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Misc #10278 » 0001-st.c-use-ccan-linked-list.patch

normalperson (Eric Wong), 09/22/2014 05:32 AM

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include/ruby/st.h
union {
struct {
struct st_table_entry **bins;
struct st_table_entry *head, *tail;
void *private_list_head[2];
} big;
struct {
struct st_packed_entry *entries;
st.c
#include <stdlib.h>
#endif
#include <string.h>
#include "ccan/list/list.h"
typedef struct st_table_entry st_table_entry;
......
st_data_t key;
st_data_t record;
st_table_entry *next;
st_table_entry *fore, *back;
struct list_node olist;
};
typedef struct st_packed_entry {
......
/* Shortcut */
#define bins as.big.bins
#define head as.big.head
#define tail as.big.tail
#define real_entries as.packed.real_entries
/* preparation for possible packing improvements */
......
}
#endif
static inline struct list_head *
st_head(const st_table *tbl)
{
return (struct list_head *)&tbl->as.big.private_list_head;
}
st_table*
st_init_table_with_size(const struct st_hash_type *type, st_index_t size)
{
......
tbl->entries_packed = size <= MAX_PACKED_HASH;
if (tbl->entries_packed) {
size = ST_DEFAULT_PACKED_TABLE_SIZE;
tbl->real_entries = 0;
}
else {
size = new_size(size); /* round up to power-of-two */
list_head_init(st_head(tbl));
}
tbl->num_bins = size;
tbl->bins = st_alloc_bins(size);
tbl->head = 0;
tbl->tail = 0;
return tbl;
}
......
st_clear(st_table *table)
{
register st_table_entry *ptr, *next;
st_index_t i;
if (table->entries_packed) {
table->num_entries = 0;
......
return;
}
for (i = 0; i < table->num_bins; i++) {
ptr = table->bins[i];
table->bins[i] = 0;
while (ptr != 0) {
next = ptr->next;
st_free_entry(ptr);
ptr = next;
}
list_for_each_safe(st_head(table), ptr, next, olist) {
/* list_del is not needed */
st_free_entry(ptr);
}
table->num_entries = 0;
table->head = 0;
table->tail = 0;
MEMZERO(table->bins, st_table_entry*, table->num_bins);
list_head_init(st_head(table));
}
void
......
}
entry = new_entry(table, key, value, hash_val, bin_pos);
if (table->head != 0) {
entry->fore = 0;
(entry->back = table->tail)->fore = entry;
table->tail = entry;
}
else {
table->head = table->tail = entry;
entry->fore = entry->back = 0;
}
list_add_tail(st_head(table), &entry->olist);
table->num_entries++;
}
......
{
st_index_t i;
st_packed_entry packed_bins[MAX_PACKED_HASH];
register st_table_entry *entry, *preventry = 0, **chain;
register st_table_entry *entry;
st_table tmp_table = *table;
MEMCPY(packed_bins, PACKED_BINS(table), st_packed_entry, MAX_PACKED_HASH);
......
tmp_table.bins = st_realloc_bins(tmp_table.bins, ST_DEFAULT_INIT_TABLE_SIZE, tmp_table.num_bins);
tmp_table.num_bins = ST_DEFAULT_INIT_TABLE_SIZE;
#endif
/*
* order is important here, we need to keep the original table
* walkable during GC (GC may be triggered by new_entry call)
*/
i = 0;
chain = &tmp_table.head;
list_head_init(st_head(&tmp_table));
do {
st_data_t key = packed_bins[i].key;
st_data_t val = packed_bins[i].val;
st_index_t hash = packed_bins[i].hash;
entry = new_entry(&tmp_table, key, val, hash,
hash_pos(hash, ST_DEFAULT_INIT_TABLE_SIZE));
*chain = entry;
entry->back = preventry;
preventry = entry;
chain = &entry->fore;
list_add_tail(st_head(&tmp_table), &entry->olist);
} while (++i < MAX_PACKED_HASH);
*chain = NULL;
tmp_table.tail = entry;
*table = tmp_table;
list_head_init(st_head(table));
list_append_list(st_head(table), st_head(&tmp_table));
}
static void
......
