bool)}
19939 """
19940 pass
19941
19943 """
19944 Creates and runs a color selector dialog for a mask.
19945
19946 Note this function does not return anything, it runs the color selection
19947 dialog modally and returns when it is finished.
19948
19949 @since: 2.1
19950
19951 @param dialog_title: Title of the color selection dialog (B{C{None}} to use default). I{(string)}
19952 @param parent: Dialog parent window. The color selector dialog will be made
19953 transient for this window. I{(L{gtk.Window})}
19954 @param color_button: Color button to update on color change (or B{C{None}}). I{(L{ColorButton})}
19955 @param container: Container to initialize the color from and save it to. I{(L{Container})}
19956 @param prefix: Prefix in B{C{container}} (normally "/0/mask"). I{(string)}
19957 """
19958 pass
19959
19961 """
19962 Calculates curvature parameters at the apex from two-dimensional quadratic polynomial coefficients.
19963
19964 This is an old name for L{gwy_math_curvature_at_apex}(). See the description there.
19965
19966 @since: 2.22
19967
19968 @param coeffs: Array of the six polynomial coefficients of a quadratic surface in the following order: 1, x, y, x², xy, y². I{(list)}
19969 @return: Tuple consisting of 8 values (B{C{dimen}}, B{C{kappa1}}, B{C{kappa2}}, B{C{phi1}}, B{C{phi2}}, B{C{xc}}, B{C{yc}}, B{C{zc}}). (I{(int)}, I{(float)}, I{(float)}, I{(float)}, I{(float)}, I{(float)}, I{(float)}, I{(float)})
19970 """
19971 return None, None, None, None, None, None, None, None
19972
19974 """
19975 Finds the line from B{C{coords}} nearest to the point (B{C{x}}, B{C{y}}).
19976
19977
19978 @param x: X-coordinate of the point to search. I{(float)}
19979 @param y: Y-coordinate of the point to search. I{(float)}
19980 @param coords: Line coordinates stored as x00, y00, x01, y01, x10, y10, etc. I{(list)}
19981 @param metric: Metric matrix (2x2, but stored sequentially by rows: m11, m12, m21, m22), it must be positive definite.
19982 Vector norm is then calculated as m11*x*x + (m12 + m21)*x*y + m22*y*y. It can be B{C{None}}, standard Euclidean
19983 metric is then used. I{(list)}
19984 @return: Tuple consisting of 2 values (B{C{idx}}, B{C{d2min}}). (I{(int)}, I{(float)})
19985 """
19986 return None, None
19987
19989 """
19990 Finds the point from B{C{coords}} nearest to the point (B{C{x}}, B{C{y}}).
19991
19992
19993 @param x: X-coordinate of the point to search. I{(float)}
19994 @param y: Y-coordinate of the point to search. I{(float)}
19995 @param coords: Point coordinates stored as x0, y0, x1, y1, x2, y2, etc. I{(list)}
19996 @param metric: Metric matrix (2x2, but stored sequentially by rows: m11, m12, m21, m22). Vector norm is then calculated
19997 as m11*x*x + (m12 + m21)*x*y + m22*y*y. It can be B{C{None}}, standard Euclidean metric is then used. I{(list)}
19998 @return: Tuple consisting of 2 values (B{C{idx}}, B{C{d2min}}). (I{(int)}, I{(float)})
19999 """
20000 return None, None
20001
20003 """
20004 Fits a polynom through a general (x, y) data set.
20005
20006
20007 @param xdata: Independent variable data (of size B{C{ndata}}). I{(list)}
20008 @param ydata: Dependent variable data (of size B{C{ndata}}). I{(list)}
20009 @param n: The degree of polynom to fit. I{(int)}
20010 @return: Value B{C{coeffs}}. (I{(list)})
20011 """
20012 return None
20013
20015 """
20016 Finds a human-friendly representation for a range of numbers.
20017
20018
20019 @param unit: The smallest possible step. I{(float)}
20020 @param maximum: The maximum possible value. I{(float)}
20021 @return: Tuple consisting of 2 values (B{C{value}}, B{C{precision}}). (I{(float)}, I{(int)})
20022 """
20023 return None, None
20024
20026 """
20027 Establishes wether the test point B{C{x}}, B{C{y}} is inside the polygon B{C{poly}}. The polygon can be defined either clockwise
20028 or anti-clockwise and can be a concave, convex or self-intersecting polygon.
20029
20030 @warning: Result can be either True or False if the test point is *exactly* on an edge.
20031
20032 @since: 2.7
20033
20034 @param x: The x coordinate of the test point. I{(float)}
20035 @param y: The y coordinate of the test point. I{(float)}
20036 @param poly: An array of coordinate pairs (points) that define a polygon. I{(list)}
20037 @return: Value B{C{is_inside}}. (I{(BooleanOutArg)})
20038 """
20039 return None
20040
20042 """
20043 Finds k-th item of an array of values using Quick select algorithm.
20044
20045 The value positions change as follows. The returned value is guaranteed to be at B{C{k}}-th position in the array (i.e.
20046 correctly ranked). All other values are correctly ordered with respect to this value: preceeding values are
20047 smaller (or equal) and following values are larger (or equal).
20048
20049 @since: 2.50
20050
20051 @param array: Array of doubles. It is shuffled by this function. I{(list)}
20052 @param k: Rank of the value to find (from lowest to highest). I{(int)}
20053 @return: The B{C{k}}-th value of B{C{array}} if it was sorted. I{(float)}
20054 """
20055 return None
20056
20068
20070 """
20071 Performs subpixel refinement of parabolic a two-dimensional maximum.
20072
20073 An alias for L{gwy_math_refine_maximum_2d}().
20074
20075 @since: 2.42
20076
20077 @param z: Array of length 9, containing the square 3x3 neighbourhood values in matrix order and with the maximum in the
20078 centre. I{(list)}
20079 @return: Tuple consisting of 3 values (B{C{x}}, B{C{y}}, B{C{refined}}). (I{(float)}, I{(float)}, I{(BooleanOutArg)})
20080 """
20081 return None, None, None
20082
20084 """
20085 Performs subpixel refinement of parabolic a one-dimensional maximum.
20086
20087 The central value corresponds to x-coordinate 0, distances between values are unity. The refinement is based by
20088 fitting a parabola through the maximum. If it fails or the calculated maximum lies farther than the surrounding
20089 values the function sets the refined maximum to the origin and returns B{C{False}}.
20090
20091 @since: 2.49
20092
20093 @param y: Array of length 3, containing the neighbourhood values with the maximum in the centre. I{(list)}
20094 @return: Tuple consisting of 2 values (B{C{x}}, B{C{refined}}). (I{(float)}, I{(BooleanOutArg)})
20095 """
20096 return None, None
20097
20099 """
20100 Performs subpixel refinement of parabolic a two-dimensional maximum.
20101
20102 The central value corresponds to coordinates (0,0), distances between values are unity. The refinement is based by
20103 fitting a two-dimensional parabola through the maximum. If it fails or the calculated maximum lies farther than
20104 the surrounding values the function sets the refined maximum to the origin and returns B{C{False}}.
20105
20106 @since: 2.49
20107
20108 @param z: Array of length 9, containing the square 3x3 neighbourhood values in matrix order and with the maximum in the
20109 centre. I{(list)}
20110 @return: Tuple consisting of 3 values (B{C{x}}, B{C{y}}, B{C{refined}}). (I{(float)}, I{(float)}, I{(BooleanOutArg)})
20111 """
20112 return None, None, None
20113
20115 """
20116 Finds trimmed mean of an array of values.
20117
20118 At least one value must remain after the trimming, i.e. B{C{nlowest}} + B{C{nhighest}} must be smaller than B{C{n}}. Usually one
20119 passes the same number as both B{C{nlowest}} and B{C{nhighest}}, but it is not a requirement.
20120
20121 The function can be also used to calculate normal mean values as it implements efficiently the cases when no
20122 trimming is done at either end.
20123
20124 @since: 2.50
20125
20126 @param array: Array of doubles. It is shuffled by this function. I{(list)}
20127 @param nlowest: The number of lowest values to discard. I{(int)}
20128 @param nhighest: The number of highest values to discard. I{(int)}
20129 @return: The trimmed mean. I{(float)}
20130 """
20131 return None
20132
20134 """
20135 Creates a pop-up GL material menu.
20136
20137 Object data C{"gl-material-name"} is set to GL material
20138 name for each menu item.
20139
20140
20141 @return: The newly created pop-up menu as B{C{GtkWidget}}. I{(L{gtk.Widget})}
20142 """
20143 return None
20144
20146 """
20147 Creates a pop-up gradient menu.
20148
20149 Object data C{"gradient-name"} is set to gradient name for
20150 each menu item.
20151
20152
20153 @return: The newly created pop-up menu as B{C{GtkWidget}}. I{(L{gtk.Widget})}
20154 """
20155 return None
20156
20158 """
20159 Shows a simple module browser.
20160
20161 """
20162 pass
20163
20165 """
20166 Opens a module data file in the user directory.
20167
20168 The function wraps L{gwy_fopen}(), forming the full file name automatically and handling subdirectory creation.
20169
20170 The error can be from B{C{glib.FILE_ERROR}} domain.
20171
20172 @since: 2.51
20173
20174 @param modname: Module name (determines the subdirectory). I{(string)}
20175 @param filename: Name of the file to save. In GLib encoding, but it really should be just ASCII. I{(string)}
20176 @param mode: File open mode, as in fopen(). I{(string)}
20177 @return: A file handle if the file was opened as requested, B{C{None}} on failure. I{(FILE*)}
20178 """
20179 return None
20180
20182 """
20183 Saves module data file to the user directory.
20184
20185 The function wraps g_file_set_contents(), forming the full file name automatically and handling subdirectory
20186 creation.
20187
20188 The error can be from B{C{glib.FILE_ERROR}} domain.
20189
20190 @since: 2.51
20191
20192 @param modname: Module name (determines the subdirectory). I{(string)}
20193 @param filename: Name of the file to save. In GLib encoding, but it really should be just ASCII. I{(string)}
20194 @param contents: File contents to write. I{(string)}
20195 @param length: Length of B{C{contents}}, or -1 if it is a NUL-terminated string. I{(gssize)}
20196 @return: B{C{True}} if the file was saved. I{(bool)}
20197 """
20198 return None
20199
20201 """
20202 Prevents the registration of a module of given name.
20203
20204 This function blocks future module registration using L{gwy_module_register_modules}(). Already loaded modules are
20205 unaffected. The low-level module loading function L{gwy_module_register_module}() always attempts to load the module,
20206 even if blocked.
20207
20208 @since: 2.48
20209
20210 @param name: A module name. I{(string)}
20211 """
20212 pass
20213
20215 """
20216 Unblocks the registration of a module of given name.
20217
20218 This function influences future module registration. Already loaded modules are unaffected.
20219
20220 @since: 2.48
20221
20222 @param name: A module name. I{(string)}
20223 """
20224 pass
20225
20227 """
20228 Returns error domain for module loading.
20229
20230 See and use B{C{MODULE_ERROR}}.
20231
20232
20233 @return: The error domain. I{(int)}
20234 """
20235 return None
20236
20238 """
20239 Returns error domain for file module functions.
20240
20241 See and use B{C{MODULE_FILE_ERROR}}.
20242
20243
20244 @return: The error domain. I{(int)}
20245 """
20246 return None
20247
20249 """
20250 Returns full file name of a module.
20251
20252
20253 @param name: A module name. I{(string)}
20254 @return: Module file name as a string that must be modified or freed. I{(string)}
20255 """
20256 return None
20257
20259 """
20260 Reports whether the registration of a module is enabled.
20261
20262 If the registration of module B{C{name}} was prevented using L{gwy_module_disable_registration}() and not subsequently
20263 re-enabled using L{gwy_module_enabled_registration}() this function returns B{C{False}}.
20264
20265 The reported values only represents the current state of blocking. A module B{C{name}} could have been loaded when it
20266 was not blocked.
20267
20268 @since: 2.48
20269
20270 @param name: A module name. I{(string)}
20271 @return: B{C{True}} if module B{C{name}} can be registered; B{C{False}} when it is blocked from registration. I{(bool)}
20272 """
20273 return None
20274
20276 """
20277 Convert numerical representation of key to string.
20278
20279 The argument may only be identifier actually corresponding to string key,
20280 for instance obtained with L{gwy_key_from_name}(). Do not pass random integers
20281 to this function.
20282
20283
20284 @param key: Numerical representation of a key. I{(int)}
20285 @return: Corresponding string key. I{(string)}
20286 """
20287 return None
20288
20290 """
20291 Gets inventory with all the NLFit presets.
20292
20293
20294 @return: NLFit preset inventory. I{(L{Inventory})}
20295 """
20296 return None
20297
20299 """
20300 Paints a data field to a pixbuf with an auto-stretched color gradient.
20301
20302 Minimum data value is mapped to start of B{C{gradient}}, maximum value to its
20303 end, values between are mapped linearly to B{C{gradient}}.
20304
20305 @param pixbuf: A Gdk pixbuf to draw to. I{(L{gdk.Pixbuf})}
20306 @param data_field: A data field to draw. I{(L{DataField})}
20307 @param gradient: A color gradient to draw with. I{(L{Gradient})}
20308 """
20309 pass
20310
20312 """
20313 Paints a data field to a pixbuf with a color gradient adaptively.
20314
20315 The mapping from data field (minimum, maximum) range to gradient is
20316 nonlinear, deformed using inverse function to height density cummulative
20317 distribution.
20318
20319 @param pixbuf: A Gdk pixbuf to draw to. I{(L{gdk.Pixbuf})}
20320 @param data_field: A data field to draw. I{(L{DataField})}
20321 @param gradient: A color gradient to draw with. I{(L{Gradient})}
20322 """
20323 pass
20324
20326 """
20327 Paints a data field to a pixbuf as a single-color mask with varying opacity.
20328
20329 Values equal or smaller to 0.0 are drawn as fully transparent, values
20330 greater or equal to 1.0 as fully opaque, values between are linearly
20331 mapped to pixel opacity.
20332
20333 @param pixbuf: A Gdk pixbuf to draw to. I{(L{gdk.Pixbuf})}
20334 @param data_field: A data field to draw. I{(L{DataField})}
20335 @param color: A color to use. I{(const-RGBA*)}
20336 """
20337 pass
20338
20340 """
20341 Paints a data field to a pixbuf with an explicite color gradient range.
20342
20343 B{C{minimum}} and all smaller values are mapped to start of B{C{gradient}}, B{C{maximum}}
20344 and all greater values to its end, values between are mapped linearly to
20345 B{C{gradient}}.
20346
20347 @param pixbuf: A Gdk pixbuf to draw to. I{(L{gdk.Pixbuf})}
20348 @param data_field: A data field to draw. I{(L{DataField})}
20349 @param gradient: A color gradient to draw with. I{(L{Gradient})}
20350 @param minimum: The value corresponding to gradient start. I{(float)}
20351 @param maximum: The value corresponding to gradient end. I{(float)}
20352 """
20353 pass
20354
20356 """
20357 Renders a preview of a XYZ data surface to a data field.
20358
20359 @since: 2.46
20360
20361 @param surface: A surface representing a XYZ data. I{(L{Surface})}
20362 @param dfield: A data field to fill with B{C{surface}} preview. I{(L{DataField})}
20363 @param max_xres: Maximum width of the preview, it must be at least 2. I{(int)}
20364 @param max_yres: Maximum height of the preview, it must be at least 2. I{(int)}
20365 @param flags: Flags modifying the behaviour. Expected values: C{B{PREVIEW_SURFACE_DENSITY}}, C{B{PREVIEW_SURFACE_FILL}}. I{(L{PreviewSurfaceFlags})}
20366 """
20367 pass
20368
20370 """
20371 Obtains the name of currently running data processing function.
20372
20373 If no process function is currently running, B{C{None}} is returned.
20374
20375 If multiple nested functions are running (which is not usual but technically
20376 possible), the innermost function name is returned.
