/* * This handles recursive filename detection with exclude * files, index knowledge etc.. * * Copyright (C) Linus Torvalds, 2005-2006 * Junio Hamano, 2005-2006 */ #include "cache.h" #include "config.h" #include "dir.h" #include "object-store.h" #include "attr.h" #include "refs.h" #include "wildmatch.h" #include "pathspec.h" #include "utf8.h" #include "varint.h" #include "ewah/ewok.h" #include "fsmonitor.h" #include "submodule-config.h" /* * Tells read_directory_recursive how a file or directory should be treated. * Values are ordered by significance, e.g. if a directory contains both * excluded and untracked files, it is listed as untracked because * path_untracked > path_excluded. */ enum path_treatment { path_none = 0, path_recurse, path_excluded, path_untracked }; /* * Support data structure for our opendir/readdir/closedir wrappers */ struct cached_dir { DIR *fdir; struct untracked_cache_dir *untracked; int nr_files; int nr_dirs; const char *d_name; int d_type; const char *file; struct untracked_cache_dir *ucd; }; static enum path_treatment read_directory_recursive(struct dir_struct *dir, struct index_state *istate, const char *path, int len, struct untracked_cache_dir *untracked, int check_only, int stop_at_first_file, const struct pathspec *pathspec); static int resolve_dtype(int dtype, struct index_state *istate, const char *path, int len); struct dirent *readdir_skip_dot_and_dotdot(DIR *dirp) { struct dirent *e; while ((e = readdir(dirp)) != NULL) { if (!is_dot_or_dotdot(e->d_name)) break; } return e; } int count_slashes(const char *s) { int cnt = 0; while (*s) if (*s++ == '/') cnt++; return cnt; } int fspathcmp(const char *a, const char *b) { return ignore_case ? strcasecmp(a, b) : strcmp(a, b); } int fspatheq(const char *a, const char *b) { return !fspathcmp(a, b); } int fspathncmp(const char *a, const char *b, size_t count) { return ignore_case ? strncasecmp(a, b, count) : strncmp(a, b, count); } unsigned int fspathhash(const char *str) { return ignore_case ? strihash(str) : strhash(str); } int git_fnmatch(const struct pathspec_item *item, const char *pattern, const char *string, int prefix) { if (prefix > 0) { if (ps_strncmp(item, pattern, string, prefix)) return WM_NOMATCH; pattern += prefix; string += prefix; } if (item->flags & PATHSPEC_ONESTAR) { int pattern_len = strlen(++pattern); int string_len = strlen(string); return string_len < pattern_len || ps_strcmp(item, pattern, string + string_len - pattern_len); } if (item->magic & PATHSPEC_GLOB) return wildmatch(pattern, string, WM_PATHNAME | (item->magic & PATHSPEC_ICASE ? WM_CASEFOLD : 0)); else /* wildmatch has not learned no FNM_PATHNAME mode yet */ return wildmatch(pattern, string, item->magic & PATHSPEC_ICASE ? WM_CASEFOLD : 0); } static int fnmatch_icase_mem(const char *pattern, int patternlen, const char *string, int stringlen, int flags) { int match_status; struct strbuf pat_buf = STRBUF_INIT; struct strbuf str_buf = STRBUF_INIT; const char *use_pat = pattern; const char *use_str = string; if (pattern[patternlen]) { strbuf_add(&pat_buf, pattern, patternlen); use_pat = pat_buf.buf; } if (string[stringlen]) { strbuf_add(&str_buf, string, stringlen); use_str = str_buf.buf; } if (ignore_case) flags |= WM_CASEFOLD; match_status = wildmatch(use_pat, use_str, flags); strbuf_release(&pat_buf); strbuf_release(&str_buf); return match_status; } static size_t common_prefix_len(const struct pathspec *pathspec) { int n; size_t max = 0; /* * ":(icase)path" is treated as a pathspec full of * wildcard. In other words, only prefix is considered common * prefix. If the pathspec is abc/foo abc/bar, running in * subdir xyz, the common prefix is still xyz, not xyz/abc as * in non-:(icase). */ GUARD_PATHSPEC(pathspec, PATHSPEC_FROMTOP | PATHSPEC_MAXDEPTH | PATHSPEC_LITERAL | PATHSPEC_GLOB | PATHSPEC_ICASE | PATHSPEC_EXCLUDE | PATHSPEC_ATTR); for (n = 0; n < pathspec->nr; n++) { size_t i = 0, len = 0, item_len; if (pathspec->items[n].magic & PATHSPEC_EXCLUDE) continue; if (pathspec->items[n].magic & PATHSPEC_ICASE) item_len = pathspec->items[n].prefix; else item_len = pathspec->items[n].nowildcard_len; while (i < item_len && (n == 0 || i < max)) { char c = pathspec->items[n].match[i]; if (c != pathspec->items[0].match[i]) break; if (c == '/') len = i + 1; i++; } if (n == 0 || len < max) { max = len; if (!max) break; } } return max; } /* * Returns a copy of the longest leading path common among all * pathspecs. */ char *common_prefix(const struct pathspec *pathspec) { unsigned long len = common_prefix_len(pathspec); return len ? xmemdupz(pathspec->items[0].match, len) : NULL; } int fill_directory(struct dir_struct *dir, struct index_state *istate, const struct pathspec *pathspec) { const char *prefix; size_t prefix_len; unsigned exclusive_flags = DIR_SHOW_IGNORED | DIR_SHOW_IGNORED_TOO; if ((dir->flags & exclusive_flags) == exclusive_flags) BUG("DIR_SHOW_IGNORED and DIR_SHOW_IGNORED_TOO are exclusive"); /* * Calculate common prefix for the pathspec, and * use that to optimize the directory walk */ prefix_len = common_prefix_len(pathspec); prefix = prefix_len ? pathspec->items[0].match : ""; /* Read the directory and prune it */ read_directory(dir, istate, prefix, prefix_len, pathspec); return prefix_len; } int within_depth(const char *name, int namelen, int depth, int max_depth) { const char *cp = name, *cpe = name + namelen; while (cp < cpe) { if (*cp++ != '/') continue; depth++; if (depth > max_depth) return 0; } return 1; } /* * Read the contents of the blob with the given OID into a buffer. * Append a trailing LF to the end if the last line doesn't have one. * * Returns: * -1 when the OID is invalid or unknown or does not refer to a blob. * 0 when the blob is empty. * 1 along with { data, size } of the (possibly augmented) buffer * when successful. * * Optionally updates the given oid_stat with the given OID (when valid). */ static int do_read_blob(const struct object_id *oid, struct oid_stat *oid_stat, size_t *size_out, char **data_out) { enum object_type type; unsigned long sz; char *data; *size_out = 0; *data_out = NULL; data = read_object_file(oid, &type, &sz); if (!data || type != OBJ_BLOB) { free(data); return -1; } if (oid_stat) { memset(&oid_stat->stat, 0, sizeof(oid_stat->stat)); oidcpy(&oid_stat->oid, oid); } if (sz == 0) { free(data); return 0; } if (data[sz - 1] != '\n') { data = xrealloc(data, st_add(sz, 1)); data[sz++] = '\n'; } *size_out = xsize_t(sz); *data_out = data; return 1; } #define DO_MATCH_EXCLUDE (1<<0) #define DO_MATCH_DIRECTORY (1<<1) #define DO_MATCH_LEADING_PATHSPEC (1<<2) /* * Does the given pathspec match the given name? A match is found if * * (1) the pathspec string is leading directory of 'name' ("RECURSIVELY"), or * (2) the pathspec string has a leading part matching 'name' ("LEADING"), or * (3) the pathspec string is a wildcard and matches 'name' ("WILDCARD"), or * (4) the pathspec string is exactly the same as 'name' ("EXACT"). * * Return value tells which case it was (1-4), or 0 when there is no match. * * It may be instructive to look at a small table of concrete examples * to understand the differences between 1, 2, and 4: * * Pathspecs * | a/b | a/b/ | a/b/c * ------+-----------+-----------+------------ * a/b | EXACT | EXACT[1] | LEADING[2] * Names a/b/ | RECURSIVE | EXACT | LEADING[2] * a/b/c | RECURSIVE | RECURSIVE | EXACT * * [1] Only if DO_MATCH_DIRECTORY is passed; otherwise, this is NOT a match. * [2] Only if DO_MATCH_LEADING_PATHSPEC is passed; otherwise, not a match. */ static int match_pathspec_item(struct index_state *istate, const struct pathspec_item *item, int prefix, const char *name, int namelen, unsigned flags) { /* name/namelen has prefix cut off by caller */ const char *match = item->match + prefix; int matchlen = item->len - prefix; /* * The normal call pattern is: * 1. prefix = common_prefix_len(ps); * 2. prune something, or fill_directory * 3. match_pathspec() * * 'prefix' at #1 may be shorter than the command's prefix and * it's ok for #2 to match extra files. Those extras will be * trimmed at #3. * * Suppose the pathspec is 'foo' and '../bar' running from * subdir 'xyz'. The common prefix at #1 will be empty, thanks * to "../". We may have xyz/foo _and_ XYZ/foo after #2. The * user does not want XYZ/foo, only the "foo" part should be * case-insensitive. We need to filter out XYZ/foo here. In * other words, we do not trust the caller on comparing the * prefix part when :(icase) is involved. We do exact * comparison ourselves. * * Normally the caller (common_prefix_len() in fact) does * _exact_ matching on name[-prefix+1..-1] and we do not need * to check that part. Be defensive and check it anyway, in * case common_prefix_len is changed, or a new caller is * introduced that does not use common_prefix_len. * * If the penalty turns out too high when prefix is really * long, maybe change it to * strncmp(match, name, item->prefix - prefix) */ if (item->prefix && (item->magic & PATHSPEC_ICASE) && strncmp(item->match, name - prefix, item->prefix)) return 0; if (item->attr_match_nr && !match_pathspec_attrs(istate, name, namelen, item)) return 0; /* If the match was just the prefix, we matched */ if (!*match) return MATCHED_RECURSIVELY; if (matchlen <= namelen && !ps_strncmp(item, match, name, matchlen)) { if (matchlen == namelen) return MATCHED_EXACTLY; if (match[matchlen-1] == '/' || name[matchlen] == '/') return MATCHED_RECURSIVELY; } else if ((flags & DO_MATCH_DIRECTORY) && match[matchlen - 1] == '/' && namelen == matchlen - 1 && !ps_strncmp(item, match, name, namelen)) return MATCHED_EXACTLY; if (item->nowildcard_len < item->len && !git_fnmatch(item, match, name, item->nowildcard_len - prefix)) return MATCHED_FNMATCH; /* Perform checks to see if "name" is a leading string of the pathspec */ if ( (flags & DO_MATCH_LEADING_PATHSPEC) && !(flags & DO_MATCH_EXCLUDE)) { /* name is a literal prefix of the pathspec */ int offset = name[namelen-1] == '/' ? 1 : 0; if ((namelen < matchlen) && (match[namelen-offset] == '/') && !ps_strncmp(item, match, name, namelen)) return MATCHED_RECURSIVELY_LEADING_PATHSPEC; /* name doesn't match up to the first wild character */ if (item->nowildcard_len < item->len && ps_strncmp(item, match, name, item->nowildcard_len - prefix)) return 0; /* * name has no wildcard, and it didn't match as a leading * pathspec so return. */ if (item->nowildcard_len == item->len) return 0; /* * Here is where we would perform a wildmatch to check if * "name" can be matched as a directory (or a prefix) against * the pathspec. Since wildmatch doesn't have this capability * at the present we have to punt and say that it is a match, * potentially returning a false positive * The submodules themselves will be able to perform more * accurate matching to determine if the pathspec matches. */ return MATCHED_RECURSIVELY_LEADING_PATHSPEC; } return 0; } /* * do_match_pathspec() is meant to ONLY be called by * match_pathspec_with_flags(); calling it directly risks pathspecs * like ':!unwanted_path' being ignored. * * Given a name and a list of pathspecs, returns the nature of the * closest (i.e. most specific) match of the name to any of the * pathspecs. * * The caller typically calls this multiple times with the same * pathspec and seen[] array but with different name/namelen * (e.g. entries from the index) and is interested in seeing if and * how each pathspec matches all the names it calls this function * with. A mark is left in the seen[] array for each pathspec element * indicating the closest type of match that element achieved, so if * seen[n] remains zero after multiple invocations, that means the nth * pathspec did not match any names, which could indicate that the * user mistyped the nth pathspec. */ static int do_match_pathspec(struct index_state *istate, const struct pathspec *ps, const char *name, int namelen, int prefix, char *seen, unsigned flags) { int i, retval = 0, exclude = flags & DO_MATCH_EXCLUDE; GUARD_PATHSPEC(ps, PATHSPEC_FROMTOP | PATHSPEC_MAXDEPTH | PATHSPEC_LITERAL | PATHSPEC_GLOB | PATHSPEC_ICASE | PATHSPEC_EXCLUDE | PATHSPEC_ATTR); if (!ps->nr) { if (!ps->recursive || !