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id_table.c
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id_table.c
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/* This file is included by symbol.c */
#include "id_table.h"
#ifndef ID_TABLE_DEBUG
#define ID_TABLE_DEBUG 0
#endif
#if ID_TABLE_DEBUG == 0
#define NDEBUG
#endif
#include "ruby_assert.h"
/*
* st
* 0: using st with debug information.
* 1: using st.
* array
* 11: simple array. ids = [ID1, ID2, ...], values = [val1, val2, ...]
* 12: simple array, and use rb_id_serial_t instead of ID.
* 13: simple array, and use rb_id_serial_t instead of ID. Swap recent access.
* 14: sorted array, and use rb_id_serial_t instead of ID.
* 15: sorted array, and use rb_id_serial_t instead of ID, linear small part.
* hash
* 21: funny falcon's Coalesced Hashing implementation [Feature #6962]
* 22: simple open addressing with quadratic probing.
* mix (array + hash)
* 31: array(12) (capa <= 32) + hash(22)
* 32: array(14) (capa <= 32) + hash(22)
* 33: array(12) (capa <= 64) + hash(22)
* 34: array(14) (capa <= 64) + hash(22)
* 34: array(15) (capa <= 64) + hash(22)
*/
#ifndef ID_TABLE_IMPL
#define ID_TABLE_IMPL 34
#endif
#if ID_TABLE_IMPL == 0
#define ID_TABLE_NAME st
#define ID_TABLE_IMPL_TYPE struct st_id_table
#define ID_TABLE_USE_ST 1
#define ID_TABLE_USE_ST_DEBUG 1
#elif ID_TABLE_IMPL == 1
#define ID_TABLE_NAME st
#define ID_TABLE_IMPL_TYPE struct st_id_table
#define ID_TABLE_USE_ST 1
#define ID_TABLE_USE_ST_DEBUG 0
#elif ID_TABLE_IMPL == 11
#define ID_TABLE_NAME list
#define ID_TABLE_IMPL_TYPE struct list_id_table
#define ID_TABLE_USE_LIST 1
#define ID_TABLE_USE_CALC_VALUES 1
#elif ID_TABLE_IMPL == 12
#define ID_TABLE_NAME list
#define ID_TABLE_IMPL_TYPE struct list_id_table
#define ID_TABLE_USE_LIST 1
#define ID_TABLE_USE_CALC_VALUES 1
#define ID_TABLE_USE_ID_SERIAL 1
#elif ID_TABLE_IMPL == 13
#define ID_TABLE_NAME list
#define ID_TABLE_IMPL_TYPE struct list_id_table
#define ID_TABLE_USE_LIST 1
#define ID_TABLE_USE_CALC_VALUES 1
#define ID_TABLE_USE_ID_SERIAL 1
#define ID_TABLE_SWAP_RECENT_ACCESS 1
#elif ID_TABLE_IMPL == 14
#define ID_TABLE_NAME list
#define ID_TABLE_IMPL_TYPE struct list_id_table
#define ID_TABLE_USE_LIST 1
#define ID_TABLE_USE_CALC_VALUES 1
#define ID_TABLE_USE_ID_SERIAL 1
#define ID_TABLE_USE_LIST_SORTED 1
#elif ID_TABLE_IMPL == 15
#define ID_TABLE_NAME list
#define ID_TABLE_IMPL_TYPE struct list_id_table
#define ID_TABLE_USE_LIST 1
#define ID_TABLE_USE_CALC_VALUES 1
#define ID_TABLE_USE_ID_SERIAL 1
#define ID_TABLE_USE_LIST_SORTED 1
#define ID_TABLE_USE_LIST_SORTED_LINEAR_SMALL_RANGE 1
#elif ID_TABLE_IMPL == 21
#define ID_TABLE_NAME hash
#define ID_TABLE_IMPL_TYPE sa_table
#define ID_TABLE_USE_COALESCED_HASHING 1
#define ID_TABLE_USE_ID_SERIAL 1
#elif ID_TABLE_IMPL == 22
#define ID_TABLE_NAME hash
#define ID_TABLE_IMPL_TYPE struct hash_id_table
#define ID_TABLE_USE_SMALL_HASH 1
#define ID_TABLE_USE_ID_SERIAL 1
#elif ID_TABLE_IMPL == 31
#define ID_TABLE_NAME mix
#define ID_TABLE_IMPL_TYPE struct mix_id_table