20377
20378 @since: 2.38
20379
20380 @return: The name of currently running data processing function or B{C{None}}. I{(string)}
20381 """
20382 return None
20383
20385 """
20386 Checks whether a data processing function exists.
20387
20388
20389 @param name: Data processing function name. I{(string)}
20390 @return: B{C{True}} if function B{C{name}} exists, B{C{False}} otherwise. I{(bool)}
20391 """
20392 return None
20393
20395 """
20396 Returns the menu path of a data processing function.
20397
20398 The returned menu path is only the tail part registered by the function,
20399 i.e., without any leading "/Data Process".
20400
20401
20402 @param name: Data processing function name. I{(string)}
20403 @return: The menu path. The returned string is owned by the module. I{(string)}
20404 """
20405 return None
20406
20408 """
20409 Returns run modes supported by a data processing function.
20410
20411
20412 @param name: Data processing function name. I{(string)}
20413 @return: The run mode bit mask. I{(RunType)}
20414 """
20415 return None
20416
20418 """
20419 Gets menu sensititivy mask for a data processing function.
20420
20421
20422 @param name: Data processing function name. I{(string)}
20423 @return: The menu item sensitivity mask (a combination of B{C{MenuSensFlags}}
20424 flags). I{(int)}
20425 """
20426 return None
20427
20429 """
20430 Gets stock icon id of a data processing function.
20431
20432
20433 @param name: Data processing function name. I{(string)}
20434 @return: The stock icon id. The returned string is owned by the module. I{(string)}
20435 """
20436 return None
20437
20447
20449 """
20450 Runs a data processing function identified by B{C{name}}.
20451
20452 @param name: Data processing function name. I{(string)}
20453 @param data: Data (a B{C{Container}}). I{(L{Container})}
20454 @param run: How the function should be run. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
20455 """
20456 pass
20457
20459 """
20460 Makes libgwyprocess types safe for deserialization and performs other
20461 initialization. You have to call this function from the main thread before
20462 using objects from libgwyprocess.
20463
20464 It calls L{gwy_type_init}() first to make sure libgwyddion is initialized.
20465
20466 It is safe to call this function more than once, subsequent calls are no-op.
20467
20468 """
20469 pass
20470
20481
20494
20496 """
20497 Reports the size of a single raw data item.
20498
20499 @since: 2.25
20500
20501 @param datatype: Raw data type. Expected values: C{B{RAW_DATA_SINT8}}, C{B{RAW_DATA_UINT8}}, C{B{RAW_DATA_SINT16}}, C{B{RAW_DATA_UINT16}}, C{B{RAW_DATA_SINT32}}, C{B{RAW_DATA_UINT32}}, C{B{RAW_DATA_SINT64}}, C{B{RAW_DATA_UINT64}}, C{B{RAW_DATA_HALF}}, C{B{RAW_DATA_FLOAT}}, C{B{RAW_DATA_REAL}}, C{B{RAW_DATA_DOUBLE}}. I{(L{RawDataType})}
20502 @return: The size of a single raw data item of type B{C{datatype}}. I{(int)}
20503 """
20504 return None
20505
20507 """
20508 Checks if data field has equal lateral and value units, possibly showing error message.
20509
20510 If the data field does not have the same lateral and value units a simple error message dialog is shown for B{C{data}}
20511 and B{C{id}}. This is only done if other GUI functions (like progress bars for waiting) are enabled.
20512
20513 @since: 2.59
20514
20515 @param field: The data field to check. I{(L{DataField})}
20516 @param data: Data container with the data field. I{(L{Container})}
20517 @param id: The id of B{C{field}} in B{C{data}}. I{(int)}
20518 @param name: Error message prefix, usually module function name. I{(string)}
20519 @return: B{C{True}} if the units are the same, B{C{False}} otherwise. I{(bool)}
20520 """
20521 return None
20522
20524 """
20525 Checks if data field has the same horizontal and vertical pixel dimensions, possibly showing error message.
20526
20527 If the data field is not square a simple error message dialog is shown for B{C{data}} and B{C{id}}. This is only done if
20528 other GUI functions (like progress bars for waiting) are enabled.
20529
20530 @since: 2.59
20531
20532 @param field: The data field to check. I{(L{DataField})}
20533 @param data: Data container with the data field. I{(L{Container})}
20534 @param id: The id of B{C{field}} in B{C{data}}. I{(int)}
20535 @param name: Error message prefix, usually module function name. I{(string)}
20536 @return: B{C{True}} if the data field is square, B{C{False}} otherwise. I{(bool)}
20537 """
20538 return None
20539
20541 """
20542 Destroys the inventories of all resource classes.
20543
20544 This function makes the affected resource classes unusable. Its purpose is to faciliate reference leak debugging
20545 by destroying a large number of objects that normally live forever.
20546
20547 Note static resource classes that never called L{Resource.class_load}() are excluded.
20548
20549 @since: 2.8
20550
20551 """
20552 pass
20553
20555 """
20556 Reconstructs a resource from human readable form.
20557
20558
20559 @param text: Textual resource representation. I{(string)}
20560 @param expected_type: Resource object type. If not 0, only resources of give type are allowed. Zero value means any
20561 B{C{Resource}} is allowed. I{(GType)}
20562 @return: Newly created resource (or B{C{None}}). I{(L{Resource})}
20563 """
20564 return None
20565
20567 """
20568 Selects a resource in a list and scrolls to make it visible.
20569
20570
20571 @param treeview: A resource selector tree view. I{(L{gtk.Widget})}
20572 @param active: Resource name to be shown as currently selected. I{(string)}
20573 @return: B{C{True}} if B{C{active}} was selected, B{C{False}} if there is no such
20574 resource. I{(bool)}
20575 """
20576 return None
20577
20579 """
20580 Removes RGBA color components from a container.
20581
20582 This is a convenience function to remove the components in the common
20583 arrangement.
20584
20585
20586 @param container: A B{C{Container}} to remove the color components from. I{(L{Container})}
20587 @param prefix: Prefix in B{C{container}}, e.g. "/0/mask" (it will remove
20588 "/0/mask/red", "/0/mask/green", etc. then). I{(string)}
20589 @return: B{C{True}} if anything was removed. I{(bool)}
20590 """
20591 return None
20592
20594 """
20595 Runs a modal dialog transient for another another dialog, trying to work around bugs.
20596
20597 If both dialogs are modal, bad things can happen in some graphical environments, such as the second being hidden
20598 under the first one and inaccessible. This function attempts to work around this by temporarily setting the parent
20599 dialog (the one B{C{dialog}} is transient for) non-modal.
20600
20601 If the dialog is not transient for anything or its parent is not modal it is just run normally.
20602
20603 When the function resturns only the dialog has been destroyed.
20604
20605 @since: 2.62
20606
20607 @param dialog: A data dialog to be run as modal. I{(L{gtk.Dialog})}
20608 @return: The response of B{C{dialog}}. I{(int)}
20609 """
20610 return None
20611
20613 """
20614 Saves a report or other auxiliary data to a user specified file.
20615
20616 This is actually a simple L{gwy_save_auxiliary_with_callback}() wrapper, see its description for details.
20617
20618 @since: 2.3
20619
20620 @param title: File chooser dialog title. I{(string)}
20621 @param parent: Parent window for the file chooser dialog (may be B{C{None}}). I{(L{gtk.Window})}
20622 @param data_len: The length of B{C{data}} in bytes. Pass -1 if B{C{data}} is text, it must be nul-terminated then and it will be
20623 saved in text mode (this matters if the operating system distinguishes between text and binary).
20624 A non-negative value causes the data to be saved as binary. I{(gssize)}
20625 @param data: The data to save. I{(string)}
20626 @return: B{C{True}} if the data was saved, B{C{False}} if it was not saved for any reason. I{(bool)}
20627 """
20628 return None
20629
20631 """
20632 Selects an item in filtered tree view showing an inventory.
20633
20634 Usually the tree view would show a B{C{GtkTreeModelFilter}} model created by
20635 L{gwy_create_inventory_model_without_default}(). However, this function works also for other filter models around
20636 a B{C{InventoryStore}}.
20637
20638 @since: 2.62
20639
20640 @param treeview: A filtered tree view showing an inventory. I{(L{gtk.TreeView})}
20641 @param name: Item name to select. I{(string)}
20642 """
20643 pass
20644
20646 """
20647 Makes an object identical to another object of the same type.
20648
20649 More precisely, B{C{source}} may be subclass of B{C{copy}} (the extra information
20650 is lost then).
20651
20652 @param source: An object implementing B{C{Serializable}} interface. I{(L{gobject.GObject})}
20653 @param copy: An object of the same type as B{C{source}} to modify after it. I{(L{gobject.GObject})}
20654 """
20655 pass
20656
20658 """
20659 Makes an object identical to another object of the same type, with explicit
20660 type checking.
20661
20662 This function is the same as L{gwy_serializable_clone}(), except it asserts
20663 the object type, which must be B{C{type}}.
20664
20665 Since 2.52
20666
20667 @param source: An object implementing B{C{Serializable}} interface. I{(L{gobject.GObject})}
20668 @param copy: An object of the same type as B{C{source}} to modify after it. I{(L{gobject.GObject})}
20669 @param type: The type the objects are asserted to be. I{(GType)}
20670 """
20671 pass
20672
20674 """
20675 Creates a copy of an object.
20676
20677 If the object doesn't support duplication natively, it's brute-force
20678 serialized and then deserialized, this may be quite inefficient,
20679 namely for large objects.
20680
20681 You can duplicate a B{C{None}}, too, but you are discouraged from doing it.
20682
20683
20684 @param object: An object implementing B{C{Serializable}} interface. I{(L{gobject.GObject})}
20685 @return: The newly created object copy. However if the object is a
20686 singleton, B{C{object}} itself (with incremented reference count)
20687 can be returned, too. I{(L{gobject.GObject})}
20688 """
20689 return None
20690
20692 """
20693 Calculates the expected size of serialized object.
20694
20695
20696 @param serializable: A B{C{GObject}} that implements B{C{Serializable}} interface. I{(L{gobject.GObject})}
20697 @return: The expected size of serialized B{C{serializable}}. I{(gsize)}
20698 """
20699 return None
20700
20702 """
20703 Check whether B{C{size}} bytes of memory in B{C{buffer}} can be interpreted as a
20704 NUL-terminated string, and eventually whether it's equal to B{C{compare_to}}.
20705
20706 When B{C{compare_to}} is B{C{None}}, the comparsion is not performed.
20707
20708
20709 @param buffer: A memory location containing a NUL-terminated string at position
20710 B{C{position}}. I{(string)}
20711 @param size: The size of B{C{buffer}}. I{(gsize)}
20712 @param position: The position of the string in B{C{buffer}}. I{(gsize)}
20713 @param compare_to: String to compare B{C{buffer}} to, or B{C{None}}. I{(string)}
20714 @return: The length of the NUL-terminated string including the NUL
20715 character; zero otherwise. I{(gsize)}
20716 """
20717 return None
20718
20720 """
20721 Sets up data view zoom to not exceed specified size.
20722
20723 Before calling this function, data keys have be set, data fields and layers have to be present and physically
20724 square mode set in the container. Sizing of both pixel-wise square and physically square displays is performed
20725 correctly.
20726
20727 @since: 2.7
20728
20729 @param data_view: A data view used for module preview. I{(L{DataView})}
20730 @param max_size: Maximum allowed B{C{data_view}} size (width and height). I{(int)}
20731 """
20732 pass
20733
20734 -def gwy_sgettext(msgid):
20735 """
20736 Translate a message id containing disambiguating prefix ending with `|'.
20737
20738
20739 @param msgid: Message id to translate, containing `|'-separated prefix. I{(string)}
20740 @return: Translated message, or B{C{msgid}} itself with all text up to the last `|' removed if there is no translation. I{(string)}
20741 """
20742 return None
20743
20745 """
20746 Gets inventory with all the 3D geometric shape fitting presets.
20747
20748 @since: 2.47
20749
20750 @return: 3D geometric shape fitting preset inventory. I{(L{Inventory})}
20751 """
20752 return None
20753
20755 """
20756 Creates a new SI unit from string representation.
20757
20758 This is a more powerful version of L{SIUnit.new}(): B{C{unit_string}} may be a relatively complex unit, with prefixes,
20759 like "pA/s" or "km^2". Beside conversion to a base SI unit like "A/s" or "m^2" it also computes the power of 10 one
20760 has to multiply the base unit with to get an equivalent of B{C{unit_string}}.
20761
20762 For example, for C{"pA/s"} it will store -12 to B{C{power10}} because 1 pA/s is 1e-12 A/s, for
20763 C{"km^2"} it will store 6 to B{C{power10}} because 1 km^2 is 1e6 m^2.
20764
20765
20766 @param unit_string: Unit string (it can be B{C{None}} for an empty unit). I{(string)}
20767 @return: Tuple consisting of 2 values (B{C{value}}, B{C{power10}}). (I{(L{SIUnit})}, I{(int)})
20768 """
20769 return None, None
20770
20786
20797
20805
20807 """
20808 Calculates the sinc function.
20809
20810 The sinc function is equal to sin(B{C{x}})/B{C{x}} for non-zero B{C{x}}, and defined to the limit 1 for zero B{C{x}}.
20811
20812 @since: 2.51
20813
20814 @param x: Value to calculate sinc (cardinal sine) of. I{(float)}
20815 @return: Value of sinc(B{C{x}}). I{(float)}
20816 """
20817 return None
20818
20820 """
20821 Creates a new spline curve passing through given points.
20822
20823 See L{Spline.set_points}() for discussion.
20824
20825 @since: 2.45
20826
20827 @param xy: Array of points in plane the curve will pass through. I{(list)}
20828 @return: A newly created spline curve. I{(L{Spline})}
20829 """
20830 return None
20831
20833 """
20834 Registers stock items.
20835
20836 This function must be called before any stock items are used.
20837
20838 """
20839 pass
20840
20842 """
20843 Measures the width of UTF-8 encoded string in fixed-width font.
20844
20845 This corresponds to width of the string displayed on a text terminal, for instance. Zero and double width
20846 characters are taken into account. It is not guaranteed all terminals display the string with the calculated
20847 width.
20848
20849 @since: 2.52
20850
20851 @param str: UTF-8 encoded string. I{(string)}
20852 @return: String width in fixed font, in character cells. I{(int)}
20853 """
20854 return None
20855
20857 """
20858 Finds position where two strings differ.
20859
20860
20861 @param s1: A string. I{(string)}
20862 @param s2: A string. I{(string)}
20863 @return: The last position where the strings do not differ yet. Possibly -1 can be returned if either string is
20864 B{C{None}}, zero-length, or they differ in the very first character. I{(int)}
20865 """
20866 return None
20867
20869 """
20870 Checks whether a string is valid identifier.
20871
20872 Valid identifier must start with an alphabetic character or a character from B{C{startmore}}, and it must continue with
20873 alphanumeric characters or characters from B{C{more}}.
