/* SPDX-License-Identifier: GPL-2.0-or-later */ /** \file * \ingroup bli * * An (edge -> pointer) hash table. * Using unordered int-pairs as keys. * * \note The API matches BLI_ghash.c, but the implementation is different. */ #include #include #include #include #include "MEM_guardedalloc.h" #include "BLI_edgehash.h" #include "BLI_strict_flags.h" #include "BLI_utildefines.h" typedef struct _EdgeHash_Edge Edge; typedef struct _EdgeHash_Entry EdgeHashEntry; typedef struct EdgeHash { EdgeHashEntry *entries; int32_t *map; uint32_t slot_mask; uint capacity_exp; uint length; uint dummy_count; } EdgeHash; typedef struct EdgeSet { Edge *entries; int32_t *map; uint32_t slot_mask; uint capacity_exp; uint length; } EdgeSet; /* -------------------------------------------------------------------- */ /** \name Internal Helper Macros & Defines * \{ */ #define ENTRIES_CAPACITY(container) (uint)(1 << (container)->capacity_exp) #define MAP_CAPACITY(container) (uint)(1 << ((container)->capacity_exp + 1)) #define CLEAR_MAP(container) \ memset((container)->map, 0xFF, sizeof(int32_t) * MAP_CAPACITY(container)) #define UPDATE_SLOT_MASK(container) \ { \ (container)->slot_mask = MAP_CAPACITY(container) - 1; \ } \ ((void)0) #define PERTURB_SHIFT 5 #define ITER_SLOTS(CONTAINER, EDGE, SLOT, INDEX) \ uint32_t hash = calc_edge_hash(EDGE); \ uint32_t mask = (CONTAINER)->slot_mask; \ uint32_t perturb = hash; \ int32_t *map = (CONTAINER)->map; \ uint32_t SLOT = mask & hash; \ int INDEX = map[SLOT]; \ for (;; SLOT = mask & ((5 * SLOT) + 1 + perturb), perturb >>= PERTURB_SHIFT, INDEX = map[SLOT]) #define SLOT_EMPTY -1 #define SLOT_DUMMY -2 #define CAPACITY_EXP_DEFAULT 3 /** \} */ /* -------------------------------------------------------------------- */ /** \name Internal Edge API * \{ */ BLI_INLINE uint32_t calc_edge_hash(Edge edge) { return (edge.v_low << 8) ^ edge.v_high; } BLI_INLINE Edge init_edge(uint v0, uint v1) { /* If there are use cases where we need this it could be removed (or flag to allow), * for now this helps avoid incorrect usage (creating degenerate geometry). */ BLI_assert(v0 != v1); Edge edge; if (v0 < v1) { edge.v_low = v0; edge.v_high = v1; } else { edge.v_low = v1; edge.v_high = v0; } return edge; } BLI_INLINE bool edges_equal(Edge e1, Edge e2) { return memcmp(&e1, &e2, sizeof(Edge)) == 0; } static uint calc_capacity_exp_for_reserve(uint reserve) { uint result = 1; while (reserve >>= 1) { result++; } return result; } /** \} */ /* -------------------------------------------------------------------- */ /** \name Internal Utility API * \{ */ #define EH_INDEX_HAS_EDGE(eh, index, edge) \ ((index) >= 0 && edges_equal((edge), (eh)->entries[index].edge)) static void edgehash_free_values(EdgeHash *eh, EdgeHashFreeFP free_value) { if (free_value) { for (uint i = 0; i < eh->length; i++) { free_value(eh->entries[i].value); } } } BLI_INLINE void edgehash_insert_index(EdgeHash *eh, Edge edge, uint entry_index) { ITER_SLOTS (eh, edge, slot, index) { if (index == SLOT_EMPTY) { eh->map[slot] = (int32_t)entry_index; break; } } } BLI_INLINE