#define ID_TABLE_USE_MIX 1
#define ID_TABLE_USE_MIX_LIST_MAX_CAPA 32
#define ID_TABLE_USE_ID_SERIAL 1
#define ID_TABLE_USE_LIST 1
#define ID_TABLE_USE_CALC_VALUES 1
#define ID_TABLE_USE_SMALL_HASH 1
#elif ID_TABLE_IMPL == 32
#define ID_TABLE_NAME mix
#define ID_TABLE_IMPL_TYPE struct mix_id_table
#define ID_TABLE_USE_MIX 1
#define ID_TABLE_USE_MIX_LIST_MAX_CAPA 32
#define ID_TABLE_USE_ID_SERIAL 1
#define ID_TABLE_USE_LIST 1
#define ID_TABLE_USE_CALC_VALUES 1
#define ID_TABLE_USE_LIST_SORTED 1
#define ID_TABLE_USE_SMALL_HASH 1
#elif ID_TABLE_IMPL == 33
#define ID_TABLE_NAME mix
#define ID_TABLE_IMPL_TYPE struct mix_id_table
#define ID_TABLE_USE_MIX 1
#define ID_TABLE_USE_MIX_LIST_MAX_CAPA 64
#define ID_TABLE_USE_ID_SERIAL 1
#define ID_TABLE_USE_LIST 1
#define ID_TABLE_USE_CALC_VALUES 1
#define ID_TABLE_USE_SMALL_HASH 1
#elif ID_TABLE_IMPL == 34
#define ID_TABLE_NAME mix
#define ID_TABLE_IMPL_TYPE struct mix_id_table
#define ID_TABLE_USE_MIX 1
#define ID_TABLE_USE_MIX_LIST_MAX_CAPA 64
#define ID_TABLE_USE_ID_SERIAL 1
#define ID_TABLE_USE_LIST 1
#define ID_TABLE_USE_CALC_VALUES 1
#define ID_TABLE_USE_LIST_SORTED 1
#define ID_TABLE_USE_SMALL_HASH 1
#elif ID_TABLE_IMPL == 35
#define ID_TABLE_NAME mix
#define ID_TABLE_IMPL_TYPE struct mix_id_table
#define ID_TABLE_USE_MIX 1
#define ID_TABLE_USE_MIX_LIST_MAX_CAPA 64
#define ID_TABLE_USE_ID_SERIAL 1
#define ID_TABLE_USE_LIST 1
#define ID_TABLE_USE_CALC_VALUES 1
#define ID_TABLE_USE_LIST_SORTED 1
#define ID_TABLE_USE_LIST_SORTED_LINEAR_SMALL_RANGE 1
#define ID_TABLE_USE_SMALL_HASH 1
#else
#error
#endif
#if ID_TABLE_SWAP_RECENT_ACCESS && ID_TABLE_USE_LIST_SORTED
#error
#endif
/* IMPL(create) will be "hash_id_table_create" and so on */
#define IMPL1(name, op) TOKEN_PASTE(name, _id##op) /* expand `name' */
#define IMPL(op) IMPL1(ID_TABLE_NAME, _table##op) /* but prevent `op' */
#ifdef __GNUC__
# define UNUSED(func) static func __attribute__((unused))
#else
# define UNUSED(func) static func
#endif
UNUSED(ID_TABLE_IMPL_TYPE *IMPL(_create)(size_t));
UNUSED(void IMPL(_free)(ID_TABLE_IMPL_TYPE *));
UNUSED(void IMPL(_clear)(ID_TABLE_IMPL_TYPE *));
UNUSED(size_t IMPL(_size)(const ID_TABLE_IMPL_TYPE *));
UNUSED(size_t IMPL(_memsize)(const ID_TABLE_IMPL_TYPE *));
UNUSED(int IMPL(_insert)(ID_TABLE_IMPL_TYPE *, ID, VALUE));
UNUSED(int IMPL(_lookup)(ID_TABLE_IMPL_TYPE *, ID, VALUE *));
UNUSED(int IMPL(_delete)(ID_TABLE_IMPL_TYPE *, ID));
UNUSED(void IMPL(_foreach)(ID_TABLE_IMPL_TYPE *, rb_id_table_foreach_func_t *, void *));
UNUSED(void IMPL(_foreach_values)(ID_TABLE_IMPL_TYPE *, rb_id_table_foreach_values_func_t *, void *));
#if ID_TABLE_USE_ID_SERIAL
typedef rb_id_serial_t id_key_t;
static inline ID
key2id(id_key_t key)
{
return rb_id_serial_to_id(key);
}
static inline id_key_t
id2key(ID id)
{
return rb_id_to_serial(id);
}
#else /* ID_TABLE_USE_ID_SERIAL */
typedef ID id_key_t;
#define key2id(key) key
#define id2key(id) id
#endif /* ID_TABLE_USE_ID_SERIAL */
/***************************************************************
* 0: using st with debug information.