20874
20875 Note underscore is not allowed by default, you have to pass it in B{C{more}} and/or B{C{startmore}}.
20876
20877
20878 @param s: A NUL-terminated string. I{(string)}
20879 @param more: List of additional ASCII characters allowed inside identifier, empty list can be passed as B{C{None}}. I{(string)}
20880 @param startmore: List of additional ASCII characters allowed as the first identifier characters, empty list can be
20881 passed as B{C{None}}. I{(string)}
20882 @return: B{C{True}} if B{C{s}} is valid identifier, B{C{False}} otherwise. I{(bool)}
20883 """
20884 return None
20885
20887 """
20888 Removes characters in B{C{killchars}} from string B{C{s}}, modifying it in place.
20889
20890 Use L{gwy_strkill}(g_strdup(B{C{s}}), B{C{killchars}}) to get a modified copy.
20891
20892
20893 @param s: A NUL-terminated string. I{(string)}
20894 @param killchars: A string containing characters to kill. I{(string)}
20895 @return: B{C{s}} itself, the return value is to allow function call nesting. I{(string)}
20896 """
20897 return None
20898
20900 """
20901 Replaces occurences of string B{C{needle}} in B{C{haystack}} with B{C{replacement}}.
20902
20903 See L{gwy_gstring_replace}() for a function which does in-place replacement on a B{C{GString}}.
20904
20905
20906 @param haystack: A NUL-terminated string to search in. I{(string)}
20907 @param needle: A NUL-terminated string to search for. I{(string)}
20908 @param replacement: A NUL-terminated string to replace B{C{needle}} with. I{(string)}
20909 @param maxrepl: Maximum number of occurences to replace (use (gsize)-1 to replace all occurences). I{(gsize)}
20910 @return: A newly allocated string. I{(string)}
20911 """
20912 return None
20913
20915 """
20916 Creates a new surface, filling it with provided points.
20917
20918 @since: 2.45
20919
20920 @param points: Array of B{C{n}} points with the surface data. I{(const-XYZ*)}
20921 @param n: Number of points. I{(int)}
20922 @return: A new surface. I{(L{Surface})}
20923 """
20924 return None
20925
20927 """
20928 Creates a new surface with preallocated size.
20929
20930 The surface will contain the speficied number of points with uninitialised
20931 values.
20932
20933 @since: 2.45
20934
20935 @param n: Number of points. I{(int)}
20936 @return: A new surface. I{(L{Surface})}
20937 """
20938 return None
20939
20941 """
20942 Attaches an adjustment bar with spinbutton and labels, or something else, to
20943 a table row.
20944
20945 The group of controls takes three table columns: adjustment bar, spinbutton
20946 and units.
20947
20948 You can use functions L{gwy_table_hscale_get_scale}(),
20949 L{gwy_table_hscale_get_check}(), etc. to get the various widgets from pivot
20950 later.
20951
20952 The function usually does the right thing but what exactly happens with
20953 various B{C{style}} values is a bit convoluted.
20954
20955 @since: 2.49
20956
20957 @param table: A B{C{GtkTable}}. I{(L{gtk.Widget})}
20958 @param row: Row in B{C{table}} to attach stuff to. I{(int)}
20959 @param name: The label before B{C{pivot}} widget. I{(string)}
20960 @param units: The label after B{C{pivot}} widget. I{(string)}
20961 @param pivot: Either a B{C{GtkAdjustment}}, or a widget to use instead of the spin
20962 button and scale widgets (if B{C{style}} is B{C{HSCALE_WIDGET}}). I{(L{gtk.Object})}
20963 @param style: A mix of options an flags determining what and how will be attached
20964 to the table. Expected values: C{B{HSCALE_DEFAULT}}, C{B{HSCALE_LOG}}, C{B{HSCALE_SQRT}}, C{B{HSCALE_LINEAR}}, C{B{HSCALE_NO_SCALE}}, C{B{HSCALE_WIDGET}}, C{B{HSCALE_WIDGET_NO_EXPAND}}, C{B{HSCALE_CHECK}}, C{B{HSCALE_SNAP}}. I{(L{HScaleStyle})}
20965 @return: The middle widget. If a spinbutton is attached, then this
20966 spinbutton is returned. Otherwise (in B{C{HSCALE_WIDGET}} case)
20967 B{C{pivot}} itself. I{(L{gtk.Widget})}
20968 """
20969 return None
20970
20972 """
20973 Attaches a spinbutton with a scale and labels, or something else, to a table
20974 row.
20975
20976 The group of controls takes four table columns: label, scale, spinbutton
20977 and units.
20978
20979 You can use functions L{gwy_table_hscale_get_scale}(),
20980 L{gwy_table_hscale_get_check}(), etc. to get the various widgets from pivot
20981 later.
20982
20983 The function usually does the right thing but what exactly happens with
20984 various B{C{style}} values is a bit convoluted.
20985
20986
20987 @param table: A B{C{GtkTable}}. I{(L{gtk.Widget})}
20988 @param row: Row in B{C{table}} to attach stuff to. I{(int)}
20989 @param name: The label before B{C{pivot}} widget. I{(string)}
20990 @param units: The label after B{C{pivot}} widget. I{(string)}
20991 @param pivot: Either a B{C{GtkAdjustment}}, or a widget to use instead of the spin
20992 button and scale widgets (if B{C{style}} is B{C{HSCALE_WIDGET}}). I{(L{gtk.Object})}
20993 @param style: A mix of options an flags determining what and how will be attached
20994 to the table. Expected values: C{B{HSCALE_DEFAULT}}, C{B{HSCALE_LOG}}, C{B{HSCALE_SQRT}}, C{B{HSCALE_LINEAR}}, C{B{HSCALE_NO_SCALE}}, C{B{HSCALE_WIDGET}}, C{B{HSCALE_WIDGET_NO_EXPAND}}, C{B{HSCALE_CHECK}}, C{B{HSCALE_SNAP}}. I{(L{HScaleStyle})}
20995 @return: The middle widget. If a spinbutton is attached, then this
20996 spinbutton is returned. Otherwise (in B{C{HSCALE_WIDGET}} case)
20997 B{C{pivot}} itself. I{(L{gtk.Widget})}
20998 """
20999 return None
21000
21002 """
21003 Attaches a widget with two labels to a table.
21004
21005 @param table: A B{C{GtkTable}}. I{(L{gtk.Widget})}
21006 @param row: Table row to attach to. I{(int)}
21007 @param name: The label before B{C{middle_widget}}. I{(string)}
21008 @param units: The label after B{C{adj}}. I{(string)}
21009 @param middle_widget: A widget. I{(L{gtk.Widget})}
21010 """
21011 pass
21012
21026
21046
21048 """
21049 Gets the check button associated with a pivot object.
21050
21051 May return B{C{None}} if not constructed with B{C{HSCALE_CHECK}}.
21052
21053 @param pivot: Pivot object passed to L{gwy_table_attach_hscale}(). I{(L{gtk.Object})}
21054 @return: I{(L{gtk.Widget})}
21055 """
21056 return None
21057
21059 """
21060 Gets the (left) label associated with a pivot object.
21061
21062 May return B{C{None}} if constructed with B{C{HSCALE_CHECK}}.
21063
21064 @param pivot: Pivot object passed to L{gwy_table_attach_hscale}(). I{(L{gtk.Object})}
21065 @return: I{(L{gtk.Widget})}
21066 """
21067 return None
21068
21077
21079 """
21080 Gets the horizontal scale associated with a pivot object.
21081
21082 May return B{C{None}} if constructed with B{C{HSCALE_NO_SCALE}},
21083 B{C{HSCALE_WIDGET}}, or B{C{HSCALE_WIDGET_NO_EXPAND}}.
21084
21085 @param pivot: Pivot object passed to L{gwy_table_attach_hscale}(). I{(L{gtk.Object})}
21086 @return: I{(L{gtk.Widget})}
21087 """
21088 return None
21089
21091 """
21092 Gets the units label associated with a pivot object.
21093
21094 May return B{C{None}} if constructed without units.
21095
21096 @param pivot: Pivot object passed to L{gwy_table_attach_hscale}(). I{(L{gtk.Object})}
21097 @return: I{(L{gtk.Widget})}
21098 """
21099 return None
21100
21102 """
21103 Sets sensitivity of a group of controls create by L{gwy_table_attach_hscale}()
21104 or L{gwy_table_attach_adjbar}().
21105
21106 For controls without an enable/disable check button controls the sensitivity
21107 as expected. If the hscale was created with B{C{HSCALE_CHECK}} you usually
21108 manage its sensitivity by setting state of the check button instead.
21109 Only use this function when you want to enable/disable the entire group
21110 of controls, including the check button.
21111
21112 This function can also be used with rows created by
21113 L{gwy_table_attach_spinbutton}() too if the spinbutton is passed as B{C{pivot}}.
21114
21115 @param pivot: The same object that was passed to L{gwy_table_attach_hscale}() as
21116 B{C{pivot}}. I{(L{gtk.Object})}
21117 @param sensitive: B{C{True}} to make the row sensitive, B{C{False}} to insensitive. I{(bool)}
21118 """
21119 pass
21120
21122 """
21123 Returns error domain for expression parsin and evaluation.
21124
21125 See and use B{C{TEXT_HEADER_ERROR}}.
21126
21127 @since: 2.18
21128
21129 @return: The error domain. I{(int)}
21130 """
21131 return None
21132
21134 """
21135 Obtains the state of internal multithread processing.
21136
21137 @since: 2.53
21138
21139 @return: B{C{True}} if multithread processing is enabled; B{C{False}} otherwise (this
21140 includes the case of Gwyddion not built with multithread processing
21141 support at all). I{(bool)}
21142 """
21143 return None
21144
21146 """
21147 Enables or disables internal multithread processing.
21148
21149 This function can be called any time during the program life time to switch
21150 between single- and multithread processing. It must be called from the main
21151 thread while no Gwyddion data processing functions are being executed.
21152
21153 @since: 2.53
21154
21155 @param setting: B{C{True}} to enable multithread processing; B{C{False}} to disable it. I{(bool)}
21156 """
21157 pass
21158
21160 """
21161 Performs certainty map algorithm published by Villarrubia. This function
21162 converts all fields into form requested by "morph_lib.c" library, that is
21163 almost identical with original Villarubia's library. Result certainty map
21164 can be used as a mask of points where tip did not directly touch the
21165 surface.
21166
21167
21168 @param tip: Tip data. I{(L{DataField})}
21169 @param surface: Surface data. I{(L{DataField})}
21170 @return: Certainty map, i.e. B{C{result}}, on success. May return B{C{None}} if
21171 aborted. I{(L{DataField})}
21172 """
21173 return None
21174
21176 """
21177 Performs the tip convolution algorithm published by Villarrubia, which is
21178 equivalent to morphological dilation operation.
21179
21180 If the operation is aborted the size and contents of B{C{result}} field is
21181 undefined.
21182
21183
21184 @param tip: Tip data. I{(L{DataField})}
21185 @param surface: Surface data. I{(L{DataField})}
21186 @return: Dilated surface data, i.e. B{C{result}}, on success. May return B{C{None}}
21187 if aborted. I{(L{DataField})}
21188 """
21189 return None
21190
21192 """
21193 Performs surface reconstruction (erosion) algorithm published by
21194 Villarrubia, which is equivalent to morphological erosion operation.
21195
21196 If the operation is aborted the size and contents of B{C{result}} field is
21197 undefined.
21198
21199
21200 @param tip: Tip data. I{(L{DataField})}
21201 @param surface: Surface to be eroded. I{(L{DataField})}
21202 @return: Reconstructed (eroded) surface, i.e. B{C{result}}, on success. May
21203 return B{C{None}} if aborted. I{(L{DataField})}
21204 """
21205 return None
21206
21208 """
21209 Performs full blind estimation algorithm published by Villarrubia. This
21210 function converts all fields into form requested by "morph_lib.c" library,
21211 that is almost identical with original Villarubia's library. Note that the
21212 threshold value must be chosen sufficently high value to supress small
21213 fluctulations due to noise (that would lead to very sharp tip) but
21214 sufficiently low value to put algorithm at work. A value similar to 1/10000
21215 of surface range can be good. Otherwise we recommend to start with zero
21216 threshold and increase it slowly to observe changes and choose right value.
21217
21218
21219 @param tip: Tip data to be refined (allocated). I{(L{DataField})}
21220 @param surface: Surface data. I{(L{DataField})}
21221 @param threshold: Threshold for noise supression. I{(float)}
21222 @param use_edges: Whether use also edges of image. I{(bool)}
21223 @return: Tuple consisting of 4 values (B{C{value}}, B{C{count}}, B{C{set_fraction}}, B{C{set_message}}). (I{(L{DataField})}, I{(int)}, I{(SkipArg)}, I{(SkipArg)})
21224 """
21225 return None, None, None, None
21226
21228 """
21229 Performs partial blind estimation algorithm published by Villarrubia. This
21230 function converts all fields into form requested by "morph_lib.c" library,
21231 that is almost identical with original Villarubia's library. Note that the
21232 threshold value must be chosen sufficently high value to supress small
21233 fluctulations due to noise (that would lead to very sharp tip) but
21234 sufficiently low value to put algorithm at work. A value similar to 1/10000
21235 of surface range can be good. Otherwise we recommend to start with zero
21236 threshold and increase it slowly to observe changes and choose right value.
21237
21238
21239 @param tip: Tip data to be refined (allocated). I{(L{DataField})}
21240 @param surface: Surface data. I{(L{DataField})}
21241 @param threshold: Threshold for noise supression. I{(float)}
21242 @param use_edges: Whether use also edges of image. I{(bool)}
21243 @return: Tuple consisting of 4 values (B{C{value}}, B{C{count}}, B{C{set_fraction}}, B{C{set_message}}). (I{(L{DataField})}, I{(int)}, I{(SkipArg)}, I{(SkipArg)})
21244 """
21245 return None, None, None, None
21246
21248 """
21249 Find number of actual tip model presets.
21250
21251
21252 @return: Number of presets. I{(int)}
21253 """
21254 return None
21255
21257 """
21258 Get data related to tip preset.
21259
21260
21261 @param preset_id: Preset identifier. I{(int)}
21262 @return: Chosen preset data. I{(const-TipModelPreset*)}
21263 """
21264 return None
21265
21267 """
21268 Get data related to preset with specified name.
21269
21270
21271 @param name: Name of tip (e. g. "contact"). I{(string)}
21272 @return: Chosen preset data. I{(const-TipModelPreset*)}
21273 """
21274 return None
21275
21277 """
21278 Get group name of preset (e. g. "analytical".)
21279
21280
21281 @param preset: Tip model preset. I{(const-TipModelPreset*)}
21282 @return: Preset group name. I{(string)}
21283 """
21284 return None
21285
21287 """
21288 Get preset identifier within all presets.
21289
21290
21291 @param preset: Tip model preset. I{(const-TipModelPreset*)}
21292 @return: Preset id. I{(int)}
21293 """
21294 return None
21295
21297 """
21298 Get name of the preset (e. g. "contact").
21299
21300
21301 @param preset: Tip model preset. I{(const-TipModelPreset*)}
21302 @return: Preset name. I{(string)}
21303 """
21304 return None
21305
21316
21318 """
21319 Makes libgwyddion types safe for deserialization and performs other
21320 initialization. You have to call this function from the main thread before
21321 using objects from libgwyddion.
