| blob | da1052ac94bb47282fb6191e457dda6597c3e8fc |
19 {
25 }
28 {
30 }
33 {
39 /* Should be present exactly once in commit chain */
44 else
48 }
49 }
51 }
52 }
54 /*
55 * Given a commit and a path in it, create a new origin structure.
56 * The callers that add blame to the scoreboard should use
57 * get_origin() to obtain shared, refcounted copy instead of calling
58 * this function directly.
59 */
61 {
69 }
71 /*
72 * Locate an existing origin or create a new one.
73 * This moves the origin to front position in the commit util list.
74 */
76 {
81 /* bump to front */
86 }
88 }
89 }
91 }
97 {
109 }
117 else
119 }
124 {
131 }
135 {
145 }
153 }
156 }
158 /*
159 * This isn't as simple as passing sb->buf and sb->len, because we
160 * want to transfer ownership of the buffer to the commit (so we
161 * must use detach).
162 */
166 {
170 }
172 /*
173 * Prepare a dummy commit that represents the work tree (or staged) item.
174 * Note that annotating work tree item never works in the reverse.
175 */
180 {
234 }
239 }
256 }
257 }
259 /* Reading from stdin */
263 }
269 /*
270 * Read the current index, replace the path entry with
271 * origin->blob_sha1 without mucking with its mode or type
272 * bits; we are not going to write this index out -- we just
273 * want to run "diff-index --cached".
274 */
283 else
284 /* Let's not bother reading from HEAD tree */
286 }
299 }
305 {
314 }
317 {
321 }
325 {
332 num++;
343 }
347 /* A fingerprint is intended to loosely represent a string, such that two
348 * fingerprints can be quickly compared to give an indication of the similarity
349 * of the strings that they represent.
350 *
351 * A fingerprint is represented as a multiset of the lower-cased byte pairs in
352 * the string that it represents. Whitespace is added at each end of the
353 * string. Whitespace pairs are ignored. Whitespace is converted to '\0'.
354 * For example, the string "Darth Radar" will be converted to the following
355 * fingerprint:
356 * {"\0d", "da", "da", "ar", "ar", "rt", "th", "h\0", "\0r", "ra", "ad", "r\0"}
357 *
358 * The similarity between two fingerprints is the size of the intersection of
359 * their multisets, including repeated elements. See fingerprint_similarity for
360 * examples.
361 *
362 * For ease of implementation, the fingerprint is implemented as a map
363 * of byte pairs to the count of that byte pair in the string, instead of
364 * allowing repeated elements in a set.
365 */
368 /* As we know the maximum number of entries in advance, it's
369 * convenient to store the entries in a single array instead of having
370 * the hashmap manage the memory.
371 */
373 };
375 /* A byte pair in a fingerprint. Stores the number of times the byte pair
376 * occurs in the string that the fingerprint represents.
377 */
379 /* The hashmap entry - the hash represents the byte pair in its
380 * entirety so we don't need to store the byte pair separately.
381 */
383 /* The number of times the byte pair occurs in the string that the
384 * fingerprint represents.
385 */
387 };
389 /* See `struct fingerprint` for an explanation of what a fingerprint is.
390 * \param result the fingerprint of the string is stored here. This must be
391 * freed later using free_fingerprint.
392 * \param line_begin the start of the string
393 * \param line_end the end of the string
394 */
398 {
409 /* Always terminate the string with whitespace.
410 * Normalise whitespace to 0, and normalise letters to
411 * lower case. This won't work for multibyte characters but at
412 * worst will match some unrelated characters.
413 */
416 else
419 /* Ignore whitespace pairs */
432 }
433 }
434 }
437 {
440 }
442 /* Calculates the similarity between two fingerprints as the size of the
443 * intersection of their multisets, including repeated elements. See
444 * `struct fingerprint` for an explanation of the fingerprint representation.
445 * The similarity between "cat mat" and "father rather" is 2 because "at" is
446 * present twice in both strings while the similarity between "tim" and "mit"
447 * is 0.
