| blob | 481305d2bcf0a21a52f0a051b3a93fa1a7a05be0 |
1 /*
2 * "Ostensibly Recursive's Twin" merge strategy, or "ort" for short. Meant
3 * as a drop-in replacement for the "recursive" merge strategy, allowing one
4 * to replace
5 *
6 * git merge [-s recursive]
7 *
8 * with
9 *
10 * git merge -s ort
11 *
12 * Note: git's parser allows the space between '-s' and its argument to be
13 * missing. (Should I have backronymed "ham", "alsa", "kip", "nap, "alvo",
14 * "cale", "peedy", or "ins" instead of "ort"?)
15 */
41 /*
42 * We have many arrays of size 3. Whenever we have such an array, the
43 * indices refer to one of the sides of the three-way merge. This is so
44 * pervasive that the constants 0, 1, and 2 are used in many places in the
45 * code (especially in arithmetic operations to find the other side's index
46 * or to compute a relevant mask), but sometimes these enum names are used
47 * to aid code clarity.
48 *
49 * See also 'filemask' and 'dirmask' in struct conflict_info; the "ith side"
50 * referred to there is one of these three sides.
51 */
56 };
64 };
67 /*
68 * possible_trivial_merges: directories to be explored only when needed
69 *
70 * possible_trivial_merges is a map of directory names to
71 * dir_rename_mask. When we detect that a directory is unchanged on
72 * one side, we can sometimes resolve the directory without recursing
73 * into it. Renames are the only things that can prevent such an
74 * optimization. However, for rename sources:
75 * - If no parent directory needed directory rename detection, then
76 * no path under such a directory can be a relevant_source.
77 * and for rename destinations:
78 * - If no cached rename has a target path under the directory AND
79 * - If there are no unpaired relevant_sources elsewhere in the
80 * repository
81 * then we don't need any path under this directory for a rename
82 * destination. The only way to know the last item above is to defer
83 * handling such directories until the end of collect_merge_info(),
84 * in handle_deferred_entries().
85 *
86 * For each we store dir_rename_mask, since that's the only bit of
87 * information we need, other than the path, to resume the recursive
88 * traversal.
89 */
92 /*
93 * trivial_merges_okay: if trivial directory merges are okay
94 *
95 * See possible_trivial_merges above. The "no unpaired
96 * relevant_sources elsewhere in the repository" is a single boolean
97 * per merge side, which we store here. Note that while 0 means no,
98 * 1 only means "maybe" rather than "yes"; we optimistically set it
99 * to 1 initially and only clear when we determine it is unsafe to
100 * do trivial directory merges.
101 */
104 /*
105 * target_dirs: ancestor directories of rename targets
106 *
107 * target_dirs contains all directory names that are an ancestor of
108 * any rename destination.
109 */
111 };
114 /*
115 * All variables that are arrays of size 3 correspond to data tracked
116 * for the sides in enum merge_side. Index 0 is almost always unused
117 * because we often only need to track information for MERGE_SIDE1 and
118 * MERGE_SIDE2 (MERGE_BASE can't have rename information since renames
119 * are determined relative to what changed since the MERGE_BASE).
120 */
122 /*
123 * pairs: pairing of filenames from diffcore_rename()
124 */
127 /*
128 * dirs_removed: directories removed on a given side of history.
129 *
130 * The keys of dirs_removed[side] are the directories that were removed
131 * on the given side of history. The value of the strintmap for each
132 * directory is a value from enum dir_rename_relevance.
133 */
136 /*
137 * dir_rename_count: tracking where parts of a directory were renamed to
138 *
139 * When files in a directory are renamed, they may not all go to the
140 * same location. Each strmap here tracks:
141 * old_dir => {new_dir => int}
142 * That is, dir_rename_count[side] is a strmap to a strintmap.
143 */
146 /*
147 * dir_renames: computed directory renames
148 *
149 * This is a map of old_dir => new_dir and is derived in part from
150 * dir_rename_count.
151 */
154 /*
155 * relevant_sources: deleted paths wanted in rename detection, and why
156 *
157 * relevant_sources is a set of deleted paths on each side of
158 * history for which we need rename detection. If a path is deleted
159 * on one side of history, we need to detect if it is part of a
160 * rename if either
161 * * the file is modified/deleted on the other side of history
162 * * we need to detect renames for an ancestor directory
163 * If neither of those are true, we can skip rename detection for
164 * that path. The reason is stored as a value from enum
165 * file_rename_relevance, as the reason can inform the algorithm in
166 * diffcore_rename_extended().
167 */
172 /*
173 * dir_rename_mask:
174 * 0: optimization removing unmodified potential rename source okay
175 * 2 or 4: optimization okay, but must check for files added to dir
176 * 7: optimization forbidden; need rename source in case of dir rename
177 */
180 /*
181 * callback_data_*: supporting data structures for alternate traversal
182 *
183 * We sometimes need to be able to traverse through all the files
184 * in a given tree before all immediate subdirectories within that
185 * tree. Since traverse_trees() doesn't do that naturally, we have
186 * a traverse_trees_wrapper() that stores any immediate
187 * subdirectories while traversing files, then traverses the
188 * immediate subdirectories later. These callback_data* variables
189 * store the information for the subdirectories so that we can do
190 * that traversal order.
191 */
196 /*
197 * merge_trees: trees passed to the merge algorithm for the merge
198 *
199 * merge_trees records the trees passed to the merge algorithm. But,
200 * this data also is stored in merge_result->priv. If a sequence of
201 * merges are being done (such as when cherry-picking or rebasing),
202 * the next merge can look at this and re-use information from
203 * previous merges under certain circumstances.
204 *
205 * See also all the cached_* variables.
206 */
209 /*
210 * cached_pairs_valid_side: which side's cached info can be reused
211 *
212 * See the description for merge_trees. For repeated merges, at most
213 * only one side's cached information can be used. Valid values:
214 * MERGE_SIDE2: cached data from side2 can be reused
215 * MERGE_SIDE1: cached data from side1 can be reused
216 * 0: no cached data can be reused
217 * -1: See redo_after_renames; both sides can be reused.
218 */
221 /*
222 * cached_pairs: Caching of renames and deletions.
223 *
224 * These are mappings recording renames and deletions of individual
225 * files (not directories). They are thus a map from an old
226 * filename to either NULL (for deletions) or a new filename (for
227 * renames).
228 */
231 /*
232 * cached_target_names: just the destinations from cached_pairs
233 *
234 * We sometimes want a fast lookup to determine if a given filename
235 * is one of the destinations in cached_pairs. cached_target_names
236 * is thus duplicative information, but it provides a fast lookup.
237 */
240 /*
241 * cached_irrelevant: Caching of rename_sources that aren't relevant.
242 *
243 * If we try to detect a rename for a source path and succeed, it's
244 * part of a rename. If we try to detect a rename for a source path
245 * and fail, then it's a delete. If we do not try to detect a rename
246 * for a path, then we don't know if it's a rename or a delete. If
247 * merge-ort doesn't think the path is relevant, then we just won't
248 * cache anything for that path. But there's a slight problem in
249 * that merge-ort can think a path is RELEVANT_LOCATION, but due to
250 * commit 9bd342137e ("diffcore-rename: determine which
251 * relevant_sources are no longer relevant", 2021-03-13),
252 * diffcore-rename can downgrade the path to RELEVANT_NO_MORE. To
253 * avoid excessive calls to diffcore_rename_extended() we still need
254 * to cache such paths, though we cannot record them as either
255 * renames or deletes. So we cache them here as a "turned out to be
256 * irrelevant *for this commit*" as they are often also irrelevant
257 * for subsequent commits, though we will have to do some extra
258 * checking to see whether such paths become relevant for rename
259 * detection when cherry-picking/rebasing subsequent commits.
260 */
263 /*
264 * redo_after_renames: optimization flag for "restarting" the merge
265 *
266 * Sometimes it pays to detect renames, cache them, and then
267 * restart the merge operation from the beginning. The reason for
268 * this is that when we know where all the renames are, we know
269 * whether a certain directory has any paths under it affected --
270 * and if a directory is not affected then it permits us to do
271 * trivial tree merging in more cases. Doing trivial tree merging
272 * prevents the need to run process_entry() on every path
273 * underneath trees that can be trivially merged, and
274 * process_entry() is more expensive than collect_merge_info() --
275 * plus, the second collect_merge_info() will be much faster since
276 * it doesn't have to recurse into the relevant trees.
