Protocol Buffers - Google's data interchange format (grpc依赖) https://developers.google.com/protocol-buffers/
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/*
** upb_table Implementation
**
** Implementation is heavily inspired by Lua's ltable.c.
*/
#include "upb/table.int.h"
#include <stdlib.h>
#include <string.h>
#define UPB_MAXARRSIZE 16 /* 64k. */
/* From Chromium. */
#define ARRAY_SIZE(x) \
((sizeof(x)/sizeof(0[x])) / ((size_t)(!(sizeof(x) % sizeof(0[x])))))
static const double MAX_LOAD = 0.85;
/* The minimum utilization of the array part of a mixed hash/array table. This
* is a speed/memory-usage tradeoff (though it's not straightforward because of
* cache effects). The lower this is, the more memory we'll use. */
static const double MIN_DENSITY = 0.1;
bool is_pow2(uint64_t v) { return v == 0 || (v & (v - 1)) == 0; }
int log2ceil(uint64_t v) {
int ret = 0;
bool pow2 = is_pow2(v);
while (v >>= 1) ret++;
ret = pow2 ? ret : ret + 1; /* Ceiling. */
return UPB_MIN(UPB_MAXARRSIZE, ret);
}
char *upb_strdup(const char *s) {
return upb_strdup2(s, strlen(s));
}
char *upb_strdup2(const char *s, size_t len) {
size_t n;
char *p;
/* Prevent overflow errors. */
if (len == SIZE_MAX) return NULL;
/* Always null-terminate, even if binary data; but don't rely on the input to
* have a null-terminating byte since it may be a raw binary buffer. */
n = len + 1;
p = malloc(n);
if (p) {
memcpy(p, s, len);
p[len] = 0;
}
return p;
}
/* A type to represent the lookup key of either a strtable or an inttable. */
typedef union {
uintptr_t num;
struct {
const char *str;
size_t len;
} str;
} lookupkey_t;
static lookupkey_t strkey2(const char *str, size_t len) {
lookupkey_t k;
k.str.str = str;
k.str.len = len;
return k;
}
static lookupkey_t intkey(uintptr_t key) {
lookupkey_t k;
k.num = key;
return k;
}
typedef uint32_t hashfunc_t(upb_tabkey key);
typedef bool eqlfunc_t(upb_tabkey k1, lookupkey_t k2);
/* Base table (shared code) ***************************************************/
/* For when we need to cast away const. */
static upb_tabent *mutable_entries(upb_table *t) {
return (upb_tabent*)t->entries;
}
static bool isfull(upb_table *t) {
if (upb_table_size(t) == 0) {
return true;
} else {
return ((double)(t->count + 1) / upb_table_size(t)) > MAX_LOAD;
}
}
static bool init(upb_table *t, upb_ctype_t ctype, uint8_t size_lg2) {
size_t bytes;
t->count = 0;
t->ctype = ctype;
t->size_lg2 = size_lg2;
t->mask = upb_table_size(t) ? upb_table_size(t) - 1 : 0;
bytes = upb_table_size(t) * sizeof(upb_tabent);
if (bytes > 0) {
t->entries = malloc(bytes);
if (!t->entries) return false;
memset(mutable_entries(t), 0, bytes);
} else {
t->entries = NULL;
}
return true;
}
static void uninit(upb_table *t) { free(mutable_entries(t)); }
static upb_tabent *emptyent(upb_table *t) {
upb_tabent *e = mutable_entries(t) + upb_table_size(t);
while (1) { if (upb_tabent_isempty(--e)) return e; assert(e > t->entries); }
}
static upb_tabent *getentry_mutable(upb_table *t, uint32_t hash) {
return (upb_tabent*)upb_getentry(t, hash);
}
static const upb_tabent *findentry(const upb_table *t, lookupkey_t key,
uint32_t hash, eqlfunc_t *eql) {
const upb_tabent *e;
if (t->size_lg2 == 0) return NULL;
e = upb_getentry(t, hash);
if (upb_tabent_isempty(e)) return NULL;
while (1) {
if (eql(e->key, key)) return e;
if ((e = e->next) == NULL) return NULL;
}
}
static upb_tabent *findentry_mutable(upb_table *t, lookupkey_t key,
uint32_t hash, eqlfunc_t *eql) {
return (upb_tabent*)findentry(t, key, hash, eql);
}
static bool lookup(const upb_table *t, lookupkey_t key, upb_value *v,
uint32_t hash, eqlfunc_t *eql) {
const upb_tabent *e = findentry(t, key, hash, eql);