table->num_bins = new_num_bins;
table->bins = new_bins;
if ((ptr = table->head) != 0) {
do {
hash_val = hash_pos(ptr->hash, new_num_bins);
ptr->next = new_bins[hash_val];
new_bins[hash_val] = ptr;
} while ((ptr = ptr->fore) != 0);
list_for_each(st_head(table), ptr, olist) {
hash_val = hash_pos(ptr->hash, new_num_bins);
ptr->next = new_bins[hash_val];
new_bins[hash_val] = ptr;
}
}
......
st_copy(st_table *old_table)
{
st_table *new_table;
st_table_entry *ptr, *entry, *prev, **tailp;
st_table_entry *ptr, *entry;
st_index_t num_bins = old_table->num_bins;
st_index_t hash_val;
new_table = st_alloc_table();
if (new_table == 0) {
......
return new_table;
}
if ((ptr = old_table->head) != 0) {
prev = 0;
tailp = &new_table->head;
do {
entry = st_alloc_entry();
if (entry == 0) {
st_free_table(new_table);
return 0;
}
*entry = *ptr;
hash_val = hash_pos(entry->hash, num_bins);
entry->next = new_table->bins[hash_val];
new_table->bins[hash_val] = entry;
entry->back = prev;
*tailp = prev = entry;
tailp = &entry->fore;
} while ((ptr = ptr->fore) != 0);
new_table->tail = prev;
list_head_init(st_head(new_table));
list_for_each(st_head(old_table), ptr, olist) {
entry = new_entry(new_table, ptr->key, ptr->record, ptr->hash,
hash_pos(ptr->hash, num_bins));
list_add_tail(st_head(new_table), &entry->olist);
}
return new_table;
......
static inline void
remove_entry(st_table *table, st_table_entry *ptr)
{
if (ptr->fore == 0 && ptr->back == 0) {
table->head = 0;
table->tail = 0;
}
else {
st_table_entry *fore = ptr->fore, *back = ptr->back;
if (fore) fore->back = back;
if (back) back->fore = fore;
if (ptr == table->head) table->head = fore;
if (ptr == table->tail) table->tail = back;
}
list_del(&ptr->olist);
table->num_entries--;
}
......
int
st_shift(register st_table *table, register st_data_t *key, st_data_t *value)
{
st_table_entry *old;
st_table_entry **prev;
register st_table_entry *ptr;
......
return 1;
}
prev = &table->bins[hash_pos(table->head->hash, table->num_bins)];
while ((ptr = *prev) != table->head) prev = &ptr->next;
old = list_pop(st_head(table), st_table_entry, olist);
table->num_entries--;
prev = &table->bins[hash_pos(old->hash, table->num_bins)];
while ((ptr = *prev) != old) prev = &ptr->next;
*prev = ptr->next;
if (value != 0) *value = ptr->record;
*key = ptr->key;
remove_entry(table, ptr);
st_free_entry(ptr);
return 1;
}
......
int
st_foreach_check(st_table *table, int (*func)(ANYARGS), st_data_t arg, st_data_t never)
{
st_table_entry *ptr, **last, *tmp;
st_table_entry *ptr, **last, *tmp, *next, *resume_tail = 0;
struct list_head resume_head;
struct list_head *head;
enum st_retval retval;
st_index_t i;
......
FIND_ENTRY(table, ptr, hash, i);
if (retval == ST_CHECK) {
if (!ptr) goto deleted;
goto unpacked_continue;
}
if (table->num_entries == 0) return 0;
resume_head.n = ptr->olist;
head = &resume_head;
next = list_next(st_head(table), ptr, olist);
resume_tail = list_tail(st_head(table), st_table_entry, olist);
goto unpacked;
}
switch (retval) {
......