* 1: using st.
***************************************************************/
#if ID_TABLE_USE_ST
#if ID_TABLE_USE_ST_DEBUG
#define ID_TABLE_MARK 0x12345678
struct st_id_table {
struct st_table *st;
unsigned int check;
};
static struct st_table *
tbl2st(struct st_id_table *tbl)
{
if (tbl->check != ID_TABLE_MARK) rb_bug("tbl2st: check error %x", tbl->check);
return tbl->st;
}
static struct st_id_table *
st_id_table_create(size_t size)
{
struct st_id_table *tbl = ALLOC(struct st_id_table);
tbl->st = st_init_numtable_with_size(size);
tbl->check = ID_TABLE_MARK;
return tbl;
}
static void
st_id_table_free(struct st_id_table *tbl)
{
st_free_table(tbl->st);
xfree(tbl);
}
#else /* ID_TABLE_USE_ST_DEBUG */
struct st_id_table {
struct st_table st;
};
static struct st_table *
tbl2st(struct st_id_table *tbl)
{
return (struct st_table *)tbl;
}
static struct st_id_table *
st_id_table_create(size_t size)
{
return (struct st_id_table *)st_init_numtable_with_size(size);
}
static void
st_id_table_free(struct st_id_table *tbl)
{
st_free_table((struct st_table*)tbl);
}
#endif /* ID_TABLE_USE_ST_DEBUG */
static void
st_id_table_clear(struct st_id_table *tbl)
{
st_clear(tbl2st(tbl));
}
static size_t
st_id_table_size(const struct st_id_table *tbl)
{
return tbl2st(tbl)->num_entries;
}
static size_t
st_id_table_memsize(const struct st_id_table *tbl)
{
size_t header_size = ID_TABLE_USE_ST_DEBUG ? sizeof(struct st_id_table) : 0;
return header_size + st_memsize(tbl2st(tbl));
}
static int
st_id_table_lookup(struct st_id_table *tbl, ID id, VALUE *val)
{
return st_lookup(tbl2st(tbl), (st_data_t)id, (st_data_t *)val);
}
static int
st_id_table_insert(struct st_id_table *tbl, ID id, VALUE val)
{
return st_insert(tbl2st(tbl), id, val);
}
static int
st_id_table_delete(struct st_id_table *tbl, ID id)
{
return st_delete(tbl2st(tbl), (st_data_t *)&id, NULL);
}
static void
st_id_table_foreach(struct st_id_table *tbl, rb_id_table_foreach_func_t *func, void *data)
{
st_foreach(tbl2st(tbl), (int (*)(ANYARGS))func, (st_data_t)data);
}
struct values_iter_data {
rb_id_table_foreach_values_func_t *values_i;
void *data;
};
static int
each_values(st_data_t key, st_data_t val, st_data_t ptr)
{
struct values_iter_data *values_iter_data = (struct values_iter_data *)ptr;
return values_iter_data->values_i(val, values_iter_data->data);
}
static void
st_id_table_foreach_values(struct st_id_table *tbl, rb_id_table_foreach_values_func_t *func, void *data)
{
struct values_iter_data values_iter_data;
values_iter_data.values_i = func;
values_iter_data.data = data;
st_foreach(tbl2st(tbl), each_values, (st_data_t)&values_iter_data);
}
#endif /* ID_TABLE_USE_ST */
#if ID_TABLE_USE_LIST
#define LIST_MIN_CAPA 4
struct list_id_table {
int capa;
int num;
id_key_t *keys;
#if ID_TABLE_USE_CALC_VALUES == 0
VALUE *values_;
#endif
};
#if ID_TABLE_USE_CALC_VALUES
#define TABLE_VALUES(tbl) ((VALUE *)((tbl)->keys + (tbl)->capa))
#else
#define TABLE_VALUES(tbl) (tbl)->values_
#endif
static struct list_id_table *
list_id_table_init(struct list_id_table *tbl, size_t capa)
{
if (capa > 0) {
#if ID_TABLE_USE_CALC_VALUES && \
(UNALIGNED_WORD_ACCESS == 0) && (SIZEOF_VALUE == 8)
/* Workaround for 8-byte word alignment on 64-bit SPARC.