(ps->magic & PATHSPEC_MAXDEPTH) || ps->max_depth == -1) return MATCHED_RECURSIVELY; if (within_depth(name, namelen, 0, ps->max_depth)) return MATCHED_EXACTLY; else return 0; } name += prefix; namelen -= prefix; for (i = ps->nr - 1; i >= 0; i--) { int how; if ((!exclude && ps->items[i].magic & PATHSPEC_EXCLUDE) || ( exclude && !(ps->items[i].magic & PATHSPEC_EXCLUDE))) continue; if (seen && seen[i] == MATCHED_EXACTLY) continue; /* * Make exclude patterns optional and never report * "pathspec ':(exclude)foo' matches no files" */ if (seen && ps->items[i].magic & PATHSPEC_EXCLUDE) seen[i] = MATCHED_FNMATCH; how = match_pathspec_item(istate, ps->items+i, prefix, name, namelen, flags); if (ps->recursive && (ps->magic & PATHSPEC_MAXDEPTH) && ps->max_depth != -1 && how && how != MATCHED_FNMATCH) { int len = ps->items[i].len; if (name[len] == '/') len++; if (within_depth(name+len, namelen-len, 0, ps->max_depth)) how = MATCHED_EXACTLY; else how = 0; } if (how) { if (retval < how) retval = how; if (seen && seen[i] < how) seen[i] = how; } } return retval; } static int match_pathspec_with_flags(struct index_state *istate, const struct pathspec *ps, const char *name, int namelen, int prefix, char *seen, unsigned flags) { int positive, negative; positive = do_match_pathspec(istate, ps, name, namelen, prefix, seen, flags); if (!(ps->magic & PATHSPEC_EXCLUDE) || !positive) return positive; negative = do_match_pathspec(istate, ps, name, namelen, prefix, seen, flags | DO_MATCH_EXCLUDE); return negative ? 0 : positive; } int match_pathspec(struct index_state *istate, const struct pathspec *ps, const char *name, int namelen, int prefix, char *seen, int is_dir) { unsigned flags = is_dir ? DO_MATCH_DIRECTORY : 0; return match_pathspec_with_flags(istate, ps, name, namelen, prefix, seen, flags); } /** * Check if a submodule is a superset of the pathspec */ int submodule_path_match(struct index_state *istate, const struct pathspec *ps, const char *submodule_name, char *seen) { int matched = match_pathspec_with_flags(istate, ps, submodule_name, strlen(submodule_name), 0, seen, DO_MATCH_DIRECTORY | DO_MATCH_LEADING_PATHSPEC); return matched; } int report_path_error(const char *ps_matched, const struct pathspec *pathspec) { /* * Make sure all pathspec matched; otherwise it is an error. */ int num, errors = 0; for (num = 0; num < pathspec->nr; num++) { int other, found_dup; if (ps_matched[num]) continue; /* * The caller might have fed identical pathspec * twice. Do not barf on such a mistake. * FIXME: parse_pathspec should have eliminated * duplicate pathspec. */ for (found_dup = other = 0; !found_dup && other < pathspec->nr; other++) { if (other == num || !ps_matched[other]) continue; if (!strcmp(pathspec->items[other].original, pathspec->items[num].original)) /* * Ok, we have a match already. */ found_dup = 1; } if (found_dup) continue; error(_("pathspec '%s' did not match any file(s) known to git"), pathspec->items[num].original); errors++; } return errors; } /* * Return the length of the "simple" part of a path match limiter. */ int simple_length(const char *match) { int len = -1; for (;;) { unsigned char c = *match++; len++; if (c == '\0' || is_glob_special(c)) return len; } } int no_wildcard(const char *string) { return string[simple_length(string)] == '\0'; } void parse_path_pattern(const char **pattern, int *patternlen, unsigned *flags, int *nowildcardlen) { const char *p = *pattern; size_t i, len; *flags = 0; if (*p == '!') { *flags |= PATTERN_FLAG_NEGATIVE; p++; } len = strlen(p); if (len && p[len - 1] == '/') { len--; *flags |= PATTERN_FLAG_MUSTBEDIR; } for (i = 0; i < len; i++) { if (p[i] == '/') break; } if (i == len) *flags |= PATTERN_FLAG_NODIR; *nowildcardlen = simple_length(p); /* * we should have excluded the trailing slash from 'p' too, * but that's one more allocation. Instead just make sure * nowildcardlen does not exceed real patternlen */ if (*nowildcardlen > len) *nowildcardlen = len; if (*p == '*' && no_wildcard(p + 1)) *flags |= PATTERN_FLAG_ENDSWITH; *pattern = p; *patternlen = len; } int pl_hashmap_cmp(const void *unused_cmp_data, const struct hashmap_entry *a, const struct hashmap_entry *b, const void *key) { const struct pattern_entry *ee1 = container_of(a, struct pattern_entry, ent); const struct pattern_entry *ee2 = container_of(b, struct pattern_entry, ent); size_t min_len = ee1->patternlen <= ee2->patternlen ? ee1->patternlen : ee2->patternlen; if (ignore_case) return strncasecmp(ee1->pattern, ee2->pattern, min_len); return strncmp(ee1->pattern, ee2->pattern, min_len); } static char *dup_and_filter_pattern(const char *pattern) { char *set, *read; size_t count = 0; char *result = xstrdup(pattern); set = result; read = result; while (*read) { /* skip escape characters (once) */ if (*read == '\\') read++; *set = *read; set++; read++; count++; } *set = 0; if (count > 2 && *(set - 1) == '*' && *(set - 2) == '/') *(set - 2) = 0; return result; } static void add_pattern_to_hashsets(struct pattern_list *pl, struct path_pattern *given) { struct pattern_entry *translated; char *truncated; char *data = NULL; const char *prev, *cur, *next; if (!pl->use_cone_patterns) return; if (given->flags & PATTERN_FLAG_NEGATIVE && given->flags & PATTERN_FLAG_MUSTBEDIR && !strcmp(given->pattern, "/*")) { pl->full_cone = 0; return; } if (!given->flags && !strcmp(given->pattern, "/*")) { pl->full_cone = 1; return; } if (given->patternlen < 2 || *given->pattern == '*' || strstr(given->pattern, "**")) { /* Not a cone pattern. */ warning(_("unrecognized pattern: '%s'"), given->pattern); goto clear_hashmaps; } prev = given->pattern; cur = given->pattern + 1; next = given->pattern + 2; while (*cur) { /* Watch for glob characters '*', '\', '[', '?' */ if (!is_glob_special(*cur)) goto increment; /* But only if *prev != '\\' */ if (*prev == '\\') goto increment; /* But allow the initial '\' */ if (*cur == '\\' && is_glob_special(*next)) goto increment; /* But a trailing '/' then '*' is fine */ if (*prev == '/' && *cur == '*' && *next == 0) goto increment; /* Not a cone pattern. */ warning(_("unrecognized pattern: '%s'"), given->pattern); goto clear_hashmaps; increment: prev++; cur++; next++; } if (given->patternlen > 2 && !strcmp(given->pattern + given->patternlen - 2, "/*")) { if (!(given->flags & PATTERN_FLAG_NEGATIVE)) { /* Not a cone pattern. */ warning(_("unrecognized pattern: '%s'"), given->pattern); goto clear_hashmaps; } truncated = dup_and_filter_pattern(given->pattern); translated = xmalloc(sizeof(struct pattern_entry)); translated->pattern = truncated; translated->patternlen = given->patternlen - 2; hashmap_entry_init(&translated->ent, fspathhash(translated->pattern)); if (!hashmap_get_entry(&pl->recursive_hashmap, translated, ent, NULL)) { /* We did not see the "parent" included */ warning(_("unrecognized negative pattern: '%s'"), given->pattern); free(truncated); free(translated); goto clear_hashmaps; } hashmap_add(&pl->parent_hashmap, &translated->ent); hashmap_remove(&pl->recursive_hashmap, &translated->ent, &data); free(data); return; } if (given->flags & PATTERN_FLAG_NEGATIVE) { warning(_("unrecognized negative pattern: '%s'"), given->pattern); goto clear_hashmaps; } translated = xmalloc(sizeof(struct pattern_entry)); translated->pattern = dup_and_filter_pattern(given->pattern); translated->patternlen = given->patternlen; hashmap_entry_init(&translated->ent, fspathhash(translated->pattern)); hashmap_add(&pl->recursive_hashmap, &translated->ent); if (hashmap_get_entry(&pl->parent_hashmap, translated, ent, NULL)) { /* we already included this at the parent level */ warning(_("your sparse-checkout file may have issues: pattern '%s' is repeated"), given->pattern); hashmap_remove(&pl->parent_hashmap, &translated->ent, &data); free(data); free(translated); } return; clear_hashmaps: warning(_("disabling cone pattern matching")); hashmap_clear_and_free(&pl->parent_hashmap, struct pattern_entry, ent); hashmap_clear_and_free(&pl->recursive_hashmap, struct pattern_entry, ent); pl->use_cone_patterns = 0; } static int hashmap_contains_path(struct hashmap *map, struct strbuf *pattern) { struct pattern_entry p; /* Check straight mapping */ p.pattern = pattern->buf; p.patternlen = pattern->len; hashmap_entry_init(&p.ent, fspathhash(p.pattern)); return !!hashmap_get_entry(map, &p, ent, NULL); } int hashmap_contains_parent(struct hashmap *map, const char *path, struct strbuf *buffer) { char *slash_pos; strbuf_setlen(buffer, 0); if (path[0] != '/') strbuf_addch(buffer, '/'); strbuf_addstr(buffer, path); slash_pos = strrchr(buffer->buf, '/'); while (slash_pos > buffer->buf) { strbuf_setlen(buffer, slash_pos - buffer->buf); if (hashmap_contains_path(map, buffer)) return 1; slash_pos = strrchr(buffer->buf, '/'); } return 0; } void add_pattern(const char *string, const char *base, int baselen, struct pattern_list *pl, int srcpos) { struct path_pattern *pattern; int patternlen; unsigned flags; int nowildcardlen; parse_path_pattern(&string, &patternlen, &flags, &nowildcardlen); if (flags & PATTERN_FLAG_MUSTBEDIR) { FLEXPTR_ALLOC_MEM(pattern, pattern, string, patternlen); } else { pattern = xmalloc(sizeof(*pattern)); pattern->pattern = string; } pattern->patternlen = patternlen; pattern->nowildcardlen = nowildcardlen; pattern->base = base; pattern->baselen = baselen; pattern->flags = flags; pattern->srcpos = srcpos; ALLOC_GROW(pl->patterns, pl->nr + 1, pl->alloc); pl->patterns[pl->nr++] = pattern; pattern->pl = pl; add_pattern_to_hashsets(pl, pattern); } static int read_skip_worktree_file_from_index(struct index_state *istate, const char *path, size_t *size_out, char **data_out, struct oid_stat *oid_stat) { int pos, len; len = strlen(path); pos = index_name_pos(istate, path, len); if (pos < 0) return -1; if (!ce_skip_worktree(istate->cache[pos])) return -1; return do_read_blob(&istate->cache[pos]->oid, oid_stat, size_out, data_out); } /* * Frees memory within pl which was allocated for exclude patterns and * the file buffer. Does not free pl itself. */ void clear_pattern_list(struct pattern_list *pl) { int i; for (i = 0; i < pl->nr; i++) free(pl->patterns[i]); free(pl->patterns); free(pl->filebuf); hashmap_clear_and_free(&pl->recursive_hashmap, struct pattern_entry, ent); hashmap_clear_and_free(&pl->parent_hashmap, struct pattern_entry, ent); memset(pl, 0, sizeof(*pl)); } static void trim_trailing_spaces(char *buf) { char *p, *last_space = NULL; for (p = buf; *p; p++) switch (*p) { case ' ': if (!last_space) last_space = p; break; case '\\': p++; if (!