if (e) {
if (v) {
_upb_value_setval(v, e->val.val, t->ctype);
}
return true;
} else {
return false;
}
}
/* The given key must not already exist in the table. */
static void insert(upb_table *t, lookupkey_t key, upb_tabkey tabkey,
upb_value val, uint32_t hash,
hashfunc_t *hashfunc, eqlfunc_t *eql) {
upb_tabent *mainpos_e;
upb_tabent *our_e;
UPB_UNUSED(eql);
UPB_UNUSED(key);
assert(findentry(t, key, hash, eql) == NULL);
assert(val.ctype == t->ctype);
t->count++;
mainpos_e = getentry_mutable(t, hash);
our_e = mainpos_e;
if (upb_tabent_isempty(mainpos_e)) {
/* Our main position is empty; use it. */
our_e->next = NULL;
} else {
/* Collision. */
upb_tabent *new_e = emptyent(t);
/* Head of collider's chain. */
upb_tabent *chain = getentry_mutable(t, hashfunc(mainpos_e->key));
if (chain == mainpos_e) {
/* Existing ent is in its main posisiton (it has the same hash as us, and
* is the head of our chain). Insert to new ent and append to this chain. */
new_e->next = mainpos_e->next;
mainpos_e->next = new_e;
our_e = new_e;
} else {
/* Existing ent is not in its main position (it is a node in some other
* chain). This implies that no existing ent in the table has our hash.
* Evict it (updating its chain) and use its ent for head of our chain. */
*new_e = *mainpos_e; /* copies next. */
while (chain->next != mainpos_e) {
chain = (upb_tabent*)chain->next;
assert(chain);
}
chain->next = new_e;
our_e = mainpos_e;
our_e->next = NULL;
}
}
our_e->key = tabkey;
our_e->val.val = val.val;
assert(findentry(t, key, hash, eql) == our_e);
}
static bool rm(upb_table *t, lookupkey_t key, upb_value *val,
upb_tabkey *removed, uint32_t hash, eqlfunc_t *eql) {
upb_tabent *chain = getentry_mutable(t, hash);
if (upb_tabent_isempty(chain)) return false;
if (eql(chain->key, key)) {
/* Element to remove is at the head of its chain. */
t->count--;
if (val) {
_upb_value_setval(val, chain->val.val, t->ctype);
}
if (chain->next) {
upb_tabent *move = (upb_tabent*)chain->next;
*chain = *move;
if (removed) *removed = move->key;
move->key = 0; /* Make the slot empty. */
} else {
if (removed) *removed = chain->key;
chain->key = 0; /* Make the slot empty. */
}
return true;
} else {
/* Element to remove is either in a non-head position or not in the
* table. */
while (chain->next && !eql(chain->next->key, key))
chain = (upb_tabent*)chain->next;
if (chain->next) {
/* Found element to remove. */
upb_tabent *rm;
if (val) {
_upb_value_setval(val, chain->next->val.val, t->ctype);
}
rm = (upb_tabent*)chain->next;
if (removed) *removed = rm->key;
rm->key = 0;
chain->next = rm->next;
t->count--;
return true;
} else {
return false;
}
}
}
static size_t next(const upb_table *t, size_t i) {
do {
if (++i >= upb_table_size(t))
return SIZE_MAX;
} while(upb_tabent_isempty(&t->entries[i]));
return i;
}
static size_t begin(const upb_table *t) {
return next(t, -1);
}
/* upb_strtable ***************************************************************/
/* A simple "subclass" of upb_table that only adds a hash function for strings. */
static upb_tabkey strcopy(lookupkey_t k2) {
char *str = malloc(k2.str.len + sizeof(uint32_t) + 1);
if (str == NULL) return 0;
memcpy(str, &k2.str.len, sizeof(uint32_t));
memcpy(str + sizeof(uint32_t), k2.str.str, k2.str.len + 1);
return (uintptr_t)str;
}
static uint32_t strhash(upb_tabkey key) {
uint32_t len;
char *str = upb_tabstr(key, &len);
return MurmurHash2(str, len, 0);
}
static bool streql(upb_tabkey k1, lookupkey_t k2) {
uint32_t len;
char *str = upb_tabstr(k1, &len);
return len == k2.str.len && memcmp(str, k2.str.str, len) == 0;
}
bool upb_strtable_init(upb_strtable *t, upb_ctype_t ctype) {
return init(&t->t, ctype, 2);