* This code assumes that sizeof(ID) == 4, sizeof(VALUE) == 8, and
* xmalloc() returns 8-byte aligned memory block.
*/
if (capa & (size_t)1) capa += 1;
#endif
tbl->capa = (int)capa;
#if ID_TABLE_USE_CALC_VALUES
tbl->keys = (id_key_t *)xmalloc(sizeof(id_key_t) * capa + sizeof(VALUE) * capa);
#else
tbl->keys = ALLOC_N(id_key_t, capa);
tbl->values_ = ALLOC_N(VALUE, capa);
#endif
}
return tbl;
}
#ifndef ID_TABLE_USE_MIX
static struct list_id_table *
list_id_table_create(size_t capa)
{
struct list_id_table *tbl = ZALLOC(struct list_id_table);
return list_id_table_init(tbl, capa);
}
#endif
static void
list_id_table_free(struct list_id_table *tbl)
{
xfree(tbl->keys);
#if ID_TABLE_USE_CALC_VALUES == 0
xfree(tbl->values_);
#endif
xfree(tbl);
}
static void
list_id_table_clear(struct list_id_table *tbl)
{
tbl->num = 0;
}
static size_t
list_id_table_size(const struct list_id_table *tbl)
{
return (size_t)tbl->num;
}
static size_t
list_id_table_memsize(const struct list_id_table *tbl)
{
return (sizeof(id_key_t) + sizeof(VALUE)) * tbl->capa + sizeof(struct list_id_table);
}
static void
list_table_extend(struct list_id_table *tbl)
{
if (tbl->capa == tbl->num) {
const int capa = tbl->capa == 0 ? LIST_MIN_CAPA : (tbl->capa * 2);
#if ID_TABLE_USE_CALC_VALUES
{
VALUE *old_values, *new_values;
VALUE *debug_values = NULL;
const int num = tbl->num;
const int size = sizeof(id_key_t) * capa + sizeof(VALUE) * capa;
int i;
if (num > 0) {
VALUE *orig_values = (VALUE *)(tbl->keys + num);
debug_values = ALLOC_N(VALUE, num);
for (i=0; i<num; i++) {
debug_values[i] = orig_values[i];
}
if (0)
for (i=0; i< 2 * num; i++) {
unsigned char *cs = (unsigned char *)&tbl->keys[i];
size_t j;
fprintf(stderr, ">> %3d | %p - ", i, cs);
for (j=0; j<sizeof(VALUE); j++) {
fprintf(stderr, "%x ", cs[j]);
}
fprintf(stderr, "\n");
}
}
tbl->keys = (id_key_t *)xrealloc(tbl->keys, size);
old_values = (VALUE *)(tbl->keys + num);
new_values = (VALUE *)(tbl->keys + capa);
/* [ keys (num) ] [ values (num) ]
* ^ old_values
* realloc =>
* [ keys (capa = num * 2) ] [ values (capa = num * 2) ]
* ^ new_values
*/
/* memmove */
if (0) {
fprintf(stderr, "memmove: %p -> %p (%d, capa: %d)\n",
old_values, new_values, num, capa);
}
assert(num < capa);
assert(num == 0 || old_values < new_values);
for (i=num-1; i>=0; i--) {
new_values[i] = old_values[i];
}
if (num > 0) {
for (i=0; i<num; i++) {
assert(debug_values[i] == new_values[i]);
}
xfree(debug_values);
}
}
tbl->capa = capa;
#else
tbl->capa = capa;
tbl->keys = (id_key_t *)xrealloc(tbl->keys, sizeof(id_key_t) * capa);
tbl->values_ = (VALUE *)xrealloc(tbl->values_, sizeof(VALUE) * capa);
#endif
}
}
#if ID_TABLE_DEBUG
static void
list_table_show(struct list_id_table *tbl)
{
const id_key_t *keys = tbl->keys;
const int num = tbl->num;
int i;
fprintf(stderr, "tbl: %p (num: %d)\n", tbl, num);
for (i=0; i<num; i++) {
fprintf(stderr, " -> [%d] %s %d\n", i, rb_id2name(key2id(keys[i])), (int)keys[i]);
}
}
#endif
static void
tbl_assert(struct list_id_table *tbl)
{
#if ID_TABLE_DEBUG
#if ID_TABLE_USE_LIST_SORTED