277 *
278 * Values for this flag:
279 * 0 = don't bother, not worth it (or conditions not yet checked)
280 * 1 = conditions for optimization met, optimization worthwhile
281 * 2 = we already did it (don't restart merge yet again)
282 */
285 /*
286 * needed_limit: value needed for inexact rename detection to run
287 *
288 * If the current rename limit wasn't high enough for inexact
289 * rename detection to run, this records the limit needed. Otherwise,
290 * this value remains 0.
291 */
293 };
296 /*
297 * paths: primary data structure in all of merge ort.
298 *
299 * The keys of paths:
300 * * are full relative paths from the toplevel of the repository
301 * (e.g. "drivers/firmware/raspberrypi.c").
302 * * store all relevant paths in the repo, both directories and
303 * files (e.g. drivers, drivers/firmware would also be included)
304 * * these keys serve to intern all the path strings, which allows
305 * us to do pointer comparison on directory names instead of
306 * strcmp; we just have to be careful to use the interned strings.
307 *
308 * The values of paths:
309 * * either a pointer to a merged_info, or a conflict_info struct
310 * * merged_info contains all relevant information for a
311 * non-conflicted entry.
312 * * conflict_info contains a merged_info, plus any additional
313 * information about a conflict such as the higher orders stages
314 * involved and the names of the paths those came from (handy
315 * once renames get involved).
316 * * a path may start "conflicted" (i.e. point to a conflict_info)
317 * and then a later step (e.g. three-way content merge) determines
318 * it can be cleanly merged, at which point it'll be marked clean
319 * and the algorithm will ignore any data outside the contained
320 * merged_info for that entry
321 * * If an entry remains conflicted, the merged_info portion of a
322 * conflict_info will later be filled with whatever version of
323 * the file should be placed in the working directory (e.g. an
324 * as-merged-as-possible variation that contains conflict markers).
325 */
328 /*
329 * conflicted: a subset of keys->values from "paths"
330 *
331 * conflicted is basically an optimization between process_entries()
332 * and record_conflicted_index_entries(); the latter could loop over
333 * ALL the entries in paths AGAIN and look for the ones that are
334 * still conflicted, but since process_entries() has to loop over
335 * all of them, it saves the ones it couldn't resolve in this strmap
336 * so that record_conflicted_index_entries() can iterate just the
337 * relevant entries.
338 */
341 /*
342 * pool: memory pool for fast allocation/deallocation
343 *
344 * We allocate room for lots of filenames and auxiliary data
345 * structures in merge_options_internal, and it tends to all be
346 * freed together too. Using a memory pool for these provides a
347 * nice speedup.
348 */
351 /*
352 * output: special messages and conflict notices for various paths
353 *
354 * This is a map of pathnames (a subset of the keys in "paths" above)
355 * to strbufs. It gathers various warning/conflict/notice messages
356 * for later processing.
357 */
360 /*
361 * renames: various data relating to rename detection
362 */
365 /*
366 * attr_index: hacky minimal index used for renormalization
367 *
368 * renormalization code _requires_ an index, though it only needs to
369 * find a .gitattributes file within the index. So, when
370 * renormalization is important, we create a special index with just
371 * that one file.
372 */
375 /*
376 * current_dir_name, toplevel_dir: temporary vars
377 *
378 * These are used in collect_merge_info_callback(), and will set the
379 * various merged_info.directory_name for the various paths we get;
380 * see documentation for that variable and the requirements placed on
381 * that field.
382 */
386 /* call_depth: recursion level counter for merging merge bases */
388 };
393 };
396 /* if is_null, ignore result. otherwise result has oid & mode */
400 /*
401 * clean: whether the path in question is cleanly merged.
402 *
403 * see conflict_info.merged for more details.
404 */
407 /*
408 * basename_offset: offset of basename of path.
409 *
410 * perf optimization to avoid recomputing offset of final '/'
411 * character in pathname (0 if no '/' in pathname).
412 */
415 /*
416 * directory_name: containing directory name.
417 *
418 * Note that we assume directory_name is constructed such that
419 * strcmp(dir1_name, dir2_name) == 0 iff dir1_name == dir2_name,
420 * i.e. string equality is equivalent to pointer equality. For this
421 * to hold, we have to be careful setting directory_name.
422 */
424 };
427 /*
428 * merged: the version of the path that will be written to working tree
429 *
430 * WARNING: It is critical to check merged.clean and ensure it is 0
431 * before reading any conflict_info fields outside of merged.
432 * Allocated merge_info structs will always have clean set to 1.
433 * Allocated conflict_info structs will have merged.clean set to 0
434 * initially. The merged.clean field is how we know if it is safe
435 * to access other parts of conflict_info besides merged; if a
436 * conflict_info's merged.clean is changed to 1, the rest of the
437 * algorithm is not allowed to look at anything outside of the
438 * merged member anymore.
439 */
442 /* oids & modes from each of the three trees for this path */
445 /* pathnames for each stage; may differ due to rename detection */
448 /* Whether this path is/was involved in a directory/file conflict */
451 /*
452 * Whether this path is/was involved in a non-content conflict other
453 * than a directory/file conflict (e.g. rename/rename, rename/delete,
454 * file location based on possible directory rename).
455 */
458 /*
459 * For filemask and dirmask, the ith bit corresponds to whether the
460 * ith entry is a file (filemask) or a directory (dirmask). Thus,
461 * filemask & dirmask is always zero, and filemask | dirmask is at
462 * most 7 but can be less when a path does not appear as either a
463 * file or a directory on at least one side of history.
464 *
465 * Note that these masks are related to enum merge_side, as the ith
466 * entry corresponds to side i.
467 *
468 * These values come from a traverse_trees() call; more info may be
469 * found looking at tree-walk.h's struct traverse_info,
470 * particularly the documentation above the "fn" member (note that
471 * filemask = mask & ~dirmask from that documentation).
472 */
476 /*
477 * Optimization to track which stages match, to avoid the need to
478 * recompute it in multiple steps. Either 0 or at least 2 bits are
479 * set; if at least 2 bits are set, their corresponding stages match.
480 */
482 };
484 /*** Function Grouping: various utility functions ***/
486 /*
487 * For the next three macros, see warning for conflict_info.merged.
488 *
489 * In each of the below, mi is a struct merged_info*, and ci was defined
490 * as a struct conflict_info* (but we need to verify ci isn't actually
491 * pointed at a struct merged_info*).
492 *
493 * INITIALIZE_CI: Assign ci to mi but only if it's safe; set to NULL otherwise.
494 * VERIFY_CI: Ensure that something we assigned to a conflict_info* is one.
495 * ASSIGN_AND_VERIFY_CI: Similar to VERIFY_CI but do assignment first.
496 */
497 #define INITIALIZE_CI(ci, mi) do { \
498 (ci) = (!(mi) || (mi)->clean) ? NULL : (struct conflict_info *)(mi); \
499 } while (0)
500 #define VERIFY_CI(ci) assert(ci && !ci->merged.clean);
501 #define ASSIGN_AND_VERIFY_CI(ci, mi) do { \
502 (ci) = (struct conflict_info *)(mi); \
503 assert((ci) && !(mi)->clean); \
504 } while (0)
507 {
513 }
514 }
518 {
530 /*
531 * All keys and values in opti->conflicted are a subset of those in
532 * opti->paths. We don't want to deallocate anything twice, so we
533 * don't free the keys and we pass 0 for free_values.
534 */
540 /* Free memory used by various renames maps */
555 }
556 }
561 }
569 /* Release and free each strbuf found in output */
573 /*
574 * While strictly speaking we don't need to free(sb)
575 * here because we could pass free_values=1 when
576 * calling strmap_clear() on opti->output, that would
577 * require strmap_clear to do another
578 * strmap_for_each_entry() loop, so we just free it
579 * while we're iterating anyway.