448 */
450 {
461 }
462 }
464 }
466 /* Subtracts byte-pair elements in B from A, modifying A in place.
467 */
469 {
482 else
484 }
485 }
486 }
488 /* Calculate fingerprints for a series of lines.
489 * Puts the fingerprints in the fingerprints array, which must have been
490 * preallocated to allow storing line_count elements.
491 */
495 {
504 }
505 }
509 {
514 }
516 /* This contains the data necessary to linearly map a line number in one half
517 * of a diff chunk to the line in the other half of the diff chunk that is
518 * closest in terms of its position as a fraction of the length of the chunk.
519 */
523 };
525 /* Given a line number in one range, offset and scale it to map it onto the
526 * other range.
527 * Essentially this mapping is a simple linear equation but the calculation is
528 * more complicated to allow performing it with integer operations.
529 * Another complication is that if a line could map onto many lines in the
530 * destination range then we want to choose the line at the center of those
531 * possibilities.
532 * Example: if the chunk is 2 lines long in A and 10 lines long in B then the
533 * first 5 lines in B will map onto the first line in the A chunk, while the
534 * last 5 lines will all map onto the second line in the A chunk.
535 * Example: if the chunk is 10 lines long in A and 2 lines long in B then line
536 * 0 in B will map onto line 2 in A, and line 1 in B will map onto line 7 in A.
537 */
540 {
545 }
547 /* Get a pointer to the element storing the similarity between a line in A
548 * and a line in B.
549 *
550 * The similarities are stored in a 2-dimensional array. Each "row" in the
551 * array contains the similarities for a line in B. The similarities stored in
552 * a row are the similarities between the line in B and the nearby lines in A.
553 * To keep the length of each row the same, it is padded out with values of -1
554 * where the search range extends beyond the lines in A.
555 * For example, if max_search_distance_a is 2 and the two sides of a diff chunk
556 * look like this:
557 * a | m
558 * b | n
559 * c | o
560 * d | p
561 * e | q
562 * Then the similarity array will contain:
563 * [-1, -1, am, bm, cm,
564 * -1, an, bn, cn, dn,
565 * ao, bo, co, do, eo,
566 * bp, cp, dp, ep, -1,
567 * cq, dq, eq, -1, -1]
568 * Where similarities are denoted either by -1 for invalid, or the
569 * concatenation of the two lines in the diff being compared.
570 *
571 * \param similarities array of similarities between lines in A and B
572 * \param line_a the index of the line in A, in the same frame of reference as
573 * closest_line_a.
574 * \param local_line_b the index of the line in B, relative to the first line
575 * in B that similarities represents.
576 * \param closest_line_a the index of the line in A that is deemed to be
577 * closest to local_line_b. This must be in the same
578 * frame of reference as line_a. This value defines
579 * where similarities is centered for the line in B.
580 * \param max_search_distance_a maximum distance in lines from the closest line
581 * in A for other lines in A for which
582 * similarities may be calculated.
583 */
587 {
589 max_search_distance_a);
591 max_search_distance_a +
593 }
595 #define CERTAIN_NOTHING_MATCHES -2
596 #define CERTAINTY_NOT_CALCULATED -1
598 /* Given a line in B, first calculate its similarities with nearby lines in A
599 * if not already calculated, then identify the most similar and second most
600 * similar lines. The "certainty" is calculated based on those two
601 * similarities.
602 *
603 * \param start_a the index of the first line of the chunk in A
604 * \param length_a the length in lines of the chunk in A
605 * \param local_line_b the index of the line in B, relative to the first line
606 * in the chunk.
607 * \param fingerprints_a array of fingerprints for the chunk in A
608 * \param fingerprints_b array of fingerprints for the chunk in B
609 * \param similarities 2-dimensional array of similarities between lines in A
610 * and B. See get_similarity() for more details.
611 * \param certainties array of values indicating how strongly a line in B is
612 * matched with some line in A.
613 * \param second_best_result array of absolute indices in A for the second
614 * closest match of a line in B.
