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test2/source/blender/blenlib/intern/edgehash.c
Sergey Sharybin c1bc70b711 Cleanup: Add a copyright notice to files and use SPDX format 
A lot of files were missing copyright field in the header and
the Blender Foundation contributed to them in a sense of bug
fixing and general maintenance.

This change makes it explicit that those files are at least
partially copyrighted by the Blender Foundation.

Note that this does not make it so the Blender Foundation is
the only holder of the copyright in those files, and developers
who do not have a signed contract with the foundation still
hold the copyright as well.

Another aspect of this change is using SPDX format for the
header. We already used it for the license specification,
and now we state it for the copyright as well, following the
FAQ:

    https://reuse.software/faq/
2023-05-31 16:19:06 +02:00

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/* SPDX-FileCopyrightText: 2023 Blender Foundation
*
* 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 <limits.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#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);
}
/** \} */
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