}
void upb_strtable_uninit(upb_strtable *t) {
size_t i;
for (i = 0; i < upb_table_size(&t->t); i++)
free((void*)t->t.entries[i].key);
uninit(&t->t);
}
bool upb_strtable_resize(upb_strtable *t, size_t size_lg2) {
upb_strtable new_table;
upb_strtable_iter i;
if (!init(&new_table.t, t->t.ctype, size_lg2))
return false;
upb_strtable_begin(&i, t);
for ( ; !upb_strtable_done(&i); upb_strtable_next(&i)) {
upb_strtable_insert2(
&new_table,
upb_strtable_iter_key(&i),
upb_strtable_iter_keylength(&i),
upb_strtable_iter_value(&i));
}
upb_strtable_uninit(t);
*t = new_table;
return true;
}
bool upb_strtable_insert2(upb_strtable *t, const char *k, size_t len,
upb_value v) {
lookupkey_t key;
upb_tabkey tabkey;
uint32_t hash;
if (isfull(&t->t)) {
/* Need to resize. New table of double the size, add old elements to it. */
if (!upb_strtable_resize(t, t->t.size_lg2 + 1)) {
return false;
}
}
key = strkey2(k, len);
tabkey = strcopy(key);
if (tabkey == 0) return false;
hash = MurmurHash2(key.str.str, key.str.len, 0);
insert(&t->t, key, tabkey, v, hash, &strhash, &streql);
return true;
}
bool upb_strtable_lookup2(const upb_strtable *t, const char *key, size_t len,
upb_value *v) {
uint32_t hash = MurmurHash2(key, len, 0);
return lookup(&t->t, strkey2(key, len), v, hash, &streql);
}
bool upb_strtable_remove2(upb_strtable *t, const char *key, size_t len,
upb_value *val) {
uint32_t hash = MurmurHash2(key, strlen(key), 0);
upb_tabkey tabkey;
if (rm(&t->t, strkey2(key, len), val, &tabkey, hash, &streql)) {
free((void*)tabkey);
return true;
} else {
return false;
}
}
/* Iteration */
static const upb_tabent *str_tabent(const upb_strtable_iter *i) {
return &i->t->t.entries[i->index];
}
void upb_strtable_begin(upb_strtable_iter *i, const upb_strtable *t) {
i->t = t;
i->index = begin(&t->t);
}
void upb_strtable_next(upb_strtable_iter *i) {
i->index = next(&i->t->t, i->index);
}
bool upb_strtable_done(const upb_strtable_iter *i) {
return i->index >= upb_table_size(&i->t->t) ||
upb_tabent_isempty(str_tabent(i));
}
const char *upb_strtable_iter_key(upb_strtable_iter *i) {
assert(!upb_strtable_done(i));
return upb_tabstr(str_tabent(i)->key, NULL);
}
size_t upb_strtable_iter_keylength(upb_strtable_iter *i) {
uint32_t len;
assert(!upb_strtable_done(i));
upb_tabstr(str_tabent(i)->key, &len);
return len;
}
upb_value upb_strtable_iter_value(const upb_strtable_iter *i) {
assert(!upb_strtable_done(i));
return _upb_value_val(str_tabent(i)->val.val, i->t->t.ctype);
}
void upb_strtable_iter_setdone(upb_strtable_iter *i) {
i->index = SIZE_MAX;
}
bool upb_strtable_iter_isequal(const upb_strtable_iter *i1,
const upb_strtable_iter *i2) {
if (upb_strtable_done(i1) && upb_strtable_done(i2))
return true;
return i1->t == i2->t && i1->index == i2->index;
}
/* upb_inttable ***************************************************************/
/* For inttables we use a hybrid structure where small keys are kept in an
* array and large keys are put in the hash table. */
static uint32_t inthash(upb_tabkey key) { return upb_inthash(key); }
static bool inteql(upb_tabkey k1, lookupkey_t k2) {
return k1 == k2.num;
}
static upb_tabval *mutable_array(upb_inttable *t) {
return (upb_tabval*)t->array;
}
static upb_tabval *inttable_val(upb_inttable *t, uintptr_t key) {
if (key < t->array_size) {
return upb_arrhas(t->array[key]) ? &(mutable_array(t)[key]) : NULL;
} else {
upb_tabent *e =
findentry_mutable(&t->t, intkey(key), upb_inthash(key), &inteql);
return e ? &e->val : NULL;
}
}
static const upb_tabval *inttable_val_const(const upb_inttable *t,
uintptr_t key) {
return inttable_val((upb_inttable*)t, key);
}
size_t upb_inttable_count(const upb_inttable *t) {