615 * \param result array of absolute indices in A for the closest match of a line
616 * in B.
617 * \param max_search_distance_a maximum distance in lines from the closest line
618 * in A for other lines in A for which
619 * similarities may be calculated.
620 * \param map_line_number_in_b_to_a parameter to map_line_number().
621 */
635 {
641 /* certainty has already been calculated so no need to redo the work */
659 closest_local_line_a,
660 max_search_distance_a);
662 /* This value will never exceed 10 but assert just in
663 * case
664 */
666 /* scale the similarity by (1000 - distance from
667 * closest line) to act as a tie break between lines
668 * that otherwise are equally similar.
669 */
674 }
683 }
684 }
687 /* this line definitely doesn't match with anything. Mark it
688 * with this special value so it doesn't get invalidated and
689 * won't be recalculated.
690 */
694 /* Calculate the certainty with which this line matches.
695 * If the line matches well with two lines then that reduces
696 * the certainty. However we still want to prioritise matching
697 * a line that matches very well with two lines over matching a
698 * line that matches poorly with one line, hence doubling
699 * best_similarity.
700 * This means that if we have
701 * line X that matches only one line with a score of 3,
702 * line Y that matches two lines equally with a score of 5,
703 * and line Z that matches only one line with a score or 2,
704 * then the lines in order of certainty are X, Y, Z.
705 */
707 second_best_similarity;
709 /* We keep both the best and second best results to allow us to
710 * check at a later stage of the matching process whether the
711 * result needs to be invalidated.
712 */
716 }
717 }
719 /*
720 * This finds the line that we can match with the most confidence, and
721 * uses it as a partition. It then calls itself on the lines on either side of
722 * that partition. In this way we avoid lines appearing out of order, and
723 * retain a sensible line ordering.
724 * \param start_a index of the first line in A with which lines in B may be
725 * compared.
726 * \param start_b index of the first line in B for which matching should be
727 * done.
728 * \param length_a number of lines in A with which lines in B may be compared.
729 * \param length_b number of lines in B for which matching should be done.
730 * \param fingerprints_a mutable array of fingerprints in A. The first element
731 * corresponds to the line at start_a.
732 * \param fingerprints_b array of fingerprints in B. The first element
733 * corresponds to the line at start_b.
734 * \param similarities 2-dimensional array of similarities between lines in A
735 * and B. See get_similarity() for more details.
736 * \param certainties array of values indicating how strongly a line in B is
737 * matched with some line in A.
738 * \param second_best_result array of absolute indices in A for the second
739 * closest match of a line in B.
740 * \param result array of absolute indices in A for the closest match of a line
741 * in B.
742 * \param max_search_distance_a maximum distance in lines from the closest line
743 * in A for other lines in A for which
744 * similarities may be calculated.
745 * \param max_search_distance_b an upper bound on the greatest possible
746 * distance between lines in B such that they will
747 * both be compared with the same line in A
748 * according to max_search_distance_a.
749 * \param map_line_number_in_b_to_a parameter to map_line_number().
750 */
763 {
769 closest_local_line_a;
773 length_a,
774 start_b,
775 i,
776 fingerprints_a,
777 fingerprints_b,
778 similarities,
779 certainties,
780 second_best_result,
781 result,
782 max_search_distance_a,
783 map_line_number_in_b_to_a);
788 }
789 }
791 /* No matches. */
797 /*
798 * Subtract the most certain line's fingerprint in B from the matched
799 * fingerprint in A. This means that other lines in B can't also match
800 * the same parts of the line in A.
801 */
805 /* Invalidate results that may be affected by the choice of most
806 * certain line.
807 */
815 /* As the fingerprint in A has changed, discard previously calculated
816 * similarity values with that fingerprint.
817 */
822 /* Check that the lines in A and B are close enough that there
823 * is a similarity value for them.
824 */
826 max_search_distance_a) {
828 }
833 }
835 /* More invalidating of results that may be affected by the choice of
836 * most certain line.