580 */
582 }
584 }
588 /* Clean out callback_data as well. */
591 }
595 {
608 }
614 {
624 }
628 }
635 {
647 }
658 /* Start with the specified prefix */
662 /* Copy tmp to sb, adding spaces after newlines */
665 /* Copy next character from tmp to sb */
668 /* If we copied a newline, add a space */
671 }
672 /* Update length and ensure it's NUL-terminated */
677 }
679 /* Add final newline character to sb */
681 }
685 {
686 /* Similar to alloc_filespec(), but allocate from pool and reuse path */
695 }
701 {
702 /* Same code as diff_queue(), except allocate from pool */
711 }
713 /* add a string to a strbuf, but converting "/" to "_" */
715 {
721 }
726 {
738 }
741 }
743 /*** Function Grouping: functions related to collect_merge_info() ***/
750 {
772 }
774 /*
775 * Much like traverse_trees(), BUT:
776 * - read all the tree entries FIRST, saving them
777 * - note that the above step provides an opportunity to compute necessary
778 * additional details before the "real" traversal
779 * - loop through the saved entries and call the original callback on them
780 */
785 {
787 traverse_callback_t old_fn;
811 info);
812 }
819 }
833 {
834 /* result->util is void*, so mi is a convenience typed variable */
860 }
865 /*
866 * Assume is_null for now, but if we have entries
867 * under the directory then when it is complete in
868 * write_completed_directory() it'll update this.
869 * Also, for D/F conflicts, we have to handle the
870 * directory first, then clear this bit and process
871 * the file to see how it is handled -- that occurs
872 * near the top of process_entry().
873 */
875 }
879 }
888 {
896 pathname))
904 /*
905 * If pathname is found in cached_irrelevant[side] due to
906 * previous pick but for this commit content is relevant,
907 * then we need to remove it from cached_irrelevant.
908 */
910 /* strset_remove is no-op if strset doesn't have key */
912 pathname);
914 /*
915 * We do not need to re-detect renames for paths that we already
916 * know the pairing, i.e. for cached_pairs (or
917 * cached_irrelevant). However, handle_deferred_entries() needs
918 * to loop over the union of keys from relevant_sources[side] and
919 * cached_pairs[side], so for simplicity we set relevant_sources
920 * for all the cached_pairs too and then strip them back out in
921 * prune_cached_from_relevant() at the beginning of
922 * detect_regular_renames().
923 */
925 /* content_relevant trumps location_relevant */
928 }
930 /*
931 * Avoid creating pair if we've already cached rename results.
932 * Note that we do this after setting relevant_sources[side]
933 * as noted in the comment above.
934 */
938 }
945 }
954 {
958 /*
959 * Update dir_rename_mask (determines ignore-rename-source validity)
960 *
961 * dir_rename_mask helps us keep track of when directory rename
962 * detection may be relevant. Basically, whenver a directory is
963 * removed on one side of history, and a file is added to that
964 * directory on the other side of history, directory rename
965 * detection is relevant (meaning we have to detect renames for all
966 * files within that directory to deduce where the directory
967 * moved). Also, whenever a directory needs directory rename
968 * detection, due to the "majority rules" choice for where to move
969 * it (see t6423 testcase 1f), we also need to detect renames for
970 * all files within subdirectories of that directory as well.
971 *
972 * Here we haven't looked at files within the directory yet, we are
973 * just looking at the directory itself. So, if we aren't yet in
974 * a case where a parent directory needed directory rename detection
975 * (i.e. dir_rename_mask != 0x07), and if the directory was removed
976 * on one side of history, record the mask of the other side of
977 * history in dir_rename_mask.
978 */
981 /* simple sanity check */
984 /* update dir_rename_mask; have it record mask of new side */
986 }
988 /* Update dirs_removed, as needed */
990 /* absent_mask = 0x07 - dirmask; sides = absent_mask/2 */
994 /*
995 * Record relevance of this directory. However, note that
996 * when collect_merge_info_callback() recurses into this
997 * directory and calls collect_rename_info() on paths
998 * within that directory, if we find a path that was added
999 * to this directory on the other side of history, we will
1000 * upgrade this value to RELEVANT_FOR_SELF; see below.
1001 */
1004 relevance);
1007 relevance);
1008 }
1010 /*
1011 * Here's the block that potentially upgrades to RELEVANT_FOR_SELF.
1012 * When we run across a file added to a directory. In such a case,
1013 * find the directory of the file and upgrade its relevance.
1014 */
1017 /*
1018 * Need directory rename for parent directory on other side
1019 * of history from added file. Thus
1020 * side = (~filemask & 0x06) >> 1
1021 * or
1022 * side = 3 - (filemask/2).
1023 */
1026 RELEVANT_FOR_SELF);
1027 }
1035 /* Check for deletion on side */
1041 /* Check for addition on side */
1046 }
1047 }
1054 {
1055 /*
1056 * n is 3. Always.
1057 * common ancestor (mbase) has mask 1, and stored in index 0 of names
1058 * head of side 1 (side1) has mask 2, and stored in index 1 of names
1059 * head of side 2 (side2) has mask 4, and stored in index 2 of names
1060 */
1086 /*
1087 * Note: When a path is a file on one side of history and a directory
1088 * in another, we have a directory/file conflict. In such cases, if
1089 * the conflict doesn't resolve from renames and deletions, then we
1090 * always leave directories where they are and move files out of the
1091 * way. Thus, while struct conflict_info has a df_conflict field to
1092 * track such conflicts, we ignore that field for any directories at
1093 * a path and only pay attention to it for files at the given path.
1094 * The fact that we leave directories were they are also means that
1095 * we do not need to worry about getting additional df_conflict
1096 * information propagated from parent directories down to children
1097 * (unlike, say traverse_trees_recursive() in unpack-trees.c, which
1098 * sets a newinfo.df_conflicts field specifically to propagate it).
1099 */
1102 /* n = 3 is a fundamental assumption. */
1106 /*
1107 * A bunch of sanity checks verifying that traverse_trees() calls
1108 * us the way I expect. Could just remove these at some point,
1109 * though maybe they are helpful to future code readers.
1110 */
1117 /* Determine match_mask */
1125 /*
1126 * Get the name of the relevant filepath, which we'll pass to
1127 * setup_path_info() for tracking.
1128 */
1131 p++;
1134 /* +1 in both of the following lines to include the NUL byte */
1138 /*
1139 * If mbase, side1, and side2 all match, we can resolve early. Even
1140 * if these are trees, there will be no renames or anything
1141 * underneath.
1142 */
1144 /* mbase, side1, & side2 all match; use mbase as resolution */
1149 }
1151 /*
1152 * If the sides match, and all three paths are present and are
1153 * files, then we can take either as the resolution. We can't do
1154 * this with trees, because there may be rename sources from the
1155 * merge_base.
1156 */
1158 /* use side1 (== side2) version as resolution */
1163 }
1165 /*
1166 * If side1 matches mbase and all three paths are present and are
1167 * files, then we can use side2 as the resolution. We cannot
1168 * necessarily do so this for trees, because there may be rename
1169 * destinations within side2.
1170 */
1172 /* use side2 version as resolution */
1177 }
1179 /* Similar to above but swapping sides 1 and 2 */
1181 /* use side1 version as resolution */
1186 }
1188 /*
1189 * Sometimes we can tell that a source path need not be included in
1190 * rename detection -- namely, whenever either
1191 * side1_matches_mbase && side2_null
1192 * or
1193 * side2_matches_mbase && side1_null
1194 * However, we call collect_rename_info() even in those cases,
1195 * because exact renames are cheap and would let us remove both a
1196 * source and destination path. We'll cull the unneeded sources
1197 * later.
1198 */
1202 /*
1203 * None of the special cases above matched, so we have a
1204 * provisional conflict. (Rename detection might allow us to
1205 * unconflict some more cases, but that comes later so all we can
1206 * do now is record the different non-null file hashes.)
1207 */
1215 /* If dirmask, recurse into subdirectories */
1223 /*
1224 * Check for whether we can avoid recursing due to one side
1225 * matching the merge base. The side that does NOT match is
1226 * the one that might have a rename destination we need.
1227 */
1232 /*
1233 * Also defer recursing into new directories; set up a
1234 * few variables to let us do so.