EdgeHashEntry *edgehash_insert_at_slot(EdgeHash *eh, uint slot, Edge edge, void *value) { EdgeHashEntry *entry = &eh->entries[eh->length]; entry->edge = edge; entry->value = value; eh->map[slot] = (int32_t)eh->length; eh->length++; return entry; } BLI_INLINE bool edgehash_ensure_can_insert(EdgeHash *eh) { if (UNLIKELY(ENTRIES_CAPACITY(eh) <= eh->length + eh->dummy_count)) { eh->capacity_exp++; UPDATE_SLOT_MASK(eh); eh->dummy_count = 0; eh->entries = MEM_reallocN(eh->entries, sizeof(EdgeHashEntry) * ENTRIES_CAPACITY(eh)); eh->map = MEM_reallocN(eh->map, sizeof(int32_t) * MAP_CAPACITY(eh)); CLEAR_MAP(eh); for (uint i = 0; i < eh->length; i++) { edgehash_insert_index(eh, eh->entries[i].edge, i); } return true; } return false; } BLI_INLINE EdgeHashEntry *edgehash_insert(EdgeHash *eh, Edge edge, void *value) { ITER_SLOTS (eh, edge, slot, index) { if (index == SLOT_EMPTY) { return edgehash_insert_at_slot(eh, slot, edge, value); } if (index == SLOT_DUMMY) { eh->dummy_count--; return edgehash_insert_at_slot(eh, slot, edge, value); } } } BLI_INLINE EdgeHashEntry *edgehash_lookup_entry(const EdgeHash *eh, uint v0, uint v1) { Edge edge = init_edge(v0, v1); ITER_SLOTS (eh, edge, slot, index) { if (EH_INDEX_HAS_EDGE(eh, index, edge)) { return &eh->entries[index]; } if (index == SLOT_EMPTY) { return NULL; } } } BLI_INLINE void edgehash_change_index(EdgeHash *eh, Edge edge, int new_index) { ITER_SLOTS (eh, edge, slot, index) { if (EH_INDEX_HAS_EDGE(eh, index, edge)) { eh->map[slot] = new_index; break; } } } /** \} */ /* -------------------------------------------------------------------- */ /** \name Edge Hash API * \{ */ EdgeHash *BLI_edgehash_new_ex(const char *info, const uint reserve) { EdgeHash *eh = MEM_mallocN(sizeof(EdgeHash), info); eh->capacity_exp = calc_capacity_exp_for_reserve(reserve); UPDATE_SLOT_MASK(eh); eh->length = 0; eh->dummy_count = 0; eh->entries = MEM_calloc_arrayN(ENTRIES_CAPACITY(eh), sizeof(EdgeHashEntry), "eh entries"); eh->map = MEM_malloc_arrayN(MAP_CAPACITY(eh), sizeof(int32_t), "eh map"); CLEAR_MAP(eh); return eh; } EdgeHash *BLI_edgehash_new(const char *info) { return BLI_edgehash_new_ex(info, 1 << CAPACITY_EXP_DEFAULT); } void BLI_edgehash_free(EdgeHash *eh, EdgeHashFreeFP free_value) { edgehash_free_values(eh, free_value); MEM_freeN(eh->map); MEM_freeN(eh->entries); MEM_freeN(eh); } void BLI_edgehash_print(EdgeHash *eh) { printf("Edgehash at %p:\n", eh); printf(" Map:\n"); for (uint i = 0; i < MAP_CAPACITY(eh); i++) { int index = eh->map[i]; printf(" %u: %d", i, index); if (index >= 0) { EdgeHashEntry entry = eh->entries[index]; printf(" -> (%u, %u) -> %p", entry.edge.v_low, entry.edge.v_high, entry.value); } printf("\n"); } printf(" Entries:\n"); for (uint i = 0; i < ENTRIES_CAPACITY(eh); i++) { if (i == eh->length) { printf(" **** below is rest capacity ****\n"); } EdgeHashEntry entry = eh->entries[i]; printf(" %u: (%u, %u) -> %p\n", i, entry.edge.v_low, entry.edge.v_high, entry.value); } } void BLI_edgehash_insert(EdgeHash *eh, uint v0, uint v1, void *value) { edgehash_ensure_can_insert(eh); Edge