837 * Discard the matches for lines in B that are currently matched with a
838 * line in A such that their ordering contradicts the ordering imposed
839 * by the choice of most certain line.
840 */
842 /* In this loop we discard results for lines in B that are
843 * before most-certain-line-B but are matched with a line in A
844 * that is after most-certain-line-A.
845 */
850 }
851 }
853 /* In this loop we discard results for lines in B that are
854 * after most-certain-line-B but are matched with a line in A
855 * that is before most-certain-line-A.
856 */
861 }
862 }
864 /* Repeat the matching process for lines before the most certain line.
865 */
870 most_certain_local_line_b,
873 max_search_distance_a,
874 max_search_distance_b,
875 map_line_number_in_b_to_a);
876 }
877 /* Repeat the matching process for lines after the most certain line.
878 */
883 second_half_length_a =
885 second_half_length_b =
892 similarities +
896 max_search_distance_a,
897 max_search_distance_b,
898 map_line_number_in_b_to_a);
899 }
900 }
902 /* Find the lines in the parent line range that most closely match the lines in
903 * the target line range. This is accomplished by matching fingerprints in each
904 * blame_origin, and choosing the best matches that preserve the line ordering.
905 * See struct fingerprint for details of fingerprint matching, and
906 * fuzzy_find_matching_lines_recurse for details of preserving line ordering.
907 *
908 * The performance is believed to be O(n log n) in the typical case and O(n^2)
909 * in a pathological case, where n is the number of lines in the target range.
910 */
915 {
916 /* We use the terminology "A" for the left hand side of the diff AKA
917 * parent, and "B" for the right hand side of the diff AKA target. */
925 };
933 /*
934 * max_search_distance_a means that given a line in B, compare it to
935 * the line in A that is closest to its position, and the lines in A
936 * that are no greater than max_search_distance_a lines away from the
937 * closest line in A.
938 *
939 * max_search_distance_b is an upper bound on the greatest possible
940 * distance between lines in B such that they will both be compared
941 * with the same line in A according to max_search_distance_a.
942 */
958 /* See get_similarity() for details of similarities. */
966 }
975 similarities,
976 certainties,
977 second_best_result,
978 result,
979 max_search_distance_a,
980 max_search_distance_b,
988 }
991 {
1002 }
1005 {
1010 }
1011 }
1013 /*
1014 * Given an origin, prepare mmfile_t structure to be used by the
1015 * diff machinery
1016 */
1020 {
1029 ;
1030 else
1040 }
1041 else
1045 }
1048 {
1051 }
1053 /*
1054 * Any merge of blames happens on lists of blames that arrived via
1055 * different parents in a single suspect. In this case, we want to
1056 * sort according to the suspect line numbers as opposed to the final
1057 * image line numbers. The function body is somewhat longish because
1058 * it avoids unnecessary writes.
1059 */
1063 {
1078 }
1080 }
1088 }
1096 }
1098 }
1099 }
1102 {
1104 }
1107 {
1109 }
1111 /*
1112 * Final image line numbers are all different, so we don't need a
1113 * three-way comparison here.
1114 */
1117 {
1120 }
1123 {
1125 /*
1126 * to allow for collating suspects, we sort according to the
1127 * respective pointer value as the primary sorting criterion.
1128 * The actual relation is pretty unimportant as long as it
1129 * establishes a total order. Comparing as integers gives us
1130 * that.
1131 */
1137 }
1140 {
1142 compare_blame_final);
1143 }
1148 {
1150 }
1152 /*
1153 * For debugging -- origin is refcounted, and this asserts that
1154 * we do not underflow.
1155 */
1157 {
1162 /* Nobody should have zero or negative refcnt */
1169 }
1170 }
1173 }
1175 /*
1176 * If two blame entries that are next to each other came from
1177 * contiguous lines in the same origin (i.e. <commit, path> pair),
1178 * merge them together.
1179 */
1181 {
1196 }
1197 }
1201 }
1203 /*
1204 * Merge the given sorted list of blames into a preexisting origin.