return t->t.count + t->array_count;
}
static void check(upb_inttable *t) {
UPB_UNUSED(t);
#if defined(UPB_DEBUG_TABLE) && !defined(NDEBUG)
{
/* This check is very expensive (makes inserts/deletes O(N)). */
size_t count = 0;
upb_inttable_iter i;
upb_inttable_begin(&i, t);
for(; !upb_inttable_done(&i); upb_inttable_next(&i), count++) {
assert(upb_inttable_lookup(t, upb_inttable_iter_key(&i), NULL));
}
assert(count == upb_inttable_count(t));
}
#endif
}
bool upb_inttable_sizedinit(upb_inttable *t, upb_ctype_t ctype,
size_t asize, int hsize_lg2) {
size_t array_bytes;
if (!init(&t->t, ctype, hsize_lg2)) return false;
/* Always make the array part at least 1 long, so that we know key 0
* won't be in the hash part, which simplifies things. */
t->array_size = UPB_MAX(1, asize);
t->array_count = 0;
array_bytes = t->array_size * sizeof(upb_value);
t->array = malloc(array_bytes);
if (!t->array) {
uninit(&t->t);
return false;
}
memset(mutable_array(t), 0xff, array_bytes);
check(t);
return true;
}
bool upb_inttable_init(upb_inttable *t, upb_ctype_t ctype) {
return upb_inttable_sizedinit(t, ctype, 0, 4);
}
void upb_inttable_uninit(upb_inttable *t) {
uninit(&t->t);
free(mutable_array(t));
}
bool upb_inttable_insert(upb_inttable *t, uintptr_t key, upb_value val) {
/* XXX: Table can't store value (uint64_t)-1. Need to somehow statically
* guarantee that this is not necessary, or fix the limitation. */
upb_tabval tabval;
tabval.val = val.val;
UPB_UNUSED(tabval);
assert(upb_arrhas(tabval));
if (key < t->array_size) {
assert(!upb_arrhas(t->array[key]));
t->array_count++;
mutable_array(t)[key].val = val.val;
} else {
if (isfull(&t->t)) {
/* Need to resize the hash part, but we re-use the array part. */
size_t i;
upb_table new_table;
if (!init(&new_table, t->t.ctype, t->t.size_lg2 + 1))
return false;
for (i = begin(&t->t); i < upb_table_size(&t->t); i = next(&t->t, i)) {
const upb_tabent *e = &t->t.entries[i];
uint32_t hash;
upb_value v;
_upb_value_setval(&v, e->val.val, t->t.ctype);
hash = upb_inthash(e->key);
insert(&new_table, intkey(e->key), e->key, v, hash, &inthash, &inteql);
}
assert(t->t.count == new_table.count);
uninit(&t->t);
t->t = new_table;
}
insert(&t->t, intkey(key), key, val, upb_inthash(key), &inthash, &inteql);
}
check(t);
return true;
}
bool upb_inttable_lookup(const upb_inttable *t, uintptr_t key, upb_value *v) {
const upb_tabval *table_v = inttable_val_const(t, key);
if (!table_v) return false;
if (v) _upb_value_setval(v, table_v->val, t->t.ctype);
return true;
}
bool upb_inttable_replace(upb_inttable *t, uintptr_t key, upb_value val) {
upb_tabval *table_v = inttable_val(t, key);
if (!table_v) return false;
table_v->val = val.val;
return true;
}
bool upb_inttable_remove(upb_inttable *t, uintptr_t key, upb_value *val) {
bool success;
if (key < t->array_size) {
if (upb_arrhas(t->array[key])) {
upb_tabval empty = UPB_TABVALUE_EMPTY_INIT;
t->array_count--;
if (val) {
_upb_value_setval(val, t->array[key].val, t->t.ctype);
}
mutable_array(t)[key] = empty;
success = true;
} else {
success = false;
}
} else {
upb_tabkey removed;
uint32_t hash = upb_inthash(key);
success = rm(&t->t, intkey(key), val, &removed, hash, &inteql);
}
check(t);
return success;
}
bool upb_inttable_push(upb_inttable *t, upb_value val) {
return upb_inttable_insert(t, upb_inttable_count(t), val);
}
upb_value upb_inttable_pop(upb_inttable *t) {
upb_value val;
bool ok = upb_inttable_remove(t, upb_inttable_count(t) - 1, &val);
UPB_ASSERT_VAR(ok, ok);
return val;
}
bool upb_inttable_insertptr(upb_inttable *t, const void *key, upb_value val) {
return upb_inttable_insert(t, (uintptr_t)key, val);
}
bool upb_inttable_lookupptr(const upb_inttable *t, const void *key,