1235 */
1238 }
1248 }
1250 /* We need to recurse */
1257 /*
1258 * If this directory we are about to recurse into cared about
1259 * its parent directory (the current directory) having a D/F
1260 * conflict, then we'd propagate the masks in this way:
1261 * newinfo.df_conflicts |= (mask & ~dirmask);
1262 * But we don't worry about propagating D/F conflicts. (See
1263 * comment near setting of local df_conflict variable near
1264 * the beginning of this function).
1265 */
1280 }
1282 }
1289 else
1299 }
1302 }
1305 {
1314 }
1318 {
1330 /* Loop over the set of paths we need to know rename info for */
1336 /*
1337 * If we don't know delete/rename info for this path,
1338 * then we need to recurse into all trees to get all
1339 * adds to make sure we have it.
1340 */
1349 }
1351 /* If this is a delete, we have enough info already */
1356 /* If we already walked the rename target, we're good */
1360 /*
1361 * Otherwise, we need to get a list of directories that
1362 * will need to be recursed into to get this
1363 * rename_target.
1364 */
1369 dir))
1372 dir);
1373 }
1375 }
1377 /*
1378 * We need to recurse into any directories in
1379 * possible_trivial_merges[side] found in target_dirs[side].
1380 * But when we recurse, we may need to queue up some of the
1381 * subdirectories for possible_trivial_merges[side]. Since
1382 * we can't safely iterate through a hashmap while also adding
1383 * entries, move the entries into 'copy', iterate over 'copy',
1384 * and then we'll also iterate anything added into
1385 * possible_trivial_merges[side] once this loop is done.
1386 */
1407 path)) {
1410 }
1429 }
1430 }
1438 else
1446 }
1458 path));
1460 }
1463 }
1465 /*
1466 * The choice of wanted_factor here does not affect
1467 * correctness, only performance. When the
1468 * path_count_after / path_count_before
1469 * ratio is high, redoing after renames is a big
1470 * performance boost. I suspect that redoing is a wash
1471 * somewhere near a value of 2, and below that redoing will
1472 * slow things down. I applied a fudge factor and picked
1473 * 3; see the commit message when this was introduced for
1474 * back of the envelope calculations for this ratio.
1475 */
1478 /* We should only redo collect_merge_info one time */
1484 }
1488 }
1494 {
1520 }
1522 /*** Function Grouping: functions related to threeway content merges ***/
1529 {
1544 /* get all revisions that merge commit a */
1548 /* FIXME: can't handle linked worktrees in submodules yet */
1552 /* save all revisions from the above list that contain b */
1559 }
1562 /* Now we've got all merges that contain a and b. Prune all
1563 * merges that contain another found merge and save them in
1564 * result.
1565 */
1575 }
1576 }
1580 }
1584 }
1592 {
1603 /* store fallback answer in result in case we fail */
1606 /* we can not handle deletion conflicts */
1617 path);
1619 }
1626 path);
1628 }
1630 /* check whether both changes are forward */
1636 path);
1638 }
1640 /* Case #1: a is contained in b or vice versa */
1648 }
1656 }
1658 /*
1659 * Case #2: There are one or more merges that contain a and b in
1660 * the submodule. If there is only one, then present it as a
1661 * suggestion to the user, but leave it marked unmerged so the
1662 * user needs to confirm the resolution.
1663 */
1665 /* Skip the search if makes no sense to the calling context. */
1669 /* find commit which merges them */
1701 }
1704 cleanup:
1707 }
1710 {
1711 /*
1712 * The renormalize_buffer() functions require attributes, and
1713 * annoyingly those can only be read from the working tree or from
1714 * an index_state. merge-ort doesn't have an index_state, so we
1715 * generate a fake one containing only attribute information.
1716 */
1762 }
1763 }
1764 }
1774 {
1801 }
1802 }
1813 }
1834 }
1844 {
1845 /*
1846 * path is the target location where we want to put the file, and
1847 * is used to determine any normalization rules in ll_merge.
1848 *
1849 * The normal case is that path and all entries in pathnames are
1850 * identical, though renames can affect which path we got one of
1851 * the three blobs to merge on various sides of history.
1852 *
1853 * extra_marker_size is the amount to extend conflict markers in
1854 * ll_merge; this is neeed if we have content merges of content
1855 * merges, which happens for example with rename/rename(2to1) and
1856 * rename/add conflicts.
1857 */
1860 /*
1861 * handle_content_merge() needs both files to be of the same type, i.e.
1862 * both files OR both submodules OR both symlinks. Conflicting types
1863 * needs to be handled elsewhere.
1864 */
1867 /* Merge modes */
1871 /* must be the 100644/100755 case */
1875 /*
1876 * FIXME: If opt->priv->call_depth && !clean, then we really
1877 * should not make result->mode match either a->mode or
1878 * b->mode; that causes t6036 "check conflicting mode for
1879 * regular file" to fail. It would be best to use some other
1880 * mode, but we'll confuse all kinds of stuff if we use one
1881 * where S_ISREG(result->mode) isn't true, and if we use
1882 * something like 0100666, then tree-walk.c's calls to
1883 * canon_mode() will just normalize that to 100644 for us and
1884 * thus not solve anything.
1885 *
1886 * Figure out if there's some kind of way we can work around
1887 * this...
1888 */
1889 }
1891 /*
1892 * Trivial oid merge.
1893 *
1894 * Note: While one might assume that the next four lines would
1895 * be unnecessary due to the fact that match_mask is often
1896 * setup and already handled, renames don't always take care
1897 * of that.
1898 */
1904 /* Remaining rules depend on file vs. submodule vs. symlink. */
1906 mmbuffer_t result_buf;
1910 /*
1911 * If 'o' is different type, treat it as null so we do a
1912 * two-way merge.
1913 */
1929 path);
1944 }
1962 }
1963 }
1969 }
1971 /*** Function Grouping: functions related to detect_and_process_renames(), ***
1972 *** which are split into directory and regular rename detection sections. ***/
1974 /*** Function Grouping: functions related to directory rename detection ***/
1979 };
1981 /*
1982 * Return a new string that replaces the beginning portion (which matches
1983 * rename_info->key), with rename_info->util.new_dir. In perl-speak:
1984 * new_path_name = (old_path =~ s/rename_info->key/rename_info->value/);
1985 * NOTE:
1986 * Caller must ensure that old_path starts with rename_info->key + '/'.
1987 */
1990 {
1998 /*
1999 * If someone renamed/merged a subdirectory into the root
2000 * directory (e.g. 'some/subdir' -> ''), then we want to
2001 * avoid returning
2002 * '' + '/filename'
2003 * as the rename; we need to make old_path + oldlen advance
2004 * past the '/' character.
2005 */
2006 oldlen++;
2014 }
2017 {
2024 }
2026 /*
2027 * See if there is a directory rename for path, and if there are any file
2028 * level conflicts on the given side for the renamed location. If there is
2029 * a rename and there are no conflicts, return the new name. Otherwise,
2030 * return NULL.
2031 */
2037 {
2043 /*
2044 * entry has the mapping of old directory name to new directory name
2045 * that we want to apply to path.
2046 */
2051 /*
2052 * The caller needs to have ensured that it has pre-populated
2053 * collisions with all paths that map to new_path. Do a quick check
2054 * to ensure that's the case.
2055 */
2060 /*
2061 * Check for one-sided add/add/.../add conflicts, i.e.
2062 * where implicit renames from the other side doing
2063 * directory rename(s) can affect this side of history
2064 * to put multiple paths into the same location. Warn
2065 * and bail on directory renames for such paths.
2066 */
2075 "at %s in the way of implicit directory rename(s) "
2085 "than one path to %s; implicit directory renames "
2089 }
2091 /* Free memory we no longer need */
2096 }
2099 }
2104 {
2109 /*
2110 * Collapse
2111 * dir_rename_count: old_directory -> {new_directory -> count}
2112 * down to
2113 * dir_renames: old_directory -> best_new_directory
2114 * where best_new_directory is the one with the unique highest count.