1205 * If there were no previous blames to that commit, it is entered into
1206 * the commit priority queue of the score board.
1207 */
1211 {
1220 }
1221 }
1224 }
1225 }
1227 /*
1228 * Fill the blob_sha1 field of an origin if it hasn't, so that later
1229 * call to fill_origin_blob() can use it to locate the data. blob_sha1
1230 * for an origin is also used to pass the blame for the entire file to
1231 * the parent to detect the case where a child's blob is identical to
1232 * that of its parent's.
1233 *
1234 * This also fills origin->mode for corresponding tree path.
1235 */
1238 {
1241 if (get_tree_entry(r, &origin->commit->object.oid, origin->path, &origin->blob_oid, &origin->mode))
1246 error_out:
1250 }
1253 /*
1254 * Changed-path Bloom filter keys. These can help prevent
1255 * computing diffs against first parents, but we need to
1256 * expand the list as code is moved or files are renamed.
1257 */
1262 };
1269 {
1284 bloom_count_queries++;
1290 }
1292 bloom_count_no++;
1294 }
1298 {
1305 }
1310 }
1312 /*
1313 * We have an origin -- check if the same path exists in the
1314 * parent and return an origin structure to represent it.
1315 */
1320 {
1325 /* First check any existing origins */
1328 /*
1329 * The same path between origin and its parent
1330 * without renaming -- the most common case.
1331 */
1333 }
1335 /* See if the origin->path is different between parent
1336 * and origin first. Most of the time they are the
1337 * same and diff-tree is fairly efficient about this.
1338 */
1364 }
1368 /* The path is the same as parent */
1373 /*
1374 * Since origin->path is a pathspec, if the parent
1375 * commit had it as a directory, we will see a whole
1376 * bunch of deletion of files in the directory that we
1377 * do not care about.
1378 */
1387 }
1401 /* Did not exist in parent, or type changed */
1403 }
1404 }
1407 }
1409 /*
1410 * We have an origin -- find the path that corresponds to it in its
1411 * parent and return an origin structure to represent it.
1412 */
1417 {
1431 else
1446 }
1447 }
1450 }
1452 /*
1453 * Append a new blame entry to a given output queue.
1454 */
1457 {
1465 }
1467 /*
1468 * src typically is on-stack; we want to copy the information in it to
1469 * a malloced blame_entry that gets added to the given queue. The
1470 * origin of dst loses a refcnt.
1471 */
1474 {
1481 }
1484 {
1486 }
1488 /*
1489 * It is known that lines between tlno to same came from parent, and e
1490 * has an overlap with that range. it also is known that parent's
1491 * line plno corresponds to e's line tlno.
1492 *
1493 * <---- e ----->
1494 * <------>
1495 * <------------>
1496 * <------------>
1497 * <------------------>
1498 *
1499 * Split e into potentially three parts; before this chunk, the chunk
1500 * to be blamed for the parent, and after that portion.
1501 */
1506 {
1514 }
1517 /* there is a pre-chunk part not blamed on parent */
1524 }
1528 }
1531 /* there is a post-chunk part not blamed on parent */
1537 }
1538 else
1542 /*
1543 * if it turns out there is nothing to blame the parent for,
1544 * forget about the splitting. !split[1].suspect signals this.
1545 */
1549 }
1551 /*
1552 * split_overlap() divided an existing blame e into up to three parts
1553 * in split. Any assigned blame is moved to queue to
1554 * reflect the split.
1555 */
1560 {
1562 /* The first part (reuse storage for the existing entry e) */
1565 /* The last part -- me */
1568 /* ... and the middle part -- parent */
1570 }
1572 /*
1573 * The parent covers the entire area; reuse storage for
1574 * e and replace it with the parent.
1575 */
1578 /* me and then parent */
1581 }
1583 /* parent and then me */
1586 }
1587 }
1589 /*
1590 * After splitting the blame, the origins used by the
1591 * on-stack blame_entry should lose one refcnt each.