21322
21323 It calls g_type_init() first to make sure GLib object system is initialized.
21324
21325 It is safe to call this function more than once, subsequent calls are no-op.
21326
21327 """
21328 pass
21329
21331 """
21332 Create a point in the undo history it is possible to return to.
21333
21334
21335 @param container: I{(L{Container})}
21336 @param keys: I{(StringArray*)}
21337 @return: Undo level id. Not useful (yet). I{(gulong)}
21338 """
21339 return None
21340
21342 """
21343 Tests whether a container was modified.
21344
21345 FIXME: it may not work.
21346
21347
21348 @param data: Data container to get modification infomation of. I{(L{Container})}
21349 @return: B{C{True}} if container was modified, B{C{False}} otherwise. I{(int)}
21350 """
21351 return None
21352
21354 """
21355 Returns whether there is any redo available for a container.
21356
21357
21358 @param data: Data container to get redo infomation of. I{(L{Container})}
21359 @return: B{C{True}} if there is redo, B{C{False}} otherwise. I{(bool)}
21360 """
21361 return None
21362
21364 """
21365 Returns whether there is any undo available for a container.
21366
21367
21368 @param data: Data container to get undo infomation of. I{(L{Container})}
21369 @return: B{C{True}} if there is undo, B{C{False}} otherwise. I{(bool)}
21370 """
21371 return None
21372
21374 """
21375 Removes undo/redo information for a data container.
21376
21377 @param data: A data container. I{(L{Container})}
21378 @param prefix: Prefix to remove undo/redo information under. Pass B{C{None}} to remove
21379 undo/redo information altogether. I{(string)}
21380 """
21381 pass
21382
21384 """
21385 Marks a data container as umodified (that is, saved).
21386
21387 @param data: Data container to set modification infomation of. I{(L{Container})}
21388 """
21389 pass
21390
21392 """
21393 Reports whether undo/redo is globally enabled.
21394
21395 @since: 2.21
21396
21397 @return: B{C{True}} if undo/redo is enabled, B{C{False}} if it is disabled. I{(bool)}
21398 """
21399 return None
21400
21402 """
21403 Create a point in the undo history it is possible to return to.
21404
21405
21406 @param container: I{(L{Container})}
21407 @param keys: I{(list)}
21408 @return: Undo level id. Not useful (yet). I{(gulong)}
21409 """
21410 return None
21411
21413 """
21414 Performs undo on a data container.
21415
21416 It must have redo available.
21417
21418 @param data: A data container. I{(L{Container})}
21419 """
21420 pass
21421
21423 """
21424 Globally enables or disables undo/redo.
21425
21426 By default, undo/redo is enabled. Non-GUI applications that run module
21427 functions may wish to disable it to conserve resources.
21428
21429 If undo/redo is disabled undo information manipulating functions such as
21430 L{gwy_app_undo_qcheckpoint}() become no-op and
21431 L{gwy_undo_container_get_modified}() always returns zero. Disabling undo also
21432 removes saved undo data of all containers.
21433
21434 @since: 2.21
21435
21436 @param setting: B{C{True}} to enable undo, B{C{False}} to disable it. I{(bool)}
21437 """
21438 pass
21439
21441 """
21442 Performs undo on a data container.
21443
21444 It must have undo available.
21445
21446 @param data: A data container. I{(L{Container})}
21447 """
21448 pass
21449
21451 """
21452 Escapes special characters in a string.
21453
21454 Escapes the special characters '\b', '\f', '\n', '\r', '\t', '\v', '\' and '"' in the string source by inserting
21455 a '\' before them. Additionally all characters in the range 0x01-0x1F (everything below SPACE), the character 0x7F,
21456 characters 0xC0 and 0xC1, and all characters in the range 0xF5-0xFF are replaced with a '\' followed by their octal
21457 representation. Characters supplied in exceptions are not escaped.
21458
21459 In essence, this functions differs from g_strescape() by preserving valid UTF-8 strings, unless they contain ‘odd’
21460 characters. Passing strings which are not valid UTF-8 is possible, but generally not advised.
21461
21462 Function g_strcompress() does the reverse conversion.
21463
21464 @since: 2.62
21465
21466 @param source: A string to escape. I{(string)}
21467 @param exceptions: A string containing characters to not escape, or B{C{None}}. I{(string)}
21468 @return: A newly allocated string with special characters escaped. I{(string)}
21469 """
21470 return None
21471
21473 """
21474 Gets the major version of Gwyddion.
21475
21476 If the version is 1.99.7.20060604, this function returns 1.
21477
21478
21479 @return: The major version. I{(int)}
21480 """
21481 return None
21482
21484 """
21485 Gets the minor version of Gwyddion.
21486
21487 If the version is 1.99.7.20060604, this function returns 99.
21488
21489
21490 @return: The minor version. I{(int)}
21491 """
21492 return None
21493
21495 """
21496 Gets the full Gwyddion version as a string.
21497
21498 If the version is 1.99.7.20060604, this function returns
21499 C{"1.99.7.20060604"}.
21500
21501 This is the only method to get finer version information than major.minor.
21502 However, only development versions use finer versioning than major.minor
21503 therefore a module or app requiring such information is probably broken
21504 anyway. A meaningful use is to advertise the version of Gwyddion your app
21505 runs with.
21506
21507
21508 @return: The full version as a constant string. I{(string)}
21509 """
21510 return None
21511
21513 """
21514 Obtains the name of currently running volume data processing function.
21515
21516 If no volume data processing function is currently running, B{C{None}} is
21517 returned.
21518
21519 If multiple nested functions are running (which is not usual but technically
21520 possible), the innermost function name is returned.
21521
21522 @since: 2.38
21523
21524 @return: The name of currently running volume data processing function or
21525 B{C{None}}. I{(string)}
21526 """
21527 return None
21528
21530 """
21531 Checks whether a volume data processing function exists.
21532
21533 @since: 2.32
21534
21535 @param name: Volume data processing function name. I{(string)}
21536 @return: B{C{True}} if function B{C{name}} exists, B{C{False}} otherwise. I{(bool)}
21537 """
21538 return None
21539
21541 """
21542 Returns the menu path of a volume data processing function.
21543
21544 The returned menu path is only the tail part registered by the function,
21545 i.e., without any leading "/Volume Data".
21546
21547 @since: 2.32
21548
21549 @param name: Volume data processing function name. I{(string)}
21550 @return: The menu path. The returned string is owned by the module. I{(string)}
21551 """
21552 return None
21553
21555 """
21556 Returns run modes supported by a volume data processing function.
21557
21558 @since: 2.32
21559
21560 @param name: Volume data processing function name. I{(string)}
21561 @return: The run mode bit mask. I{(RunType)}
21562 """
21563 return None
21564
21566 """
21567 Gets menu sensititivy mask for a volume data processing function.
21568
21569 @since: 2.32
21570
21571 @param name: Volume data processing function name. I{(string)}
21572 @return: The menu item sensitivity mask (a combination of B{C{MenuSensFlags}}
21573 flags). I{(int)}
21574 """
21575 return None
21576
21578 """
21579 Gets stock icon id of a volume data processing function.
21580
21581 @since: 2.32
21582
21583 @param name: Volume data processing function name. I{(string)}
21584 @return: The stock icon id. The returned string is owned by the module. I{(string)}
21585 """
21586 return None
21587
21598
21600 """
21601 Runs a volume data processing function identified by B{C{name}}.
21602
21603 @since: 2.32
21604
21605 @param name: Volume data processing function name. I{(string)}
21606 @param data: Data (a B{C{Container}}). I{(L{Container})}
21607 @param run: How the function should be run. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
21608 """
21609 pass
21610
21622
21636
21651
21663
21677
21690
21692 """
21693 Calculates natural logarithm multiplied by the argument for integers.
21694
21695 The value for zero B{C{x}} is taken as the limit, i.e. zero.
21696
21697 This function is useful for entropy calculations where values of B{C{n}}*log(B{C{n}}) can be evaulated a lot for small B{C{n}}.
21698 Therefore, values for small arguments are tabulated. For large arguments the function is evaluated using the
21699 standard log() function which is of course slower.
21700
21701 @since: 2.44
21702
21703 @param x: Value to calculate B{C{x}}*log(B{C{x}}) of. I{(int)}
21704 @return: Value of B{C{x}}*log(B{C{x}}). I{(float)}
21705 """
21706 return None
21707
21709 """
21710 Obtains the name of currently running surface data processing function.
21711
21712 If no surface data processing function is currently running, B{C{None}} is
21713 returned.
21714
21715 If multiple nested functions are running (which is not usual but technically
21716 possible), the innermost function name is returned.
21717
21718 @since: 2.38
21719
21720 @return: The name of currently running surface data processing function or
21721 B{C{None}}. I{(string)}
21722 """
21723 return None
21724
21726 """
21727 Checks whether a surface data processing function exists.
21728
21729 @since: 2.45
21730
21731 @param name: XYZ surface data processing function name. I{(string)}
21732 @return: B{C{True}} if function B{C{name}} exists, B{C{False}} otherwise. I{(bool)}
21733 """
21734 return None
21735
21737 """
21738 Returns the menu path of a surface data processing function.
21739
21740 The returned menu path is only the tail part registered by the function,
21741 i.e., without any leading "/XYZ Data".
21742
21743 @since: 2.45
21744
21745 @param name: XYZ surface data processing function name. I{(string)}
21746 @return: The menu path. The returned string is owned by the module. I{(string)}
21747 """
21748 return None
21749
21751 """
21752 Returns run modes supported by a surface data processing function.
21753
21754 @since: 2.45
21755
21756 @param name: XYZ surface data processing function name. I{(string)}
21757 @return: The run mode bit mask. I{(RunType)}
21758 """
21759 return None
21760
21762 """
21763 Gets menu sensititivy mask for a surface data processing function.
21764
21765 @since: 2.45
21766
21767 @param name: XYZ surface data processing function name. I{(string)}
21768 @return: The menu item sensitivity mask (a combination of B{C{MenuSensFlags}}
21769 flags). I{(int)}
21770 """
21771 return None
21772
21774 """
21775 Gets stock icon id of a surface data processing function.
21776
21777 @since: 2.45
21778
21779 @param name: XYZ surface data processing function name. I{(string)}
21780 @return: The stock icon id. The returned string is owned by the module. I{(string)}
21781 """
21782 return None
21783
21794
21796 """
21797 Runs a surface data processing function identified by B{C{name}}.
21798
21799 @since: 2.45
21800
21801 @param name: XYZ surface data processing function name. I{(string)}
21802 @param data: Data (a B{C{Container}}). I{(L{Container})}
21803 @param run: How the function should be run. Expected values: C{B{RUN_NONE}}, C{B{RUN_NONINTERACTIVE}}, C{B{RUN_INTERACTIVE}}, C{B{RUN_IMMEDIATE}}, C{B{RUN_MASK}}. I{(L{RunType})}
21804 """
21805 pass
21806
21807
21830
21832 """
21833 Type of fitting parameter properties.
21834
21835 @since: 2.47
21836
21837 @note: All the enumerated values are defined at the module level, I{not} the
21838 class level. The are just groupped by class here for easier orientation.
21839
21840 @cvar NLFIT_PARAM_ANGLE: Parameter is an angle. It is defined in radians and
21841 unitless but you may wish to convert it from/to
21842 degrees in the user interface. It is consdered
21843 periodic and always reduced to the range [0, 2π).
21844 @cvar NLFIT_PARAM_ABSVAL: Parameter is a width or distance that is by
21845 definition positive. Only its absolute value
21846 matters and it is always made non-negative.
21847 """
21848 pass
21849
21851 """
21852 Type of interpolation for percentile calculation.
21853
21854 The interpolations are used when the percentile does not correspond exactly to a rank.
21855
21856 @since: 2.50
21857
21858 @note: All the enumerated values are defined at the module level, I{not} the
21859 class level. The are just groupped by class here for easier orientation.
21860
21861 @cvar PERCENTILE_INTERPOLATION_LINEAR: Linear interpolation of the two nearest values.
21862 @cvar PERCENTILE_INTERPOLATION_LOWER: Round the rank down to an integer.
21863 @cvar PERCENTILE_INTERPOLATION_HIGHER: Round the rank up to an integer.
21864 @cvar PERCENTILE_INTERPOLATION_NEAREST: Round the rank to nearest integer.
21865 @cvar PERCENTILE_INTERPOLATION_MIDPOINT: Average of the two nearest values.
21866 """
21867 pass
21868
21870 """
21871 Error codes returned by expression parsing and execution.
21872
21873 @note: All the enumerated values are defined at the module level, I{not} the
21874 class level. The are just groupped by class here for easier orientation.
21875
21876 @cvar EXPR_ERROR_CLOSING_PARENTHESIS: A closing parenthesis is missing.
21877 @cvar EXPR_ERROR_EMPTY: Expression is empty.
21878 @cvar EXPR_ERROR_EMPTY_PARENTHESES: A parentheses pair contain nothing
21879 inside.
21880 @cvar EXPR_ERROR_GARBAGE: An symbol unexpectedly managed to survive.
21881 @cvar EXPR_ERROR_INVALID_ARGUMENT: Function or operator argument is not a
21882 value.
21883 @cvar EXPR_ERROR_INVALID_TOKEN: Expression contains an invalid token.
21884 @cvar EXPR_ERROR_MISSING_ARGUMENT: Function or operator arguments is missing.
21885 @cvar EXPR_ERROR_NOT_EXECUTABLE: Compiled stack is not executable.
21886 @cvar EXPR_ERROR_OPENING_PARENTHESIS: An opening parenthesis is missing.
21887 @cvar EXPR_ERROR_STRAY_COMMA: A comma at the start or end of list.
21888 @cvar EXPR_ERROR_UNRESOLVED_IDENTIFIERS: Expression contains unresolved
21889 identifiers.
21890 @cvar EXPR_ERROR_CONSTANT_NAME: Constant name is invalid.
21891 """
21892 pass
21893
21895 """
21896 Types of raw data.
21897
21898 Multibyte types usually need to be complemented with B{C{ByteOrder}} to get a full type specification.
21899
21900 @since: 2.25
21901
21902 @note: All the enumerated values are defined at the module level, I{not} the
21903 class level. The are just groupped by class here for easier orientation.
21904
21905 @cvar RAW_DATA_SINT8: Signed 8bit integer (one byte).
21906 @cvar RAW_DATA_UINT8: Unsigned 8bit integer (one byte).
21907 @cvar RAW_DATA_SINT16: Signed 16bit integer (two bytes).
21908 @cvar RAW_DATA_UINT16: Unsigned 16bit integer (two bytes).
21909 @cvar RAW_DATA_SINT32: Signed 32bit integer (four bytes).
21910 @cvar RAW_DATA_UINT32: Unsigned 32bit integer (four bytes).
21911 @cvar RAW_DATA_SINT64: Signed 64bit integer (eight bytes).
21912 @cvar RAW_DATA_UINT64: Unsigned 64bit integer (eight bytes).
21913 @cvar RAW_DATA_HALF: Half-precision floating point number (two bytes).
21914 @cvar RAW_DATA_FLOAT: Single-precision floating point number (four bytes).
21915 @cvar RAW_DATA_REAL: Pascal ‘real’ floating point number (six bytes).
21916 @cvar RAW_DATA_DOUBLE: Double-precision floating point number (eight bytes).
21917 """
21918 pass
21919
21921 """
21922 Type of byte order.
21923
21924 Note all types are valid for all functions.
21925
21926 @since: 2.25
21927
21928 @note: All the enumerated values are defined at the module level, I{not} the
21929 class level. The are just groupped by class here for easier orientation.
21930
21931 @cvar BYTE_ORDER_NATIVE: Native byte order for the system the code is running on.
21932 @cvar BYTE_ORDER_LITTLE_ENDIAN: Little endian byte order (the same as B{C{glib.LITTLE_ENDIAN}}).
21933 @cvar BYTE_ORDER_BIG_ENDIAN: Big endian byte order (the same as B{C{glib.BIG_ENDIAN}}).
21934 @cvar BYTE_ORDER_IMPLICIT: Byte order implied by data, for instance a byte-order-mark (Since 2.60).
21935 """
21936 pass
21937
21939 """
21940 Mask merge type (namely used in grain processing).
21941
21942 @note: All the enumerated values are defined at the module level, I{not} the
21943 class level. The are just groupped by class here for easier orientation.
