| blob | 589aeb9c0052c7e36ac1ac6abd760b08152b020a |
1 /* Indentation functions.
2 Copyright (C) 1985-1988, 1993-1995, 1998, 2000-2015 Free Software
3 Foundation, Inc.
5 This file is part of GNU Emacs.
7 GNU Emacs is free software: you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation, either version 3 of the License, or
10 (at your option) any later version.
12 GNU Emacs is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>. */
20 #include <config.h>
21 #include <stdio.h>
38 #define CR 015
40 /* These three values memorize the current column to avoid recalculation. */
42 /* Last value returned by current_column.
43 Some things in set last_known_column_point to -1
44 to mark the memorized value as invalid. */
48 /* Value of point when current_column was called. */
52 /* Value of MODIFF when current_column was called. */
59 /* Get the display table to use for the current buffer. */
63 {
64 Lisp_Object thisbuf;
72 }
73 \f
74 /* Width run cache considerations. */
76 /* Return the width of character C under display table DP. */
78 static int
80 {
81 Lisp_Object elt;
83 /* These width computations were determined by examining the cases
84 in display_text_line. */
86 /* Everything can be handled by the display table, if it's
87 present and the element is right. */
91 /* Some characters are special. */
95 /* Printing characters have width 1. */
99 /* Everybody else (control characters, metacharacters) has other
100 widths. We could return their actual widths here, but they
101 depend on things like ctl_arrow and crud like that, and they're
102 not very common at all. So we'll just claim we don't know their
103 widths. */
104 else
106 }
108 /* Return true if the display table DISPTAB specifies the same widths
109 for characters as WIDTHTAB. We use this to decide when to
110 invalidate the buffer's width_run_cache. */
112 bool
114 {
125 }
127 /* Recompute BUF's width table, using the display table DISPTAB. */
129 void
131 {
142 }
144 /* Allocate or free the width run cache, as requested by the
145 current state of current_buffer's cache_long_scans variable. */
149 {
154 {
157 }
160 /* And, for the moment, this feature doesn't work on multibyte
161 characters. */
163 {
167 {
168 /* It should be off. */
170 {
174 }
175 }
177 }
178 else
179 {
183 {
184 /* It should be on. */
186 {
189 }
190 }
192 }
193 }
195 \f
196 /* Skip some invisible characters starting from POS.
197 This includes characters invisible because of text properties
198 and characters invisible because of overlays.
200 If position POS is followed by invisible characters,
201 skip some of them and return the position after them.
202 Otherwise return POS itself.
204 Set *NEXT_BOUNDARY_P to the next position at which
205 it will be necessary to call this function again.
207 Don't scan past TO, and don't set *NEXT_BOUNDARY_P
208 to a value greater than TO.
210 If WINDOW is non-nil, and this buffer is displayed in WINDOW,
211 take account of overlays that apply only in WINDOW.
213 We don't necessarily skip all the invisible characters after POS
214 because that could take a long time. We skip a reasonable number
215 which can be skipped quickly. If there might be more invisible
216 characters immediately following, then *NEXT_BOUNDARY_P
217 will equal the return value. */
219 ptrdiff_t
221 {
230 /* Give faster response for overlay lookup near POS. */
233 /* We must not advance farther than the next overlay change.
234 The overlay change might change the invisible property;
235 or there might be overlay strings to be displayed there. */
237 /* As for text properties, this gives a lower bound
238 for where the invisible text property could change. */
242 /* PROPLIMIT is now a lower bound for the next change
243 in invisible status. If that is plenty far away,
244 use that lower bound. */
247 /* Otherwise, scan for the next `invisible' property change. */
248 else
249 {
250 /* Don't scan terribly far. */
252 /* No matter what, don't go past next overlay change. */
258 #if 0
259 /* Don't put the boundary in the middle of multibyte form if
260 there is no actual property change. */
265 end--;
266 #endif
268 }
269 /* if the `invisible' property is set, we can skip to
270 the next property change */
276 /* When counting columns (window == nil), don't skip over ellipsis text. */
280 }
281 \f
282 /* Set variables WIDTH and BYTES for a multibyte sequence starting at P.