1592 */
1594 {
1599 }
1601 /*
1602 * reverse_blame reverses the list given in head, appending tail.
1603 * That allows us to build lists in reverse order, then reverse them
1604 * afterwards. This can be faster than building the list in proper
1605 * order right away. The reason is that building in proper order
1606 * requires writing a link in the _previous_ element, while building
1607 * in reverse order just requires placing the list head into the
1608 * _current_ element.
1609 */
1613 {
1619 }
1621 }
1623 /*
1624 * Splits a blame entry into two entries at 'len' lines. The original 'e'
1625 * consists of len lines, i.e. [e->lno, e->lno + len), and the second part,
1626 * which is returned, consists of the remainder: [e->lno + len, e->lno +
1627 * e->num_lines). The caller needs to sort out the reference counting for the
1628 * new entry's suspect.
1629 */
1632 {
1644 }
1649 };
1653 {
1656 }
1661 {
1663 #define FINGERPRINT_FILE_THRESHOLD 10
1671 /* Break ties with the closest-to-target line number */
1677 }
1679 }
1681 /*
1682 * The first pass checks the blame entry (from the target) against the parent's
1683 * diff chunk. If that fails for a line, the second pass tries to match that
1684 * line to any part of parent file. That catches cases where a change was
1685 * broken into two chunks by 'context.'
1686 */
1691 {
1698 parent_len);
1708 }
1715 }
1716 }
1718 }
1720 /*
1721 * This decides which parts of a blame entry go to the parent (added to the
1722 * ignoredp list) and which stay with the target (added to the diffp list). The
1723 * actual decision was made in a separate heuristic function, and those answers
1724 * for the lines in 'e' are in line_blames. This consumes e, essentially
1725 * putting it on a list.
1726 *
1727 * Note that the blame entries on the ignoredp list are not necessarily sorted
1728 * with respect to the parent's line numbers yet.
1729 */
1735 {
1738 /*
1739 * We carve new entries off the front of e. Each entry comes from a
1740 * contiguous chunk of lines: adjacent lines from the same origin
1741 * (either the parent or the target).
1742 */
1748 /*
1749 * We are often adjacent to the next line - only split the blame
1750 * entry when we have to.
1751 */
1755 entry_len++;
1757 }
1760 }
1770 /* e->s_lno is already in the target's address space. */
1773 }
1777 }
1779 }
1781 /*
1782 * Process one hunk from the patch between the current suspect for
1783 * blame_entry e and its parent. This first blames any unfinished
1784 * entries before the chunk (which is where target and parent start
1785 * differing) on the parent, and then splits blame entries at the
1786 * start and at the end of the difference region. Since use of -M and
1787 * -C options may lead to overlapping/duplicate source line number
1788 * ranges, all we can rely on from sorting/merging is the order of the
1789 * first suspect line number.
1790 *
1791 * tlno: line number in the target where this chunk begins
1792 * same: line number in the target where this chunk ends
1793 * offset: add to tlno to get the chunk starting point in the parent
1794 * parent_len: number of lines in the parent chunk
1795 */
1800 {
1807 /*
1808 * current record starts before differing portion. If
1809 * it reaches into it, we need to split it up and
1810 * examine the second part separately.
1811 */
1813 /* Move second half to a new record */
1817 /* Push new record to diffp */
1822 /* Pass blame for everything before the differing
1823 * chunk to the parent */
1829 }
1830 /*
1831 * As we don't know how much of a common stretch after this
1832 * diff will occur, the currently blamed parts are all that we
1833 * can assign to the parent for now.
1834 */
1839 }
1840 /*
1841 * Prepend the split off portions: everything after e starts
1842 * after the blameable portion.
1843 */
1846 /*
1847 * Now retain records on the target while parts are different
1848 * from the parent.
1849 */
1857 }
1862 /*
1863 * If current record extends into sameness, need to split.
1864 */
1866 /*
1867 * Move second half to a new record to be
1868 * processed by later chunks
1869 */
1874 /* Push new record to samep */
1877 }
1884 }
1886 }
1889 /*
1890 * Note ignoredp is not sorted yet, and thus neither is dstq.