*p) return; /* fallthrough */ default: last_space = NULL; } if (last_space) *last_space = '\0'; } /* * Given a subdirectory name and "dir" of the current directory, * search the subdir in "dir" and return it, or create a new one if it * does not exist in "dir". * * If "name" has the trailing slash, it'll be excluded in the search. */ static struct untracked_cache_dir *lookup_untracked(struct untracked_cache *uc, struct untracked_cache_dir *dir, const char *name, int len) { int first, last; struct untracked_cache_dir *d; if (!dir) return NULL; if (len && name[len - 1] == '/') len--; first = 0; last = dir->dirs_nr; while (last > first) { int cmp, next = first + ((last - first) >> 1); d = dir->dirs[next]; cmp = strncmp(name, d->name, len); if (!cmp && strlen(d->name) > len) cmp = -1; if (!cmp) return d; if (cmp < 0) { last = next; continue; } first = next+1; } uc->dir_created++; FLEX_ALLOC_MEM(d, name, name, len); ALLOC_GROW(dir->dirs, dir->dirs_nr + 1, dir->dirs_alloc); MOVE_ARRAY(dir->dirs + first + 1, dir->dirs + first, dir->dirs_nr - first); dir->dirs_nr++; dir->dirs[first] = d; return d; } static void do_invalidate_gitignore(struct untracked_cache_dir *dir) { int i; dir->valid = 0; dir->untracked_nr = 0; for (i = 0; i < dir->dirs_nr; i++) do_invalidate_gitignore(dir->dirs[i]); } static void invalidate_gitignore(struct untracked_cache *uc, struct untracked_cache_dir *dir) { uc->gitignore_invalidated++; do_invalidate_gitignore(dir); } static void invalidate_directory(struct untracked_cache *uc, struct untracked_cache_dir *dir) { int i; /* * Invalidation increment here is just roughly correct. If * untracked_nr or any of dirs[].recurse is non-zero, we * should increment dir_invalidated too. But that's more * expensive to do. */ if (dir->valid) uc->dir_invalidated++; dir->valid = 0; dir->untracked_nr = 0; for (i = 0; i < dir->dirs_nr; i++) dir->dirs[i]->recurse = 0; } static int add_patterns_from_buffer(char *buf, size_t size, const char *base, int baselen, struct pattern_list *pl); /* Flags for add_patterns() */ #define PATTERN_NOFOLLOW (1<<0) /* * Given a file with name "fname", read it (either from disk, or from * an index if 'istate' is non-null), parse it and store the * exclude rules in "pl". * * If "oid_stat" is not NULL, compute oid of the exclude file and fill * stat data from disk (only valid if add_patterns returns zero). If * oid_stat.valid is non-zero, "oid_stat" must contain good value as input. */ static int add_patterns(const char *fname, const char *base, int baselen, struct pattern_list *pl, struct index_state *istate, unsigned flags, struct oid_stat *oid_stat) { struct stat st; int r; int fd; size_t size = 0; char *buf; if (flags & PATTERN_NOFOLLOW) fd = open_nofollow(fname, O_RDONLY); else fd = open(fname, O_RDONLY); if (fd < 0 || fstat(fd, &st) < 0) { if (fd < 0) warn_on_fopen_errors(fname); else close(fd); if (!istate) return -1; r = read_skip_worktree_file_from_index(istate, fname, &size, &buf, oid_stat); if (r != 1) return r; } else { size = xsize_t(st.st_size); if (size == 0) { if (oid_stat) { fill_stat_data(&oid_stat->stat, &st); oidcpy(&oid_stat->oid, the_hash_algo->empty_blob); oid_stat->valid = 1; } close(fd); return 0; } buf = xmallocz(size); if (read_in_full(fd, buf, size) != size) { free(buf); close(fd); return -1; } buf[size++] = '\n'; close(fd); if (oid_stat) { int pos; if (oid_stat->valid && !match_stat_data_racy(istate, &oid_stat->stat, &st)) ; /* no content change, oid_stat->oid still good */ else if (istate && (pos = index_name_pos(istate, fname, strlen(fname))) >= 0 && !ce_stage(istate->cache[pos]) && ce_uptodate(istate->cache[pos]) && !would_convert_to_git(istate, fname)) oidcpy(&oid_stat->oid, &istate->cache[pos]->oid); else hash_object_file(the_hash_algo, buf, size, "blob", &oid_stat->oid); fill_stat_data(&oid_stat->stat, &st); oid_stat->valid = 1; } } add_patterns_from_buffer(buf, size, base, baselen, pl); return 0; } static int add_patterns_from_buffer(char *buf, size_t size, const char *base, int baselen, struct pattern_list *pl) { int i, lineno = 1; char *entry; hashmap_init(&pl->recursive_hashmap, pl_hashmap_cmp, NULL, 0); hashmap_init(&pl->parent_hashmap, pl_hashmap_cmp, NULL, 0); pl->filebuf = buf; if (skip_utf8_bom(&buf, size)) size -= buf - pl->filebuf; entry = buf; for (i = 0; i < size; i++) { if (buf[i] == '\n') { if (entry != buf + i && entry[0] != '#') { buf[i - (i && buf[i-1] == '\r')] = 0; trim_trailing_spaces(entry); add_pattern(entry, base, baselen, pl, lineno); } lineno++; entry = buf + i + 1; } } return 0; } int add_patterns_from_file_to_list(const char *fname, const char *base, int baselen, struct pattern_list *pl, struct index_state *istate, unsigned flags) { return add_patterns(fname, base, baselen, pl, istate, flags, NULL); } int add_patterns_from_blob_to_list( struct object_id *oid, const char *base, int baselen, struct pattern_list *pl) { char *buf; size_t size; int r; r = do_read_blob(oid, NULL, &size, &buf); if (r != 1) return r; add_patterns_from_buffer(buf, size, base, baselen, pl); return 0; } struct pattern_list *add_pattern_list(struct dir_struct *dir, int group_type, const char *src) { struct pattern_list *pl; struct exclude_list_group *group; group = &dir->exclude_list_group[group_type]; ALLOC_GROW(group->pl, group->nr + 1, group->alloc); pl = &group->pl[group->nr++]; memset(pl, 0, sizeof(*pl)); pl->src = src; return pl; } /* * Used to set up core.excludesfile and .git/info/exclude lists. */ static void add_patterns_from_file_1(struct dir_struct *dir, const char *fname, struct oid_stat *oid_stat) { struct pattern_list *pl; /* * catch setup_standard_excludes() that's called before * dir->untracked is assigned. That function behaves * differently when dir->untracked is non-NULL. */ if (!dir->untracked) dir->unmanaged_exclude_files++; pl = add_pattern_list(dir, EXC_FILE, fname); if (add_patterns(fname, "", 0, pl, NULL, 0, oid_stat) < 0) die(_("cannot use %s as an exclude file"), fname); } void add_patterns_from_file(struct dir_struct *dir, const char *fname) { dir->unmanaged_exclude_files++; /* see validate_untracked_cache() */ add_patterns_from_file_1(dir, fname, NULL); } int match_basename(const char *basename, int basenamelen, const char *pattern, int prefix, int patternlen, unsigned flags) { if (prefix == patternlen) { if (patternlen == basenamelen && !fspathncmp(pattern, basename, basenamelen)) return 1; } else if (flags & PATTERN_FLAG_ENDSWITH) { /* "*literal" matching against "fooliteral" */ if (patternlen - 1 <= basenamelen && !fspathncmp(pattern + 1, basename + basenamelen - (patternlen - 1), patternlen - 1)) return 1; } else { if (fnmatch_icase_mem(pattern, patternlen, basename, basenamelen, 0) == 0) return 1; } return 0; } int match_pathname(const char *pathname, int pathlen, const char *base, int baselen, const char *pattern, int prefix, int patternlen, unsigned flags) { const char *name; int namelen; /* * match with FNM_PATHNAME; the pattern has base implicitly * in front of it. */ if (*pattern == '/') { pattern++; patternlen--; prefix--; } /* * baselen does not count the trailing slash. base[] may or * may not end with a trailing slash though. */ if (pathlen < baselen + 1 || (baselen && pathname[baselen] != '/') || fspathncmp(pathname, base, baselen)) return 0; namelen = baselen ? pathlen - baselen - 1 : pathlen; name = pathname + pathlen - namelen; if (prefix) { /* * if the non-wildcard part is longer than the * remaining pathname, surely it cannot match. */ if (prefix > namelen) return 0; if (fspathncmp(pattern, name, prefix)) return 0; pattern += prefix; patternlen -= prefix; name += prefix; namelen -= prefix; /* * If the whole pattern did not have a wildcard, * then our prefix match is all we need; we * do not need to call fnmatch at all. */ if (!patternlen && (!namelen || (flags & PATTERN_FLAG_MUSTBEDIR))) return 1; } return fnmatch_icase_mem(pattern, patternlen, name, namelen, WM_PATHNAME) == 0; } static int path_matches_dir_pattern(const char *pathname, int pathlen, struct strbuf **path_parent, int *dtype, struct path_pattern *pattern, struct index_state *istate) { if (!*path_parent) { char *slash; CALLOC_ARRAY(*path_parent, 1); strbuf_add(*path_parent, pathname, pathlen); slash = find_last_dir_sep((*path_parent)->buf); if (slash) strbuf_setlen(*path_parent, slash - (*path_parent)->buf); else strbuf_setlen(*path_parent, 0); } /* * If the parent directory matches the pattern, then we do not * need to check for dtype. */ if ((*path_parent)->len && match_pathname((*path_parent)->buf, (*path_parent)->len, pattern->base, pattern->baselen ? pattern->baselen - 1 : 0, pattern->pattern, pattern->nowildcardlen, pattern->patternlen, pattern->flags)) return 1; *dtype = resolve_dtype(*dtype, istate, pathname, pathlen); if (*dtype != DT_DIR) return 0; return 1; } /* * Scan the given exclude list in reverse to see whether pathname * should be ignored. The first match (i.e. the last on the list), if * any, determines the fate. Returns the exclude_list element which * matched, or NULL for undecided. */ static struct path_pattern *last_matching_pattern_from_list(const char *pathname, int pathlen, const char *basename, int *dtype, struct pattern_list *pl, struct index_state *istate) { struct path_pattern *res = NULL; /* undecided */ int i; struct strbuf *path_parent = NULL; if (!pl->nr) return NULL; /* undefined */ for (i = pl->nr - 1; 0 <= i; i--) { struct path_pattern *pattern = pl->patterns[i]; const char *exclude = pattern->pattern; int prefix = pattern->nowildcardlen; if (pattern->flags & PATTERN_FLAG_MUSTBEDIR && !path_matches_dir_pattern(pathname, pathlen, &path_parent, dtype, pattern, istate)) continue; if (pattern->flags & PATTERN_FLAG_NODIR) { if (match_basename(basename, pathlen - (basename - pathname), exclude, prefix, pattern->patternlen, pattern->flags)) { res = pattern; break; } continue; } assert(pattern->baselen == 0 || pattern->base[pattern->baselen - 1] == '/'); if (match_pathname(pathname, pathlen, pattern->base, pattern->baselen ? pattern->baselen - 1 : 0, exclude, prefix, pattern->patternlen, pattern->flags)) { res = pattern; break; } } if (path_parent) { strbuf_release(path_parent); free(path_parent); } return res; } /* * Scan the list of patterns to determine if the ordered list * of patterns matches on 'pathname'. * * Return 1 for a match, 0 for not matched and -1 for undecided. */ enum pattern_match_result path_matches_pattern_list( const char *pathname, int pathlen, const char *basename, int *dtype, struct pattern_list *pl, struct index_state *istate) { struct path_pattern *pattern; struct strbuf parent_pathname = STRBUF_INIT; int result = NOT_MATCHED; size_t slash_pos; if (!pl->use_cone_patterns) { pattern = last_matching_pattern_from_list(pathname, pathlen, basename, dtype, pl, istate); if (pattern) { if (pattern->flags & PATTERN_FLAG_NEGATIVE) return NOT_MATCHED; else return MATCHED; } return UNDECIDED; } if (pl->full_cone) return MATCHED; strbuf_addch(&parent_pathname, '/'); strbuf_add(&parent_pathname, pathname, pathlen); /* * Directory entries are matched if and only if a file * contained immediately within them is matched. For the * case of a directory entry, modify the path to create * a fake filename within this directory, allowing us to * use the file-base matching logic in an equivalent way. */ if (parent_pathname.len > 0 && parent_pathname.buf[parent_pathname.len - 1] == '/') { slash_pos = parent_pathname.len - 1; strbuf_add(&parent_pathname, "-", 1); } else { const char *slash_ptr = strrchr(parent_pathname.buf, '/'); slash_pos = slash_ptr ? slash_ptr - parent_pathname.buf : 0; } if (hashmap_contains_path(&pl->recursive_hashmap, &parent_pathname)) { result = MATCHED_RECURSIVE; goto done; } if (!slash_pos) { /* include every file in root */ result = MATCHED; goto done; } strbuf_setlen(&parent_pathname, slash_pos); if (hashmap_contains_path(&pl->parent_hashmap, &parent_pathname)) { result = MATCHED; goto done; } if (hashmap_contains_parent(&pl->recursive_hashmap, pathname, &parent_pathname)) result = MATCHED_RECURSIVE; done: strbuf_release(&parent_pathname); return result; } int init_sparse_checkout_patterns(struct index_state *istate) { if (!core_apply_sparse_checkout) return 1; if (istate->sparse_checkout_patterns) return 0; CALLOC_ARRAY(istate->sparse_checkout_patterns, 1); if (get_sparse_checkout_patterns(istate->sparse_checkout_patterns) < 0) { FREE_AND_NULL(istate->sparse_checkout_patterns); return -1; } return 0; } static int path_in_sparse_checkout_1(const char *path, struct index_state *istate, int require_cone_mode) { int dtype = DT_REG; enum pattern_match_result match = UNDECIDED; const char *end, *slash; /* * We default to accepting a path if there are no patterns or * they are of the wrong type. */ if (init_sparse_checkout_patterns(istate) || (require_cone_mode && !istate->sparse_checkout_patterns->use_cone_patterns)) return 1; /* * If UNDECIDED, use the match from the parent dir (recursively), or * fall back to NOT_MATCHED at the topmost level. Note that cone mode * never returns UNDECIDED, so we will execute only one iteration in * this case. */ for (end = path + strlen(path); end > path && match == UNDECIDED; end = slash) { for (slash = end - 1; slash > path && *slash != '/'; slash--) ; /* do nothing */ match = path_matches_pattern_list(path, end - path, slash > path ? slash + 1 : path, &dtype, istate->sparse_checkout_patterns, istate); /* We are going to match the parent dir now */ dtype = DT_DIR; } return match > 0; } int path_in_sparse_checkout(const char *path, struct index_state *istate) { return path_in_sparse_checkout_1(path, istate, 0); } int path_in_cone_mode_sparse_checkout(const char *path, struct index_state *istate) { return path_in_sparse_checkout_1(path, istate, 1); } static struct path_pattern *last_matching_pattern_from_lists( struct dir_struct *dir, struct index_state *istate, const char *pathname, int pathlen, const char *basename, int *dtype_p) { int i, j; struct exclude_list_group *group; struct path_pattern *pattern; for (i = EXC_CMDL; i <= EXC_FILE; i++) { group = &dir->exclude_list_group[i]; for (j = group->nr - 1; j >= 0; j--) { pattern = last_matching_pattern_from_list( pathname, pathlen, basename, dtype_p, &group->pl[j], istate); if (pattern) return pattern; } } return NULL; } /* * Loads the per-directory exclude list for the substring of base * which has a char length of baselen. */ static void prep_exclude(struct dir_struct *dir, struct index_state *istate, const char *base, int baselen) { struct exclude_list_group *group; struct pattern_list *pl; struct exclude_stack *stk = NULL; struct untracked_cache_dir *untracked; int current; group = &dir->exclude_list_group[EXC_DIRS]; /* * Pop the exclude lists from the EXCL_DIRS exclude_list_group * which originate from directories not in the prefix of the * path being checked. */ while ((stk = dir->exclude_stack) != NULL) { if (stk->baselen <= baselen && !strncmp(dir->basebuf.buf, base, stk->baselen)) break; pl = &group->pl[dir->exclude_stack->exclude_ix]; dir->exclude_stack = stk->prev; dir->pattern = NULL; free((char *)pl->src); /* see strbuf_detach() below */ clear_pattern_list(pl); free(stk); group->nr--; } /* Skip traversing into sub directories if the parent is excluded */ if (dir->pattern) return; /* * Lazy initialization. All call sites currently just * memset(dir, 0, sizeof(*dir)) before use. Changing all of * them seems lots of work for little benefit. */ if (!dir->basebuf.buf) strbuf_init(&dir->basebuf, PATH_MAX); /* Read from the parent directories and push them down. */ current = stk ? stk->baselen : -1; strbuf_setlen(&dir->basebuf, current < 0 ? 0 : current); if (dir->untracked) untracked = stk ? stk->ucd : dir->untracked->root; else untracked = NULL; while (current < baselen) { const char *cp; struct oid_stat oid_stat; CALLOC_ARRAY(stk, 1); if (current < 0) { cp = base; current = 0; } else { cp = strchr(base + current + 1, '/'); if (!cp) die("oops in prep_exclude"); cp++; untracked = lookup_untracked(dir->untracked, untracked, base + current, cp - base - current); } stk->prev = dir->exclude_stack; stk->baselen = cp - base; stk->exclude_ix = group->nr; stk->ucd = untracked; pl = add_pattern_list(dir, EXC_DIRS, NULL); strbuf_add(&dir->basebuf, base + current, stk->baselen - current); assert(stk->baselen == dir->basebuf.len); /* Abort if the directory is excluded */ if (stk->baselen) { int dt = DT_DIR; dir->basebuf.buf[stk->baselen - 1] = 0; dir->pattern = last_matching_pattern_from_lists(dir, istate, dir->basebuf.buf, stk->baselen - 1, dir->basebuf.buf + current, &dt); dir->basebuf.buf[stk->baselen - 1] = '/'; if (dir->pattern && dir->pattern->flags & PATTERN_FLAG_NEGATIVE) dir->pattern = NULL; if (dir->pattern) { dir->exclude_stack = stk; return; } } /* Try to read per-directory file */ oidclr(&oid_stat.oid); oid_stat.valid = 0; if (dir->exclude_per_dir && /* * If we know that no files have been added in * this directory (i.e. valid_cached_dir() has * been executed and set untracked->valid) .. */ (!untracked || !untracked->valid || /* * .. and .gitignore does not exist before * (i.e. null exclude_oid). Then we can skip * loading .gitignore, which would result in * ENOENT anyway. */ !is_null_oid(&untracked->exclude_oid))) { /* * dir->basebuf gets reused by the traversal, but we * need fname to remain unchanged to ensure the src * member of each struct path_pattern correctly * back-references its source file. Other invocations * of add_pattern_list provide stable strings, so we * strbuf_detach() and free() here in the caller. */ struct strbuf sb = STRBUF_INIT; strbuf_addbuf(&sb, &dir->basebuf); strbuf_addstr(&sb, dir->exclude_per_dir); pl->src = strbuf_detach(&sb, NULL); add_patterns(pl->src, pl->src, stk->baselen, pl, istate, PATTERN_NOFOLLOW, untracked ? &oid_stat : NULL); } /* * NEEDSWORK: when untracked cache is enabled, prep_exclude() * will first be called in valid_cached_dir() then maybe many * times more in last_matching_pattern(). When the cache is * used, last_matching_pattern() will not be called and * reading .gitignore content will be a waste. * * So when it's called by valid_cached_dir() and we can get * .gitignore SHA-1 from the index (i.e. .gitignore is not * modified on work tree), we could delay reading the * .gitignore content until we absolutely need it in * last_matching_pattern(). Be careful about ignore rule * order, though, if you do that. */ if (untracked && !oideq(&oid_stat.oid, &untracked->exclude_oid)) { invalidate_gitignore(dir->untracked, untracked); oidcpy(&untracked->exclude_oid, &oid_stat.oid); } dir->exclude_stack = stk; current = stk->baselen; } strbuf_setlen(&dir->basebuf, baselen); } /* * Loads the exclude lists for the directory containing pathname, then * scans all exclude lists to determine whether pathname is excluded. * Returns the exclude_list element which matched, or NULL for * undecided. */ struct path_pattern *last_matching_pattern(struct dir_struct *dir, struct index_state *istate, const char *pathname, int *dtype_p) { int pathlen = strlen(pathname); const char *basename = strrchr(pathname, '/'); basename = (basename) ? basename+1 : pathname; prep_exclude(dir, istate, pathname, basename-pathname); if (dir->pattern) return dir->pattern; return last_matching_pattern_from_lists(dir, istate, pathname, pathlen, basename, dtype_p); } /* * Loads the exclude lists for the directory containing pathname, then * scans all exclude lists to determine whether pathname is excluded. * Returns 1 if true, otherwise 0. */ int is_excluded(struct dir_struct *dir, struct index_state *istate, const char *pathname, int *dtype_p) { struct path_pattern *pattern = last_matching_pattern(dir, istate, pathname, dtype_p); if (pattern) return pattern->flags & PATTERN_FLAG_NEGATIVE ? 0 : 1; return 0; } static struct dir_entry *dir_entry_new(const char *pathname, int len) { struct dir_entry *ent; FLEX_ALLOC_MEM(ent, name, pathname, len); ent->len = len; return ent; } static struct dir_entry *dir_add_name(struct dir_struct *dir, struct index_state *istate, const char *pathname, int len) { if (index_file_exists(istate, pathname, len, ignore_case)) return NULL; ALLOC_GROW(dir->entries, dir->nr+1, dir->alloc); return dir->entries[dir->nr++] = dir_entry_new(pathname, len); } struct dir_entry *dir_add_ignored(struct dir_struct *dir, struct index_state *istate, const char *pathname, int len) { if (!index_name_is_other(istate, pathname, len)) return NULL; ALLOC_GROW(dir->ignored, dir->ignored_nr+1, dir->ignored_alloc); return dir->ignored[dir->ignored_nr++] = dir_entry_new(pathname, len); } enum exist_status { index_nonexistent = 0, index_directory, index_gitdir }; /* * Do not use the alphabetically sorted index to look up * the directory name; instead, use the case insensitive * directory hash. */ static enum exist_status directory_exists_in_index_icase(struct index_state *istate, const char *dirname, int len) { struct cache_entry *ce; if (index_dir_exists(istate, dirname, len)) return index_directory; ce = index_file_exists(istate, dirname, len, ignore_case); if (ce && S_ISGITLINK(ce->ce_mode)) return index_gitdir; return index_nonexistent; } /* * The index sorts alphabetically by entry name, which * means that a gitlink sorts as '\0' at the end, while * a directory (which is defined not as an entry, but as * the files it contains) will sort with the '/' at the * end. */ static enum exist_status directory_exists_in_index(struct index_state *istate, const char *dirname, int len) { int pos; if (ignore_case) return directory_exists_in_index_icase(istate, dirname, len); pos = index_name_pos(istate, dirname, len); if (pos < 0) pos = -pos-1; while (pos < istate->cache_nr) { const struct cache_entry *ce = istate->cache[pos++]; unsigned char endchar; if (strncmp(ce->name, dirname, len)) break; endchar = ce->name[len]; if (endchar > '/') break; if (endchar == '/') return index_directory; if (!endchar && S_ISGITLINK(ce->ce_mode)) return index_gitdir; } return index_nonexistent; } /* * When we find a directory when traversing the filesystem, we * have three distinct cases: * * - ignore it * - see it as a directory * - recurse into it * * and which one we choose depends on a combination of existing * git index contents and the flags passed into the directory * traversal routine. * * Case 1: If we *already* have entries in the index under that * directory name, we always recurse into the directory to see * all the files. * * Case 2: If we *already* have that directory name as a gitlink, * we always continue to see it as a gitlink, regardless of whether * there is an actual git directory there or not (it might not * be checked out as a subproject!) * * Case 3: if we didn't have it in the index previously, we * have a few sub-cases: * * (a) if DIR_SHOW_OTHER_DIRECTORIES flag is set, we show it as * just a directory, unless DIR_HIDE_EMPTY_DIRECTORIES is * also true, in which case we need to check if it contains any * untracked and / or ignored files. * (b) if it looks like a git directory and we don't have the * DIR_NO_GITLINKS flag, then we treat it as a gitlink, and * show it as a directory. * (c) otherwise, we recurse into it. */ static enum path_treatment treat_directory(struct dir_struct *dir, struct index_state *istate, struct untracked_cache_dir *untracked, const char *dirname, int len, int baselen, int excluded, const struct pathspec *pathspec) { /* * WARNING: From this function, you can return path_recurse or you * can call read_directory_recursive() (or neither), but * you CAN'T DO BOTH. */ enum path_treatment state; int matches_how = 0; int nested_repo = 0, check_only, stop_early; int old_ignored_nr, old_untracked_nr; /* The "len-1" is to strip the final '/' */ enum exist_status status = directory_exists_in_index(istate, dirname, len-1); if (status == index_directory) return path_recurse; if (status == index_gitdir) return path_none; if (status != index_nonexistent) BUG("Unhandled value for directory_exists_in_index: %d\n", status); /* * We don't want to descend into paths that don't match the necessary * patterns. Clearly, if we don't have a pathspec, then we can't check * for matching patterns. Also, if (excluded) then we know we matched * the exclusion patterns so as an optimization we can skip checking * for matching patterns. */ if (pathspec && !excluded) { matches_how = match_pathspec_with_flags(istate, pathspec, dirname, len, 0 /* prefix */, NULL /* seen */, DO_MATCH_LEADING_PATHSPEC); if (!matches_how) return path_none; } if ((dir->flags & DIR_SKIP_NESTED_GIT) || !(dir->flags & DIR_NO_GITLINKS)) { struct strbuf sb = STRBUF_INIT; strbuf_addstr(&sb, dirname); nested_repo = is_nonbare_repository_dir(&sb); strbuf_release(&sb); } if (nested_repo) { if ((dir->flags & DIR_SKIP_NESTED_GIT) || (matches_how == MATCHED_RECURSIVELY_LEADING_PATHSPEC)) return path_none; return excluded ? path_excluded : path_untracked; } if (!(dir->flags & DIR_SHOW_OTHER_DIRECTORIES)) { if (excluded && (dir->flags & DIR_SHOW_IGNORED_TOO) && (dir->flags & DIR_SHOW_IGNORED_TOO_MODE_MATCHING)) { /* * This is an excluded directory and we are * showing ignored paths that match an exclude * pattern. (e.g. show directory as ignored * only if it matches an exclude pattern). * This path will either be 'path_excluded` * (if we are showing empty directories or if * the directory is not empty), or will be * 'path_none' (empty directory, and we are * not showing empty directories). */ if (!