2115 */
2134 }
2135 }
2143 "Unclear where to rename %s to; it was "
2144 "renamed to multiple other directories, with "
2145 "no destination getting a majority of the "
2147 source_dir);
2152 }
2153 }
2154 }
2157 {
2169 }
2174 }
2176 }
2180 {
2190 }
2193 }
2198 {
2205 /*
2206 * Multiple files can be mapped to the same path due to directory
2207 * renames done by the other side of history. Since that other
2208 * side of history could have merged multiple directories into one,
2209 * if our side of history added the same file basename to each of
2210 * those directories, then all N of them would get implicitly
2211 * renamed by the directory rename detection into the same path,
2212 * and we'd get an add/add/.../add conflict, and all those adds
2213 * from *this* side of history. This is not representable in the
2214 * index, and users aren't going to easily be able to make sense of
2215 * it. So we need to provide a good warning about what's
2216 * happening, and fall back to no-directory-rename detection
2217 * behavior for those paths.
2218 *
2219 * See testcases 9e and all of section 5 from t6043 for examples.
2220 */
2242 }
2245 }
2246 }
2255 {
2266 /* old_dir = rename_info->key; */
2269 /*
2270 * This next part is a little weird. We do not want to do an
2271 * implicit rename into a directory we renamed on our side, because
2272 * that will result in a spurious rename/rename(1to2) conflict. An
2273 * example:
2274 * Base commit: dumbdir/afile, otherdir/bfile
2275 * Side 1: smrtdir/afile, otherdir/bfile
2276 * Side 2: dumbdir/afile, dumbdir/bfile
2277 * Here, while working on Side 1, we could notice that otherdir was
2278 * renamed/merged to dumbdir, and change the diff_filepair for
2279 * otherdir/bfile into a rename into dumbdir/bfile. However, Side
2280 * 2 will notice the rename from dumbdir to smrtdir, and do the
2281 * transitive rename to move it from dumbdir/bfile to
2282 * smrtdir/bfile. That gives us bfile in dumbdir vs being in
2283 * smrtdir, a rename/rename(1to2) conflict. We really just want
2284 * the file to end up in smrtdir. And the way to achieve that is
2285 * to not let Side1 do the rename to dumbdir, since we know that is
2286 * the source of one of our directory renames.
2287 *
2288 * That's why otherinfo and dir_rename_exclusions is here.
2289 *
2290 * As it turns out, this also prevents N-way transient rename
2291 * confusion; See testcases 9c and 9d of t6043.
2292 */
2300 }
2307 }
2312 {
2313 /*
2314 * The basic idea is to get the conflict_info from opt->priv->paths
2315 * at old path, and insert it into new_path; basically just this:
2316 * ci = strmap_get(&opt->priv->paths, old_path);
2317 * strmap_remove(&opt->priv->paths, old_path, 0);
2318 * strmap_put(&opt->priv->paths, new_path, ci);
2319 * However, there are some factors complicating this:
2320 * - opt->priv->paths may already have an entry at new_path
2321 * - Each ci tracks its containing directory, so we need to
2322 * update that
2323 * - If another ci has the same containing directory, then
2324 * the two char*'s MUST point to the same location. See the
2325 * comment in struct merged_info. strcmp equality is not
2326 * enough; we need pointer equality.
2327 * - opt->priv->paths must hold the parent directories of any
2328 * entries that are added. So, if this directory rename
2329 * causes entirely new directories, we must recursively add
2330 * parent directories.
2331 * - For each parent directory added to opt->priv->paths, we
2332 * also need to get its parent directory stored in its
2333 * conflict_info->merged.directory_name with all the same
2334 * requirements about pointer equality.
2335 */
2350 /* Find parent directories missing from opt->priv->paths */
2356 /* Find the parent directory of cur_path */
2360 cur_path,
2365 }
2367 /* Look it up in opt->priv->paths */
2372 }
2374 /* Record this is one of the directories we need to insert */
2377 }
2379 /* Traverse dirs_to_insert and insert them into opt->priv->paths */
2388 /* len+1 because of trailing '/' character */
2394 }
2403 /* Now, finally update ci and stick it into opt->priv->paths */
2409 /* Place ci back into opt->priv->paths, but at new_path */
2414 /* A few sanity checks */
2420 /* Copy stuff from ci into new_ci */
2430 }
2433 /* Notify user of updated path */
2437 "directory that was renamed in %s; moving "
2441 else
2444 "inside a directory that was renamed in %s; "
2449 /*
2450 * opt->detect_directory_renames has the value
2451 * MERGE_DIRECTORY_RENAMES_CONFLICT, so mark these as conflicts.
2452 */
2457 "inside a directory that was renamed in %s, "
2458 "suggesting it should perhaps be moved to "
2462 else
2465 "in %s, inside a directory that was renamed "
2466 "in %s, suggesting it should perhaps be "
2470 }
2472 /*
2473 * Finally, record the new location.
2474 */
2476 }
2478 /*** Function Grouping: functions related to regular rename detection ***/
2482 {
2500 }
2505 }
2507 /*
2508 * If pair->one->path isn't in opt->priv->paths, that means
2509 * that either directory rename detection removed that
2510 * path, or a parent directory of oldpath was resolved and
2511 * we don't even need the rename; in either case, we can
2512 * skip it. If oldinfo->merged.clean, then the other side
2513 * of history had no changes to oldpath and we don't need
2514 * the rename and can skip it.
2515 */
2519 /*
2520 * diff_filepairs have copies of pathnames, thus we have to
2521 * use standard 'strcmp()' (negated) instead of '=='.
2522 */
2525 /* Handle rename/rename(1to2) or rename/rename(1to1) */
2547 /* Both sides renamed the same way */
2552 /* Mark base as resolved by removal */
2556 /*
2557 * Disable remembering renames optimization;
2558 * rename/rename(1to1) is incredibly rare, and
2559 * just disabling the optimization is easier
2560 * than purging cached_pairs,
2561 * cached_target_names, and dir_rename_counts.
2562 */
2566 /* We handled both renames, i.e. i+1 handled */
2567 i++;
2568 /* Move to next rename */
2570 }
2572 /* This is a rename/rename(1to2) */
2578 pathnames,
2587 /*
2588 * Getting here means we were attempting to
2589 * merge a binary blob.
2590 *
2591 * Since we can't merge binaries,
2592 * handle_content_merge() just takes one
2593 * side. But we don't want to copy the
2594 * contents of one side to both paths. We
2595 * used the contents of side1 above for
2596 * side1->stages, let's use the contents of
2597 * side2 for side2->stages below.
2598 */
2601 }
2606 /*
2607 * TODO: For renames we normally remove the path at the
2608 * old name. It would thus seem consistent to do the
2609 * same for rename/rename(1to2) cases, but we haven't
2610 * done so traditionally and a number of the regression
2611 * tests now encode an expectation that the file is
2612 * left there at stage 1. If we ever decide to change
2613 * this, add the following two lines here:
2614 * base->merged.is_null = 1;
2615 * base->merged.clean = 1;
2616 * and remove the setting of base->path_conflict to 1.
2617 */
2628 }
2642 /*
2643 * special handling so later blocks can handle this...
2644 *
2645 * if type_changed && collision are both true, then this
2646 * was really a double rename, but one side wasn't
2647 * detected due to lack of break detection. I.e.
2648 * something like
2649 * orig: has normal file 'foo'
2650 * side1: renames 'foo' to 'bar', adds 'foo' symlink
2651 * side2: renames 'foo' to 'bar'
2652 * In this case, the foo->bar rename on side1 won't be
2653 * detected because the new symlink named 'foo' is
2654 * there and we don't do break detection. But we detect
2655 * this here because we don't want to merge the content
2656 * of the foo symlink with the foo->bar file, so we
2657 * have some logic to handle this special case. The
2658 * easiest way to do that is make 'bar' on side1 not
2659 * be considered a colliding file but the other part
2660 * of a normal rename. If the file is very different,
2661 * well we're going to get content merge conflicts
2662 * anyway so it doesn't hurt. And if the colliding
2663 * file also has a different type, that'll be handled
2664 * by the content merge logic in process_entry() too.
2665 *
2666 * See also t6430, 'rename vs. rename/symlink'
2667 */
2669 }
2677 }
2678 }
2682 /* Need to check for special types of rename conflicts... */
2684 /* collision: rename/add or rename/rename(2to1) */
2707 pathnames,
2716 "collision): rename of %s -> %s has "
2717 "content conflicts AND collides "
2718 "with another path; this may result "
2721 }
2723 /*
2724 * rename/add/delete or rename/rename(2to1)/delete:
2725 * since oldpath was deleted on the side that didn't
2726 * do the rename, there's not much of a content merge
2727 * we can do for the rename. oldinfo->merged.is_null
2728 * was already set, so we just leave things as-is so
2729 * they look like an add/add conflict.