edge = init_edge(v0, v1); edgehash_insert(eh, edge, value); } bool BLI_edgehash_reinsert(EdgeHash *eh, uint v0, uint v1, void *value) { Edge edge = init_edge(v0, v1); ITER_SLOTS (eh, edge, slot, index) { if (EH_INDEX_HAS_EDGE(eh, index, edge)) { eh->entries[index].value = value; return false; } if (index == SLOT_EMPTY) { if (edgehash_ensure_can_insert(eh)) { edgehash_insert(eh, edge, value); } else { edgehash_insert_at_slot(eh, slot, edge, value); } return true; } } } void *BLI_edgehash_lookup_default(const EdgeHash *eh, uint v0, uint v1, void *default_value) { EdgeHashEntry *entry = edgehash_lookup_entry(eh, v0, v1); return entry ? entry->value : default_value; } void *BLI_edgehash_lookup(const EdgeHash *eh, uint v0, uint v1) { EdgeHashEntry *entry = edgehash_lookup_entry(eh, v0, v1); return entry ? entry->value : NULL; } void **BLI_edgehash_lookup_p(EdgeHash *eh, uint v0, uint v1) { EdgeHashEntry *entry = edgehash_lookup_entry(eh, v0, v1); return entry ? &entry->value : NULL; } bool BLI_edgehash_ensure_p(EdgeHash *eh, uint v0, uint v1, void ***r_value) { Edge edge = init_edge(v0, v1); ITER_SLOTS (eh, edge, slot, index) { if (EH_INDEX_HAS_EDGE(eh, index, edge)) { *r_value = &eh->entries[index].value; return true; } if (index == SLOT_EMPTY) { if (edgehash_ensure_can_insert(eh)) { *r_value = &edgehash_insert(eh, edge, NULL)->value; } else { *r_value = &edgehash_insert_at_slot(eh, slot, edge, NULL)->value; } return false; } } } bool BLI_edgehash_remove(EdgeHash *eh, uint v0, uint v1, EdgeHashFreeFP free_value) { uint old_length = eh->length; void *value = BLI_edgehash_popkey(eh, v0, v1); if (free_value && value) { free_value(value); } return old_length > eh->length; } void *BLI_edgehash_popkey(EdgeHash *eh, uint v0, uint v1) { /* Same as #BLI_edgehash_remove but return the value, * no free value argument since it will be returned */ Edge edge = init_edge(v0, v1); ITER_SLOTS (eh, edge, slot, index) { if (EH_INDEX_HAS_EDGE(eh, index, edge)) { void *value = eh->entries[index].value; eh->length--; eh->dummy_count++; eh->map[slot] = SLOT_DUMMY; eh->entries[index] = eh->entries[eh->length]; if ((uint)index < eh->length) { edgehash_change_index(eh, eh->entries[index].edge, index); } return value; } if (index == SLOT_EMPTY) { return NULL; } } } bool BLI_edgehash_haskey(const EdgeHash *eh, uint v0, uint v1) { return edgehash_lookup_entry(eh, v0, v1) != NULL; } int BLI_edgehash_len(const EdgeHash *eh) { return (int)eh->length; } void BLI_edgehash_clear_ex(EdgeHash *eh, EdgeHashFreeFP free_value, const uint UNUSED(reserve)) { /* TODO: handle reserve */ edgehash_free_values(eh, free_value); eh->length = 0; eh->dummy_count = 0; eh->capacity_exp = CAPACITY_EXP_DEFAULT; CLEAR_MAP(eh); } void BLI_edgehash_clear(EdgeHash *eh, EdgeHashFreeFP free_value) { BLI_edgehash_clear_ex(eh, free_value, 0); } /** \} */ /* -------------------------------------------------------------------- */ /** \name Edge Hash Iterator API * \{ */ EdgeHashIterator *BLI_edgehashIterator_new(EdgeHash *eh) { EdgeHashIterator *ehi = MEM_mallocN(sizeof(EdgeHashIterator), __func__); BLI_edgehashIterator_init(ehi, eh); return ehi; } void BLI_edgehashIterator_init(EdgeHashIterator *ehi, EdgeHash *eh) { ehi->entries = eh->entries; ehi->length = eh->length; ehi->index = 0; } void BLI_edgehashIterator_free(EdgeHashIterator *ehi) { MEM_freeN(ehi); } /** \} */ /* -------------------------------------------------------------------- */ /** \name EdgeSet API * * Use edgehash API to give 'set' functionality * \{ */ #define ES_INDEX_HAS_EDGE(es, index, edge) \ (index) >= 0 && edges_equal((edge), (es)->entries[index]) EdgeSet *BLI_edgeset_new_ex(const char *info, const uint reserve) { EdgeSet *es = MEM_mallocN(sizeof(EdgeSet), info); es->capacity_exp = calc_capacity_exp_for_reserve(reserve); UPDATE_SLOT_MASK(es); es->length = 0; es->entries = MEM_malloc_arrayN(ENTRIES_CAPACITY(es), sizeof(Edge), "es entries"); es->map = MEM_malloc_arrayN(MAP_CAPACITY(es), sizeof(int32_t), "es map"); CLEAR_MAP(es); return es; } EdgeSet *BLI_edgeset_new(const char *info) { return BLI_edgeset_new_ex(info, 1 << CAPACITY_EXP_DEFAULT); } void BLI_edgeset_free(EdgeSet *es) { MEM_freeN(es->entries); MEM_freeN(es->map); MEM_freeN(es); } int BLI_edgeset_len(const EdgeSet *es) { return (int)es->length; } static void edgeset_insert_index(EdgeSet *es, Edge edge, uint entry_index) { ITER_SLOTS (es, edge, slot, index) { if (index == SLOT_EMPTY) { es->map[slot] = (int)entry_index; break; } } } BLI_INLINE void edgeset_ensure_can_insert(EdgeSet *es) { if (UNLIKELY(ENTRIES_CAPACITY(es) <= es->length)) { es->capacity_exp++; UPDATE_SLOT_MASK(es); es->entries = MEM_reallocN(es->entries, sizeof(Edge) * ENTRIES_CAPACITY(es)); es->map = MEM_reallocN(es->map, sizeof(int32_t) * MAP_CAPACITY(es)); CLEAR_MAP(es); for (uint i = 0; i < es->length; i++) { edgeset_insert_index(es, es->entries[i], i); } } } BLI_INLINE void edgeset_insert_at_slot(EdgeSet *es, uint slot, Edge edge) { es->entries[es->length] = edge; es->map[slot] = (int)es->length; es->length++; } bool BLI_edgeset_add(EdgeSet *es, uint v0, uint v1) { edgeset_ensure_can_insert(es); Edge edge = init_edge(v0, v1); ITER_SLOTS (es, edge, slot, index) { if (ES_INDEX_HAS_EDGE(es, index, edge)) { return false; } if (index == SLOT_EMPTY) { edgeset_insert_at_slot(es, slot, edge); return true; } } } void BLI_edgeset_insert(EdgeSet *es, uint v0, uint v1) { edgeset_ensure_can_insert(es); Edge edge = init_edge(v0, v1); ITER_SLOTS (es, edge, slot, index) { if (index == SLOT_EMPTY) { edgeset_insert_at_slot(es, slot, edge); return; } } } bool BLI_edgeset_haskey(const EdgeSet *es, uint v0, uint v1) { Edge edge = init_edge(v0, v1); ITER_SLOTS (es, edge, slot, index) { if (ES_INDEX_HAS_EDGE(es, index, edge)) { return true; } if (index == SLOT_EMPTY) { return false; } } } EdgeSetIterator *BLI_edgesetIterator_new(EdgeSet *es) { EdgeSetIterator *esi = MEM_mallocN(sizeof(EdgeSetIterator), __func__); esi->edges = es->entries; esi->length = es->length; esi->index = 0; return esi; } void BLI_edgesetIterator_free(EdgeSetIterator *esi) { MEM_freeN(esi); } /** \} */