1891 * That list must be sorted before we queue_blames(). We defer
1892 * sorting until after all diff hunks are processed, so that
1893 * guess_line_blames() can pick *any* line in the parent. The
1894 * slight drawback is that we end up sorting all blame entries
1895 * passed to the parent, including those that are unrelated to
1896 * changes made by the ignored commit.
1897 */
1900 }
1902 /* Move across elements that are in the unblamable portion */
1905 }
1914 };
1916 /* diff chunks are from parent to target */
1919 {
1928 }
1930 /*
1931 * We are looking at the origin 'target' and aiming to pass blame
1932 * for the lines it is suspected to its parent. Run diff to find
1933 * which lines came from parent and pass blame for them.
1934 */
1938 {
1962 /* The rest are the same as the parent */
1968 set_next_blame,
1969 compare_blame_suspect);
1973 }
1975 /*
1976 * The lines in blame_entry after splitting blames many times can become
1977 * very small and trivial, and at some point it becomes pointless to
1978 * blame the parents. E.g. "\t\t}\n\t}\n\n" appears everywhere in any
1979 * ordinary C program, and it is not worth to say it was copied from
1980 * totally unrelated file in the parent.
1981 *
1982 * Compute how trivial the lines in the blame_entry are.
1983 */
1985 {
1998 score++;
1999 cp++;
2000 }
2003 }
2005 /*
2006 * best_so_far[] and potential[] are both a split of an existing blame_entry
2007 * that passes blame to the parent. Maintain best_so_far the best split so
2008 * far, by comparing potential and best_so_far and copying potential into
2009 * bst_so_far as needed.
2010 */
2014 {
2023 }
2029 }
2031 /*
2032 * We are looking at a part of the final image represented by
2033 * ent (tlno and same are offset by ent->s_lno).
2034 * tlno is where we are looking at in the final image.
2035 * up to (but not including) same match preimage.
2036 * plno is where we are looking at in the preimage.
2037 *
2038 * <-------------- final image ---------------------->
2039 * <------ent------>
2040 * ^tlno ^same
2041 * <---------preimage----->
2042 * ^plno
2043 *
2044 * All line numbers are 0-based.
2045 */
2051 {
2061 }
2062 }
2071 };
2075 {
2082 }
2084 /*
2085 * Find the lines from parent that are the same as ent so that
2086 * we can pass blames to it. file_p has the blob contents for
2087 * the parent.
2088 */
2094 {
2096 mmfile_t file_o;
2101 /*
2102 * Prepare mmfile that contains only the lines in ent.
2103 */
2108 /*
2109 * file_o is a part of final image we are annotating.
2110 * file_p partially may match that image.
2111 */
2116 /* remainder, if any, all match the preimage */
2118 }
2120 /* Move all blame entries from list *source that have a score smaller
2121 * than score_min to the front of list *small.
2122 * Returns a pointer to the link pointing to the old head of the small list.
2123 */
2129 {
2141 }
2142 }
2146 }
2148 /*
2149 * See if lines currently target is suspected for can be attributed to
2150 * parent.
2151 */
2157 {
2161 mmfile_t file_p;
2171 /* At each iteration, unblamed has a NULL-terminated list of
2172 * entries that have not yet been tested for blame. leftover
2173 * contains the reversed list of entries that have been tested
2174 * without being assignable to the parent.
2175 */
2188 }
2190 }
2195 }
2200 };
2202 /*
2203 * Count the number of entries the target is suspected for,
2204 * and prepare a list of entry and the best split.
2205 */
2208 {
2214 num_ents++;
2219 }
2222 }
2224 /*
2225 * For lines target is suspected for, see if we can find code movement
2226 * across file boundary from the parent commit. porigin is the path
2227 * in the parent we already tried.