upb_value *v) {
return upb_inttable_lookup(t, (uintptr_t)key, v);
}
bool upb_inttable_removeptr(upb_inttable *t, const void *key, upb_value *val) {
return upb_inttable_remove(t, (uintptr_t)key, val);
}
void upb_inttable_compact(upb_inttable *t) {
/* A power-of-two histogram of the table keys. */
size_t counts[UPB_MAXARRSIZE + 1] = {0};
/* The max key in each bucket. */
uintptr_t max[UPB_MAXARRSIZE + 1] = {0};
upb_inttable_iter i;
size_t arr_count;
int size_lg2;
upb_inttable new_t;
upb_inttable_begin(&i, t);
for (; !upb_inttable_done(&i); upb_inttable_next(&i)) {
uintptr_t key = upb_inttable_iter_key(&i);
int bucket = log2ceil(key);
max[bucket] = UPB_MAX(max[bucket], key);
counts[bucket]++;
}
/* Find the largest power of two that satisfies the MIN_DENSITY
* definition (while actually having some keys). */
arr_count = upb_inttable_count(t);
for (size_lg2 = ARRAY_SIZE(counts) - 1; size_lg2 > 0; size_lg2--) {
if (counts[size_lg2] == 0) {
/* We can halve again without losing any entries. */
continue;
} else if (arr_count >= (1 << size_lg2) * MIN_DENSITY) {
break;
}
arr_count -= counts[size_lg2];
}
assert(arr_count <= upb_inttable_count(t));
{
/* Insert all elements into new, perfectly-sized table. */
size_t arr_size = max[size_lg2] + 1; /* +1 so arr[max] will fit. */
size_t hash_count = upb_inttable_count(t) - arr_count;
size_t hash_size = hash_count ? (hash_count / MAX_LOAD) + 1 : 0;
size_t hashsize_lg2 = log2ceil(hash_size);
upb_inttable_sizedinit(&new_t, t->t.ctype, arr_size, hashsize_lg2);
upb_inttable_begin(&i, t);
for (; !upb_inttable_done(&i); upb_inttable_next(&i)) {
uintptr_t k = upb_inttable_iter_key(&i);
upb_inttable_insert(&new_t, k, upb_inttable_iter_value(&i));
}
assert(new_t.array_size == arr_size);
assert(new_t.t.size_lg2 == hashsize_lg2);
}
upb_inttable_uninit(t);
*t = new_t;
}
/* Iteration. */
static const upb_tabent *int_tabent(const upb_inttable_iter *i) {
assert(!i->array_part);
return &i->t->t.entries[i->index];
}
static upb_tabval int_arrent(const upb_inttable_iter *i) {
assert(i->array_part);
return i->t->array[i->index];
}
void upb_inttable_begin(upb_inttable_iter *i, const upb_inttable *t) {
i->t = t;
i->index = -1;
i->array_part = true;
upb_inttable_next(i);
}
void upb_inttable_next(upb_inttable_iter *iter) {
const upb_inttable *t = iter->t;
if (iter->array_part) {
while (++iter->index < t->array_size) {
if (upb_arrhas(int_arrent(iter))) {
return;
}
}
iter->array_part = false;
iter->index = begin(&t->t);
} else {
iter->index = next(&t->t, iter->index);
}
}
bool upb_inttable_done(const upb_inttable_iter *i) {
if (i->array_part) {
return i->index >= i->t->array_size ||
!upb_arrhas(int_arrent(i));
} else {
return i->index >= upb_table_size(&i->t->t) ||
upb_tabent_isempty(int_tabent(i));
}
}
uintptr_t upb_inttable_iter_key(const upb_inttable_iter *i) {
assert(!upb_inttable_done(i));
return i->array_part ? i->index : int_tabent(i)->key;
}
upb_value upb_inttable_iter_value(const upb_inttable_iter *i) {
assert(!upb_inttable_done(i));
return _upb_value_val(
i->array_part ? i->t->array[i->index].val : int_tabent(i)->val.val,
i->t->t.ctype);
}
void upb_inttable_iter_setdone(upb_inttable_iter *i) {
i->index = SIZE_MAX;
i->array_part = false;
}
bool upb_inttable_iter_isequal(const upb_inttable_iter *i1,
const upb_inttable_iter *i2) {
if (upb_inttable_done(i1) && upb_inttable_done(i2))
return true;
return i1->t == i2->t && i1->index == i2->index &&
i1->array_part == i2->array_part;
}
#ifdef UPB_UNALIGNED_READS_OK
/* -----------------------------------------------------------------------------
* MurmurHash2, by Austin Appleby (released as public domain).