284 DP is a display table or NULL.
286 This macro is used in scan_for_column and in
287 compute_motion. */
289 #define MULTIBYTE_BYTES_WIDTH(p, dp, bytes, width) \
290 do { \
291 int ch; \
292 \
293 ch = STRING_CHAR_AND_LENGTH (p, bytes); \
294 if (BYTES_BY_CHAR_HEAD (*p) != bytes) \
295 width = bytes * 4; \
296 else \
297 { \
298 if (dp != 0 && VECTORP (DISP_CHAR_VECTOR (dp, ch))) \
299 width = sanitize_char_width (ASIZE (DISP_CHAR_VECTOR (dp, ch))); \
300 else \
301 width = CHAR_WIDTH (ch); \
302 } \
303 } while (0)
308 This is calculated by adding together the widths of all the displayed
309 representations of the character between the start of the previous line
310 and point (e.g., control characters will have a width of 2 or 4, tabs
311 will have a variable width).
312 Ignores finite width of frame, which means that this function may return
313 values greater than (frame-width).
314 Whether the line is visible (if `selective-display' is t) has no effect;
315 however, ^M is treated as end of line when `selective-display' is t.
316 Text that has an invisible property is considered as having width 0, unless
319 {
320 Lisp_Object temp;
323 }
325 /* Cancel any recorded value of the horizontal position. */
327 void
329 {
331 }
333 ptrdiff_t
335 {
349 /* If the buffer has overlays, text properties,
350 or multibyte characters, use a more general algorithm. */
356 /* Scan backwards from point to the previous newline,
357 counting width. Tab characters are the only complicated case. */
359 /* Make a pointer for decrementing through the chars before point. */
361 /* Make a pointer to where consecutive chars leave off,
362 going backwards from point. */
367 else
373 {
375 Lisp_Object charvec;
378 {
379 /* We stopped either for the beginning of the buffer
380 or for the gap. */
384 /* It was the gap. Jump back over it. */
388 /* Check whether that brings us to beginning of buffer. */
391 }
396 {
399 }
400 else
401 {
404 }
407 {
409 {
410 /* This should be handled the same as
411 next_element_from_display_vector does it. */
416 else
418 }
421 col++;
425 {
426 ptr++;
428 }
430 {
437 }
439 /* With a display table entry, C is displayed as is, and
440 not displayed as \NNN or as ^N. If C is a single-byte
441 character, it takes one column. If C is multi-byte in
442 a unibyte buffer, it's translated to unibyte, so it
443 also takes one column. */
445 else
447 }
448 }
450 start_of_line_found:
453 {
456 }
463 }
464 \f
466 /* Check the presence of a display property and compute its width.
467 If a property was found and its width was found as well, return
468 its width (>= 0) and set the position of the end of the property
469 in ENDPOS.
470 Otherwise just return -1. */
471 static int
473 {
482 EMACS_INT align_to_max =
501 {
505 else
508 }
509 }
511 }
513 /* Scanning from the beginning of the current line, stop at the buffer
514 position ENDPOS or at the column GOALCOL or at the end of line, whichever
515 comes first.
516 Return the resulting buffer position and column in ENDPOS and GOALCOL.
517 PREVCOL gets set to the column of the previous position (it's always
518 strictly smaller than the goal column). */
519 static void
521 {
527 Lisp_Object window;
530 /* Start the scan at the beginning of this line with column number 0. */
546 /* Scan forward to the target position. */
548 {
551 /* Occasionally we may need to skip invisible text. */
553 {
555 /* This updates NEXT_BOUNDARY to the next place
556 where we might need to skip more invisible text. */
562 }
564 /* Test reaching the goal column. We do this after skipping
565 invisible characters, so that we put point before the
566 character on which the cursor will appear. */
575 {
578 {
582 }
583 }
584 }
586 /* Check composition sequence. */
593 {
599 {
602 Qnil);
603 }
604 else
607 }
611 /* See if there is a display table and it relates
612 to this character. */
617 {
618 Lisp_Object charvec;
621 /* This character is displayed using a vector of glyphs.
622 Update the column/position based on those glyphs. */
628 {
629 /* This should be handled the same as
630 next_element_from_display_vector does it. */
635 else
643 {
646 }
647 else
649 }
650 }
651 else
652 {
653 /* The display table doesn't affect this character;
654 it displays as itself. */
661 {
664 }
666 {
667 /* Start of multi-byte form. */
673 /* Subtract one to compensate for the increment
674 that is going to happen below. */
677 }
682 else
683 col++;
684 }
685 scan++;
686 scan_byte++;
688 }
689 endloop:
701 }
703 /* Return the column number of point
704 by scanning forward from the beginning of the line.