21944
21945 @cvar MERGE_UNION: Union (logical or) merging.
21946 @cvar MERGE_INTERSECTION: Intersection (logical and) merging.
21947 """
21948 pass
21949
21951 """
21952 Mask handling in procedures that can apply masking.
21953
21954 Note at present many procedures do not have a masking argument and hence cannot apply masks in exclude mode.
21955
21956 @since: 2.12
21957
21958 @note: All the enumerated values are defined at the module level, I{not} the
21959 class level. The are just groupped by class here for easier orientation.
21960
21961 @cvar MASK_EXCLUDE: Exclude data under mask, i.e. take into account only
21962 data not covered by the mask.
21963 @cvar MASK_INCLUDE: Take into account only data under the mask.
21964 @cvar MASK_IGNORE: Ignore mask, if present, and use all data.
21965 """
21966 pass
21967
21969 """
21970 @note: All the enumerated values are defined at the module level, I{not} the
21971 class level. The are just groupped by class here for easier orientation.
21972
21973 @cvar WATERSHED_STATE_INIT:
21974 @cvar WATERSHED_STATE_LOCATE:
21975 @cvar WATERSHED_STATE_MIN:
21976 @cvar WATERSHED_STATE_WATERSHED:
21977 @cvar WATERSHED_STATE_MARK:
21978 @cvar WATERSHED_STATE_FINISHED:
21979 """
21980 pass
21981
21983 """
21984 Plane symmetry types for rotation correction.
21985
21986 @note: All the enumerated values are defined at the module level, I{not} the
21987 class level. The are just groupped by class here for easier orientation.
21988
21989 @cvar SYMMETRY_AUTO: Automatic symmetry selection.
21990 @cvar SYMMETRY_PARALLEL: Parallel symmetry, there is one prevalent direction (bilateral).
21991 @cvar SYMMETRY_TRIANGULAR: Triangular symmetry, there are three prevalent directions (unilateral) by 120 degrees.
21992 @cvar SYMMETRY_SQUARE: Square symmetry, two prevalent directions (bilateral) oriented approximately along image
21993 sides.
21994 @cvar SYMMETRY_RHOMBIC: Rhombic symmetry, two prevalent directions (bilateral) oriented approximately along
21995 diagonals.
21996 @cvar SYMMETRY_HEXAGONAL: Hexagonal symmetry, three prevalent directions (bilateral) by 120 degrees.
21997 @cvar SYMMETRY_LAST: The number of symmetries.
21998 """
21999 pass
22000
22002 """
22003 Orientation type.
22004
22005 @note: All the enumerated values are defined at the module level, I{not} the
22006 class level. The are just groupped by class here for easier orientation.
22007
22008 @cvar ORIENTATION_HORIZONTAL: Horizontal orientation.
22009 @cvar ORIENTATION_VERTICAL: Vertical orientation.
22010 """
22011 pass
22012
22027
22029 """
22030 Cached data field quantity type.
22031
22032 There should be little need to this enum directly except in libgwyprocess
22033 methods.
22034
22035 @note: All the enumerated values are defined at the module level, I{not} the
22036 class level. The are just groupped by class here for easier orientation.
22037
22038 @cvar DATA_FIELD_CACHE_MIN: Overall minimum.
22039 @cvar DATA_FIELD_CACHE_MAX: Overall maximum.
22040 @cvar DATA_FIELD_CACHE_SUM: Sum of all values.
22041 @cvar DATA_FIELD_CACHE_RMS: Root mean square.
22042 @cvar DATA_FIELD_CACHE_MED: Median.
22043 @cvar DATA_FIELD_CACHE_ARF: Auto-range from.
22044 @cvar DATA_FIELD_CACHE_ART: Auto-range to.
22045 @cvar DATA_FIELD_CACHE_ARE: Surface area.
22046 @cvar DATA_FIELD_CACHE_VAR: Variation.
22047 @cvar DATA_FIELD_CACHE_ENT: Entropy.
22048 @cvar DATA_FIELD_CACHE_MSQ: Mean square.
22049 @cvar DATA_FIELD_CACHE_SIZE: The size of statistics cache.
22050 """
22051 pass
22052
22054 """
22055 Common iterative computation iterator state type.
22056
22057 @note: All the enumerated values are defined at the module level, I{not} the
22058 class level. The are just groupped by class here for easier orientation.
22059
22060 @cvar COMPUTATION_STATE_INIT: Iterator was set up, the next step will actually create temporary data structures and
22061 precalculate values.
22062 @cvar COMPUTATION_STATE_ITERATE: Iteration is in progress, the B{C{fraction}} field of state struct holds the fraction
22063 completed.
22064 @cvar COMPUTATION_STATE_FINISHED: Calculation has been finished, further calls to the iterator will be no-op.
22065 """
22066 pass
22067
22069 """
22070 @note: All the enumerated values are defined at the module level, I{not} the
22071 class level. The are just groupped by class here for easier orientation.
22072
22073 @cvar DWT_HAAR:
22074 @cvar DWT_DAUB4:
22075 @cvar DWT_DAUB6:
22076 @cvar DWT_DAUB8:
22077 @cvar DWT_DAUB12:
22078 @cvar DWT_DAUB20:
22079 """
22080 pass
22081
22083 """
22084 @note: All the enumerated values are defined at the module level, I{not} the
22085 class level. The are just groupped by class here for easier orientation.
22086
22087 @cvar DWT_DENOISE_UNIVERSAL:
22088 @cvar DWT_DENOISE_SCALE_ADAPTIVE:
22089 @cvar DWT_DENOISE_SPACE_ADAPTIVE:
22090 """
22091 pass
22092
22094 """
22095 Interpolation types.
22096
22097 @note: All the enumerated values are defined at the module level, I{not} the
22098 class level. The are just groupped by class here for easier orientation.
22099
22100 @cvar INTERPOLATION_NONE: No interpolation at all, resulting values are not
22101 defined, it must not be used for interpolation.
22102 It can be used in resize operations discarding
22103 original data.
22104 @cvar INTERPOLATION_ROUND: Round interpolation (more precisely symmetric
22105 nearest neighbour interpolation).
22106 @cvar INTERPOLATION_LINEAR: Linear interpolation.
22107 @cvar INTERPOLATION_BILINEAR: Old name for B{C{INTERPOLATION_LINEAR}}. This
22108 is a misnomer because it in fact denotes linear
22109 interpolation of arbitrary dimension. Use
22110 B{C{INTERPOLATION_LINEAR}} instead.
22111 @cvar INTERPOLATION_KEY: Cubic Key's interpolation (with a=-1/2).
22112 @cvar INTERPOLATION_BSPLINE: B-spline interpolation.
22113 @cvar INTERPOLATION_OMOMS: Omoms interpolation.
22114 @cvar INTERPOLATION_NNA: Nearest neighbour approximation.
22115 @cvar INTERPOLATION_SCHAUM: Cubic Schaum interpolation.
22116 """
22117 pass
22118
22120 """
22121 Local plane fitting quantity to request from L{DataField.area_fit_local_planes}() and similar functions.
22122
22123 @note: All the enumerated values are defined at the module level, I{not} the
22124 class level. The are just groupped by class here for easier orientation.
22125
22126 @cvar PLANE_FIT_A: Constant coefficient (mean value).
22127 @cvar PLANE_FIT_BX: Linear coefficient in B{C{x}}, where B{C{x}} is in pixel coordinates.
22128 @cvar PLANE_FIT_BY: Linear coefficient in B{C{y}}, where B{C{y}} is in pixel coordinates.
22129 @cvar PLANE_FIT_ANGLE: Slope orientation in (x,y) plane (in radians).
22130 @cvar PLANE_FIT_SLOPE: Absolute slope value (that is sqrt(bx*bx + by*by)).
22131 @cvar PLANE_FIT_S0: Residual sum of squares.
22132 @cvar PLANE_FIT_S0_REDUCED: Slope-reduced residual sum of squares.
22133 """
22134 pass
22135
22137 """
22138 Frequency windowing type.
22139
22140 @note: All the enumerated values are defined at the module level, I{not} the
22141 class level. The are just groupped by class here for easier orientation.
22142
22143 @cvar WINDOWING_NONE: No windowing is applied.
22144 @cvar WINDOWING_HANN: Hann window.
22145 @cvar WINDOWING_HAMMING: Hamming window.
22146 @cvar WINDOWING_BLACKMANN: Blackmann window.
22147 @cvar WINDOWING_LANCZOS: Lanczos window.
22148 @cvar WINDOWING_WELCH: Welch window.
22149 @cvar WINDOWING_RECT: Rectangular window.
22150 @cvar WINDOWING_NUTTALL: Nuttall window (Since 2.7).
22151 @cvar WINDOWING_FLAT_TOP: Flat-top window (Since 2.7).
22152 @cvar WINDOWING_KAISER25: Kaiser window with β=2.5 (Since 2.7).
22153 """
22154 pass
22155
22157 """
22158 Type of tip shape presets.
22159
22160 @note: All the enumerated values are defined at the module level, I{not} the
22161 class level. The are just groupped by class here for easier orientation.
22162
22163 @cvar TIP_PYRAMID: N-sided pyramidal tip.
22164 @cvar TIP_PYRAMIDE: Legacy name for B{C{TIP_PYRAMID}}.
22165 @cvar TIP_CONTACT: Four-sided pyramidal tip.
22166 @cvar TIP_NONCONTACT: Three-sided pyramidal tip.
22167 @cvar TIP_DELTA: Delta function (single-pixel tip).
22168 @cvar TIP_PARABOLA: Parabolic tip. (Since 2.45)
22169 @cvar TIP_CONE: Conical tip. (Since 2.45)
22170 @cvar TIP_ELLPARABOLA: Elliptical parabola tip. (Since 2.47)
22171 @cvar TIP_BALL_ON_STICK: Spherical tip at the end of almost-cyliner. (Since 2.50)
22172 """
22173 pass
22174
22176 """
22177 Type of tip model preset parameter.
22178
22179 This enum is used with the new tip preset functions L{gwy_tip_model_get_preset_params}(),
22180 L{gwy_tip_model_preset_create}(), L{gwy_tip_model_preset_create_for_zrange}().
22181
22182 @since: 2.47
22183
22184 @note: All the enumerated values are defined at the module level, I{not} the
22185 class level. The are just groupped by class here for easier orientation.
22186
22187 @cvar TIP_PARAM_HEIGHT: Total tip height. This is used only in the delta function tip; for all others it is
22188 implied.
22189 @cvar TIP_PARAM_RADIUS: Radius of curvature of the tip apex.
22190 @cvar TIP_PARAM_ROTATION: Rotation angle.
22191 @cvar TIP_PARAM_NSIDES: Number of sides for pyramidal tips.
22192 @cvar TIP_PARAM_SLOPE: Half-angle of the apex (complement of the side slope for straight sides).
22193 @cvar TIP_PARAM_ANISOTROPY: Ratio between larger and smaller tip width in two orthotonal directions.
22194 """
22195 pass
22196
22198 """
22199 @note: All the enumerated values are defined at the module level, I{not} the
22200 class level. The are just groupped by class here for easier orientation.
22201
22202 @cvar CORRELATION_NORMAL:
22203 @cvar CORRELATION_FFT:
22204 @cvar CORRELATION_POC:
22205 """
22206 pass
22207
22209 """
22210 Type of correlation search output.
22211
22212 @since: 2.50
22213
22214 @note: All the enumerated values are defined at the module level, I{not} the
22215 class level. The are just groupped by class here for easier orientation.
22216
22217 @cvar CORR_SEARCH_COVARIANCE_RAW: Raw average of data values multiplied by kernel values.
22218 @cvar CORR_SEARCH_COVARIANCE: Local mean value is subtracted from data before kernel multiplication.
22219 @cvar CORR_SEARCH_COVARIANCE_SCORE: In addition, result is normalised by dividing by the local variance.
22220 @cvar CORR_SEARCH_HEIGHT_DIFF_RAW: Raw mean square difference between data and kernel values.
22221 @cvar CORR_SEARCH_HEIGHT_DIFF: Mean values of data and kernel are adjusted before summing the squared differences.
22222 @cvar CORR_SEARCH_HEIGHT_DIFF_SCORE: In addition, result is normalised by dividing by the local variance.
22223 """
22224 pass
22225
22227 """
22228 Grain quantity to request from L{DataField.grains_get_distribution}() and similar functions.
22229
22230 @note: All the enumerated values are defined at the module level, I{not} the
22231 class level. The are just groupped by class here for easier orientation.
22232
22233 @cvar GRAIN_VALUE_PROJECTED_AREA: Projected (flat) grain area.
22234 @cvar GRAIN_VALUE_EQUIV_SQUARE_SIDE: Side of a square with the same area as the grain.
22235 @cvar GRAIN_VALUE_EQUIV_DISC_RADIUS: Radius of a disc with the same area as the grain.
22236 @cvar GRAIN_VALUE_SURFACE_AREA: Surface area.
22237 @cvar GRAIN_VALUE_MAXIMUM: Minimum value.
22238 @cvar GRAIN_VALUE_MINIMUM: Maximum value.
22239 @cvar GRAIN_VALUE_MEAN: Mean value.
22240 @cvar GRAIN_VALUE_MEDIAN: Median value.
22241 @cvar GRAIN_VALUE_PIXEL_AREA: Flat grain area measured in pixels. This value is redundant but it is useful for
22242 filtering (Since 2.37).
22243 @cvar GRAIN_VALUE_HALF_HEIGHT_AREA: Projected area of the part of grain that is above the half-height, i.e. the
22244 height between the minimum and maximum (Since 2.8).
22245 @cvar GRAIN_VALUE_FLAT_BOUNDARY_LENGTH: Length of projected grain boundary. Note for grains not topologically
22246 equivalent to disc, only the length of the outer boundary is calculated.
22247 @cvar GRAIN_VALUE_RMS: Standard deviation of grain values. (Since 2.51)
22248 @cvar GRAIN_VALUE_MINIMUM_BOUND_SIZE: Minimum lateral bounding size, in other words the minimum length of grain
22249 projection to any line in the horizontal plane.
22250 @cvar GRAIN_VALUE_MINIMUM_BOUND_ANGLE: Direction of the minimum lateral bounding size (arbitrary one if the minimum
22251 is not unique).
22252 @cvar GRAIN_VALUE_MAXIMUM_BOUND_SIZE: Maximum lateral bounding size, in other words the maximum length of grain
22253 projection to any line in the horizontal plane.
22254 @cvar GRAIN_VALUE_MAXIMUM_BOUND_ANGLE: Direction of the maximum lateral bounding size (arbitrary one if the maximum
22255 is not unique).
22256 @cvar GRAIN_VALUE_CENTER_X: Grain centre horizontal position, i.e. the mean value of its physical x-coordinates.
22257 (Since 2.7)
22258 @cvar GRAIN_VALUE_CENTER_Y: Grain centre vertical position, i.e. the mean value of its physical y-coordinates.