* Reformatted and C99-ified by Joshua Haberman.
* Note - This code makes a few assumptions about how your machine behaves -
* 1. We can read a 4-byte value from any address without crashing
* 2. sizeof(int) == 4 (in upb this limitation is removed by using uint32_t
* And it has a few limitations -
* 1. It will not work incrementally.
* 2. It will not produce the same results on little-endian and big-endian
* machines. */
uint32_t MurmurHash2(const void *key, size_t len, uint32_t seed) {
/* 'm' and 'r' are mixing constants generated offline.
* They're not really 'magic', they just happen to work well. */
const uint32_t m = 0x5bd1e995;
const int32_t r = 24;
/* Initialize the hash to a 'random' value */
uint32_t h = seed ^ len;
/* Mix 4 bytes at a time into the hash */
const uint8_t * data = (const uint8_t *)key;
while(len >= 4) {
uint32_t k = *(uint32_t *)data;
k *= m;
k ^= k >> r;
k *= m;
h *= m;
h ^= k;
data += 4;
len -= 4;
}
/* Handle the last few bytes of the input array */
switch(len) {
case 3: h ^= data[2] << 16;
case 2: h ^= data[1] << 8;
case 1: h ^= data[0]; h *= m;
};
/* Do a few final mixes of the hash to ensure the last few
* bytes are well-incorporated. */
h ^= h >> 13;
h *= m;
h ^= h >> 15;
return h;
}
#else /* !UPB_UNALIGNED_READS_OK */
/* -----------------------------------------------------------------------------
* MurmurHashAligned2, by Austin Appleby
* Same algorithm as MurmurHash2, but only does aligned reads - should be safer
* on certain platforms.
* Performance will be lower than MurmurHash2 */
#define MIX(h,k,m) { k *= m; k ^= k >> r; k *= m; h *= m; h ^= k; }
uint32_t MurmurHash2(const void * key, size_t len, uint32_t seed) {
const uint32_t m = 0x5bd1e995;
const int32_t r = 24;
const uint8_t * data = (const uint8_t *)key;
uint32_t h = seed ^ len;
uint8_t align = (uintptr_t)data & 3;
if(align && (len >= 4)) {
/* Pre-load the temp registers */
uint32_t t = 0, d = 0;
int32_t sl;
int32_t sr;
switch(align) {
case 1: t |= data[2] << 16;
case 2: t |= data[1] << 8;
case 3: t |= data[0];
}
t <<= (8 * align);
data += 4-align;
len -= 4-align;
sl = 8 * (4-align);
sr = 8 * align;
/* Mix */
while(len >= 4) {
uint32_t k;
d = *(uint32_t *)data;
t = (t >> sr) | (d << sl);
k = t;
MIX(h,k,m);
t = d;
data += 4;
len -= 4;
}
/* Handle leftover data in temp registers */
d = 0;
if(len >= align) {
uint32_t k;
switch(align) {
case 3: d |= data[2] << 16;
case 2: d |= data[1] << 8;
case 1: d |= data[0];
}
k = (t >> sr) | (d << sl);
MIX(h,k,m);
data += align;
len -= align;
/* ----------
* Handle tail bytes */
switch(len) {
case 3: h ^= data[2] << 16;
case 2: h ^= data[1] << 8;
case 1: h ^= data[0]; h *= m;
};
} else {
switch(len) {
case 3: d |= data[2] << 16;
case 2: d |= data[1] << 8;
case 1: d |= data[0];
case 0: h ^= (t >> sr) | (d << sl); h *= m;
}
}
h ^= h >> 13;
h *= m;
h ^= h >> 15;
return h;
} else {
while(len >= 4) {
uint32_t k = *(uint32_t *)data;
MIX(h,k,m);
data += 4;
len -= 4;
}
/* ----------
* Handle tail bytes */
switch(len) {
case 3: h ^= data[2] << 16;
case 2: h ^= data[1] << 8;
case 1: h ^= data[0]; h *= m;
};
h ^= h >> 13;
h *= m;
h ^= h >> 15;
return h;
}
}
#undef MIX
#endif /* UPB_UNALIGNED_READS_OK */