705 This function handles characters that are invisible
706 due to text properties or overlays. */
708 static ptrdiff_t
710 {
716 }
717 \f
721 /* Return the width in columns of the part of STRING from BEG to END.
722 If BEG is nil, that stands for the beginning of STRING.
723 If END is nil, that stands for the end of STRING. */
725 static double
727 {
740 else
741 {
744 }
748 else
749 {
752 }
754 /* Make a pointer for decrementing through the chars before point. */
756 /* Make a pointer to where consecutive chars leave off,
757 going backwards from point. */
763 {
771 col++;
775 {
782 }
783 else
785 }
788 {
791 }
794 }
798 \f
801 Optional second argument MINIMUM says always do at least MINIMUM spaces
802 even if that goes past COLUMN; by default, MINIMUM is zero.
806 {
807 EMACS_INT mincol;
824 {
825 Lisp_Object n;
828 {
832 }
833 }
844 }
846 \f
850 This is the horizontal position of the character
853 {
858 }
860 static ptrdiff_t
862 {
872 /* STOP records the value of P at which we will need
873 to think about the gap, or about invisible text,
874 or about the end of the buffer. */
876 /* START records the starting value of P. */
879 {
881 {
884 /* If we have updated P, set POS_BYTE to match.
885 The first time we enter the loop, POS_BYTE is already right. */
888 /* Consider the various reasons STOP might have been set here. */
892 {
898 }
901 /* Compute the next place we need to stop and think,
902 and set STOP accordingly. */
904 /* The -1 and +1 arrange to point at the first byte of gap
905 (if STOP_POS_BYTE is the position of the gap)
906 rather than at the data after the gap. */
910 }
912 {
917 column++;
926 {
931 {
932 column++;
935 }
936 else
938 }
939 }
940 }
941 }
943 /* Test whether the line beginning at POS is indented beyond COLUMN.
944 Blank lines are treated as if they had the same indentation as the
945 preceding line. */
947 bool
949 {
951 {
955 }
957 }
958 \f
962 Interactively, COLUMN is the value of prefix numeric argument.
963 The column of a character is calculated by adding together the widths
964 as displayed of the previous characters in the line.
965 This function ignores line-continuation;
966 there is no upper limit on the column number a character can have
967 and horizontal scrolling has no effect.
969 If specified column is within a character, point goes after that character.
970 If it's past end of line, point goes to end of line.
972 Optional second argument FORCE non-nil means if COLUMN is in the
973 middle of a tab character, change it to spaces.
974 In addition, if FORCE is t, and the line is too short to reach
975 COLUMN, add spaces/tabs to get there.
979 {
981 EMACS_INT col;
982 EMACS_INT goal;
993 /* If a tab char made us overshoot, change it to spaces
994 and scan through it again. */
996 {
1003 {
1006 /* Insert spaces in front of the tab to reach GOAL. Do this
1007 first so that a marker at the end of the tab gets
1008 adjusted. */
1012 /* Now delete the tab, and indent to COL. */
1019 /* Set the last_known... vars consistently. */
1021 }
1022 }
1024 /* If line ends prematurely, add space to the end. */
1033 }
1034 \f
1035 /* compute_motion: compute buffer posn given screen posn and vice versa */
1039 /* Scan the current buffer forward from offset FROM, pretending that
1040 this is at line FROMVPOS, column FROMHPOS, until reaching buffer
1041 offset TO or line TOVPOS, column TOHPOS (whichever comes first),
1042 and return the ending buffer position and screen location. If we
1043 can't hit the requested column exactly (because of a tab or other
1044 multi-column character), overshoot.
1046 DID_MOTION is true if FROMHPOS has already accounted for overlay strings
1047 at FROM. This is the case if FROMVPOS and FROMVPOS came from an
1048 earlier call to compute_motion. The other common case is that FROMHPOS
1049 is zero and FROM is a position that "belongs" at column zero, but might
1050 be shifted by overlay strings; in this case DID_MOTION should be false.
1052 WIDTH is the number of columns available to display text;
1053 compute_motion uses this to handle continuation lines and such.
1054 If WIDTH is -1, use width of window's text area adjusted for
1055 continuation glyph when needed.
