/* * Generic reference iterator infrastructure. See refs-internal.h for * documentation about the design and use of reference iterators. */ #include "cache.h" #include "refs.h" #include "refs/refs-internal.h" #include "iterator.h" int ref_iterator_advance(struct ref_iterator *ref_iterator) { return ref_iterator->vtable->advance(ref_iterator); } int ref_iterator_peel(struct ref_iterator *ref_iterator, struct object_id *peeled) { return ref_iterator->vtable->peel(ref_iterator, peeled); } int ref_iterator_abort(struct ref_iterator *ref_iterator) { return ref_iterator->vtable->abort(ref_iterator); } void base_ref_iterator_init(struct ref_iterator *iter, struct ref_iterator_vtable *vtable, int ordered) { iter->vtable = vtable; iter->ordered = !!ordered; iter->refname = NULL; iter->oid = NULL; iter->flags = 0; } void base_ref_iterator_free(struct ref_iterator *iter) { /* Help make use-after-free bugs fail quickly: */ iter->vtable = NULL; free(iter); } struct empty_ref_iterator { struct ref_iterator base; }; static int empty_ref_iterator_advance(struct ref_iterator *ref_iterator) { return ref_iterator_abort(ref_iterator); } static int empty_ref_iterator_peel(struct ref_iterator *ref_iterator, struct object_id *peeled) { BUG("peel called for empty iterator"); } static int empty_ref_iterator_abort(struct ref_iterator *ref_iterator) { base_ref_iterator_free(ref_iterator); return ITER_DONE; } static struct ref_iterator_vtable empty_ref_iterator_vtable = { empty_ref_iterator_advance, empty_ref_iterator_peel, empty_ref_iterator_abort }; struct ref_iterator *empty_ref_iterator_begin(void) { struct empty_ref_iterator *iter = xcalloc(1, sizeof(*iter)); struct ref_iterator *ref_iterator = &iter->base; base_ref_iterator_init(ref_iterator, &empty_ref_iterator_vtable, 1); return ref_iterator; } int is_empty_ref_iterator(struct ref_iterator *ref_iterator) { return ref_iterator->vtable == &empty_ref_iterator_vtable; } struct merge_ref_iterator { struct ref_iterator base; struct ref_iterator *iter0, *iter1; ref_iterator_select_fn *select; void *cb_data; /* * A pointer to iter0 or iter1 (whichever is supplying the * current value), or NULL if advance has not yet been called. */ struct ref_iterator **current; }; static int merge_ref_iterator_advance(struct ref_iterator *ref_iterator) { struct merge_ref_iterator *iter = (struct merge_ref_iterator *)ref_iterator; int ok; if (!iter->current) { /* Initialize: advance both iterators to their first entries */ if ((ok = ref_iterator_advance(iter->iter0)) != ITER_OK) { iter->iter0 = NULL; if (ok == ITER_ERROR) goto error; } if ((ok = ref_iterator_advance(iter->iter1)) != ITER_OK) { iter->iter1 = NULL; if (ok == ITER_ERROR) goto error; } } else { /* * Advance the current iterator past the just-used * entry: */ if ((ok = ref_iterator_advance(*iter->current)) != ITER_OK) { *iter->current = NULL; if (ok == ITER_ERROR) goto error; } } /* Loop until we find an entry that we can yield. */ while (1) { struct ref_iterator **secondary; enum iterator_selection selection = iter->select(iter->iter0, iter->iter1, iter->cb_data); if (selection == ITER_SELECT_DONE) { return ref_iterator_abort(ref_iterator); } else if (selection == ITER_SELECT_ERROR) { ref_iterator_abort(ref_iterator); return ITER_ERROR; } if ((selection & ITER_CURRENT_SELECTION_MASK) == 0) { iter->current = &iter->iter0; secondary = &iter->iter1; } else { iter->current = &iter->iter1; secondary = &iter->iter0; } if (selection & ITER_SKIP_SECONDARY) { if ((ok = ref_iterator_advance(*secondary)) != ITER_OK) { *secondary = NULL; if (ok == ITER_ERROR) goto error; } } if (selection & ITER_YIELD_CURRENT) { iter->base.refname = (*iter->current)->refname; iter->base.oid = (*iter->current)->oid; iter->base.flags = (*iter->current)->flags; return ITER_OK; } } error: ref_iterator_abort(ref_iterator); return ITER_ERROR; } static int merge_ref_iterator_peel(struct ref_iterator *ref_iterator, struct object_id *peeled) { struct merge_ref_iterator *iter = (struct merge_ref_iterator *)ref_iterator; if (!iter->current) { BUG("peel called before advance for merge iterator"); } return ref_iterator_peel(*iter->current, peeled); } static int merge_ref_iterator_abort(struct ref_iterator *ref_iterator) { struct merge_ref_iterator *iter = (struct merge_ref_iterator *)ref_iterator; int ok = ITER_DONE; if (iter->iter0) { if (ref_iterator_abort(iter->iter0) != ITER_DONE) ok = ITER_ERROR; } if (iter->iter1) { if (ref_iterator_abort(iter->iter1) != ITER_DONE) ok = ITER_ERROR; } base_ref_iterator_free(ref_iterator); return ok; } static struct ref_iterator_vtable merge_ref_iterator_vtable = { merge_ref_iterator_advance, merge_ref_iterator_peel, merge_ref_iterator_abort }; struct ref_iterator *merge_ref_iterator_begin( int ordered, struct ref_iterator *iter0, struct ref_iterator *iter1, ref_iterator_select_fn *select, void *cb_data) { struct merge_ref_iterator *iter = xcalloc(1, sizeof(*iter)); struct ref_iterator *ref_iterator = &iter->base; /* * We can't do the same kind of is_empty_ref_iterator()-style * optimization here