22259 (Since 2.7)
22260 @cvar GRAIN_VALUE_VOLUME_0: Grain volume calculated with grain basis at B{C{z}}=0 (therefore it is just an integral it can
22261 be negative). (Since 2.3)
22262 @cvar GRAIN_VALUE_VOLUME_MIN: Grain volume calculated with grain basis at grain minimum value. This value is
22263 a lower bound. (Since 2.3)
22264 @cvar GRAIN_VALUE_VOLUME_LAPLACE: Grain volume calculated with grain basis calculated by laplacian interpolation of
22265 surrounding values. (Since 2.3)
22266 @cvar GRAIN_VALUE_SLOPE_THETA: Spherical angle theta of grain normal (0 is upwards). (Since 2.7)
22267 @cvar GRAIN_VALUE_SLOPE_PHI: Spherical angle phi of grain normal (0 is in positive x direction). (Since 2.7)
22268 @cvar GRAIN_VALUE_BOUNDARY_MAXIMUM: Maximum value in the grain inner boundary. (Since 2.12)
22269 @cvar GRAIN_VALUE_BOUNDARY_MINIMUM: Minimum value on the grain inner boundary. (Since 2.12)
22270 @cvar GRAIN_VALUE_CURVATURE_CENTER_X: Grain curvature centre horizontal position. For too small or flat grains it
22271 reduces to the horizontal position of geometrical centre. (Since 2.22)
22272 @cvar GRAIN_VALUE_CURVATURE_CENTER_Y: Grain curvature centre vertical position. For too small or flat grains it
22273 reduces to the vertical position of geometrical centre. (Since 2.22)
22274 @cvar GRAIN_VALUE_CURVATURE_CENTER_Z: The value at curvature centre. Note this is the value in the origin of the
22275 fitted quadratic surface, not at the real surface. (Since 2.22)
22276 @cvar GRAIN_VALUE_CURVATURE1: Smaller grain curvature. (Since 2.22)
22277 @cvar GRAIN_VALUE_CURVATURE2: Larger grain curvature. (Since 2.22)
22278 @cvar GRAIN_VALUE_CURVATURE_ANGLE1: Direction of the smaller grain curvature radius. If the grain is flat or too
22279 small the angle is reported as 0. (Since 2.22)
22280 @cvar GRAIN_VALUE_CURVATURE_ANGLE2: Direction of the larger grain curvature radius. If the grain is flat or too
22281 small the angle is reported as π/2. (Since 2.22)
22282 @cvar GRAIN_VALUE_INSCRIBED_DISC_R: Radius of maximum disc that fits inside the grain (Since 2.30)
22283 @cvar GRAIN_VALUE_INSCRIBED_DISC_X: Real X-coordinate of the centre of the maximum inscribed disc. (Since 2.30)
22284 @cvar GRAIN_VALUE_INSCRIBED_DISC_Y: Real Y-coordinate of the centre of the maximum inscribed disc. (Since 2.30)
22285 @cvar GRAIN_VALUE_CONVEX_HULL_AREA: Projected (flat) area of grain convex hull. (Since 2.30)
22286 @cvar GRAIN_VALUE_CIRCUMCIRCLE_R: Radius of minimum circle containing the grain. (Since 2.30)
22287 @cvar GRAIN_VALUE_CIRCUMCIRCLE_X: Real X-coordinate of the centre of the minimum circumcircle. (Since 2.30)
22288 @cvar GRAIN_VALUE_CIRCUMCIRCLE_Y: Real Y-coordinate of the centre of the minimum circumcircle. (Since 2.30)
22289 @cvar GRAIN_VALUE_MEAN_RADIUS: Mean distance from boundary to the grain centre as defined by
22290 B{C{GRAIN_VALUE_CENTER_X}} and B{C{GRAIN_VALUE_CENTER_Y}}. (Since 2.30)
22291 @cvar GRAIN_VALUE_EQUIV_ELLIPSE_MAJOR: Length of major semiaxis of equivalent ellipse. (Since 2.36)
22292 @cvar GRAIN_VALUE_EQUIV_ELLIPSE_MINOR: Length of minor semiaxis of equivalent ellipse. (Since 2.36)
22293 @cvar GRAIN_VALUE_EQUIV_ELLIPSE_ANGLE: Orientation of the major axis of equivalent ellipse. (Since 2.36)
22294 @cvar GRAIN_VALUE_MINIMUM_MARTIN_DIAMETER: Minimum value of Martin diameter. (Since 2.50)
22295 @cvar GRAIN_VALUE_MINIMUM_MARTIN_ANGLE: Direction corresponding to minimum Martin diameter. (Since 2.50)
22296 @cvar GRAIN_VALUE_MAXIMUM_MARTIN_DIAMETER: Maximum value of Martin diameter. (Since 2.50)
22297 @cvar GRAIN_VALUE_MAXIMUM_MARTIN_ANGLE: Direction corresponding to maximum Martin diameter. (Since 2.50)
22298 """
22299 pass
22300
22302 """
22303 Data line, field, brick and lawn compatibility flags.
22304
22305 It is not recommended to pass B{C{DATA_COMPATIBILITY_ALL}} to checking functions since not all flags are meaningful
22306 for all data objects (even though meaningless flags are generally silently ignored).
22307
22308 @note: All the enumerated values are defined at the module level, I{not} the
22309 class level. The are just groupped by class here for easier orientation.
22310
22311 @cvar DATA_COMPATIBILITY_RES: Pixel sizes.
22312 @cvar DATA_COMPATIBILITY_REAL: Real (physical) dimensions.
22313 @cvar DATA_COMPATIBILITY_MEASURE: Real to pixel ratios.
22314 @cvar DATA_COMPATIBILITY_LATERAL: Units of lateral dimensions.
22315 @cvar DATA_COMPATIBILITY_VALUE: Units of values (for all curves in the case of lawns).
22316 @cvar DATA_COMPATIBILITY_AXISCAL: Axis calibrations. At present it only makes sense for B{C{Brick}} which can have
22317 Z-calibrations. (Since 2.51)
22318 @cvar DATA_COMPATIBILITY_NCURVES: Number of lawn curves. (Since 2.60)
22319 @cvar DATA_COMPATIBILITY_CURVELEN: Lengths of curves in all lawn pixels. (Since 2.60)
22320 @cvar DATA_COMPATIBILITY_ALL: Mask of all defined flags.
22321 """
22322 pass
22323
22325 """
22326 Line statistical quantities to be requested with L{DataField.area_get_line_stats}().
22327
22328 @since: 2.2
22329
22330 @note: All the enumerated values are defined at the module level, I{not} the
22331 class level. The are just groupped by class here for easier orientation.
22332
22333 @cvar LINE_STAT_MEAN: Mean value.
22334 @cvar LINE_STAT_MEDIAN: Median.
22335 @cvar LINE_STAT_MINIMUM: Minimum value.
22336 @cvar LINE_STAT_MAXIMUM: Maximum value.
22337 @cvar LINE_STAT_RMS: Root mean square of deviations from the mean value.
22338 @cvar LINE_STAT_LENGTH: Line length.
22339 @cvar LINE_STAT_SLOPE: Overall line slope.
22340 @cvar LINE_STAT_TAN_BETA0: Root mean square slope.
22341 @cvar LINE_STAT_RA: Arithmetic mean surface roughness.
22342 @cvar LINE_STAT_RZ: Maximum height of the roughness profile.
22343 @cvar LINE_STAT_RT: Total height of the roughness profile.
22344 @cvar LINE_STAT_SKEW: Line skew.
22345 @cvar LINE_STAT_KURTOSIS: Line excess kurtosis (which is 0 for a Gaussaian distrubution, not 3).
22346 @cvar LINE_STAT_RANGE: Difference between maximum and minimum value (Since 2.42).
22347 @cvar LINE_STAT_VARIATION: Variation (integral of absolute value) (Since 2.42).
22348 @cvar LINE_STAT_MINPOS: Minimum position along the line (Since 2.48).
22349 @cvar LINE_STAT_MAXPOS: Maximum position along the line (Since 2.48).
22350 """
22351 pass
22352
22354 """
22355 Methods to handle pixels outside data.
22356
22357 Many methods currently use a fixed metod of handling of exterior pixels, for example area calculation uses
22358 extension (border and mirror coincide), convolution uses mirror extension, rotation fills exterior with a fixed
22359 value.
22360
22361 @since: 2.2
22362
22363 @note: All the enumerated values are defined at the module level, I{not} the
22364 class level. The are just groupped by class here for easier orientation.
22365
22366 @cvar EXTERIOR_UNDEFINED: The values corresponding to or calculated from exterior data values are undefined, they
22367 may be left unset or set to bogus values. The caller must handle them itself afterwards,
22368 for instance by resizing the result to consist of valid data only.
22369 @cvar EXTERIOR_BORDER_EXTEND: Values of exterior pixels are considered to be equal to the values of the nearest
22370 interior pixels.
22371 @cvar EXTERIOR_MIRROR_EXTEND: The data is considered to be periodically repeated, with odd instances reflected (the
22372 total period is thus twice the size of the data).
22373 @cvar EXTERIOR_PERIODIC: The data is considered to be periodically repeated.
22374 @cvar EXTERIOR_FIXED_VALUE: Values of exterior pixels are considered to be all equal to a user-specified value.
22375 @cvar EXTERIOR_LAPLACE: Values of exterior pixels are extended using Laplace interpolation (actually extrapolation)
22376 like L{DataField.laplace_solve}(). Only some functions implement this method. (Since
22377 2.50)
22378 """
22379 pass
22380
22401
22403 """
22404 Type of operation based on morphological filters with flat structuring
22405 elements.
22406
22407 @since: 2.43
22408
22409 @note: All the enumerated values are defined at the module level, I{not} the
22410 class level. The are just groupped by class here for easier orientation.
22411
22412 @cvar MIN_MAX_FILTER_MINIMUM: Minimum filter, i.e. minimum of the surrounding values.
22413 @cvar MIN_MAX_FILTER_EROSION: Another name for the minimum filter.
22414 @cvar MIN_MAX_FILTER_MAXIMUM: Maximum filter, i.e. maximum of the surrounding values.
22415 @cvar MIN_MAX_FILTER_DILATION: Another name for the maximum filter.
22416 @cvar MIN_MAX_FILTER_OPENING: Morphological opening filter.
22417 @cvar MIN_MAX_FILTER_CLOSING: Morphological closing filter.
22418 @cvar MIN_MAX_FILTER_RANGE: Difference between maximum and minimum.
22419 @cvar MIN_MAX_FILTER_NORMALIZATION: Data value rescaled to the range between minimum and maximum.
22420 """
22421 pass
22422
22424 """
22425 Type of rotated data field size determination method.
22426
22427 @since: 2.46
22428
22429 @note: All the enumerated values are defined at the module level, I{not} the
22430 class level. The are just groupped by class here for easier orientation.
22431
22432 @cvar ROTATE_RESIZE_SAME_SIZE: The result has the same area as the original.
22433 @cvar ROTATE_RESIZE_EXPAND: The result is sufficiently large so that all original data are present (usually meaning
22434 that there will be also lot of exterior).
22435 @cvar ROTATE_RESIZE_CUT: The result is optimally cut to interior data only.
22436 """
22437 pass
22438
22440 """
22441 Type of lattice vector scaling in affine transform preparation.
22442
22443 @since: 2.49
22444
22445 @note: All the enumerated values are defined at the module level, I{not} the
22446 class level. The are just groupped by class here for easier orientation.
22447
22448 @cvar AFFINE_SCALING_AS_GIVEN: Correct lattice vectors lengths are taken as given.
22449 @cvar AFFINE_SCALING_PRESERVE_AREA: Correct lattice vectors are scaled to make the transformation area-preserving.
22450 @cvar AFFINE_SCALING_PRESERVE_X: Correct lattice vectors are scaled to preserve the scale along B{C{x}}-axis.
22451 """
22452 pass
22453
22455 """
22456 Type of volume data transposition.
22457
22458 The enum values names spell which old axis becomes which new axes.
22459
22460 @since: 2.51
22461
22462 @note: All the enumerated values are defined at the module level, I{not} the
22463 class level. The are just groupped by class here for easier orientation.
22464
22465 @cvar BRICK_TRANSPOSE_XYZ: No change (useful with axis flipping).
22466 @cvar BRICK_TRANSPOSE_XZY: Axes Z and Y are swapped.
22467 @cvar BRICK_TRANSPOSE_YXZ: Axes Y and Z are swapped.
22468 @cvar BRICK_TRANSPOSE_YZX: Axis X becomes Y, Y becomes Z and Z becomes X.
22469 @cvar BRICK_TRANSPOSE_ZXY: Axes X and Z are swapped.
22470 @cvar BRICK_TRANSPOSE_ZYX: Axis X becomes Z, Y becomes X and Z becomes Y.
22471 """
22472 pass
22473
22475 """
22476 Type of probe for calculation of force in magnetic field microscopy.
22477
22478 @since: 2.51
22479
22480 @note: All the enumerated values are defined at the module level, I{not} the
22481 class level. The are just groupped by class here for easier orientation.
22482
22483 @cvar MFM_PROBE_CHARGE: Magnetic point charge probe.
22484 @cvar MFM_PROBE_BAR: Finite rectangular bar.
22485 """
22486 pass
22487
22489 """
22490 Type of field component calculated in magnetic field microscopy.
22491
22492 @since: 2.51
22493
22494 @note: All the enumerated values are defined at the module level, I{not} the
22495 class level. The are just groupped by class here for easier orientation.
22496
22497 @cvar MFM_COMPONENT_HX: X-component of magnetic field H.
22498 @cvar MFM_COMPONENT_HY: Y-component of magnetic field H.
22499 @cvar MFM_COMPONENT_HZ: Z-component of magnetic field H.
22500 @cvar MFM_COMPONENT_DHZ_DZ: Z-derivative of Z-component of magnetic field H.
22501 @cvar MFM_COMPONENT_D2HZ_DZ2: Second Z-derivative of Z-component of magnetic
22502 field H.
22503 """
22504 pass
22505
22507 """
22508 @note: All the enumerated values are defined at the module level, I{not} the
22509 class level. The are just groupped by class here for easier orientation.
22510
22511 @cvar MFM_GRADIENT_FORCE:
22512 @cvar MFM_GRADIENT_MFM:
22513 @cvar MFM_GRADIENT_MFM_AREA:
22514 """
22515 pass
22516
22518 """
22519 Type of background available in graph peak analysers.
22520
22521 @since: 2.46
22522
22523 @note: All the enumerated values are defined at the module level, I{not} the
22524 class level. The are just groupped by class here for easier orientation.
22525
22526 @cvar PEAK_BACKGROUND_ZERO: The background is fixed at zero value.
22527 @cvar PEAK_BACKGROUND_MMSTEP: The background is a step function connecting the nearest minima on the left and right
22528 side.
22529 """
22530 pass
22531
22533 """
22534 Type of peak ordering by in the graph peak analyser results.
22535
22536 @since: 2.46
22537
22538 @note: All the enumerated values are defined at the module level, I{not} the
22539 class level. The are just groupped by class here for easier orientation.
22540
22541 @cvar PEAK_ORDER_ABSCISSA: Peaks are ordered by abscissa values, from left to right.
22542 @cvar PEAK_ORDER_PROMINENCE: Peaks are ordered by prominence, from most to least prominent.
22543 """
22544 pass
22545
22547 """
22548 Type of characteristics graph peak analysers can provide.
22549
22550 @since: 2.46
22551
22552 @note: All the enumerated values are defined at the module level, I{not} the
22553 class level. The are just groupped by class here for easier orientation.
22554
22555 @cvar PEAK_PROMINENCE: Compound quantity characteristing the overall peak prominence (taking into account height,
22556 area, distance from other peaks, ...).
22557 @cvar PEAK_ABSCISSA: Position of peak maximum.
22558 @cvar PEAK_HEIGHT: Peak height (with respect to the chosen background function).
22559 @cvar PEAK_AREA: Peak area (with respect to the chosen background function).
22560 @cvar PEAK_WIDTH: Peak width, more or less corresponding to standard deviation.
22561 """
22562 pass
22563
22565 """
22566 Type of target where selections can be rendered.
22567
22568 The pixmap image target is rarely used now.
22569
22570 @note: All the enumerated values are defined at the module level, I{not} the
22571 class level. The are just groupped by class here for easier orientation.