const id_key_t *keys = tbl->keys;
const int num = tbl->num;
int i;
for (i=0; i<num-1; i++) {
if (keys[i] >= keys[i+1]) {
list_table_show(tbl);
rb_bug(": not sorted.");
}
}
#endif
#endif
}
#if ID_TABLE_USE_LIST_SORTED
static int
list_ids_bsearch(const id_key_t *keys, id_key_t key, int num)
{
int p, min = 0, max = num;
#if ID_TABLE_USE_LIST_SORTED_LINEAR_SMALL_RANGE
if (num <= 64) {
if (num > 32) {
if (keys[num/2] <= key) {
min = num/2;
} else {
max = num/2;
}
}
for (p = min; p<num && keys[p] < key; p++) {
assert(keys[p] != 0);
}
return (p<num && keys[p] == key) ? p : -p-1;
}
#endif /* ID_TABLE_USE_LIST_SORTED_LINEAR_SMALL_RANGE */
while (1) {
p = min + (max - min) / 2;
if (min >= max) {
break;
}
else {
id_key_t kp = keys[p];
assert(p < max);
assert(p >= min);
if (kp > key) max = p;
else if (kp < key) min = p+1;
else {
assert(kp == key);
assert(p >= 0);
assert(p < num);
return p;
}
}
}
assert(min == max);
assert(min == p);
return -p-1;
}
#endif /* ID_TABLE_USE_LIST_SORTED */
static int
list_table_index(struct list_id_table *tbl, id_key_t key)
{
const int num = tbl->num;
const id_key_t *keys = tbl->keys;
#if ID_TABLE_USE_LIST_SORTED
return list_ids_bsearch(keys, key, num);
#else /* ID_TABLE_USE_LIST_SORTED */
int i;
for (i=0; i<num; i++) {
assert(keys[i] != 0);
if (keys[i] == key) {
return (int)i;
}
}
return -1;
#endif
}
static int
list_id_table_lookup(struct list_id_table *tbl, ID id, VALUE *valp)
{
id_key_t key = id2key(id);
int index = list_table_index(tbl, key);
if (index >= 0) {
*valp = TABLE_VALUES(tbl)[index];
#if ID_TABLE_SWAP_RECENT_ACCESS
if (index > 0) {
VALUE *values = TABLE_VALUES(tbl);
id_key_t tk = tbl->keys[index-1];
VALUE tv = values[index-1];
tbl->keys[index-1] = tbl->keys[index];
tbl->keys[index] = tk;
values[index-1] = values[index];
values[index] = tv;
}
#endif /* ID_TABLE_SWAP_RECENT_ACCESS */
return TRUE;
}
else {
return FALSE;
}
}
static int
list_id_table_insert(struct list_id_table *tbl, ID id, VALUE val)
{
const id_key_t key = id2key(id);
const int index = list_table_index(tbl, key);
if (index >= 0) {
TABLE_VALUES(tbl)[index] = val;
}
else {
list_table_extend(tbl);
{
const int num = tbl->num++;
#if ID_TABLE_USE_LIST_SORTED
const int insert_index = -(index + 1);
id_key_t *keys = tbl->keys;
VALUE *values = TABLE_VALUES(tbl);
int i;
if (0) fprintf(stderr, "insert: %d into %d on\n", (int)key, insert_index);
for (i=num; i>insert_index; i--) {
keys[i] = keys[i-1];
values[i] = values[i-1];
}
keys[i] = key;
values[i] = val;
tbl_assert(tbl);
#else
tbl->keys[num] = key;
TABLE_VALUES(tbl)[num] = val;
#endif
}
}
return TRUE;
}
static int
list_delete_index(struct list_id_table *tbl, id_key_t key, int index)
{
if (index >= 0) {
VALUE *values = TABLE_VALUES(tbl);
#if ID_TABLE_USE_LIST_SORTED
int i;
const int num = tbl->num;
id_key_t *keys = tbl->keys;
for (i=index+1; i<num; i++) { /* compaction */
keys[i-1] = keys[i];
values[i-1] = values[i];
}
#else
tbl->keys[index] = tbl->keys[tbl->num-1];
values[index] = values[tbl->num-1];
#endif
tbl->num--;
tbl_assert(tbl);
return TRUE;
}
else {
return FALSE;
}