1057 HSCROLL is the number of columns not being displayed at the left
1058 margin; this is usually taken from a window's hscroll member.
1059 TAB_OFFSET is the number of columns of the first tab that aren't
1060 being displayed, perhaps because of a continuation line or
1061 something.
1063 compute_motion returns a pointer to a struct position. The bufpos
1064 member gives the buffer position at the end of the scan, and hpos
1065 and vpos give its cartesian location. prevhpos is the column at
1066 which the character before bufpos started, and contin is non-zero
1067 if we reached the current line by continuing the previous.
1069 Note that FROMHPOS and TOHPOS should be expressed in real screen
1070 columns, taking HSCROLL and the truncation glyph at the left margin
1071 into account. That is, beginning-of-line moves you to the hpos
1072 -HSCROLL + (HSCROLL > 0).
1074 For example, to find the buffer position of column COL of line LINE
1075 of a certain window, pass the window's starting location as FROM
1076 and the window's upper-left coordinates as FROMVPOS and FROMHPOS.
1077 Pass the buffer's ZV as TO, to limit the scan to the end of the
1078 visible section of the buffer, and pass LINE and COL as TOVPOS and
1079 TOHPOS.
1081 When displaying in window w, a typical formula for WIDTH is:
1083 window_width - 1
1084 - (has_vertical_scroll_bars
1085 ? WINDOW_CONFIG_SCROLL_BAR_COLS (window)
1086 : (window_width + window_left != frame_cols))
1088 where
1089 window_width is w->total_cols,
1090 window_left is w->left_col,
1091 has_vertical_scroll_bars is
1092 WINDOW_HAS_VERTICAL_SCROLL_BAR (window)
1093 and frame_cols = FRAME_COLS (XFRAME (window->frame))
1095 Or you can let window_body_cols do this all for you, and write:
1096 window_body_cols (w) - 1
1098 The `-1' accounts for the continuation-line backslashes; the rest
1099 accounts for window borders if the window is split horizontally, and
1100 the scroll bars if they are turned on. */
1107 {
1117 EMACS_INT selective
1121 ptrdiff_t selective_rlen
1124 /* The next location where the `invisible' property changes, or an
1125 overlay starts or ends. */
1128 /* For computing runs of characters with similar widths.
1129 Invariant: width_run_width is zero, or all the characters
1130 from width_run_start to width_run_end have a fixed width of
1131 width_run_width. */
1137 /* The next buffer pos where we should consult the width run cache. */
1139 Lisp_Object window;
1142 /* If previous char scanned was a wide character,
1143 this is the column where it ended. Otherwise, this is 0. */
1166 else
1167 /* If the window has its own display table, we can't use the width
1168 run cache, because that's based on the buffer's display table. */
1171 /* Negative width means use all available text columns. */
1173 {
1175 /* We must make room for continuation marks if we don't have fringes. */
1176 #ifdef HAVE_WINDOW_SYSTEM
1178 #endif
1180 }
1183 #ifdef HAVE_WINDOW_SYSTEM
1186 #endif
1189 QUIT;
1191 /* It's just impossible to be too paranoid here. */
1203 {
1205 {
1209 /* Don't skip invisible if we are already at the margin. */
1211 {
1216 previous line any more. It is not the multi-column
1217 character continued in middle. Go back to previous
1218 buffer position, screen position, and set tab offset
1219 to previous value. It's the beginning of the
1220 line. */
1226 }
1228 }
1230 /* If the caller says that the screen position came from an earlier
1231 call to compute_motion, then we've already accounted for the
1232 overlay strings at point. This is only true the first time
1233 through, so clear the flag after testing it. */
1235 /* We need to skip past the overlay strings. Currently those
1236 strings must not contain TAB;
1237 if we want to relax that restriction, something will have
1238 to be changed here. */
1239 {
1244 }
1250 /* Advance POS past invisible characters
1251 (but not necessarily all that there are here),
1252 and store in next_boundary the next position where
1253 we need to call skip_invisible. */
1257 {
1261 }
1264 {
1267 }
1268 }
1270 /* Handle right margin. */
1271 /* Note on a wide-column character.
1273 Characters are classified into the following three categories
1274 according to the width (columns occupied on screen).