2730 */
2738 /*
2739 * a few different cases...start by copying the
2740 * existing stage(s) from oldinfo over the newinfo
2741 * and update the pathname(s).
2742 */
2748 /* rename vs. typechange */
2749 /* Mark the original as resolved by removal */
2755 /* rename/delete */
2763 /* normal rename */
2769 }
2770 }
2773 /* Mark the original as resolved by removal */
2776 }
2778 }
2781 }
2785 {
2788 }
2791 {
2796 }
2799 {
2800 /*
2801 * A simplified version of diff_resolve_rename_copy(); would probably
2802 * just use that function but it's static...
2803 */
2816 }
2817 }
2821 {
2822 /* Reason for this function described in add_pair() */
2826 /* Remove from relevant_sources all entries in cached_pairs[side] */
2830 }
2831 /* Remove from relevant_sources all entries in cached_irrelevant[side] */
2835 }
2836 }
2841 {
2845 /*
2846 * Add to side_pairs all entries from renames->cached_pairs[side_index].
2847 * (Info in cached_irrelevant[side_index] is not relevant here.)
2848 */
2856 /*
2857 * cached_pairs has *copies* of old_name and new_name,
2858 * because it has to persist across merges. Since
2859 * pool_alloc_filespec() will just re-use the existing
2860 * filenames, which will also get re-used by
2861 * opt->priv->paths if they become renames, and then
2862 * get freed at the end of the merge, that would leave
2863 * the copy in cached_pairs dangling. Avoid this by
2864 * making a copy here.
2865 */
2869 /* We don't care about oid/mode, only filenames and status */
2874 }
2875 }
2882 {
2890 else
2892 }
2898 {
2902 /*
2903 * Directory renames happen on the other side of history from
2904 * the side that adds new files to the old directory.
2905 */
2914 }
2917 }
2920 /*
2921 * If we already had this delete, we'll just set it's value
2922 * to NULL again, so no harm.
2923 */
2928 else
2935 }
2936 }
2939 {
2944 }
2946 /* Call diffcore_rename() to update deleted/added pairs into rename pairs */
2949 {
2955 /*
2956 * No rename detection needed for this side, but we still need
2957 * to make sure 'adds' are marked correctly in case the other
2958 * side had directory renames.
2959 */
2962 }
3001 }
3003 /*
3004 * Get information of all renames which occurred in 'side_pairs', making use
3005 * of any implicit directory renames in side_dir_renames (also making use of
3006 * implicit directory renames rename_exclusions as needed by
3007 * check_for_directory_rename()). Add all (updated) renames into result.
3008 */
3014 {
3033 }
3036 side_index,
3037 dir_renames_for_side,
3038 rename_exclusions,
3046 }
3051 /*
3052 * p->score comes back from diffcore_rename_extended() with
3053 * the similarity of the renamed file. The similarity is
3054 * was used to determine that the two files were related
3055 * and are a rename, which we have already used, but beyond
3056 * that we have no use for the similarity. So p->score is
3057 * now irrelevant. However, process_renames() will need to
3058 * know which side of the merge this rename was associated
3059 * with, so overwrite p->score with that value.
3060 */
3063 }
3065 /* Free each value in the collisions map */
3069 }
3070 /*
3071 * In compute_collisions(), we set collisions.strdup_strings to 0
3072 * so that we wouldn't have to make another copy of the new_path
3073 * allocated by apply_dir_rename(). But now that we've used them
3074 * and have no other references to these strings, it is time to
3075 * deallocate them.
3076 */
3080 }
3086 {
3103 /* Cache the renames, we found */
3108 }
3109 }
3111 /* Restart the merge with the cached renames */
3115 }
3121 need_dir_renames =
3130 }
3150 cleanup:
3151 /*
3152 * Free now unneeded filepairs, which would have been handled
3153 * in collect_renames() normally but we skipped that code.
3154 */
3163 }
3164 }
3166 simple_cleanup:
3167 /* Free memory for renames->pairs[] and combined */
3171 }
3178 }
3181 }
3183 /*** Function Grouping: functions related to process_entries() ***/
3186 {
3189 /*
3190 * Here we only care that entries for directories appear adjacent
3191 * to and before files underneath the directory. We can achieve
3192 * that by pretending to add a trailing slash to every file and
3193 * then sorting. In other words, we do not want the natural
3194 * sorting of
3195 * foo
3196 * foo.txt
3197 * foo/bar
3198 * Instead, we want "foo" to sort as though it were "foo/", so that
3199 * we instead get
3200 * foo.txt
3201 * foo
3202 * foo/bar
3203 * To achieve this, we basically implement our own strcmp, except that
3204 * if we get to the end of either string instead of comparing NUL to
3205 * another character, we compare '/' to it.
3206 *
3207 * If this unusual "sort as though '/' were appended" perplexes
3208 * you, perhaps it will help to note that this is not the final
3209 * sort. write_tree() will sort again without the trailing slash
3210 * magic, but just on paths immediately under a given tree.
3211 *
3212 * The reason to not use df_name_compare directly was that it was
3213 * just too expensive (we don't have the string lengths handy), so
3214 * it was reimplemented.
3215 */
3217 /*
3218 * NOTE: This function will never be called with two equal strings,
3219 * because it is used to sort the keys of a strmap, and strmaps have
3220 * unique keys by construction. That simplifies our c1==c2 handling
3221 * below.
3222 */
3225 one++;
3226 two++;
3227 }
3233 /* Getting here means one is a leading directory of the other */
3237 }
3242 {
3252 }
3255 }
3261 {
3278 /*
3279 * Note: binary | is used so that both renormalizations are
3280 * performed. Comparison can be skipped if both files are
3281 * unchanged since their sha1s have already been compared.
3282 */
3288 error_return:
3292 }
3295 /*
3296 * versions: list of (basename -> version_info)
3297 *
3298 * The basenames are in reverse lexicographic order of full pathnames,
3299 * as processed in process_entries(). This puts all entries within
3300 * a directory together, and covers the directory itself after
3301 * everything within it, allowing us to write subtrees before needing
3302 * to record information for the tree itself.
3303 */
3306 /*
3307 * offsets: list of (full relative path directories -> integer offsets)
3308 *
3309 * Since versions contains basenames from files in multiple different
3310 * directories, we need to know which entries in versions correspond
3311 * to which directories. Values of e.g.
3312 * "" 0
3313 * src 2
3314 * src/moduleA 5
3315 * Would mean that entries 0-1 of versions are files in the toplevel
3316 * directory, entries 2-4 are files under src/, and the remaining
3317 * entries starting at index 5 are files under src/moduleA/.
3318 */
3321 /*
3322 * last_directory: directory that previously processed file found in
3323 *
3324 * last_directory starts NULL, but records the directory in which the
3325 * previous file was found within. As soon as
3326 * directory(current_file) != last_directory
3327 * then we need to start updating accounting in versions & offsets.
3328 * Note that last_directory is always the last path in "offsets" (or
3329 * NULL if "offsets" is empty) so this exists just for quick access.
3330 */
3333 /* last_directory_len: cached computation of strlen(last_directory) */
3335 };
3338 {
3346 }
3352 {
3361 /* No need for STABLE_QSORT -- filenames must be unique */
3364 /* Pre-allocate some space in buf */
3368 }
3371 /* Write each entry out to buf */
3379 }
3381 /* Write this object file out, and record in result_oid */
3384 }
3389 {
3393 /* nothing to record */
3400 }
3405 {
3410 /*
3411 * Some explanation of info->versions and info->offsets...