(dir->flags & DIR_HIDE_EMPTY_DIRECTORIES)) return path_excluded; if (read_directory_recursive(dir, istate, dirname, len, untracked, 1, 1, pathspec) == path_excluded) return path_excluded; return path_none; } return path_recurse; } assert(dir->flags & DIR_SHOW_OTHER_DIRECTORIES); /* * If we have a pathspec which could match something _below_ this * directory (e.g. when checking 'subdir/' having a pathspec like * 'subdir/some/deep/path/file' or 'subdir/widget-*.c'), then we * need to recurse. */ if (matches_how == MATCHED_RECURSIVELY_LEADING_PATHSPEC) return path_recurse; /* Special cases for where this directory is excluded/ignored */ if (excluded) { /* * If DIR_SHOW_OTHER_DIRECTORIES is set and we're not * hiding empty directories, there is no need to * recurse into an ignored directory. */ if (!(dir->flags & DIR_HIDE_EMPTY_DIRECTORIES)) return path_excluded; /* * Even if we are hiding empty directories, we can still avoid * recursing into ignored directories for DIR_SHOW_IGNORED_TOO * if DIR_SHOW_IGNORED_TOO_MODE_MATCHING is also set. */ if ((dir->flags & DIR_SHOW_IGNORED_TOO) && (dir->flags & DIR_SHOW_IGNORED_TOO_MODE_MATCHING)) return path_excluded; } /* * Other than the path_recurse case above, we only need to * recurse into untracked directories if any of the following * bits is set: * - DIR_SHOW_IGNORED (because then we need to determine if * there are ignored entries below) * - DIR_SHOW_IGNORED_TOO (same as above) * - DIR_HIDE_EMPTY_DIRECTORIES (because we have to determine if * the directory is empty) */ if (!excluded && !(dir->flags & (DIR_SHOW_IGNORED | DIR_SHOW_IGNORED_TOO | DIR_HIDE_EMPTY_DIRECTORIES))) { return path_untracked; } /* * Even if we don't want to know all the paths under an untracked or * ignored directory, we may still need to go into the directory to * determine if it is empty (because with DIR_HIDE_EMPTY_DIRECTORIES, * an empty directory should be path_none instead of path_excluded or * path_untracked). */ check_only = ((dir->flags & DIR_HIDE_EMPTY_DIRECTORIES) && !(dir->flags & DIR_SHOW_IGNORED_TOO)); /* * However, there's another optimization possible as a subset of * check_only, based on the cases we have to consider: * A) Directory matches no exclude patterns: * * Directory is empty => path_none * * Directory has an untracked file under it => path_untracked * * Directory has only ignored files under it => path_excluded * B) Directory matches an exclude pattern: * * Directory is empty => path_none * * Directory has an untracked file under it => path_excluded * * Directory has only ignored files under it => path_excluded * In case A, we can exit as soon as we've found an untracked * file but otherwise have to walk all files. In case B, though, * we can stop at the first file we find under the directory. */ stop_early = check_only && excluded; /* * If /every/ file within an untracked directory is ignored, then * we want to treat the directory as ignored (for e.g. status * --porcelain), without listing the individual ignored files * underneath. To do so, we'll save the current ignored_nr, and * pop all the ones added after it if it turns out the entire * directory is ignored. Also, when DIR_SHOW_IGNORED_TOO and * !DIR_KEEP_UNTRACKED_CONTENTS then we don't want to show * untracked paths so will need to pop all those off the last * after we traverse. */ old_ignored_nr = dir->ignored_nr; old_untracked_nr = dir->nr; /* Actually recurse into dirname now, we'll fixup the state later. */ untracked = lookup_untracked(dir->untracked, untracked, dirname + baselen, len - baselen); state = read_directory_recursive(dir, istate, dirname, len, untracked, check_only, stop_early, pathspec); /* There are a variety of reasons we may need to fixup the state... */ if (state == path_excluded) { /* state == path_excluded implies all paths under * dirname were ignored... * * if running e.g. `git status --porcelain --ignored=matching`, * then we want to see the subpaths that are ignored. * * if running e.g. just `git status --porcelain`, then * we just want the directory itself to be listed as ignored * and not the individual paths underneath. */ int want_ignored_subpaths = ((dir->flags & DIR_SHOW_IGNORED_TOO) && (dir->flags & DIR_SHOW_IGNORED_TOO_MODE_MATCHING)); if (want_ignored_subpaths) { /* * with --ignored=matching, we want the subpaths * INSTEAD of the directory itself. */ state = path_none; } else { int i; for (i = old_ignored_nr + 1; iignored_nr; ++i) FREE_AND_NULL(dir->ignored[i]); dir->ignored_nr = old_ignored_nr; } } /* * We may need to ignore some of the untracked paths we found while * traversing subdirectories. */ if ((dir->flags & DIR_SHOW_IGNORED_TOO) && !(dir->flags & DIR_KEEP_UNTRACKED_CONTENTS)) { int i; for (i = old_untracked_nr + 1; inr; ++i) FREE_AND_NULL(dir->entries[i]); dir->nr = old_untracked_nr; } /* * If there is nothing under the current directory and we are not * hiding empty directories, then we need to report on the * untracked or ignored status of the directory itself. */ if (state == path_none && !(dir->flags & DIR_HIDE_EMPTY_DIRECTORIES)) state = excluded ? path_excluded : path_untracked; return state; } /* * This is an inexact early pruning of any recursive directory * reading - if the path cannot possibly be in the pathspec, * return true, and we'll skip it early. */ static int simplify_away(const char *path, int pathlen, const struct pathspec *pathspec) { int i; if (!pathspec || !pathspec->nr) return 0; GUARD_PATHSPEC(pathspec, PATHSPEC_FROMTOP | PATHSPEC_MAXDEPTH | PATHSPEC_LITERAL | PATHSPEC_GLOB | PATHSPEC_ICASE | PATHSPEC_EXCLUDE | PATHSPEC_ATTR); for (i = 0; i < pathspec->nr; i++) { const struct pathspec_item *item = &pathspec->items[i]; int len = item->nowildcard_len; if (len > pathlen) len = pathlen; if (!ps_strncmp(item, item->match, path, len)) return 0; } return 1; } /* * This function tells us whether an excluded path matches a * list of "interesting" pathspecs. That is, whether a path matched * by any of the pathspecs could possibly be ignored by excluding * the specified path. This can happen if: * * 1. the path is mentioned explicitly in the pathspec * * 2. the path is a directory prefix of some element in the * pathspec */ static int exclude_matches_pathspec(const char *path, int pathlen, const struct pathspec *pathspec) { int i; if (!pathspec || !pathspec->nr) return 0; GUARD_PATHSPEC(pathspec, PATHSPEC_FROMTOP | PATHSPEC_MAXDEPTH | PATHSPEC_LITERAL | PATHSPEC_GLOB | PATHSPEC_ICASE | PATHSPEC_EXCLUDE); for (i = 0; i < pathspec->nr; i++) { const struct pathspec_item *item = &pathspec->items[i]; int len = item->nowildcard_len; if (len == pathlen && !ps_strncmp(item, item->match, path, pathlen)) return 1; if (len > pathlen && item->match[pathlen] == '/' && !ps_strncmp(item, item->match, path, pathlen)) return 1; } return 0; } static int get_index_dtype(struct index_state *istate, const char *path, int len) { int pos; const struct cache_entry *ce; ce = index_file_exists(istate, path, len, 0); if (ce) { if (!ce_uptodate(ce)) return DT_UNKNOWN; if (S_ISGITLINK(ce->ce_mode)) return DT_DIR; /* * Nobody actually cares about the * difference between DT_LNK and DT_REG */ return DT_REG; } /* Try to look it up as a directory */ pos = index_name_pos(istate, path, len); if (pos >= 0) return DT_UNKNOWN; pos = -pos-1; while (pos < istate->cache_nr) { ce = istate->cache[pos++]; if (strncmp(ce->name, path, len)) break; if (ce->name[len] > '/') break; if (ce->name[len] < '/') continue; if (!ce_uptodate(ce)) break; /* continue? */ return DT_DIR; } return DT_UNKNOWN; } static int resolve_dtype(int dtype, struct index_state *istate, const char *path, int len) { struct stat st; if (dtype != DT_UNKNOWN) return dtype; dtype = get_index_dtype(istate, path, len); if (dtype != DT_UNKNOWN) return dtype; if (lstat(path, &st)) return dtype; if (S_ISREG(st.st_mode)) return DT_REG; if (S_ISDIR(st.st_mode)) return DT_DIR; if (S_ISLNK(st.st_mode)) return DT_LNK; return dtype; } static enum path_treatment treat_path_fast(struct dir_struct *dir, struct cached_dir *cdir, struct index_state *istate, struct strbuf *path, int baselen, const struct pathspec *pathspec) { /* * WARNING: From this function, you can return path_recurse or you * can call read_directory_recursive() (or neither), but * you CAN'T DO BOTH. */ strbuf_setlen(path, baselen); if (!cdir->ucd) { strbuf_addstr(path, cdir->file); return path_untracked; } strbuf_addstr(path, cdir->ucd->name); /* treat_one_path() does this before it calls treat_directory() */ strbuf_complete(path, '/'); if (cdir->ucd->check_only) /* * check_only is set as a result of treat_directory() getting * to its bottom. Verify again the same set of directories * with check_only set. */ return read_directory_recursive(dir, istate, path->buf, path->len, cdir->ucd, 1, 0, pathspec); /* * We get path_recurse in the first run when * directory_exists_in_index() returns index_nonexistent. We * are sure that new changes in the index does not impact the * outcome. Return now. */ return path_recurse; } static enum path_treatment treat_path(struct dir_struct *dir, struct untracked_cache_dir *untracked, struct cached_dir *cdir, struct index_state *istate, struct strbuf *path, int baselen, const struct pathspec *pathspec) { int has_path_in_index, dtype, excluded; if (!cdir->d_name) return treat_path_fast(dir, cdir, istate, path, baselen, pathspec); if (is_dot_or_dotdot(cdir->d_name) || !fspathcmp(cdir->d_name, ".git")) return path_none; strbuf_setlen(path, baselen); strbuf_addstr(path, cdir->d_name); if (simplify_away(path->buf, path->len, pathspec)) return path_none; dtype = resolve_dtype(cdir->d_type, istate, path->buf, path->len); /* Always exclude indexed files */ has_path_in_index = !!index_file_exists(istate, path->buf, path->len, ignore_case); if (dtype != DT_DIR && has_path_in_index) return path_none; /* * When we are looking at a directory P in the working tree, * there are three cases: * * (1) P exists in the index. Everything inside the directory P in * the working tree needs to go when P is checked out from the * index. * * (2) P does not exist in the index, but there is P/Q in the index. * We know P will stay a directory when we check out the contents * of the index, but we do not know yet if there is a directory * P/Q in the working tree to be killed, so we need to recurse. * * (3) P does not exist in the index, and there is no P/Q in the index * to require P to be a directory, either. Only in this case, we * know that everything inside P will not be killed without * recursing. */ if ((dir->flags & DIR_COLLECT_KILLED_ONLY) && (dtype == DT_DIR) && !has_path_in_index && (directory_exists_in_index(istate, path->buf, path->len) == index_nonexistent)) return path_none; excluded = is_excluded(dir, istate, path->buf, &dtype); /* * Excluded? If we don't explicitly want to show * ignored files, ignore it */ if (excluded && !(dir->flags & (DIR_SHOW_IGNORED|DIR_SHOW_IGNORED_TOO))) return path_excluded; switch (dtype) { default: return path_none; case DT_DIR: /* * WARNING: Do not ignore/amend the return value from * treat_directory(), and especially do not change it to return * path_recurse as that can cause exponential slowdown. * Instead, modify treat_directory() to return the right value. */ strbuf_addch(path, '/'); return treat_directory(dir, istate, untracked, path->buf, path->len, baselen, excluded, pathspec); case DT_REG: case DT_LNK: if (pathspec && !match_pathspec(istate, pathspec, path->buf, path->len, 0 /* prefix */, NULL /* seen */, 0 /* is_dir */)) return path_none; if (excluded) return path_excluded; return path_untracked; } } static void add_untracked(struct untracked_cache_dir *dir, const char *name) { if (!dir) return; ALLOC_GROW(dir->untracked, dir->untracked_nr + 1, dir->untracked_alloc); dir->untracked[dir->untracked_nr++] = xstrdup(name); } static int valid_cached_dir(struct dir_struct *dir, struct untracked_cache_dir *untracked, struct index_state *istate, struct strbuf *path, int check_only) { struct stat st; if (!untracked) return 0; /* * With fsmonitor, we can trust the untracked cache's valid field. */ refresh_fsmonitor(istate); if (!