1276 (1) single-column character: ex. `a'
1277 (2) multi-column character: ex. `^A', TAB, `\033'
1278 (3) wide-column character: ex. Japanese character, Chinese character
1279 (In the following example, `W_' stands for them.)
1281 Multi-column characters can be divided around the right margin,
1282 but wide-column characters cannot.
1284 NOTE:
1286 (*) The cursor is placed on the next character after the point.
1288 ----------
1289 abcdefghi\
1290 j ^---- next after the point
1291 ^--- next char. after the point.
1292 ----------
1293 In case of sigle-column character
1295 ----------
1296 abcdefgh\\
1297 033 ^---- next after the point, next char. after the point.
1298 ----------
1299 In case of multi-column character
1301 ----------
1302 abcdefgh\\
1303 W_ ^---- next after the point
1304 ^---- next char. after the point.
1305 ----------
1306 In case of wide-column character
1308 The problem here is continuation at a wide-column character.
1309 In this case, the line may shorter less than WIDTH.
1310 And we find the continuation AFTER it occurs.
1312 */
1315 {
1321 {
1323 truncate
1325 else
1327 }
1331 {
1332 /* Truncating: skip to newline, unless we are already past
1333 TO (we need to go back below). */
1335 {
1338 /* If we just skipped next_boundary,
1339 loop around in the main while
1340 and handle it. */
1346 }
1347 }
1348 else
1349 {
1350 /* Continuing. */
1351 /* Remember the previous value. */
1355 {
1358 }
1359 else
1360 {
1363 }
1364 vpos++;
1368 }
1369 }
1371 /* Stop if past the target buffer position or screen position. */
1373 {
1374 /* Go back to the previous position. */
1381 /* NOTE on contin_hpos, hpos, and prev_hpos.
1383 ----------
1384 abcdefgh\\
1385 W_ ^---- contin_hpos
1386 | ^----- hpos
1387 \---- prev_hpos
1388 ----------
1389 */
1393 {
1394 /* Line breaking occurs in the middle of multi-column
1395 character. Go back to previous line. */
1398 }
1400 }
1403 {
1408 previous line any more. It is not the multi-column
1409 character continued in middle. Go back to previous
1410 buffer position, screen position, and set tab offset
1411 to previous value. It's the beginning of the
1412 line. */
1418 }
1420 }
1430 /* Consult the width run cache to see if we can avoid inspecting
1431 the text character-by-character. */
1433 {
1435 int common_width
1438 /* A width of zero means the character's width varies (like
1439 a tab), is meaningless (like a newline), or we just don't
1440 want to skip over it for some other reason. */
1442 {
1445 /* Don't go past the final buffer posn the user
1446 requested. */
1452 /* Don't go past the final horizontal position the user
1453 requested. */
1455 {
1458 }
1460 /* Don't go past the margin. */
1462 {
1465 }
1471 {
1474 }
1475 }
1478 }
1480 /* We have to scan the text character-by-character. */
1481 else
1482 {
1484 Lisp_Object charvec;
1486 /* Check composition sequence. */
1493 {
1498 {
1501 Qnil);
1502 }
1503 else
1506 }
1511 /* Perhaps add some info to the width_run_cache. */
1513 {
1514 /* Is this character part of the current run? If so, extend
1515 the run. */
1520 /* The previous run is over, since this is a character at a
1521 different position, or a different width. */
1522 else
1523 {
1524 /* Have we accumulated a run to put in the cache?
1525 (Currently, we only cache runs of width == 1). */
1531 /* Start recording a new width run. */
1535 }
1536 }
1541 {
1544 }
1545 else
1546 {
1549 }
1552 {
1554 {
1555 /* This should be handled the same as
1556 next_element_from_display_vector does it. */
1561 else
1563 }
1566 hpos++;
1568 {
1574 }
1576 {
1579 {
1580 /* If (pos == to), we don't have to take care of
1581 selective display. */
1583 {
1584 /* Skip any number of invisible lines all at once */
1585 do
1586 {
1590 }
1593 selective));
1594 /* Allow for the " ..." that is displayed for them. */
1596 {
1600 }
1602 /* We have skipped the invis text, but not the
1603 newline after. */
1604 }
1605 }
1606 else
1607 {
1608 /* A visible line. */
1609 vpos++;
1612 /* Count the truncation glyph on column 0 */
1616 }
1618 }
1620 {
1621 /* In selective display mode,
1622 everything from a ^M to the end of the line is invisible.