3412 *
3413 * process_entries() iterates over all relevant files AND
3414 * directories in reverse lexicographic order, and calls this
3415 * function. Thus, an example of the paths that process_entries()
3416 * could operate on (along with the directories for those paths
3417 * being shown) is:
3418 *
3419 * xtract.c ""
3420 * tokens.txt ""
3421 * src/moduleB/umm.c src/moduleB
3422 * src/moduleB/stuff.h src/moduleB
3423 * src/moduleB/baz.c src/moduleB
3424 * src/moduleB src
3425 * src/moduleA/foo.c src/moduleA
3426 * src/moduleA/bar.c src/moduleA
3427 * src/moduleA src
3428 * src ""
3429 * Makefile ""
3430 *
3431 * info->versions:
3432 *
3433 * always contains the unprocessed entries and their
3434 * version_info information. For example, after the first five
3435 * entries above, info->versions would be:
3436 *
3437 * xtract.c <xtract.c's version_info>
3438 * token.txt <token.txt's version_info>
3439 * umm.c <src/moduleB/umm.c's version_info>
3440 * stuff.h <src/moduleB/stuff.h's version_info>
3441 * baz.c <src/moduleB/baz.c's version_info>
3442 *
3443 * Once a subdirectory is completed we remove the entries in
3444 * that subdirectory from info->versions, writing it as a tree
3445 * (write_tree()). Thus, as soon as we get to src/moduleB,
3446 * info->versions would be updated to
3447 *
3448 * xtract.c <xtract.c's version_info>
3449 * token.txt <token.txt's version_info>
3450 * moduleB <src/moduleB's version_info>
3451 *
3452 * info->offsets:
3453 *
3454 * helps us track which entries in info->versions correspond to
3455 * which directories. When we are N directories deep (e.g. 4
3456 * for src/modA/submod/subdir/), we have up to N+1 unprocessed
3457 * directories (+1 because of toplevel dir). Corresponding to
3458 * the info->versions example above, after processing five entries
3459 * info->offsets will be:
3460 *
3461 * "" 0
3462 * src/moduleB 2
3463 *
3464 * which is used to know that xtract.c & token.txt are from the
3465 * toplevel dirctory, while umm.c & stuff.h & baz.c are from the
3466 * src/moduleB directory. Again, following the example above,
3467 * once we need to process src/moduleB, then info->offsets is
3468 * updated to
3469 *
3470 * "" 0
3471 * src 2
3472 *
3473 * which says that moduleB (and only moduleB so far) is in the
3474 * src directory.
3475 *
3476 * One unique thing to note about info->offsets here is that
3477 * "src" was not added to info->offsets until there was a path
3478 * (a file OR directory) immediately below src/ that got
3479 * processed.
3480 *
3481 * Since process_entry() just appends new entries to info->versions,
3482 * write_completed_directory() only needs to do work if the next path
3483 * is in a directory that is different than the last directory found
3484 * in info->offsets.
3485 */
3487 /*
3488 * If we are working with the same directory as the last entry, there
3489 * is no work to do. (See comments above the directory_name member of
3490 * struct merged_info for why we can use pointer comparison instead of
3491 * strcmp here.)
3492 */
3496 /*
3497 * If we are just starting (last_directory is NULL), or last_directory
3498 * is a prefix of the current directory, then we can just update
3499 * info->offsets to record the offset where we started this directory
3500 * and update last_directory to have quick access to it.
3501 */
3509 /*
3510 * Record the offset into info->versions where we will
3511 * start recording basenames of paths found within
3512 * new_directory_name.
3513 */
3517 }
3519 /*
3520 * The next entry that will be processed will be within
3521 * new_directory_name. Since at this point we know that
3522 * new_directory_name is within a different directory than
3523 * info->last_directory, we have all entries for info->last_directory
3524 * in info->versions and we need to create a tree object for them.
3525 */
3530 /*
3531 * Actually, we don't need to create a tree object in this
3532 * case. Whenever all files within a directory disappear
3533 * during the merge (e.g. unmodified on one side and
3534 * deleted on the other, or files were renamed elsewhere),
3535 * then we get here and the directory itself needs to be
3536 * omitted from its parent tree as well.
3537 */
3540 /*
3541 * Write out the tree to the git object directory, and also
3542 * record the mode and oid in dir_info->result.
3543 */
3548 }
3550 /*
3551 * We've now used several entries from info->versions and one entry
3552 * from info->offsets, so we get rid of those values.
3553 */
3557 /*
3558 * Now we've taken care of the completed directory, but we need to
3559 * prepare things since future entries will be in
3560 * new_directory_name. (In particular, process_entry() will be
3561 * appending new entries to info->versions.) So, we need to make
3562 * sure new_directory_name is the last entry in info->offsets.
3563 */
3570 }
3572 /* And, of course, we need to update last_directory to match. */
3575 }
3577 /* Per entry merge function */
3582 {
3587 /* ci->match_mask == 7 was handled in collect_merge_info_callback() */
3594 /* nothing else to handle */
3597 }
3602 /*
3603 * directory no longer in the way, but we do have a file we
3604 * need to place here so we need to clean away the "directory
3605 * merges to nothing" result.
3606 */
3611 /* and we want to zero out any directory-related entries */
3619 }
3621 /*
3622 * This started out as a D/F conflict, and the entries in
3623 * the competing directory were not removed by the merge as
3624 * evidenced by write_completed_directory() writing a value
3625 * to ci->merged.result.mode.
3626 */
3634 /*
3635 * If filemask is 1, we can just ignore the file as having
3636 * been deleted on both sides. We do not want to overwrite
3637 * ci->merged.result, since it stores the tree for all the
3638 * files under it.
3639 */
3643 }
3645 /*
3646 * This file still exists on at least one side, and we want
3647 * the directory to remain here, so we need to move this
3648 * path to some new location.
3649 */
3652 /* We don't really want new_ci->merged.result copied, but it'll
3653 * be overwritten below so it doesn't matter. We also don't
3654 * want any directory mode/oid values copied, but we'll zero
3655 * those out immediately. We do want the rest of ci copied.
3656 */
3663 /* zero out any entries related to directories */
3666 }
3668 /*
3669 * Find out which side this file came from; note that we
3670 * cannot just use ci->filemask, because renames could cause
3671 * the filemask to go back to 7. So we use dirmask, then
3672 * pick the opposite side's index.
3673 */
3684 /*
3685 * Zero out the filemask for the old ci. At this point, ci
3686 * was just an entry for a directory, so we don't need to
3687 * do anything more with it.
3688 */
3691 /*
3692 * Now note that we're working on the new entry (path was
3693 * updated above.
3694 */
3696 }
3698 /*
3699 * NOTE: Below there is a long switch-like if-elseif-elseif... block
3700 * which the code goes through even for the df_conflict cases
3701 * above.
3702 */
3706 /* stages[1] == stages[2] */
3710 /* determine the mask of the side that didn't match */
3723 }
3727 /* Two different items from (file/submodule/symlink) */
3729 /* Just use the version from the merge base */
3735 /* Handle by renaming one or both to separate paths. */
3753 }
3758 "different types on each side; "
3759 "renamed both of them so each can "
3761 path);
3765 "different types on each side; "
3766 "renamed one of them so each can be "
3768 path);
3769 }
3774 /* Put b into new_ci, removing a from stages */
3784 }
3786 /* Leave only a in ci, fixing stages. */
3796 }
3798 /* Insert entries into opt->priv_paths */
3804 }
3809 else
3816 /*
3817 * Do special handling for b_path since process_entry()
3818 * won't be called on it specially.
3819 */
3824 /*
3825 * Remaining code for processing this entry should
3826 * think in terms of processing a_path.
3827 */
3830 }
3832 /* Need a two-way or three-way content merge */
3853 }
3863 }
3865 /* Modify/delete */
3879 path)) {
3885 /*
3886 * This came from a rename/delete; no action to take,
3887 * but avoid printing "modify/delete" conflict notice
3888 * since the contents were not modified.
3889 */
3893 "and modified in %s. Version %s of %s left "
3897 }
3899 /* Added on one side */
3905 /* Deleted on both sides */
3911 }
3913 /*
3914 * If still conflicted, record it separately. This allows us to later
3915 * iterate over just conflicted entries when updating the index instead
3916 * of iterating over all entries.