(dir->untracked->use_fsmonitor && untracked->valid)) { if (lstat(path->len ? path->buf : ".", &st)) { memset(&untracked->stat_data, 0, sizeof(untracked->stat_data)); return 0; } if (!untracked->valid || match_stat_data_racy(istate, &untracked->stat_data, &st)) { fill_stat_data(&untracked->stat_data, &st); return 0; } } if (untracked->check_only != !!check_only) return 0; /* * prep_exclude will be called eventually on this directory, * but it's called much later in last_matching_pattern(). We * need it now to determine the validity of the cache for this * path. The next calls will be nearly no-op, the way * prep_exclude() is designed. */ if (path->len && path->buf[path->len - 1] != '/') { strbuf_addch(path, '/'); prep_exclude(dir, istate, path->buf, path->len); strbuf_setlen(path, path->len - 1); } else prep_exclude(dir, istate, path->buf, path->len); /* hopefully prep_exclude() haven't invalidated this entry... */ return untracked->valid; } static int open_cached_dir(struct cached_dir *cdir, struct dir_struct *dir, struct untracked_cache_dir *untracked, struct index_state *istate, struct strbuf *path, int check_only) { const char *c_path; memset(cdir, 0, sizeof(*cdir)); cdir->untracked = untracked; if (valid_cached_dir(dir, untracked, istate, path, check_only)) return 0; c_path = path->len ? path->buf : "."; cdir->fdir = opendir(c_path); if (!cdir->fdir) warning_errno(_("could not open directory '%s'"), c_path); if (dir->untracked) { invalidate_directory(dir->untracked, untracked); dir->untracked->dir_opened++; } if (!cdir->fdir) return -1; return 0; } static int read_cached_dir(struct cached_dir *cdir) { struct dirent *de; if (cdir->fdir) { de = readdir_skip_dot_and_dotdot(cdir->fdir); if (!de) { cdir->d_name = NULL; cdir->d_type = DT_UNKNOWN; return -1; } cdir->d_name = de->d_name; cdir->d_type = DTYPE(de); return 0; } while (cdir->nr_dirs < cdir->untracked->dirs_nr) { struct untracked_cache_dir *d = cdir->untracked->dirs[cdir->nr_dirs]; if (!d->recurse) { cdir->nr_dirs++; continue; } cdir->ucd = d; cdir->nr_dirs++; return 0; } cdir->ucd = NULL; if (cdir->nr_files < cdir->untracked->untracked_nr) { struct untracked_cache_dir *d = cdir->untracked; cdir->file = d->untracked[cdir->nr_files++]; return 0; } return -1; } static void close_cached_dir(struct cached_dir *cdir) { if (cdir->fdir) closedir(cdir->fdir); /* * We have gone through this directory and found no untracked * entries. Mark it valid. */ if (cdir->untracked) { cdir->untracked->valid = 1; cdir->untracked->recurse = 1; } } static void add_path_to_appropriate_result_list(struct dir_struct *dir, struct untracked_cache_dir *untracked, struct cached_dir *cdir, struct index_state *istate, struct strbuf *path, int baselen, const struct pathspec *pathspec, enum path_treatment state) { /* add the path to the appropriate result list */ switch (state) { case path_excluded: if (dir->flags & DIR_SHOW_IGNORED) dir_add_name(dir, istate, path->buf, path->len); else if ((dir->flags & DIR_SHOW_IGNORED_TOO) || ((dir->flags & DIR_COLLECT_IGNORED) && exclude_matches_pathspec(path->buf, path->len, pathspec))) dir_add_ignored(dir, istate, path->buf, path->len); break; case path_untracked: if (dir->flags & DIR_SHOW_IGNORED) break; dir_add_name(dir, istate, path->buf, path->len); if (cdir->fdir) add_untracked(untracked, path->buf + baselen); break; default: break; } } /* * Read a directory tree. We currently ignore anything but * directories, regular files and symlinks. That's because git * doesn't handle them at all yet. Maybe that will change some * day. * * Also, we ignore the name ".git" (even if it is not a directory). * That likely will not change. * * If 'stop_at_first_file' is specified, 'path_excluded' is returned * to signal that a file was found. This is the least significant value that * indicates that a file was encountered that does not depend on the order of * whether an untracked or excluded path was encountered first. * * Returns the most significant path_treatment value encountered in the scan. * If 'stop_at_first_file' is specified, `path_excluded` is the most * significant path_treatment value that will be returned. */ static enum path_treatment read_directory_recursive(struct dir_struct *dir, struct index_state *istate, const char *base, int baselen, struct untracked_cache_dir *untracked, int check_only, int stop_at_first_file, const struct pathspec *pathspec) { /* * WARNING: Do NOT recurse unless path_recurse is returned from * treat_path(). Recursing on any other return value * can result in exponential slowdown. */ struct cached_dir cdir; enum path_treatment state, subdir_state, dir_state = path_none; struct strbuf path = STRBUF_INIT; strbuf_add(&path, base, baselen); if (open_cached_dir(&cdir, dir, untracked, istate, &path, check_only)) goto out; dir->visited_directories++; if (untracked) untracked->check_only = !!check_only; while (!read_cached_dir(&cdir)) { /* check how the file or directory should be treated */ state = treat_path(dir, untracked, &cdir, istate, &path, baselen, pathspec); dir->visited_paths++; if (state > dir_state) dir_state = state; /* recurse into subdir if instructed by treat_path */ if (state == path_recurse) { struct untracked_cache_dir *ud; ud = lookup_untracked(dir->untracked, untracked, path.buf + baselen, path.len - baselen); subdir_state = read_directory_recursive(dir, istate, path.buf, path.len, ud, check_only, stop_at_first_file, pathspec); if (subdir_state > dir_state) dir_state = subdir_state; if (pathspec && !match_pathspec(istate, pathspec, path.buf, path.len, 0 /* prefix */, NULL, 0 /* do NOT special case dirs */)) state = path_none; } if (check_only) { if (stop_at_first_file) { /* * If stopping at first file, then * signal that a file was found by * returning `path_excluded`. This is * to return a consistent value * regardless of whether an ignored or * excluded file happened to be * encountered 1st. * * In current usage, the * `stop_at_first_file` is passed when * an ancestor directory has matched * an exclude pattern, so any found * files will be excluded. */ if (dir_state >= path_excluded) { dir_state = path_excluded; break; } } /* abort early if maximum state has been reached */ if (dir_state == path_untracked) { if (cdir.fdir) add_untracked(untracked, path.buf + baselen); break; } /* skip the add_path_to_appropriate_result_list() */ continue; } add_path_to_appropriate_result_list(dir, untracked, &cdir, istate, &path, baselen, pathspec, state); } close_cached_dir(&cdir); out: strbuf_release(&path); return dir_state; } int cmp_dir_entry(const void *p1, const void *p2) { const struct dir_entry *e1 = *(const struct dir_entry **)p1; const struct dir_entry *e2 = *(const struct dir_entry **)p2; return name_compare(e1->name, e1->len, e2->name, e2->len); } /* check if *out lexically strictly contains *in */ int check_dir_entry_contains(const struct dir_entry *out, const struct dir_entry *in) { return (out->len < in->len) && (out->name[out->len - 1] == '/') && !memcmp(out->name, in->name, out->len); } static int treat_leading_path(struct dir_struct *dir, struct index_state *istate, const char *path, int len, const struct pathspec *pathspec) { struct strbuf sb = STRBUF_INIT; struct strbuf subdir = STRBUF_INIT; int prevlen, baselen; const char *cp; struct cached_dir cdir; enum path_treatment state = path_none; /* * For each directory component of path, we are going to check whether * that path is relevant given the pathspec. For example, if path is * foo/bar/baz/ * then we will ask treat_path() whether we should go into foo, then * whether we should go into bar, then whether baz is relevant. * Checking each is important because e.g. if path is * .git/info/ * then we need to check .git to know we shouldn't traverse it. * If the return from treat_path() is: * * path_none, for any path, we return false. * * path_recurse, for all path components, we return true * * for some intermediate component, we make sure * to add that path to the relevant list but return false * signifying that we shouldn't recurse into it. */ while (len && path[len - 1] == '/') len--; if (!len) return 1; memset(&cdir, 0, sizeof(cdir)); cdir.d_type = DT_DIR; baselen = 0; prevlen = 0; while (1) { prevlen = baselen + !!baselen; cp = path + prevlen; cp = memchr(cp, '/', path + len - cp); if (!cp) baselen = len; else baselen = cp - path; strbuf_reset(&sb); strbuf_add(&sb, path, baselen); if (!is_directory(sb.buf)) break; strbuf_reset(&sb); strbuf_add(&sb, path, prevlen); strbuf_reset(&subdir); strbuf_add(&subdir, path+prevlen, baselen-prevlen); cdir.d_name = subdir.buf; state = treat_path(dir, NULL, &cdir, istate, &sb, prevlen, pathspec); if (state != path_recurse) break; /* do not recurse into it */ if (len <= baselen) break; /* finished checking */ } add_path_to_appropriate_result_list(dir, NULL, &cdir, istate, &sb, baselen, pathspec, state); strbuf_release(&subdir); strbuf_release(&sb); return state == path_recurse; } static const char *get_ident_string(void) { static struct strbuf sb = STRBUF_INIT; struct utsname uts; if (sb.len) return sb.buf; if (uname(&uts) < 0) die_errno(_("failed to get kernel name and information")); strbuf_addf(&sb, "Location %s, system %s", get_git_work_tree(), uts.sysname); return sb.buf; } static int ident_in_untracked(const struct untracked_cache *uc) { /* * Previous git versions may have saved many NUL separated * strings in the "ident" field, but it is insane to manage * many locations, so just take care of the first one. */ return !strcmp(uc->ident.buf, get_ident_string()); } static void set_untracked_ident(struct untracked_cache *uc) { strbuf_reset(&uc->ident); strbuf_addstr(&uc->ident, get_ident_string()); /* * This strbuf used to contain a list of NUL separated * strings, so save NUL too for backward compatibility. */ strbuf_addch(&uc->ident, 0); } static void new_untracked_cache(struct index_state *istate) { struct untracked_cache *uc = xcalloc(1, sizeof(*uc)); strbuf_init(&uc->ident, 100); uc->exclude_per_dir = ".gitignore"; /* should be the same flags used by git-status */ uc->dir_flags = DIR_SHOW_OTHER_DIRECTORIES | DIR_HIDE_EMPTY_DIRECTORIES; set_untracked_ident(uc); istate->untracked = uc; istate->cache_changed |= UNTRACKED_CHANGED; } void add_untracked_cache(struct index_state *istate) { if (!istate->untracked) { new_untracked_cache(istate); } else { if (!ident_in_untracked(istate->untracked)) { free_untracked_cache(istate->untracked); new_untracked_cache(istate); } } } void remove_untracked_cache(struct index_state *istate) { if (istate->untracked) { free_untracked_cache(istate->untracked); istate->untracked = NULL; istate->cache_changed |= UNTRACKED_CHANGED; } } static struct untracked_cache_dir *validate_untracked_cache(struct dir_struct *dir, int base_len, const struct pathspec *pathspec) { struct untracked_cache_dir *root; static int untracked_cache_disabled = -1; if (!dir->untracked) return NULL; if (untracked_cache_disabled < 0) untracked_cache_disabled = git_env_bool("GIT_DISABLE_UNTRACKED_CACHE", 0); if (untracked_cache_disabled) return NULL; /* * We only support $GIT_DIR/info/exclude and core.excludesfile * as the global ignore rule files. Any other additions * (e.g. from command line) invalidate the cache. This * condition also catches running setup_standard_excludes() * before setting dir->untracked! */ if (dir->unmanaged_exclude_files) return NULL; /* * Optimize for the main use case only: whole-tree git * status. More work involved in treat_leading_path() if we * use cache on just a subset of the worktree. pathspec * support could make the matter even worse. */ if (base_len || (pathspec && pathspec->nr)) return NULL; /* Different set of flags may produce different results */ if (dir->flags != dir->untracked->dir_flags || /* * See treat_directory(), case index_nonexistent. Without * this flag, we may need to also cache .git file content * for the resolve_gitlink_ref() call, which we don't. */ !