1623 Stop *before* the real newline. */
1626 /* If we just skipped next_boundary,
1627 loop around in the main while
1628 and handle it. */
1631 /* Allow for the " ..." that is displayed for them. */
1633 {
1637 }
1638 }
1640 {
1641 /* Start of multi-byte form. */
1652 }
1655 else
1657 }
1658 }
1659 }
1661 after_loop:
1663 /* Remember any final width run in the cache. */
1676 else
1679 /* Nonzero if have just continued a line */
1684 }
1689 Scan the current buffer forward from offset FROM,
1690 assuming it is at position FROMPOS--a cons of the form (HPOS . VPOS)--
1691 to position TO or position TOPOS--another cons of the form (HPOS . VPOS)--
1692 and return the ending buffer position and screen location.
1694 If TOPOS is nil, the actual width and height of the window's
1695 text area are used.
1697 There are three additional arguments:
1699 WIDTH is the number of columns available to display text;
1700 this affects handling of continuation lines. A value of nil
1701 corresponds to the actual number of available text columns.
1703 OFFSETS is either nil or a cons cell (HSCROLL . TAB-OFFSET).
1704 HSCROLL is the number of columns not being displayed at the left
1705 margin; this is usually taken from a window's hscroll member.
1706 TAB-OFFSET is the number of columns of the first tab that aren't
1707 being displayed, perhaps because the line was continued within it.
1708 If OFFSETS is nil, HSCROLL and TAB-OFFSET are assumed to be zero.
1710 WINDOW is the window to operate on. It is used to choose the display table;
1711 if it is showing the current buffer, it is used also for
1712 deciding which overlay properties apply.
1713 Note that `compute-motion' always operates on the current buffer.
1715 The value is a list of five elements:
1716 (POS HPOS VPOS PREVHPOS CONTIN)
1717 POS is the buffer position where the scan stopped.
1718 VPOS is the vertical position where the scan stopped.
1719 HPOS is the horizontal position where the scan stopped.
1721 PREVHPOS is the horizontal position one character back from POS.
1722 CONTIN is t if a line was continued after (or within) the previous character.
1724 For example, to find the buffer position of column COL of line LINE
1725 of a certain window, pass the window's starting location as FROM
1726 and the window's upper-left coordinates as FROMPOS.
1727 Pass the buffer's (point-max) as TO, to limit the scan to the end of the
1731 {
1744 {
1748 }
1753 {
1762 }
1763 else
1782 - (
1783 #ifdef HAVE_WINDOW_SYSTEM
1785 #endif
1797 }
1799 /* Fvertical_motion and vmotion. */
1806 {
1809 /* VPOS is cumulative vertical position, changed as from is changed. */
1814 ptrdiff_t selective
1817 PTRDIFF_MAX)
1819 Lisp_Object window;
1821 /* This is the object we use for fetching character properties. */
1822 Lisp_Object text_prop_object;
1826 /* If the window contains this buffer, use it for getting text properties.
1827 Otherwise use the current buffer as arg for doing that. */
1830 else
1834 {
1835 /* To move upward, go a line at a time until
1836 we have gone at least far enough. */
1841 {
1843 Lisp_Object propval;
1852 /* Watch out for newlines with `invisible' property.
1853 When moving upward, check the newline before. */
1855 Qinvisible,
1856 text_prop_object),
1858 {
1861 }
1863 /* Don't care for VPOS... */
1865 /* ... nor HPOS. */
1872 }
1874 /* If we made exactly the desired vertical distance, or
1875 if we hit beginning of buffer, return point found. */
1877 {
1885 }
1887 /* Otherwise find the correct spot by moving down. */
1888 }
1890 /* Moving downward is simple, but must calculate from
1891 beg of line to determine hpos of starting point. */
1894 {
1896 Lisp_Object propval;
1902 /* Watch out for newlines with `invisible' property.
1903 When moving downward, check the newline after. */
1905 Qinvisible,
1906 text_prop_object),
1908 {
1911 }
1913 /* Don't care for VPOS... */
1915 /* ... nor HPOS. */
1919 }
1920 else
1921 {
1925 }
1929 }
1933 If LINES is negative, this means moving up.
1935 This function is an ordinary cursor motion function
1936 which calculates the new position based on how text would be displayed.
1937 The new position may be the start of a line,
1938 or just the start of a continuation line.