2228 */
2236 {
2253 /* Try "find copies harder" on new path if requested;
2254 * we do not want to use diffcore_rename() actually to
2255 * match things up; find_copies_harder is set only to
2256 * force diff_tree_oid() to feed all filepairs to diff_queue,
2257 * and this code needs to be after diff_setup_done(), which
2258 * usually makes find-copies-harder imply copy detection.
2259 */
2267 else
2282 mmfile_t file_p;
2290 /* find_move already dealt with this path */
2305 potential);
2307 }
2309 }
2320 }
2322 }
2329 }
2331 /*
2332 * The blobs of origin and porigin exactly match, so everything
2333 * origin is suspected for can be blamed on the parent.
2334 */
2337 {
2341 /* Steal its file */
2344 }
2351 }
2353 }
2355 /*
2356 * We pass blame from the current commit to its parents. We keep saying
2357 * "parent" (and "porigin"), but what we mean is to find scapegoat to
2358 * exonerate ourselves.
2359 */
2362 {
2369 }
2371 }
2373 }
2376 {
2379 }
2381 /* Distribute collected unsorted blames to the respected sorted lists
2382 * in the various origins.
2383 */
2385 {
2387 compare_blame_suspect);
2389 {
2400 }
2401 }
2403 #define MAXSG 16
2411 {
2426 else
2429 /*
2430 * The first pass looks for unrenamed path to optimize for
2431 * common cases, then we look for renames in the second pass.
2432 */
2453 }
2459 }
2462 else
2464 }
2465 }
2477 }
2481 }
2483 /*
2484 * Pass remaining suspects for ignored commits to their parents.
2485 */
2495 /*
2496 * Preemptively drop porigin so we can refresh the
2497 * fingerprints if we use the parent again, which can
2498 * occur if you ignore back-to-back commits.
2499 */
2503 }
2504 }
2506 /*
2507 * Optionally find moves in parents' files.
2508 */
2521 }
2522 }
2523 }
2525 /*
2526 * Optionally find copies from parents' files.
2527 */
2535 }
2547 }
2548 }
2550 finish:
2553 /*
2554 * prepend toosmall to origin->suspects
2555 *
2556 * There is no point in sorting: this ends up on a big
2557 * unsorted list in the caller anyway.
2558 */
2565 }
2571 }
2572 }
2576 }
2578 /*
2579 * The main loop -- while we have blobs with lines whose true origin
2580 * is still unknown, pick one blob, and allow its lines to pass blames
2581 * to its parents. */
2583 {
2591 /* find one suspect to break down */
2598 }
2602 /*
2603 * We will use this suspect later in the loop,
2604 * so hold onto it in the meantime.
2605 */
2616 }
2617 /* treat root commit as boundary */
2621 /* Take responsibility for the remaining entries */
2632 }
2637 }
2638 }
2643 }
2644 }
2646 /*
2647 * To allow quick access to the contents of nth line in the
2648 * final image, prepare an index in the scoreboard.
2649 */
2651 {
2655 }
2659 {
2676 }
2680 }
2684 {
2685 /*
2686 * DWIM "git blame --reverse ONE -- PATH" as
2687 * "git blame --reverse ONE..HEAD -- PATH" but only do so
2688 * when it makes sense.
2689 */
2697 /* Is that sole rev a committish? */
2703 /* Do we have HEAD? */
2711 /* Turn "ONE" into "ONE..HEAD" then */
2718 }
2722 {
2727 /*
2728 * There must be one and only one negative commit, and it must be
2729 * the boundary.
2730 */
2743 }
2753 }
2756 {
2760 }
2764 {
2784 }
2793 /*
2794 * "--not A B -- path" without anything positive;
2795 * do not default to HEAD, but use the working tree
2796 * or "--contents".
2797 */
2803 }
2809 }
2811 /*
2812 * If we have bottom, this will mark the ancestors of the
2813 * bottom commits we would reach while traversing as
2814 * uninteresting.
2815 */
2832 }
2836 }
2842 }
2851 ;
2852 else
2860 }
2868 }
2875 {
2884 }
2887 {
2909 }
2912 {
2918 }
2926 }
2927 }