(dir->flags & DIR_SHOW_OTHER_DIRECTORIES) || /* We don't support collecting ignore files */ (dir->flags & (DIR_SHOW_IGNORED | DIR_SHOW_IGNORED_TOO | DIR_COLLECT_IGNORED))) return NULL; /* * If we use .gitignore in the cache and now you change it to * .gitexclude, everything will go wrong. */ if (dir->exclude_per_dir != dir->untracked->exclude_per_dir && strcmp(dir->exclude_per_dir, dir->untracked->exclude_per_dir)) return NULL; /* * EXC_CMDL is not considered in the cache. If people set it, * skip the cache. */ if (dir->exclude_list_group[EXC_CMDL].nr) return NULL; if (!ident_in_untracked(dir->untracked)) { warning(_("untracked cache is disabled on this system or location")); return NULL; } if (!dir->untracked->root) FLEX_ALLOC_STR(dir->untracked->root, name, ""); /* Validate $GIT_DIR/info/exclude and core.excludesfile */ root = dir->untracked->root; if (!oideq(&dir->ss_info_exclude.oid, &dir->untracked->ss_info_exclude.oid)) { invalidate_gitignore(dir->untracked, root); dir->untracked->ss_info_exclude = dir->ss_info_exclude; } if (!oideq(&dir->ss_excludes_file.oid, &dir->untracked->ss_excludes_file.oid)) { invalidate_gitignore(dir->untracked, root); dir->untracked->ss_excludes_file = dir->ss_excludes_file; } /* Make sure this directory is not dropped out at saving phase */ root->recurse = 1; return root; } static void emit_traversal_statistics(struct dir_struct *dir, struct repository *repo, const char *path, int path_len) { if (!trace2_is_enabled()) return; if (!path_len) { trace2_data_string("read_directory", repo, "path", ""); } else { struct strbuf tmp = STRBUF_INIT; strbuf_add(&tmp, path, path_len); trace2_data_string("read_directory", repo, "path", tmp.buf); strbuf_release(&tmp); } trace2_data_intmax("read_directory", repo, "directories-visited", dir->visited_directories); trace2_data_intmax("read_directory", repo, "paths-visited", dir->visited_paths); if (!dir->untracked) return; trace2_data_intmax("read_directory", repo, "node-creation", dir->untracked->dir_created); trace2_data_intmax("read_directory", repo, "gitignore-invalidation", dir->untracked->gitignore_invalidated); trace2_data_intmax("read_directory", repo, "directory-invalidation", dir->untracked->dir_invalidated); trace2_data_intmax("read_directory", repo, "opendir", dir->untracked->dir_opened); } int read_directory(struct dir_struct *dir, struct index_state *istate, const char *path, int len, const struct pathspec *pathspec) { struct untracked_cache_dir *untracked; trace2_region_enter("dir", "read_directory", istate->repo); dir->visited_paths = 0; dir->visited_directories = 0; if (has_symlink_leading_path(path, len)) { trace2_region_leave("dir", "read_directory", istate->repo); return dir->nr; } untracked = validate_untracked_cache(dir, len, pathspec); if (!untracked) /* * make sure untracked cache code path is disabled, * e.g. prep_exclude() */ dir->untracked = NULL; if (!len || treat_leading_path(dir, istate, path, len, pathspec)) read_directory_recursive(dir, istate, path, len, untracked, 0, 0, pathspec); QSORT(dir->entries, dir->nr, cmp_dir_entry); QSORT(dir->ignored, dir->ignored_nr, cmp_dir_entry); emit_traversal_statistics(dir, istate->repo, path, len); trace2_region_leave("dir", "read_directory", istate->repo); if (dir->untracked) { static int force_untracked_cache = -1; if (force_untracked_cache < 0) force_untracked_cache = git_env_bool("GIT_FORCE_UNTRACKED_CACHE", 0); if (force_untracked_cache && dir->untracked == istate->untracked && (dir->untracked->dir_opened || dir->untracked->gitignore_invalidated || dir->untracked->dir_invalidated)) istate->cache_changed |= UNTRACKED_CHANGED; if (dir->untracked != istate->untracked) { FREE_AND_NULL(dir->untracked); } } return dir->nr; } int file_exists(const char *f) { struct stat sb; return lstat(f, &sb) == 0; } int repo_file_exists(struct repository *repo, const char *path) { if (repo != the_repository) BUG("do not know how to check file existence in arbitrary repo"); return file_exists(path); } static int cmp_icase(char a, char b) { if (a == b) return 0; if (ignore_case) return toupper(a) - toupper(b); return a - b; } /* * Given two normalized paths (a trailing slash is ok), if subdir is * outside dir, return -1. Otherwise return the offset in subdir that * can be used as relative path to dir. */ int dir_inside_of(const char *subdir, const char *dir) { int offset = 0; assert(dir && subdir && *dir && *subdir); while (*dir && *subdir && !cmp_icase(*dir, *subdir)) { dir++; subdir++; offset++; } /* hel[p]/me vs hel[l]/yeah */ if (*dir && *subdir) return -1; if (!*subdir) return !*dir ? offset : -1; /* same dir */ /* foo/[b]ar vs foo/[] */ if (is_dir_sep(dir[-1])) return is_dir_sep(subdir[-1]) ? offset : -1; /* foo[/]bar vs foo[] */ return is_dir_sep(*subdir) ? offset + 1 : -1; } int is_inside_dir(const char *dir) { char *cwd; int rc; if (!dir) return 0; cwd = xgetcwd(); rc = (dir_inside_of(cwd, dir) >= 0); free(cwd); return rc; } int is_empty_dir(const char *path) { DIR *dir = opendir(path); struct dirent *e; int ret = 1; if (!dir) return 0; e = readdir_skip_dot_and_dotdot(dir); if (e) ret = 0; closedir(dir); return ret; } static int remove_dir_recurse(struct strbuf *path, int flag, int *kept_up) { DIR *dir; struct dirent *e; int ret = 0, original_len = path->len, len, kept_down = 0; int only_empty = (flag & REMOVE_DIR_EMPTY_ONLY); int keep_toplevel = (flag & REMOVE_DIR_KEEP_TOPLEVEL); struct object_id submodule_head; if ((flag & REMOVE_DIR_KEEP_NESTED_GIT) && !resolve_gitlink_ref(path->buf, "HEAD", &submodule_head)) { /* Do not descend and nuke a nested git work tree. */ if (kept_up) *kept_up = 1; return 0; } flag &= ~REMOVE_DIR_KEEP_TOPLEVEL; dir = opendir(path->buf); if (!dir) { if (errno == ENOENT) return keep_toplevel ? -1 : 0; else if (errno == EACCES && !keep_toplevel) /* * An empty dir could be removable even if it * is unreadable: */ return rmdir(path->buf); else return -1; } strbuf_complete(path, '/'); len = path->len; while ((e = readdir_skip_dot_and_dotdot(dir)) != NULL) { struct stat st; strbuf_setlen(path, len); strbuf_addstr(path, e->d_name); if (lstat(path->buf, &st)) { if (errno == ENOENT) /* * file disappeared, which is what we * wanted anyway */ continue; /* fall through */ } else if (S_ISDIR(st.st_mode)) { if (!remove_dir_recurse(path, flag, &kept_down)) continue; /* happy */ } else if (!only_empty && (!unlink(path->buf) || errno == ENOENT)) { continue; /* happy, too */ } /* path too long, stat fails, or non-directory still exists */ ret = -1; break; } closedir(dir); strbuf_setlen(path, original_len); if (!ret && !keep_toplevel && !kept_down) ret = (!rmdir(path->buf) || errno == ENOENT) ? 0 : -1; else if (kept_up) /* * report the uplevel that it is not an error that we * did not rmdir() our directory. */ *kept_up = !ret; return ret; } int remove_dir_recursively(struct strbuf *path, int flag) { return remove_dir_recurse(path, flag, NULL); } static GIT_PATH_FUNC(git_path_info_exclude, "info/exclude") void setup_standard_excludes(struct dir_struct *dir) { dir->exclude_per_dir = ".gitignore"; /* core.excludesfile defaulting to $XDG_CONFIG_HOME/git/ignore */ if (!excludes_file) excludes_file = xdg_config_home("ignore"); if (excludes_file && !access_or_warn(excludes_file, R_OK, 0)) add_patterns_from_file_1(dir, excludes_file, dir->untracked ? &dir->ss_excludes_file : NULL); /* per repository user preference */ if (startup_info->have_repository) { const char *path = git_path_info_exclude(); if (!access_or_warn(path, R_OK, 0)) add_patterns_from_file_1(dir, path, dir->untracked ? &dir->ss_info_exclude : NULL); } } char *get_sparse_checkout_filename(void) { return git_pathdup("info/sparse-checkout"); } int get_sparse_checkout_patterns(struct pattern_list *pl) { int res; char *sparse_filename = get_sparse_checkout_filename(); pl->use_cone_patterns = core_sparse_checkout_cone; res = add_patterns_from_file_to_list(sparse_filename, "", 0, pl, NULL, 0); free(sparse_filename); return res; } int remove_path(const char *name) { char *slash; if (unlink(name) && !is_missing_file_error(errno)) return -1; slash = strrchr(name, '/'); if (slash) { char *dirs = xstrdup(name); slash = dirs + (slash - name); do { *slash = '\0'; } while (rmdir(dirs) == 0 && (slash = strrchr(dirs, '/'))); free(dirs); } return 0; } /* * Frees memory within dir which was allocated, and resets fields for further * use. Does not free dir itself. */ void dir_clear(struct dir_struct *dir) { int i, j; struct exclude_list_group *group; struct pattern_list *pl; struct exclude_stack *stk; struct dir_struct new = DIR_INIT; for (i = EXC_CMDL; i <= EXC_FILE; i++) { group = &dir->exclude_list_group[i]; for (j = 0; j < group->nr; j++) { pl = &group->pl[j]; if (i == EXC_DIRS) free((char *)pl->src); clear_pattern_list(pl); } free(group->pl); } for (i = 0; i < dir->ignored_nr; i++) free(dir->ignored[i]); for (i = 0; i < dir->nr; i++) free(dir->entries[i]); free(dir->ignored); free(dir->entries); stk = dir->exclude_stack; while (stk) { struct exclude_stack *prev = stk->prev; free(stk); stk = prev; } strbuf_release(&dir->basebuf); memcpy(dir, &new, sizeof(*dir)); } struct ondisk_untracked_cache { struct stat_data info_exclude_stat; struct stat_data excludes_file_stat; uint32_t dir_flags; }; #define ouc_offset(x) offsetof(struct ondisk_untracked_cache, x) struct write_data { int index; /* number of written untracked_cache_dir */ struct ewah_bitmap *check_only; /* from untracked_cache_dir */ struct ewah_bitmap *valid; /* from untracked_cache_dir */ struct ewah_bitmap *sha1_valid; /* set if exclude_sha1 is not null */ struct strbuf out; struct strbuf sb_stat; struct strbuf sb_sha1; }; static void stat_data_to_disk(struct stat_data *to, const struct stat_data *from) { to->sd_ctime.sec = htonl(from->sd_ctime.sec); to->sd_ctime.nsec = htonl(from->sd_ctime.nsec); to->sd_mtime.sec = htonl(from->sd_mtime.sec); to->sd_mtime.nsec = htonl(from->sd_mtime.nsec); to->sd_dev = htonl(from->sd_dev); to->sd_ino = htonl(from->sd_ino); to->sd_uid = htonl(from->sd_uid); to->sd_gid = htonl(from->sd_gid); to->sd_size = htonl(from->sd_size); } static void write_one_dir(struct untracked_cache_dir *untracked, struct write_data *wd) { struct stat_data stat_data; struct strbuf *out = &wd->out; unsigned char intbuf[16]; unsigned int intlen, value; int i = wd->index++; /* * untracked_nr should be reset whenever valid is clear, but * for safety.. */ if (!untracked->valid) { untracked->untracked_nr = 0; untracked->check_only = 0; } if (untracked->check_only) ewah_set(wd->check_only, i); if (untracked->valid) { ewah_set(wd->valid, i); stat_data_to_disk(&stat_data, &untracked->stat_data); strbuf_add(&wd->sb_stat, &stat_data, sizeof(stat_data)); } if (!is_null_oid(&untracked->exclude_oid)) { ewah_set(wd->sha1_valid, i); strbuf_add(&wd->sb_sha1, untracked->exclude_oid.hash, the_hash_algo->rawsz); } intlen = encode_varint(untracked->untracked_nr, intbuf); strbuf_add(out, intbuf, intlen); /* skip non-recurse directories */ for (i = 0, value = 0; i < untracked->dirs_nr; i++) if (untracked->dirs[i]->recurse) value++; intlen = encode_varint(value, intbuf); strbuf_add(out, intbuf, intlen); strbuf_add(out, untracked->name, strlen(untracked->name) + 1); for (i = 0; i < untracked->untracked_nr; i++) strbuf_add(out, untracked->untracked[i], strlen(untracked->untracked[i]) + 1); for (i = 0; i < untracked->dirs_nr; i++) if (untracked->dirs[i]->recurse) write_one_dir(untracked->dirs[i], wd); } void write_untracked_extension(struct strbuf *out, struct untracked_cache *untracked) { struct ondisk_untracked_cache *ouc; struct write_data wd; unsigned char varbuf[16]; int varint_len; const unsigned hashsz = the_hash_algo->rawsz; CALLOC_ARRAY(ouc, 