}
return 0;
}
else {
ptr = table->head;
}
if (ptr != 0) {
do {
if (ptr->key == never)
goto unpacked_continue;
head = st_head(table);
list_for_each_safe(head, ptr, next, olist) {
if (ptr->key != never) {
i = hash_pos(ptr->hash, table->num_bins);
retval = (*func)(ptr->key, ptr->record, arg, 0);
unpacked:
......
}
/* fall through */
case ST_CONTINUE:
unpacked_continue:
ptr = ptr->fore;
break;
case ST_STOP:
return 0;
......
last = &table->bins[hash_pos(ptr->hash, table->num_bins)];
for (; (tmp = *last) != 0; last = &tmp->next) {
if (ptr == tmp) {
tmp = ptr->fore;
remove_entry(table, ptr);
ptr->key = ptr->record = never;
ptr->hash = 0;
ptr = tmp;
break;
}
}
if (table->num_entries == 0) return 0;
}
} while (ptr && table->head);
}
if (resume_tail == ptr) break;
}
return 0;
}
......
int
st_foreach(st_table *table, int (*func)(ANYARGS), st_data_t arg)
{
st_table_entry *ptr, **last, *tmp;
st_table_entry *ptr, **last, *tmp, *next, *resume_tail = 0;
enum st_retval retval;
struct list_head resume_head;
struct list_head *head;
st_index_t i;
if (table->entries_packed) {
......
if (!table->entries_packed) {
FIND_ENTRY(table, ptr, hash, i);
if (!ptr) return 0;
resume_head.n = ptr->olist;
head = &resume_head;
next = list_next(st_head(table), ptr, olist);
resume_tail = list_tail(st_head(table), st_table_entry, olist);
goto unpacked;
}
switch (retval) {
......
}
return 0;
}
else {
ptr = table->head;
}
if (ptr != 0) {
do {
i = hash_pos(ptr->hash, table->num_bins);
retval = (*func)(ptr->key, ptr->record, arg, 0);
unpacked:
switch (retval) {
case ST_CONTINUE:
ptr = ptr->fore;
break;
case ST_CHECK:
case ST_STOP:
return 0;
case ST_DELETE:
last = &table->bins[hash_pos(ptr->hash, table->num_bins)];
for (; (tmp = *last) != 0; last = &tmp->next) {
if (ptr == tmp) {
tmp = ptr->fore;
*last = ptr->next;
remove_entry(table, ptr);
st_free_entry(ptr);
ptr = tmp;
break;
}
head = st_head(table);
list_for_each_safe(head, ptr, next, olist) {
i = hash_pos(ptr->hash, table->num_bins);
retval = (*func)(ptr->key, ptr->record, arg, 0);
unpacked:
switch (retval) {
case ST_CONTINUE:
break;
case ST_CHECK:
case ST_STOP:
return 0;
case ST_DELETE:
last = &table->bins[hash_pos(ptr->hash, table->num_bins)];
for (; (tmp = *last) != 0; last = &tmp->next) {
if (ptr == tmp) {
*last = ptr->next;
remove_entry(table, ptr);
st_free_entry(ptr);
break;
}
}
} while (ptr && table->head);
if (table->num_entries == 0) return 0;
}
if (resume_tail == ptr) break;
}
return 0;
}
......
}
}
else {
st_table_entry *ptr = table->head;
st_table_entry *ptr;
st_data_t *keys_end = keys + size;
for (; ptr && keys < keys_end; ptr = ptr->fore) {
list_for_each(st_head(table), ptr, olist) {
if (keys >= keys_end) break;
key = ptr->key;
if (check && key == never) continue;
*keys++ = key;
......
}
}
else {
st_table_entry *ptr = table->head;
st_table_entry *ptr;
st_data_t *values_end = values + size;
for (; ptr && values < values_end; ptr = ptr->fore) {
list_for_each(st_head(table), ptr, olist) {
if (values >= values_end) break;
key = ptr->key;
if (check && key == never) continue;
*values++ = ptr->record;
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