}
static int
list_id_table_delete(struct list_id_table *tbl, ID id)
{
const id_key_t key = id2key(id);
int index = list_table_index(tbl, key);
return list_delete_index(tbl, key, index);
}
#define FOREACH_LAST() do { \
switch (ret) { \
case ID_TABLE_ITERATOR_RESULT_END: \
case ID_TABLE_CONTINUE: \
case ID_TABLE_STOP: \
break; \
case ID_TABLE_DELETE: \
list_delete_index(tbl, key, i); \
values = TABLE_VALUES(tbl); \
num = tbl->num; \
i--; /* redo same index */ \
break; \
} \
} while (0)
static void
list_id_table_foreach(struct list_id_table *tbl, rb_id_table_foreach_func_t *func, void *data)
{
int num = tbl->num;
int i;
const id_key_t *keys = tbl->keys;
const VALUE *values = TABLE_VALUES(tbl);
for (i=0; i<num; i++) {
const id_key_t key = keys[i];
enum rb_id_table_iterator_result ret = (*func)(key2id(key), values[i], data);
assert(key != 0);
FOREACH_LAST();
if (ret == ID_TABLE_STOP) return;
}
}
static void
list_id_table_foreach_values(struct list_id_table *tbl, rb_id_table_foreach_values_func_t *func, void *data)
{
int num = tbl->num;
int i;
const id_key_t *keys = tbl->keys;
VALUE *values = TABLE_VALUES(tbl);
for (i=0; i<num; i++) {
const id_key_t key = keys[i];
enum rb_id_table_iterator_result ret = (*func)(values[i], data);
assert(key != 0);
FOREACH_LAST();
if (ret == ID_TABLE_STOP) return;
}
}
#endif /* ID_TABLE_USE_LIST */
#if ID_TABLE_USE_COALESCED_HASHING
/* implementation is based on
* https://bugs.ruby-lang.org/issues/6962 by funny_falcon
*/
typedef unsigned int sa_index_t;
#define SA_EMPTY 0
#define SA_LAST 1
#define SA_OFFSET 2
#define SA_MIN_SIZE 4
typedef struct sa_entry {
sa_index_t next;
id_key_t key;
VALUE value;
} sa_entry;
typedef struct {
sa_index_t num_bins;
sa_index_t num_entries;
sa_index_t free_pos;
sa_entry *entries;
} sa_table;
static void
sa_init_table(register sa_table *table, sa_index_t num_bins)
{
if (num_bins) {
table->num_entries = 0;
table->entries = ZALLOC_N(sa_entry, num_bins);
table->num_bins = num_bins;
table->free_pos = num_bins;
}
}
static sa_table*
hash_id_table_create(size_t size)
{
sa_table* table = ZALLOC(sa_table);
sa_init_table(table, (sa_index_t)size);
return table;
}
static void
hash_id_table_clear(sa_table *table)
{
xfree(table->entries);
memset(table, 0, sizeof(sa_table));
}
static void
hash_id_table_free(sa_table *table)
{
xfree(table->entries);
xfree(table);
}
static size_t
hash_id_table_memsize(const sa_table *table)
{
return sizeof(sa_table) + table->num_bins * sizeof (sa_entry);
}
static inline sa_index_t
calc_pos(register sa_table* table, id_key_t key)
{
return key & (table->num_bins - 1);
}
static void
fix_empty(register sa_table* table)
{
while (--table->free_pos &&
table->entries[table->free_pos-1].next != SA_EMPTY);
}
#define FLOOR_TO_4 ((~((sa_index_t)0)) << 2)
static sa_index_t
find_empty(register sa_table* table, register sa_index_t pos)
{
sa_index_t new_pos = table->free_pos-1;
sa_entry *entry;
static const unsigned offsets[][3] = {
{1, 2, 3},
{2, 3, 0},
{3, 1, 0},
{2, 1, 0}
};
const unsigned *const check = offsets[pos&3];
pos &= FLOOR_TO_4;