1); stat_data_to_disk(&ouc->info_exclude_stat, &untracked->ss_info_exclude.stat); stat_data_to_disk(&ouc->excludes_file_stat, &untracked->ss_excludes_file.stat); ouc->dir_flags = htonl(untracked->dir_flags); varint_len = encode_varint(untracked->ident.len, varbuf); strbuf_add(out, varbuf, varint_len); strbuf_addbuf(out, &untracked->ident); strbuf_add(out, ouc, sizeof(*ouc)); strbuf_add(out, untracked->ss_info_exclude.oid.hash, hashsz); strbuf_add(out, untracked->ss_excludes_file.oid.hash, hashsz); strbuf_add(out, untracked->exclude_per_dir, strlen(untracked->exclude_per_dir) + 1); FREE_AND_NULL(ouc); if (!untracked->root) { varint_len = encode_varint(0, varbuf); strbuf_add(out, varbuf, varint_len); return; } wd.index = 0; wd.check_only = ewah_new(); wd.valid = ewah_new(); wd.sha1_valid = ewah_new(); strbuf_init(&wd.out, 1024); strbuf_init(&wd.sb_stat, 1024); strbuf_init(&wd.sb_sha1, 1024); write_one_dir(untracked->root, &wd); varint_len = encode_varint(wd.index, varbuf); strbuf_add(out, varbuf, varint_len); strbuf_addbuf(out, &wd.out); ewah_serialize_strbuf(wd.valid, out); ewah_serialize_strbuf(wd.check_only, out); ewah_serialize_strbuf(wd.sha1_valid, out); strbuf_addbuf(out, &wd.sb_stat); strbuf_addbuf(out, &wd.sb_sha1); strbuf_addch(out, '\0'); /* safe guard for string lists */ ewah_free(wd.valid); ewah_free(wd.check_only); ewah_free(wd.sha1_valid); strbuf_release(&wd.out); strbuf_release(&wd.sb_stat); strbuf_release(&wd.sb_sha1); } static void free_untracked(struct untracked_cache_dir *ucd) { int i; if (!ucd) return; for (i = 0; i < ucd->dirs_nr; i++) free_untracked(ucd->dirs[i]); for (i = 0; i < ucd->untracked_nr; i++) free(ucd->untracked[i]); free(ucd->untracked); free(ucd->dirs); free(ucd); } void free_untracked_cache(struct untracked_cache *uc) { if (uc) free_untracked(uc->root); free(uc); } struct read_data { int index; struct untracked_cache_dir **ucd; struct ewah_bitmap *check_only; struct ewah_bitmap *valid; struct ewah_bitmap *sha1_valid; const unsigned char *data; const unsigned char *end; }; static void stat_data_from_disk(struct stat_data *to, const unsigned char *data) { memcpy(to, data, sizeof(*to)); to->sd_ctime.sec = ntohl(to->sd_ctime.sec); to->sd_ctime.nsec = ntohl(to->sd_ctime.nsec); to->sd_mtime.sec = ntohl(to->sd_mtime.sec); to->sd_mtime.nsec = ntohl(to->sd_mtime.nsec); to->sd_dev = ntohl(to->sd_dev); to->sd_ino = ntohl(to->sd_ino); to->sd_uid = ntohl(to->sd_uid); to->sd_gid = ntohl(to->sd_gid); to->sd_size = ntohl(to->sd_size); } static int read_one_dir(struct untracked_cache_dir **untracked_, struct read_data *rd) { struct untracked_cache_dir ud, *untracked; const unsigned char *data = rd->data, *end = rd->end; const unsigned char *eos; unsigned int value; int i; memset(&ud, 0, sizeof(ud)); value = decode_varint(&data); if (data > end) return -1; ud.recurse = 1; ud.untracked_alloc = value; ud.untracked_nr = value; if (ud.untracked_nr) ALLOC_ARRAY(ud.untracked, ud.untracked_nr); ud.dirs_alloc = ud.dirs_nr = decode_varint(&data); if (data > end) return -1; ALLOC_ARRAY(ud.dirs, ud.dirs_nr); eos = memchr(data, '\0', end - data); if (!eos || eos == end) return -1; *untracked_ = untracked = xmalloc(st_add3(sizeof(*untracked), eos - data, 1)); memcpy(untracked, &ud, sizeof(ud)); memcpy(untracked->name, data, eos - data + 1); data = eos + 1; for (i = 0; i < untracked->untracked_nr; i++) { eos = memchr(data, '\0', end - data); if (!eos || eos == end) return -1; untracked->untracked[i] = xmemdupz(data, eos - data); data = eos + 1; } rd->ucd[rd->index++] = untracked; rd->data = data; for (i = 0; i < untracked->dirs_nr; i++) { if (read_one_dir(untracked->dirs + i, rd) < 0) return -1; } return 0; } static void set_check_only(size_t pos, void *cb) { struct read_data *rd = cb; struct untracked_cache_dir *ud = rd->ucd[pos]; ud->check_only = 1; } static void read_stat(size_t pos, void *cb) { struct read_data *rd = cb; struct untracked_cache_dir *ud = rd->ucd[pos]; if (rd->data + sizeof(struct stat_data) > rd->end) { rd->data = rd->end + 1; return; } stat_data_from_disk(&ud->stat_data, rd->data); rd->data += sizeof(struct stat_data); ud->valid = 1; } static void read_oid(size_t pos, void *cb) { struct read_data *rd = cb; struct untracked_cache_dir *ud = rd->ucd[pos]; if (rd->data + the_hash_algo->rawsz > rd->end) { rd->data = rd->end + 1; return; } oidread(&ud->exclude_oid, rd->data); rd->data += the_hash_algo->rawsz; } static void load_oid_stat(struct oid_stat *oid_stat, const unsigned char *data, const unsigned char *sha1) { stat_data_from_disk(&oid_stat->stat, data); oidread(&oid_stat->oid, sha1); oid_stat->valid = 1; } struct untracked_cache *read_untracked_extension(const void *data, unsigned long sz) { struct untracked_cache *uc; struct read_data rd; const unsigned char *next = data, *end = (const unsigned char *)data + sz; const char *ident; int ident_len; ssize_t len; const char *exclude_per_dir; const unsigned hashsz = the_hash_algo->rawsz; const unsigned offset = sizeof(struct ondisk_untracked_cache); const unsigned exclude_per_dir_offset = offset + 2 * hashsz; if (sz <= 1 || end[-1] != '\0') return NULL; end--; ident_len = decode_varint(&next); if (next + ident_len > end) return NULL; ident = (const char *)next; next += ident_len; if (next + exclude_per_dir_offset + 1 > end) return NULL; CALLOC_ARRAY(uc, 1); strbuf_init(&uc->ident, ident_len); strbuf_add(&uc->ident, ident, ident_len); load_oid_stat(&uc->ss_info_exclude, next + ouc_offset(info_exclude_stat), next + offset); load_oid_stat(&uc->ss_excludes_file, next + ouc_offset(excludes_file_stat), next + offset + hashsz); uc->dir_flags = get_be32(next + ouc_offset(dir_flags)); exclude_per_dir = (const char *)next + exclude_per_dir_offset; uc->exclude_per_dir = xstrdup(exclude_per_dir); /* NUL after exclude_per_dir is covered by sizeof(*ouc) */ next += exclude_per_dir_offset + strlen(exclude_per_dir) + 1; if (next >= end) goto done2; len = decode_varint(&next); if (next > end || len == 0) goto done2; rd.valid = ewah_new(); rd.check_only = ewah_new(); rd.sha1_valid = ewah_new(); rd.data = next; rd.end = end; rd.index = 0; ALLOC_ARRAY(rd.ucd, len); if (read_one_dir(&uc->root, &rd) || rd.index != len) goto done; next = rd.data; len = ewah_read_mmap(rd.valid, next, end - next); if (len < 0) goto done; next += len; len = ewah_read_mmap(rd.check_only, next, end - next); if (len < 0) goto done; next += len; len = ewah_read_mmap(rd.sha1_valid, next, end - next); if (len < 0) goto done; ewah_each_bit(rd.check_only, set_check_only, &rd); rd.data = next + len; ewah_each_bit(rd.valid, read_stat, &rd); ewah_each_bit(rd.sha1_valid, read_oid, &rd); next = rd.data; done: free(rd.ucd); ewah_free(rd.valid); ewah_free(rd.check_only); ewah_free(rd.sha1_valid); done2: if (next != end) { free_untracked_cache(uc); uc = NULL; } return uc; } static void invalidate_one_directory(struct untracked_cache *uc, struct untracked_cache_dir *ucd) { uc->dir_invalidated++; ucd->valid = 0; ucd->untracked_nr = 0; } /* * Normally when an entry is added or removed from a directory, * invalidating that directory is enough. No need to touch its * ancestors. When a directory is shown as "foo/bar/" in git-status * however, deleting or adding an entry may have cascading effect. * * Say the "foo/bar/file" has become untracked, we need to tell the * untracked_cache_dir of "foo" that "bar/" is not an untracked * directory any more (because "bar" is managed by foo as an untracked * "file"). * * Similarly, if "foo/bar/file" moves from untracked to tracked and it * was the last untracked entry in the entire "foo", we should show * "foo/" instead. Which means we have to invalidate past "bar" up to * "foo". * * This function traverses all directories from root to leaf. If there * is a chance of one of the above cases happening, we invalidate back * to root. Otherwise we just invalidate the leaf. There may be a more * sophisticated way than checking for SHOW_OTHER_DIRECTORIES to * detect these cases and avoid unnecessary invalidation, for example, * checking for the untracked entry named "bar/" in "foo", but for now * stick to something safe and simple. */ static int invalidate_one_component(struct untracked_cache *uc, struct untracked_cache_dir *dir, const char *path, int len) { const char *rest = strchr(path, '/'); if (rest) { int component_len = rest - path; struct untracked_cache_dir *d = lookup_untracked(uc, dir, path, component_len); int ret = invalidate_one_component(uc, d, rest + 1, len - (component_len + 1)); if (ret) invalidate_one_directory(uc, dir); return ret; } invalidate_one_directory(uc, dir); return uc->dir_flags & DIR_SHOW_OTHER_DIRECTORIES; } void untracked_cache_invalidate_path(struct index_state *istate, const char *path, int safe_path) { if (!istate->untracked || !istate->untracked->root) return; if (!safe_path && !verify_path(path, 0)) return; invalidate_one_component(istate->untracked, istate->untracked->root, path, strlen(path)); } void untracked_cache_remove_from_index(struct index_state *istate, const char *path) { untracked_cache_invalidate_path(istate, path, 1); } void untracked_cache_add_to_index(struct index_state *istate, const char *path) { untracked_cache_invalidate_path(istate, path, 1); } static void connect_wt_gitdir_in_nested(const char *sub_worktree, const char *sub_gitdir) { int i; struct repository subrepo; struct strbuf sub_wt = STRBUF_INIT; struct strbuf sub_gd = STRBUF_INIT; const struct submodule *sub; /* If the submodule has no working tree, we can ignore it. */ if (repo_init(&subrepo, sub_gitdir, sub_worktree)) return; if (repo_read_index(&subrepo) < 0) die(_("index file corrupt in repo %s"), subrepo.gitdir); /* TODO: audit for interaction with sparse-index. */ ensure_full_index(subrepo.index); for (i = 0; i < subrepo.index->cache_nr; i++) { const struct cache_entry *ce = subrepo.index->cache[i]; if (!S_ISGITLINK(ce->ce_mode)) continue; while (i + 1 < subrepo.index->cache_nr && !strcmp(ce->name, subrepo.index->cache[i + 1]->name)) /* * Skip entries with the same name in different stages * to make sure an entry is returned only once. */ i++; sub = submodule_from_path(&subrepo, null_oid(), ce->name); if (!sub || !is_submodule_active(&subrepo, ce->name)) /* .gitmodules broken or inactive sub */ continue; strbuf_reset(&sub_wt); strbuf_reset(&sub_gd); strbuf_addf(&sub_wt, "%s/%s", sub_worktree, sub->path); strbuf_addf(&sub_gd, "%s/modules/%s", sub_gitdir, sub->name); connect_work_tree_and_git_dir(sub_wt.buf, sub_gd.buf, 1); } strbuf_release(&sub_wt); strbuf_release(&sub_gd); repo_clear(&subrepo); } void connect_work_tree_and_git_dir(const char *work_tree_, const char *git_dir_, int recurse_into_nested) { struct strbuf gitfile_sb = STRBUF_INIT; struct strbuf cfg_sb = STRBUF_INIT; struct strbuf rel_path = STRBUF_INIT; char *git_dir, *work_tree; /* Prepare .git file */ strbuf_addf(&gitfile_sb, "%s/.git", work_tree_); if (safe_create_leading_directories_const(gitfile_sb.buf)) die(_("could not create directories for %s"), gitfile_sb.buf); /* Prepare config file */ strbuf_addf(&cfg_sb, "%s/config", git_dir_); if (safe_create_leading_directories_const(cfg_sb.buf)) die(_("could not create directories for %s"), cfg_sb.buf); git_dir = real_pathdup(git_dir_, 1); work_tree = real_pathdup(work_tree_, 1); /* Write .git file */ write_file(gitfile_sb.buf, "gitdir: %s", relative_path(git_dir, work_tree, &rel_path)); /* Update core.worktree setting */ git_config_set_in_file(cfg_sb.buf, "core.worktree", relative_path(work_tree, git_dir, &rel_path)); strbuf_release(&gitfile_sb); strbuf_release(&cfg_sb); strbuf_release(&rel_path); if (recurse_into_nested) connect_wt_gitdir_in_nested(work_tree, git_dir); free(work_tree); free(git_dir); } /* * Migrate the git directory of the given path from old_git_dir to new_git_dir. */ void relocate_gitdir(const char *path, const char *old_git_dir, const char *new_git_dir) { if (rename(old_git_dir, new_git_dir) < 0) die_errno(_("could not migrate git directory from '%s' to '%s'"), old_git_dir, new_git_dir); connect_work_tree_and_git_dir(path, new_git_dir, 0); }