22572
22573 @cvar RENDERING_TARGET_SCREEN: Selection is being rendered to screen
22574 @cvar RENDERING_TARGET_PIXMAP_IMAGE: Selection is geing rendered to
22575 a pixbuf.
22576 """
22577 pass
22578
22591
22593 """
22594 Units placement on a B{C{Ruler}}.
22595
22596 @note: All the enumerated values are defined at the module level, I{not} the
22597 class level. The are just groupped by class here for easier orientation.
22598
22599 @cvar UNITS_PLACEMENT_NONE: Units are omitted.
22600 @cvar UNITS_PLACEMENT_AT_ZERO: Units are placed to major tick at zero, or
22601 to the leftmost position of zero is not
22602 present.
22603 """
22604 pass
22605
22607 """
22608 Options controlling L{gwy_table_attach_adjbar}() and L{gwy_table_attach_hscale}()
22609 behaviour.
22610
22611 @note: All the enumerated values are defined at the module level, I{not} the
22612 class level. The are just groupped by class here for easier orientation.
22613
22614 @cvar HSCALE_DEFAULT: Default label, hscale, spinbutton, and units widget
22615 row. Note that the default mapping is linear for
22616 hscales but signed square root for adjust bars.
22617 @cvar HSCALE_LOG: The scale mapping is logarithmic.
22618 @cvar HSCALE_SQRT: The scale mapping is signed square root.
22619 @cvar HSCALE_LINEAR: The scale mapping is linear. (Since 2.49)
22620 @cvar HSCALE_NO_SCALE: There is no hscale/adjust bar.
22621 @cvar HSCALE_WIDGET: An user-specified widget is used in place of the
22622 adjustment control(s).
22623 @cvar HSCALE_WIDGET_NO_EXPAND: An user-specified widget is used in place of
22624 hscale and spinbutton, and it is left-aligned
22625 instead of taking all the alloted space.
22626 @cvar HSCALE_CHECK: The label is actually a check button that controls
22627 sensitivity of the row. This is a flag, to be bitwise
22628 or-ed with other values.
22629 @cvar HSCALE_SNAP: The adjust bar snaps to ticks (hscales cannot snap).
22630 This is a flag, to be bitwise or-ed with other values.
22631 (Since 2.49)
22632 """
22633 pass
22634
22636 """
22637 @note: All the enumerated values are defined at the module level, I{not} the
22638 class level. The are just groupped by class here for easier orientation.
22639
22640 @cvar GRAPH_STATUS_PLAIN:
22641 @cvar GRAPH_STATUS_XSEL:
22642 @cvar GRAPH_STATUS_YSEL:
22643 @cvar GRAPH_STATUS_POINTS:
22644 @cvar GRAPH_STATUS_ZOOM:
22645 @cvar GRAPH_STATUS_XLINES:
22646 @cvar GRAPH_STATUS_YLINES:
22647 """
22648 pass
22649
22651 """
22652 @note: All the enumerated values are defined at the module level, I{not} the
22653 class level. The are just groupped by class here for easier orientation.
22654
22655 @cvar GRAPH_GRID_NONE:
22656 @cvar GRAPH_GRID_AUTO:
22657 @cvar GRAPH_GRID_USER:
22658 """
22659 pass
22660
22662 """
22663 @note: All the enumerated values are defined at the module level, I{not} the
22664 class level. The are just groupped by class here for easier orientation.
22665
22666 @cvar GRAPH_POINT_SQUARE:
22667 @cvar GRAPH_POINT_CROSS:
22668 @cvar GRAPH_POINT_CIRCLE:
22669 @cvar GRAPH_POINT_STAR:
22670 @cvar GRAPH_POINT_TIMES:
22671 @cvar GRAPH_POINT_TRIANGLE_UP:
22672 @cvar GRAPH_POINT_TRIANGLE_DOWN:
22673 @cvar GRAPH_POINT_DIAMOND:
22674 @cvar GRAPH_POINT_FILLED_SQUARE:
22675 @cvar GRAPH_POINT_DISC:
22676 @cvar GRAPH_POINT_FILLED_CIRCLE:
22677 @cvar GRAPH_POINT_FILLED_TRIANGLE_UP:
22678 @cvar GRAPH_POINT_FILLED_TRIANGLE_DOWN:
22679 @cvar GRAPH_POINT_FILLED_DIAMOND:
22680 @cvar GRAPH_POINT_TRIANGLE_LEFT:
22681 @cvar GRAPH_POINT_FILLED_TRIANGLE_LEFT:
22682 @cvar GRAPH_POINT_TRIANGLE_RIGHT:
22683 @cvar GRAPH_POINT_FILLED_TRIANGLE_RIGHT:
22684 @cvar GRAPH_POINT_ASTERISK:
22685 """
22686 pass
22687
22689 """
22690 Graph curve plotting type.
22691
22692 @note: All the enumerated values are defined at the module level, I{not} the
22693 class level. The are just groupped by class here for easier orientation.
22694
22695 @cvar GRAPH_CURVE_HIDDEN: Curve is invisible.
22696 @cvar GRAPH_CURVE_POINTS: Curve data is plotted with symbols.
22697 @cvar GRAPH_CURVE_LINE: Curve data is plotted with a line.
22698 @cvar GRAPH_CURVE_LINE_POINTS: Curve data is plotted with symbols and a line.
22699 """
22700 pass
22701
22703 """
22704 @note: All the enumerated values are defined at the module level, I{not} the
22705 class level. The are just groupped by class here for easier orientation.
22706
22707 @cvar GRAPH_LABEL_NORTHEAST:
22708 @cvar GRAPH_LABEL_NORTHWEST:
22709 @cvar GRAPH_LABEL_SOUTHEAST:
22710 @cvar GRAPH_LABEL_SOUTHWEST:
22711 @cvar GRAPH_LABEL_USER:
22712 """
22713 pass
22714
22716 """
22717 Graph ASCII export style.
22718
22719 @note: All the enumerated values are defined at the module level, I{not} the
22720 class level. The are just groupped by class here for easier orientation.
22721
22722 @cvar GRAPH_MODEL_EXPORT_ASCII_PLAIN: White-space separated data values,
22723 plain description lines and column
22724 headers, missing data represented with
22725 dashes.
22726 @cvar GRAPH_MODEL_EXPORT_ASCII_GNUPLOT: White-space separated data values,
22727 curves serialised,
22728 description lines and column headers
22729 prefixed with C{#}.
22730 @cvar GRAPH_MODEL_EXPORT_ASCII_CSV: Semicolon separated data values and
22731 column headers, missing
22732 data represented as empty columns.
22733 @cvar GRAPH_MODEL_EXPORT_ASCII_ORIGIN: Presently, the same as the plain
22734 format.
22735 @cvar GRAPH_MODEL_EXPORT_ASCII_IGORPRO: Text wave format of Igor Pro (.itx).
22736 (Since 2.36)
22737 @cvar GRAPH_MODEL_EXPORT_ASCII_POSIX: Flag that can be combined with the
22738 other formats, meaning
22739 locale-independent C/POSIX format of
22740 floating point numbers. (Since 2.26)
22741 @cvar GRAPH_MODEL_EXPORT_ASCII_MERGED: Flag that can be combined with the
22742 other formats (except Igor Pro),
22743 requesting multi-column output with
22744 a single merged abscissa in the first
22745 column. (Since 2.46)
22746 """
22747 pass
22748
22750 """
22751 Types of color gradient mapping in B{C{LayerBasic}}.
22752
22753 @note: All the enumerated values are defined at the module level, I{not} the
22754 class level. The are just groupped by class here for easier orientation.
22755
22756 @cvar LAYER_BASIC_RANGE_FULL: Color gradient is uniformly mapped to range
22757 from data minimum to maximum.
22758 @cvar LAYER_BASIC_RANGE_FIXED: Color gradient is uniformly mapped to a fixed
22759 range, independent on data.
22760 @cvar LAYER_BASIC_RANGE_AUTO: Color gradient is uniformly mapped to a range
22761 inside which most of data points lie, that is
22762 height distribution tails are cut off.
22763 @cvar LAYER_BASIC_RANGE_ADAPT: Color range is mapped nonuniformly,
22764 see L{gwy_pixbuf_draw_data_field_adaptive}().
22765 """
22766 pass
22767
22769 """
22770 Curve drawing type in B{C{Curve}}.
22771
22772 @note: All the enumerated values are defined at the module level, I{not} the
22773 class level. The are just groupped by class here for easier orientation.
22774
22775 @cvar CURVE_TYPE_LINEAR: Linear interpolation.
22776 @cvar CURVE_TYPE_SPLINE: Spline interpolation.
22777 @cvar CURVE_TYPE_FREE: Free form curve.
22778 """
22779 pass
22780
22782 """
22783 @note: All the enumerated values are defined at the module level, I{not} the
22784 class level. The are just groupped by class here for easier orientation.
22785
22786 @cvar CURVE_CHANNEL_RED:
22787 @cvar CURVE_CHANNEL_GREEN:
22788 @cvar CURVE_CHANNEL_BLUE:
22789 """
22790 pass
22791
22793 """
22794 B{C{MarkerBox}} operation type (for validation).
22795
22796 @note: All the enumerated values are defined at the module level, I{not} the
22797 class level. The are just groupped by class here for easier orientation.
22798
22799 @cvar MARKER_OPERATION_MOVE: Marker is being moved.
22800 @cvar MARKER_OPERATION_ADD: Marker is being added.
22801 @cvar MARKER_OPERATION_REMOVE: Marker is being removed.
22802 """
22803 pass
22804
22806 """
22807 B{C{DataView}} layer identification.
22808
22809 @note: All the enumerated values are defined at the module level, I{not} the
22810 class level. The are just groupped by class here for easier orientation.
22811
22812 @cvar DATA_VIEW_LAYER_BASE: Base (bottom) layer.
22813 @cvar DATA_VIEW_LAYER_ALPHA: Alpha (mask) layer.
22814 @cvar DATA_VIEW_LAYER_TOP: Top (vector, interactive) layer.
22815 """
22816 pass
22817
22819 """
22820 Axis ticks style (used in B{C{ColorAxis}}).
22821
22822 @note: All the enumerated values are defined at the module level, I{not} the
22823 class level. The are just groupped by class here for easier orientation.
22824
22825 @cvar TICKS_STYLE_NONE: Ticks are not drawn.
22826 @cvar TICKS_STYLE_CENTER: One tick is drawn at center.
22827 @cvar TICKS_STYLE_AUTO: A number of automatically chosen ticks are drawn at
22828 `round' values.
22829 @cvar TICKS_STYLE_UNLABELED: Only edge ticks are labelled, interior ticks
22830 are drawn but not labelled. (Since 2.44)
22831 @cvar TICKS_STYLE_UNLABELLED: Alias for B{C{TICKS_STYLE_UNLABELED}}.
22832 (Since 2.39)
22833 """
22834 pass
22835
22837 """
22838 File type function file operations (capabilities).
22839
22840 The difference between save and export is that save is supposed to create
22841 a file containing fairly complete representation of the container, while
22842 export is the possibility to write some information to given file type.
22843 Generally only native file format module implements
22844 B{C{FILE_OPERATION_SAVE}}, all others implement B{C{FILE_OPERATION_EXPORT}}.
22845
22846 @note: All the enumerated values are defined at the module level, I{not} the
22847 class level. The are just groupped by class here for easier orientation.
22848
22849 @cvar FILE_OPERATION_DETECT: Posibility to detect files are of this file type,
22850 @cvar FILE_OPERATION_LOAD: Posibility to load files of this type.
22851 @cvar FILE_OPERATION_SAVE: Posibility to save files of this type.
22852 @cvar FILE_OPERATION_EXPORT: Posibility to export files of this type.
22853 @cvar FILE_OPERATION_MASK: The mask for all the flags.
22854 """
22855 pass
22856
22866
22868 """
22869 Module function run-modes.
22870
22871 Note B{C{RUN_NONINTERACTIVE}} is only possible for file functions, processing functions do not have a truly
22872 non-interactive interface yet and therefore they should not claim they support it. The closest match for process
22873 functions is B{C{RUN_IMMEDIATE}}.
22874
22875 @note: All the enumerated values are defined at the module level, I{not} the
22876 class level. The are just groupped by class here for easier orientation.
22877
22878 @cvar RUN_NONE: None.
22879 @cvar RUN_NONINTERACTIVE: The function is run non-interactively, it must not present any GUI and touch application
22880 state.
22881 @cvar RUN_INTERACTIVE: The function presents a modal user interfaces where parameters can be adjusted, it returns
22882 after finishing all operations.
22883 @cvar RUN_IMMEDIATE: Function is run immediately and uses parameter values stored in the settings to reproduce
22884 previous run. It can however present GUI error messages or display progress, create new
22885 windows, etc.
22886 @cvar RUN_MASK: The mask for all the run modes.
22887 """
22888 pass
22889
22891 """
22892 Error codes returned by file module operations.
22893
22894 File module functions can return any of these codes, except
22895 B{C{MODULE_FILE_ERROR_UNIMPLEMENTED}} which is normally only returned by
22896 high-level functions L{gwy_file_load}() and L{gwy_file_save}(). Module functions
22897 can return it only when they are called with a wrong function name.
22898
22899 @note: All the enumerated values are defined at the module level, I{not} the
22900 class level. The are just groupped by class here for easier orientation.
22901
22902 @cvar MODULE_FILE_ERROR_CANCELED: Interactive operation was cancelled by
22903 user. (Since 2.45)
22904 @cvar MODULE_FILE_ERROR_CANCELLED: Alias for B{C{MODULE_FILE_ERROR_CANCELED}}.
22905 @cvar MODULE_FILE_ERROR_UNIMPLEMENTED: No module implements requested
22906 operation.
22907 @cvar MODULE_FILE_ERROR_IO: Input/output error occured.
22908 @cvar MODULE_FILE_ERROR_DATA: Data is corrupted or in an unsupported format.
22909 @cvar MODULE_FILE_ERROR_INTERACTIVE: Operation requires user input, but
22910 it was run as B{C{RUN_NONINTERACTIVE}}.
22911 @cvar MODULE_FILE_ERROR_SPECIFIC: Specific module errors that do not fall
22912 into any other category (such as the
22913 failure to initialize a library used to
22914 read the data). Seldom used.
22915 """
22916 pass
22917
22919 """
22920 Type of module loading and registration error.
22921
22922 @note: All the enumerated values are defined at the module level, I{not} the
22923 class level. The are just groupped by class here for easier orientation.
22924
22925 @cvar MODULE_ERROR_NAME: Module has an invalid name. It is recommended that module names are valid C identifiers,
22926 possibly with dashes instead of underscores, but only really broken names are rejected.
22927 @cvar MODULE_ERROR_DUPLICATE: A module of the same name has already been registered.
22928 @cvar MODULE_ERROR_OPEN: Calling g_module_open() on the module failed.
22929 @cvar MODULE_ERROR_QUERY: Module does not contain any query function.
22930 @cvar MODULE_ERROR_ABI: Module has different ABI version than expected/supported; or required info field are
22931 missing.
22932 @cvar MODULE_ERROR_INFO: Module query function provided B{C{None}} info.
22933 @cvar MODULE_ERROR_REGISTER: The registration function returned B{C{False}}; or the module did not register any function.
22934 @cvar MODULE_ERROR_NESTING: Nested module bundle found. (Since 2.49)
22935 """
22936 pass
22937
22939 """
22940 Types of current objects that can be requested with L{gwy_app_data_browser_get_current}().
22941
22942 @note: All the enumerated values are defined at the module level, I{not} the
22943 class level. The are just groupped by class here for easier orientation.
22944
22945 @cvar APP_CONTAINER: Data container (corresponds to files).
22946 @cvar APP_DATA_VIEW: Data view widget (shows a channel).