entry = table->entries+pos;
if (entry[check[0]].next == SA_EMPTY) { new_pos = pos + check[0]; goto check; }
if (entry[check[1]].next == SA_EMPTY) { new_pos = pos + check[1]; goto check; }
if (entry[check[2]].next == SA_EMPTY) { new_pos = pos + check[2]; goto check; }
check:
if (new_pos+1 == table->free_pos) fix_empty(table);
return new_pos;
}
static void resize(register sa_table* table);
static int insert_into_chain(register sa_table*, register id_key_t, st_data_t, sa_index_t pos);
static int insert_into_main(register sa_table*, id_key_t, st_data_t, sa_index_t pos, sa_index_t prev_pos);
static int
sa_insert(register sa_table* table, id_key_t key, VALUE value)
{
register sa_entry *entry;
sa_index_t pos, main_pos;
if (table->num_bins == 0) {
sa_init_table(table, SA_MIN_SIZE);
}
pos = calc_pos(table, key);
entry = table->entries + pos;
if (entry->next == SA_EMPTY) {
entry->next = SA_LAST;
entry->key = key;
entry->value = value;
table->num_entries++;
if (pos+1 == table->free_pos) fix_empty(table);
return 0;
}
if (entry->key == key) {
entry->value = value;
return 1;
}
if (table->num_entries + (table->num_entries >> 2) > table->num_bins) {
resize(table);
return sa_insert(table, key, value);
}
main_pos = calc_pos(table, entry->key);
if (main_pos == pos) {
return insert_into_chain(table, key, value, pos);
}
else {
if (!table->free_pos) {
resize(table);
return sa_insert(table, key, value);
}
return insert_into_main(table, key, value, pos, main_pos);
}
}
static int
hash_id_table_insert(register sa_table* table, ID id, VALUE value)
{
return sa_insert(table, id2key(id), value);
}
static int
insert_into_chain(register sa_table* table, id_key_t key, st_data_t value, sa_index_t pos)
{
sa_entry *entry = table->entries + pos, *new_entry;
sa_index_t new_pos;
while (entry->next != SA_LAST) {
pos = entry->next - SA_OFFSET;
entry = table->entries + pos;
if (entry->key == key) {
entry->value = value;
return 1;
}
}
if (!table->free_pos) {
resize(table);
return sa_insert(table, key, value);
}
new_pos = find_empty(table, pos);
new_entry = table->entries + new_pos;
entry->next = new_pos + SA_OFFSET;
new_entry->next = SA_LAST;
new_entry->key = key;
new_entry->value = value;
table->num_entries++;
return 0;
}
static int
insert_into_main(register sa_table* table, id_key_t key, st_data_t value, sa_index_t pos, sa_index_t prev_pos)
{
sa_entry *entry = table->entries + pos;
sa_index_t new_pos = find_empty(table, pos);
sa_entry *new_entry = table->entries + new_pos;
sa_index_t npos;
*new_entry = *entry;
while((npos = table->entries[prev_pos].next - SA_OFFSET) != pos) {
prev_pos = npos;
}
table->entries[prev_pos].next = new_pos + SA_OFFSET;
entry->next = SA_LAST;
entry->key = key;
entry->value = value;
table->num_entries++;
return 0;
}
static sa_index_t
new_size(sa_index_t num_entries)
{
sa_index_t size = num_entries >> 3;
size |= size >> 1;
size |= size >> 2;
size |= size >> 4;
size |= size >> 8;
size |= size >> 16;
return (size + 1) << 3;
}
static void
resize(register sa_table *table)
{
sa_table tmp_table;
sa_entry *entry;