1939 The function returns number of screen lines moved over;
1940 that usually equals LINES, but may be closer to zero
1941 if beginning or end of buffer was reached.
1943 The optional second argument WINDOW specifies the window to use for
1944 parameters such as width, horizontal scrolling, and so on.
1945 The default is to use the selected window's parameters.
1947 LINES can optionally take the form (COLS . LINES), in which case the
1948 motion will not stop at the start of a screen line but COLS column
1949 from the visual start of the line (if such exists on that line, that
1950 is). If the line is scrolled horizontally, COLS is interpreted
1951 visually, i.e., as addition to the columns of text beyond the left
1952 edge of the window.
1954 `vertical-motion' always uses the current buffer,
1955 regardless of which buffer is displayed in WINDOW.
1956 This is consistent with other cursor motion functions
1957 and makes it possible to use `vertical-motion' in any buffer,
1960 {
1964 Lisp_Object old_buffer;
1971 /* Allow LINES to be of the form (HPOS . VPOS) aka (COLUMNS . LINES). */
1973 {
1977 }
1985 {
1986 /* Set the window's buffer temporarily to the current buffer. */
1993 }
1996 {
2000 }
2001 else
2002 {
2016 /* See comments below for why we calculate this. */
2020 {
2024 disp_string_at_start_p =
2025 /* If it.area is anything but TEXT_AREA, we need not bother
2026 about the display string, as it doesn't affect cursor
2027 positioning. */
2030 /* A display string on anything but buffer text (e.g., on
2031 an overlay string) doesn't affect cursor positioning. */
2034 {
2036 it_overshoot_count++;
2037 }
2040 }
2041 else
2042 it_overshoot_count =
2045 /* Scan from the start of the line containing PT. If we don't
2046 do this, we start moving with IT->current_x == 0, while PT is
2047 really at some x > 0. */
2051 /* We used to temporarily disable selective display here; the
2052 comment said this is "so we don't move too far" (2005-01-19
2053 checkin by kfs). But this does nothing useful that I can
2054 tell, and it causes Bug#2694 . -- cyd */
2055 /* When the position we started from is covered by a display
2056 string, move_it_to will overshoot it, while vertical-motion
2057 wants to put the cursor _before_ the display string. So in
2058 that case, we move to buffer position before the display
2059 string, and avoid overshooting. But if the position before
2060 the display string is a newline, we don't do this, because
2061 otherwise we will end up in a screen line that is one too
2062 far back. */
2064 (!disp_string_at_start_p
2066 ? PT
2070 /* IT may move too far if truncate-lines is on and PT lies
2071 beyond the right margin. IT may also move too far if the
2072 starting point is on a Lisp string that has embedded
2073 newlines, or spans several screen lines. In these cases,
2074 backtrack. */
2076 {
2077 /* We need to backtrack also if the Lisp string contains no
2078 newlines, but there is a newline right after it. In this
2079 case, IT overshoots if there is an after-string just
2080 before the newline. */
2086 {
2087 /* This is the case of a display string that spans
2088 several screen lines. In that case, we end up at the
2089 end of the string, and it.vpos tells us how many
2090 screen lines we need to backtrack. */
2092 }
2097 }
2101 {
2102 /* The position we started from was covered by a display
2103 property, so we moved to position before the string, and
2104 backed up one line, because the character at PT - 1 is a
2105 newline. So we need one less line to go up. */
2106 nlines++;
2107 /* But we still need to record that one line, in order to
2108 return the correct value to the caller. */
2110 }
2112 {
2114 /* Do this even if LINES is 0, so that we move back to the
2115 beginning of the current line as we ought. */
2118 }
2120 {
2123 }
2124 else
2125 {
2126 /* Otherwise, we are at the first row occupied by PT, which
2127 might span multiple screen lines (e.g., if it's on a
2128 multi-line display string). We want to start from the
2129 last line that it occupies. */
2131 {
2133 {
2136 }
2139 }
2140 else
2141 {
2144 }
2145 }
2147 /* Move to the goal column, if one was specified. If the window
2148 was originally hscrolled, the goal column is interpreted as
2149 an addition to the hscroll amount. */
2151 {
2155 }
2159 }
2162 {
2166 }
2169 }
2172 \f
2173 /* File's initialization. */
2175 void
2177 {
2188 }