as overlay_ref_iterator_begin() does, * because we don't know the semantics of the select function. * It might, for example, implement "intersect" by passing * references through only if they exist in both iterators. */ base_ref_iterator_init(ref_iterator, &merge_ref_iterator_vtable, ordered); iter->iter0 = iter0; iter->iter1 = iter1; iter->select = select; iter->cb_data = cb_data; iter->current = NULL; return ref_iterator; } /* * A ref_iterator_select_fn that overlays the items from front on top * of those from back (like loose refs over packed refs). See * overlay_ref_iterator_begin(). */ static enum iterator_selection overlay_iterator_select( struct ref_iterator *front, struct ref_iterator *back, void *cb_data) { int cmp; if (!back) return front ? ITER_SELECT_0 : ITER_SELECT_DONE; else if (!front) return ITER_SELECT_1; cmp = strcmp(front->refname, back->refname); if (cmp < 0) return ITER_SELECT_0; else if (cmp > 0) return ITER_SELECT_1; else return ITER_SELECT_0_SKIP_1; } struct ref_iterator *overlay_ref_iterator_begin( struct ref_iterator *front, struct ref_iterator *back) { /* * Optimization: if one of the iterators is empty, return the * other one rather than incurring the overhead of wrapping * them. */ if (is_empty_ref_iterator(front)) { ref_iterator_abort(front); return back; } else if (is_empty_ref_iterator(back)) { ref_iterator_abort(back); return front; } else if (!front->ordered || !back->ordered) { BUG("overlay_ref_iterator requires ordered inputs"); } return merge_ref_iterator_begin(1, front, back, overlay_iterator_select, NULL); } struct prefix_ref_iterator { struct ref_iterator base; struct ref_iterator *iter0; char *prefix; int trim; }; /* Return -1, 0, 1 if refname is before, inside, or after the prefix. */ static int compare_prefix(const char *refname, const char *prefix) { while (*prefix) { if (*refname != *prefix) return ((unsigned char)*refname < (unsigned char)*prefix) ? -1 : +1; refname++; prefix++; } return 0; } static int prefix_ref_iterator_advance(struct ref_iterator *ref_iterator) { struct prefix_ref_iterator *iter = (struct prefix_ref_iterator *)ref_iterator; int ok; while ((ok = ref_iterator_advance(iter->iter0)) == ITER_OK) { int cmp = compare_prefix(iter->iter0->refname, iter->prefix); if (cmp < 0) continue; if (cmp > 0) { /* * If the source iterator is ordered, then we * can stop the iteration as soon as we see a * refname that comes after the prefix: */ if (iter->iter0->ordered) { ok = ref_iterator_abort(iter->iter0); break; } else { continue; } } if (iter->trim) { /* * It is nonsense to trim off characters that * you haven't already checked for via a * prefix check, whether via this * `prefix_ref_iterator` or upstream in * `iter0`). So if there wouldn't be at least * one character left in the refname after * trimming, report it as a bug: */ if (strlen(iter->iter0->refname) <= iter->trim) BUG("attempt to trim too many characters"); iter->base.refname = iter->iter0->refname + iter->trim; } else { iter->base.refname = iter->iter0->refname; } iter->base.oid = iter->iter0->oid; iter->base.flags = iter->iter0->flags; return ITER_OK; } iter->iter0 = NULL; if (ref_iterator_abort(ref_iterator) != ITER_DONE) return ITER_ERROR; return ok; } static int prefix_ref_iterator_peel(struct ref_iterator *ref_iterator, struct object_id *peeled) { struct prefix_ref_iterator *iter = (struct prefix_ref_iterator *)ref_iterator; return ref_iterator_peel(iter->iter0, peeled); } static int prefix_ref_iterator_abort(struct ref_iterator *ref_iterator) { struct prefix_ref_iterator *iter = (struct prefix_ref_iterator *)ref_iterator; int ok = ITER_DONE; if (iter->iter0) ok = ref_iterator_abort(iter->iter0); free(iter->prefix); base_ref_iterator_free(ref_iterator); return ok; } static struct ref_iterator_vtable prefix_ref_iterator_vtable = { prefix_ref_iterator_advance, prefix_ref_iterator_peel, prefix_ref_iterator_abort }; struct ref_iterator *prefix_ref_iterator_begin(struct ref_iterator *iter0, const char *prefix, int trim) { struct prefix_ref_iterator *iter; struct ref_iterator *ref_iterator; if (!*prefix && !trim) return iter0; /* optimization: no need to wrap iterator */ iter = xcalloc(1, sizeof(*iter)); ref_iterator = &iter->base; base_ref_iterator_init(ref_iterator, &prefix_ref_iterator_vtable, iter0->ordered); iter->iter0 = iter0; iter->prefix = xstrdup(prefix); iter->trim = trim; return ref_iterator; } struct ref_iterator *current_ref_iter = NULL; int do_for_each_repo_ref_iterator(struct repository *r, struct ref_iterator *iter, each_repo_ref_fn fn, void *cb_data) { int retval = 0, ok; struct ref_iterator *old_ref_iter = current_ref_iter; current_ref_iter = iter; while ((ok = ref_iterator_advance(iter)) == ITER_OK) { retval = fn(r, iter->refname, iter->oid, iter->flags, cb_data); if (retval) { /* * If ref_iterator_abort() returns ITER_ERROR, * we ignore that error in deference to the * callback function's return value. */ ref_iterator_abort(iter); goto out; } } out: current_ref_iter = old_ref_iter; if (ok == ITER_ERROR) return -1; return retval; }