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@@ -1770,6 +1770,7 @@ static void *default_alloc(void *_ud, void *ptr, size_t oldsize, size_t size) {
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* updated to its new location. */
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if (block->next) block->next->prev = block;
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if (block->prev) block->prev->next = block;
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+ if (ud->head == from) ud->head = block;
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}
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} else {
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/* Insert at head of linked list. */
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@@ -1798,7 +1799,7 @@ static void default_alloc_cleanup(void *_ud) {
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static bool default_err(void *ud, const upb_status *status) {
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UPB_UNUSED(ud);
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- fprintf(stderr, "upb error: %s\n", upb_status_errmsg(status));
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+ UPB_UNUSED(status);
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return false;
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}
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@@ -1919,7 +1920,6 @@ static size_t align_up(size_t size) {
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UPB_FORCEINLINE static void *seeded_alloc(void *ud, void *ptr, size_t oldsize,
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size_t size) {
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upb_seededalloc *a = ud;
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- UPB_UNUSED(ptr);
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size = align_up(size);
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@@ -1937,7 +1937,11 @@ UPB_FORCEINLINE static void *seeded_alloc(void *ud, void *ptr, size_t oldsize,
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/* Is `ptr` part of the user-provided initial block? Don't pass it to the
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* default allocator if so; otherwise, it may try to realloc() the block. */
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if (chptr >= a->mem_base && chptr < a->mem_limit) {
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- return a->alloc(a->alloc_ud, NULL, 0, size);
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+ void *ret;
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+ assert(chptr + oldsize <= a->mem_limit);
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+ ret = a->alloc(a->alloc_ud, NULL, 0, size);
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+ if (ret) memcpy(ret, ptr, oldsize);
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+ return ret;
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} else {
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return a->alloc(a->alloc_ud, ptr, oldsize, size);
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}
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@@ -3692,24 +3696,48 @@ const upb_def *upb_symtab_resolve(const upb_symtab *s, const char *base,
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return ret;
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}
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-/* Searches def and its children to find defs that have the same name as any
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- * def in "addtab." Returns true if any where found, and as a side-effect adds
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- * duplicates of these defs into addtab.
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+/* Starts a depth-first traversal at "def", recursing into any subdefs
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+ * (ie. submessage types). Adds duplicates of existing defs to addtab
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+ * wherever necessary, so that the resulting symtab will be consistent once
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+ * addtab is added.
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+ *
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+ * More specifically, if any def D is found in the DFS that:
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+ *
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+ * 1. can reach a def that is being replaced by something in addtab, AND
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+ *
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+ * 2. is not itself being replaced already (ie. this name doesn't already
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+ * exist in addtab)
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+ *
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+ * ...then a duplicate (new copy) of D will be added to addtab.
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+ *
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+ * Returns true if this happened for any def reachable from "def."
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+ *
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+ * It is slightly tricky to do this correctly in the presence of cycles. If we
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+ * detect that our DFS has hit a cycle, we might not yet know if any SCCs on
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+ * our stack can reach a def in addtab or not. Once we figure this out, that
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+ * answer needs to apply to *all* defs in these SCCs, even if we visited them
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+ * already. So a straight up one-pass cycle-detecting DFS won't work.
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*
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- * We use a modified depth-first traversal that traverses each SCC (which we
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- * already computed) as if it were a single node. This allows us to traverse
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- * the possibly-cyclic graph as if it were a DAG and to dup the correct set of
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- * nodes with O(n) time. */
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+ * To work around this problem, we traverse each SCC (which we already
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+ * computed, since these defs are frozen) as a single node. We first compute
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+ * whether the SCC as a whole can reach any def in addtab, then we dup (or not)
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+ * the entire SCC. This requires breaking the encapsulation of upb_refcounted,
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+ * since that is where we get the data about what SCC we are in. */
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static bool upb_resolve_dfs(const upb_def *def, upb_strtable *addtab,
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const void *new_owner, upb_inttable *seen,
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upb_status *s) {
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- /* Memoize results of this function for efficiency (since we're traversing a
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- * DAG this is not needed to limit the depth of the search). */
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upb_value v;
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bool need_dup;
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const upb_def *base;
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+ const void* memoize_key;
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+
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+ /* Memoize results of this function for efficiency (since we're traversing a
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+ * DAG this is not needed to limit the depth of the search).
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+ *
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+ * We memoize by SCC instead of by individual def. */
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+ memoize_key = def->base.group;
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- if (upb_inttable_lookup(seen, (uintptr_t)def, &v))
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+ if (upb_inttable_lookupptr(seen, memoize_key, &v))
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return upb_value_getbool(v);
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/* Visit submessages for all messages in the SCC. */
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@@ -3725,7 +3753,8 @@ static bool upb_resolve_dfs(const upb_def *def, upb_strtable *addtab,
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need_dup = true;
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}
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- /* For messages, continue the recursion by visiting all subdefs. */
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+ /* For messages, continue the recursion by visiting all subdefs, but only
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+ * ones in different SCCs. */
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m = upb_dyncast_msgdef(def);
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if (m) {
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upb_msg_field_iter i;
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@@ -3733,17 +3762,23 @@ static bool upb_resolve_dfs(const upb_def *def, upb_strtable *addtab,
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!upb_msg_field_done(&i);
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upb_msg_field_next(&i)) {
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upb_fielddef *f = upb_msg_iter_field(&i);
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+ const upb_def *subdef;
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+
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if (!upb_fielddef_hassubdef(f)) continue;
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+ subdef = upb_fielddef_subdef(f);
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+
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+ /* Skip subdefs in this SCC. */
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+ if (def->base.group == subdef->base.group) continue;
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+
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/* |= to avoid short-circuit; we need its side-effects. */
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- need_dup |= upb_resolve_dfs(
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- upb_fielddef_subdef(f), addtab, new_owner, seen, s);
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+ need_dup |= upb_resolve_dfs(subdef, addtab, new_owner, seen, s);
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if (!upb_ok(s)) return false;
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}
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}
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} while ((def = (upb_def*)def->base.next) != base);
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if (need_dup) {
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- /* Dup any defs that don't already have entries in addtab. */
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+ /* Dup all defs in this SCC that don't already have entries in addtab. */
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def = base;
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do {
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const char *name;
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@@ -3760,7 +3795,7 @@ static bool upb_resolve_dfs(const upb_def *def, upb_strtable *addtab,
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} while ((def = (upb_def*)def->base.next) != base);
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}
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- upb_inttable_insert(seen, (uintptr_t)def, upb_value_bool(need_dup));
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+ upb_inttable_insertptr(seen, memoize_key, upb_value_bool(need_dup));
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return need_dup;
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oom:
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Josh Haberman