3917 */
3921 /* Record metadata for ci->merged in dir_metadata */
3923 }
3927 {
3935 /* char *path = e->string; */
3939 /* Ignore clean entries */
3943 /* Ignore entries that don't need a content merge */
3950 /* Also don't need content merge if base matches either side */
3964 OBJECT_INFO_FOR_PREFETCH))
3966 }
3967 }
3971 }
3975 {
3981 STRING_LIST_INIT_NODUP,
3988 }
3990 /* Hack to pre-allocate plist to the desired size */
3995 /* Put every entry from paths into plist, then sort */
3999 }
4009 /*
4010 * Iterate over the items in reverse order, so we can handle paths
4011 * below a directory before needing to handle the directory itself.
4012 *
4013 * This allows us to write subtrees before we need to write trees,
4014 * and it also enables sane handling of directory/file conflicts
4015 * (because it allows us to know whether the directory is still in
4016 * the way when it is time to process the file at the same path).
4017 */
4022 /*
4023 * NOTE: mi may actually be a pointer to a conflict_info, but
4024 * we have to check mi->clean first to see if it's safe to
4025 * reassign to such a pointer type.
4026 */
4036 }
4037 }
4049 }
4056 }
4058 /*** Function Grouping: functions related to merge_switch_to_result() ***/
4063 {
4064 /* Switch the index/working copy from old to new */
4076 /*
4077 * NOTE: if this were just "git checkout" code, we would probably
4078 * read or refresh the cache and check for a conflicted index, but
4079 * builtin/merge.c or sequencer.c really needs to read the index
4080 * and check for conflicted entries before starting merging for a
4081 * good user experience (no sense waiting for merges/rebases before
4082 * erroring out), so there's no reason to duplicate that work here.
4083 */
4085 /* 2-way merge to the new branch */
4100 }
4103 {
4114 /*
4115 * We are in a conflicted state. These conflicts might be inside
4116 * sparse-directory entries, so check if any entries are outside
4117 * of the sparse-checkout cone preemptively.
4118 *
4119 * We set original_cache_nr below, but that might change if
4120 * index_name_pos() calls ask for paths within sparse directories.
4121 */
4126 }
4127 }
4129 /* If any entries have skip_worktree set, we'll have to check 'em out */
4136 /* Append every entry from conflicted into index, then sort */
4146 /*
4147 * The index will already have a stage=0 entry for this path,
4148 * because we created an as-merged-as-possible version of the
4149 * file and checkout() moved the working copy and index over
4150 * to that version.
4151 *
4152 * However, previous iterations through this loop will have
4153 * added unstaged entries to the end of the cache which
4154 * ignore the standard alphabetical ordering of cache
4155 * entries and break invariants needed for index_name_pos()
4156 * to work. However, we know the entry we want is before
4157 * those appended cache entries, so do a temporary swap on
4158 * cache_nr to only look through entries of interest.
4159 */
4170 /*
4171 * Clean paths with CE_SKIP_WORKTREE set will not be
4172 * written to the working tree by the unpack_trees()
4173 * call in checkout(). Our conflicted entries would
4174 * have appeared clean to that code since we ignored
4175 * the higher order stages. Thus, we need override
4176 * the CE_SKIP_WORKTREE bit and manually write those
4177 * files to the working disk here.
4178 */
4184 path,
4188 _("Note: %s not up to date and in way of checking out conflicted version; old copy renamed to %s"),
4192 }
4194 }
4196 /*
4197 * Mark this cache entry for removal and instead add
4198 * new stage>0 entries corresponding to the
4199 * conflicts. If there are many conflicted entries, we
4200 * want to avoid memmove'ing O(NM) entries by
4201 * inserting the new entries one at a time. So,
4202 * instead, we just add the new cache entries to the
4203 * end (ignoring normal index requirements on sort
4204 * order) and sort the index once we're all done.
4205 */
4207 }
4217 }
4218 }
4220 /*
4221 * Remove the unused cache entries (and invalidate the relevant
4222 * cache-trees), then sort the index entries to get the conflicted
4223 * entries we added to the end into their right locations.
4224 */
4226 /*
4227 * No need for STABLE_QSORT -- cmp_cache_name_compare sorts primarily
4228 * on filename and secondarily on stage, and (name, stage #) are a
4229 * unique tuple.
4230 */
4234 }
4241 {
4249 /* failure to function */
4252 }
4258 /* failure to function */
4262 }
4272 }
4286 /* Hack to pre-allocate olist to the desired size */
4290 /* Put every entry from output into olist, then sort */
4293 }
4296 /* Iterate over the items, printing them */
4301 }
4304 /* Also include needed rename limit adjustment now */
4309 }
4312 }
4316 {
4325 }
4327 /*** Function Grouping: helper functions for merge_incore_*() ***/
4332 {
4339 subtree_shift);
4340 }
4344 }
4347 {
4349 }
4354 {
4361 }
4364 {
4369 /* Sanity checks on opt */
4388 /*
4389 * detect_renames, verbosity, buffer_output, and obuf are ignored
4390 * fields that were used by "recursive" rather than "ort" -- but
4391 * sanity check them anyway.
4392 */
4402 BUG("struct merge_result passed to merge_incore_*recursive() must be zeroed or filled with values from a previous run");
4407 /*
4408 * opt->priv non-NULL means we had results from a previous
4409 * run; do a few sanity checks that user didn't mess with
4410 * it in an obvious fashion.
4411 */
4415 }
4418 /* Default to histogram diff. Actually, just hardcode it...for now. */
4421 /* Handle attr direction stuff for renormalization */
4425 /* Initialization of opt->priv, our internal merge data */
4431 }
4434 /* Initialization of various renames fields */
4445 /*
4446 * relevant_sources uses -1 for the default, because we need
4447 * to be able to distinguish not-in-strintmap from valid
4448 * relevant_source values from enum file_rename_relevance.
4449 * In particular, possibly_cache_new_pair() expects a negative
4450 * value for not-found entries.
4451 */
4461 }
4468 }
4470 /*
4471 * Although we initialize opt->priv->paths with strdup_strings=0,
4472 * that's just to avoid making yet another copy of an allocated
4473 * string. Putting the entry into paths means we are taking
4474 * ownership, so we will later free it.
4475 *
4476 * In contrast, conflicted just has a subset of keys from paths, so
4477 * we don't want to free those (it'd be a duplicate free).
4478 */
4482 /*
4483 * keys & strbufs in output will sometimes need to outlive "paths",
4484 * so it will have a copy of relevant keys. It's probably a small
4485 * subset of the overall paths that have special output.
4486 */
4490 }
4497 {
4508 /*
4509 * Handle case where previous merge operation did not want cache to
4510 * take effect, e.g. because rename/rename(1to1) makes it invalid.
4511 */
4516 }
4518 /*
4519 * Handle other cases; note that merge_trees[0..2] will only
4520 * be NULL if opti is, or if all three were manually set to
4521 * NULL by e.g. rename/rename(1to1) handling.
4522 */
4525 /* Check if we meet a condition for re-using cached_pairs */
4532 else
4534 }
4536 /*** Function Grouping: merge_incore_*() and their internal variants ***/
4538 /*
4539 * Originally from merge_trees_internal(); heavily adapted, though.
4540 */
4546 {
4554 }
4556 redo:
4559 /*
4560 * TRANSLATORS: The %s arguments are: 1) tree hash of a merge
4561 * base, and 2-3) the trees for the two trees we're merging.
4562 */
4569 }
4581 }
4587 /* Set return values */
4589 /* existence of conflicted entries implies unclean */
4595 }
4596 }
4598 /*
4599 * Originally from merge_recursive_internal(); somewhat adapted, though.
4600 */
4606 {
4614 /* See merge-ort.h:merge_incore_recursive() declaration NOTE */
4616 }
4620 /* if there is no common ancestor, use an empty tree */
4632 DEFAULT_ABBREV);
4634 }
4641 /*
4642 * When the merge fails, the result contains files
4643 * with conflict markers. The cleanness flag is
4644 * ignored (unless indicating an error), it was never
4645 * actually used, as result of merge_trees has always
4646 * overwritten it: the committed "conflicts" were
4647 * already resolved.
4648 */
4668 }
4673 merged_merge_bases),
4676 result);
4679 }
4686 {
4693 /*
4694 * Record the trees used in this merge, so if there's a next merge in
4695 * a cherry-pick or rebase sequence it might be able to take advantage
4696 * of the cached_pairs in that next merge.
4697 */
4705 }
4712 {
4715 /* We set the ancestor label based on the merge_bases */
4724 }