22947 @cvar APP_GRAPH: Graph widget (shows a graph model).
22948 @cvar APP_DATA_FIELD: Data field (image).
22949 @cvar APP_DATA_FIELD_KEY: Quark corresponding to the data field (image).
22950 @cvar APP_DATA_FIELD_ID: Number (id) of the data field (image) in its container.
22951 @cvar APP_MASK_FIELD: Mask data field.
22952 @cvar APP_MASK_FIELD_KEY: Quark corresponding to the mask field.
22953 @cvar APP_SHOW_FIELD: Presentation data field.
22954 @cvar APP_SHOW_FIELD_KEY: Quark corresponding to the presentation field.
22955 @cvar APP_GRAPH_MODEL: Graph model.
22956 @cvar APP_GRAPH_MODEL_KEY: Quark corresponding to the graph model.
22957 @cvar APP_GRAPH_MODEL_ID: Number (id) of the graph model in its container.
22958 @cvar APP_SPECTRA: Single point spectra. (Since 2.7)
22959 @cvar APP_SPECTRA_KEY: Quark corresponding to the single point spectra. (Since 2.7)
22960 @cvar APP_SPECTRA_ID: Number (id) of the the single point spectra in its container. (Since 2.7)
22961 @cvar APP_VOLUME_VIEW: Data view widget (shows preview of volume data) (Since 2.32).
22962 @cvar APP_BRICK: Data brick (volume data) (Since 2.32).
22963 @cvar APP_BRICK_KEY: Quark corresponding to the data brick (Since 2.32).
22964 @cvar APP_BRICK_ID: Number (id) of the the data brick in its container (Since 2.32).
22965 @cvar APP_CONTAINER_ID: Numeric id of data container (Since 2.41).
22966 @cvar APP_XYZ_VIEW: Data view widget (shows preview of surface XYZ data) (Since 2.45).
22967 @cvar APP_SURFACE: Surface data (XYZ) (Since 2.45).
22968 @cvar APP_SURFACE_KEY: Quark corresponding to the surface data (Since 2.45).
22969 @cvar APP_SURFACE_ID: Number (id) of the the surface data in its container (Since 2.45).
22970 @cvar APP_PAGE: Currently selected data browser page as a B{C{AppPage}} (Since 2.45).
22971 @cvar APP_LAWN: Lawn (curve map) (Since 2.60).
22972 @cvar APP_LAWN_KEY: Quark corresponding to the curve map (Since 2.60).
22973 @cvar APP_LAWN_ID: Number (id) of the lawn (curve map) in its container (Since 2.60).
22974 @cvar APP_CURVE_MAP_VIEW: Data view widget (shows preview of curve map lawn data) (Since 2.60).
22975 """
22976 pass
22977
22979 """
22980 Data browser page, corresponding to one of possible data types.
22981
22982 @since: 2.45
22983
22984 @note: All the enumerated values are defined at the module level, I{not} the
22985 class level. The are just groupped by class here for easier orientation.
22986
22987 @cvar PAGE_NOPAGE: No page. This value is returned when no data are active in the browser.
22988 @cvar PAGE_CHANNELS: Channel (image data).
22989 @cvar PAGE_GRAPHS: Graph.
22990 @cvar PAGE_SPECTRA: Single point spectra.
22991 @cvar PAGE_VOLUMES: Volume data.
22992 @cvar PAGE_XYZS: XYZ data.
22993 @cvar PAGE_CURVE_MAPS: Curve map data. (Since 2.60)
22994 """
22995 pass
22996
22998 """
22999 Type of auxiliary channel data.
23000
23001 @note: All the enumerated values are defined at the module level, I{not} the
23002 class level. The are just groupped by class here for easier orientation.
23003
23004 @cvar DATA_ITEM_GRADIENT: Color gradient.
23005 @cvar DATA_ITEM_PALETTE: An alias of B{C{DATA_ITEM_GRADIENT}}.
23006 @cvar DATA_ITEM_MASK_COLOR: Mask color components.
23007 @cvar DATA_ITEM_TITLE: Channel title.
23008 @cvar DATA_ITEM_RANGE: Range type and range boundaries.
23009 @cvar DATA_ITEM_RANGE_TYPE: Range type.
23010 @cvar DATA_ITEM_REAL_SQUARE: Physical/pixel aspect ratio mode.
23011 @cvar DATA_ITEM_SELECTIONS: Data selections.
23012 @cvar DATA_ITEM_META: Metadata.
23013 @cvar DATA_ITEM_CALDATA: Calibration and uncertainty data. (Since 2.23)
23014 @cvar DATA_ITEM_PREVIEW: Volume data preview. (Since 2.51)
23015 """
23016 pass
23017
23019 """
23020 Data object visibility reset type.
23021
23022 The precise behaviour of B{C{VISIBILITY_RESET_DEFAULT}} may be subject of further changes. It indicates the wish to
23023 restore saved visibilities and do something reasonable when there are no visibilities to restore.
23024
23025 @note: All the enumerated values are defined at the module level, I{not} the
23026 class level. The are just groupped by class here for easier orientation.
23027
23028 @cvar VISIBILITY_RESET_DEFAULT: Restore visibilities from container and if nothing would be visible, make an
23029 arbitrary data object visible.
23030 @cvar VISIBILITY_RESET_RESTORE: Restore visibilities from container.
23031 @cvar VISIBILITY_RESET_SHOW_ALL: Show all data objects.
23032 @cvar VISIBILITY_RESET_HIDE_ALL: Hide all data objects. This normally makes the file inaccessible.
23033 """
23034 pass
23035
23037 """
23038 Type of event reported to B{C{AppDataWatchFunc}} watcher functions.
23039
23040 @since: 2.21
23041
23042 @note: All the enumerated values are defined at the module level, I{not} the
23043 class level. The are just groupped by class here for easier orientation.
23044
23045 @cvar DATA_WATCH_EVENT_ADDED: A new data object has appeared.
23046 @cvar DATA_WATCH_EVENT_CHANGED: A data object has changed.
23047 @cvar DATA_WATCH_EVENT_REMOVED: A data object has been removed.
23048 """
23049 pass
23050
23052 """
23053 Error codes returned by text header parsing.
23054
23055 Some errors, in particular B{C{TEXT_HEADER_ERROR_KEY}} and
23056 B{C{TEXT_HEADER_ERROR_VALUE}} are expected to be raised by user callbacks
23057 (they are not restricted to these codes though).
23058
23059 @since: 2.18
23060
23061 @note: All the enumerated values are defined at the module level, I{not} the
23062 class level. The are just groupped by class here for easier orientation.
23063
23064 @cvar TEXT_HEADER_ERROR_SECTION_NAME: Section name is invalid. It is raised
23065 by the parser only for an empty section
23066 name.
23067 @cvar TEXT_HEADER_ERROR_SECTION_END: Section ended when a different section
23068 or no section was open. Note that
23069 L{gwy_text_header_context_get_section}()
23070 returns the section being closed at the
23071 time this error is raised.
23072 @cvar TEXT_HEADER_ERROR_SECTION_START: Section started before the previous
23073 ended. This is raised only if
23074 B{C{endsection_template}} is set.
23075 @cvar TEXT_HEADER_ERROR_PREFIX: Line lacks the mandatory prefix.
23076 @cvar TEXT_HEADER_ERROR_GARBAGE: Line cannot be parsed into a key-value pair.
23077 @cvar TEXT_HEADER_ERROR_KEY: Key name is invalid, namely empty.
23078 @cvar TEXT_HEADER_ERROR_VALUE: Value is invalid. This is never raised by
23079 the parser.
23080 @cvar TEXT_HEADER_ERROR_TERMINATOR: The text header has ended without being
23081 terminated by specified terminator.
23082 """
23083 pass
23084
23086 """
23087 Type of behaviour modifying flags that can be passed to
23088 L{gwy_preview_surface_to_datafield}().
23089
23090 @since: 2.46
23091
23092 @note: All the enumerated values are defined at the module level, I{not} the
23093 class level. The are just groupped by class here for easier orientation.
23094
23095 @cvar PREVIEW_SURFACE_DENSITY: Render a point density map instead of the data.
23096 @cvar PREVIEW_SURFACE_FILL: Make the data field as large as the specified resolutions at least in one dimension (it
23097 can be prevented in the other by different aspect ratio).
23098 """
23099 pass
23100
23115
23117 """
23118 Flags controlling the selection holding behaviour of tools.
23119
23120 Although any combination of flags is valid, this is mainly so that user's choice is not reset. For any holding to
23121 be done at all the B{C{HOLD_SELECTION_HOLD}} flag must be set. If it is unset then B{C{HOLD_SELECTION_OVERWRITE}}
23122 and B{C{HOLD_SELECTION_CLEAR}} do not matter. Similarly, for B{C{HOLD_SELECTION_CLEAR}} has any effect only if
23123 overwriting is enabled by setting B{C{HOLD_SELECTION_OVERWRITE}}.
23124
23125 @since: 2.63
23126
23127 @note: All the enumerated values are defined at the module level, I{not} the
23128 class level. The are just groupped by class here for easier orientation.
23129
23130 @cvar HOLD_SELECTION_HOLD: Selections are held (transferred to the new image).
23131 @cvar HOLD_SELECTION_OVERWRITE: Existing selections on the new image is replaced.
23132 @cvar HOLD_SELECTION_CLEAR: If the current image has no selection the selection on the new image is cleared.
23133 """
23134 pass
23135
23137 """
23138 Flags controlling help setup and behaviour.
23139
23140 @since: 2.38
23141
23142 @note: All the enumerated values are defined at the module level, I{not} the
23143 class level. The are just groupped by class here for easier orientation.
23144
23145 @cvar HELP_DEFAULT: No flags, the default behaviour.
23146 @cvar HELP_NO_BUTTON: Do not add a Help button, even to windows that are dialogs.
23147 """
23148 pass
23149
23151 """
23152 Flags controlling where program messages are written.
23153
23154 @since: 2.45
23155
23156 @note: All the enumerated values are defined at the module level, I{not} the
23157 class level. The are just groupped by class here for easier orientation.
23158
23159 @cvar APP_LOGGING_TO_FILE: Messages go to a log file, either gwyddion.log or
23160 given by environment variable GWYDDION_LOGFILE.
23161 @cvar APP_LOGGING_TO_CONSOLE: Messages go to standard output and standard
23162 error depending on message type (emulating
23163 where GLib sends them).
23164 """
23165 pass
23166
23168 """
23169 Global application sensitivity flags.
23170
23171 They represent various application states that may be preconditions for widgets to become sensitive.
23172
23173 @note: All the enumerated values are defined at the module level, I{not} the
23174 class level. The are just groupped by class here for easier orientation.
23175
23176 @cvar MENU_FLAG_DATA: There is at least a one data window present.
23177 @cvar MENU_FLAG_UNDO: There is something to undo (for current data window).
23178 @cvar MENU_FLAG_REDO: There is something to redo (for current data window).
23179 @cvar MENU_FLAG_GRAPH: There is at least a one graph window present.
23180 @cvar MENU_FLAG_LAST_PROC: There is a last-run data processing function to rerun.
23181 @cvar MENU_FLAG_LAST_GRAPH: There is a last-run graph function to rerun.
23182 @cvar MENU_FLAG_DATA_MASK: There is a mask on the data.
23183 @cvar MENU_FLAG_DATA_SHOW: There is a presentation on the data.
23184 @cvar MENU_FLAG_3D: A 3D view is present.
23185 @cvar MENU_FLAG_FILE: A file is open, with any type of data (Since 2.5).
23186 @cvar MENU_FLAG_VOLUME: There is at least one volume data window present (Since 2.32).
23187 @cvar MENU_FLAG_XYZ: There is at least one XYZ surface data window present (Since 2.45).
23188 @cvar MENU_FLAG_CURVE_MAP: There is at least one B{C{Lawn}} curve map window present (Since 2.60).
23189 @cvar MENU_FLAG_GRAPH_CURVE: There current graph window contains at least one curve (Since 2.60). This ensures a
23190 graph function will not be run on an empty graph.
23191 @cvar MENU_FLAG_MASK: All the bits combined.
23192 """
23193 pass
23194
23196 """
23197 Error codes returned by application settings functions.
23198
23199 @note: All the enumerated values are defined at the module level, I{not} the
23200 class level. The are just groupped by class here for easier orientation.
23201
23202 @cvar APP_SETTINGS_ERROR_FILE: Settings file is not readable or writable.
23203 @cvar APP_SETTINGS_ERROR_CORRUPT: Settings file contents is corrupted.
23204 @cvar APP_SETTINGS_ERROR_CFGDIR: User configuration directory is not readable or writable or it does not exist and
23205 its creation failed.
23206 @cvar APP_SETTINGS_ERROR_EMPTY: Settings file is empty (Since 2.45). This was previously reported as
23207 B{C{APP_SETTINGS_ERROR_CORRUPT}} but empty settings files can be overwritten without
23208 losing anything.
23209 """
23210 pass
23211
23213 """
23214 Type of data validation errors.
23215
23216 @since: 2.9
23217
23218 @note: All the enumerated values are defined at the module level, I{not} the
23219 class level. The are just groupped by class here for easier orientation.
23220
23221 @cvar DATA_ERROR_KEY_FORMAT: Key format is invalid (e.g. does not start with B{C{CONTAINER_PATHSEP}}).
23222 @cvar DATA_ERROR_KEY_CHARACTERS: Key contains unprintable characters or characters not representable in ASCII.
23223 @cvar DATA_ERROR_KEY_UNKNOWN: Key does not correspond to any data item known to this version of Gwyddion.
23224 @cvar DATA_ERROR_KEY_ID: Key corresponds to a data item with bogus id number.
23225 @cvar DATA_ERROR_ITEM_TYPE: Wrong item type (for instance an integer at key C{"/0/data"}).
23226 @cvar DATA_ERROR_NON_UTF8_STRING: String value is not valid UTF-8.
23227 @cvar DATA_ERROR_REF_COUNT: Reference count is higher than 1.
23228 @cvar DATA_ERROR_STRAY_SECONDARY_DATA: Secondary data item (e.g. mask, selection or visibility) without
23229 a corresponding valid primary data item.
23230 """
23231 pass
23232
23234 """
23235 Flags controlling L{gwy_data_validate}() behaviour.
23236
23237 Note passing B{C{DATA_VALIDATE_NO_REPORT}} is allowed only if B{C{DATA_VALIDATE_CORRECT}} is present too.
23238
23239 @since: 2.9
23240
23241 @note: All the enumerated values are defined at the module level, I{not} the
23242 class level. The are just groupped by class here for easier orientation.
23243
23244 @cvar DATA_VALIDATE_UNKNOWN: Report all unknown keys as B{C{DATA_ERROR_KEY_UNKNOWN}} errors. Note while a data item
23245 unknown to the current version of Gwyddion can come from a newer version therefore it
23246 can be in certain sense valid.
23247 @cvar DATA_VALIDATE_REF_COUNT: Report all object items with reference count higher than 1 as
23248 B{C{DATA_ERROR_REF_COUNT}} errors. Obviously this makes sense only with `fresh' data
23249 containers.
23250 @cvar DATA_VALIDATE_ALL: All above flags combined.
23251 @cvar DATA_VALIDATE_CORRECT: Attempt to correct problems.
23252 @cvar DATA_VALIDATE_NO_REPORT: Do not report problems.
23253 """
23254 pass
23255
23257 """
23258 @note: All the enumerated values are defined at the module level, I{not} the
23259 class level. The are just groupped by class here for easier orientation.
23260
23261 @cvar 2DCWT_GAUSS:
23262 @cvar 2DCWT_HAT:
23263 """
23264 pass
23265