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runtime: handle and test large map values

This is from CL 5451105 but was dropped from that CL.
See also CL 6137051.

The only change compared to 5451105 is to check for
h != nil in reflect·mapiterinit; allowing use of nil maps
must have happened after that original CL.

Fixes #3573.

R=golang-dev, dave, r
CC=golang-dev
https://golang.org/cl/6215078
This commit is contained in:
Russ Cox 2012-05-24 22:41:07 -04:00
parent ca6b4d535f
commit bf18d57d4a
2 changed files with 215 additions and 51 deletions

View File

@ -6,17 +6,24 @@
#include "hashmap.h"
#include "type.h"
/* Hmap flag values */
#define IndirectVal (1<<0) /* storing pointers to values */
#define IndirectKey (1<<1) /* storing pointers to keys */
#define CanFreeTable (1<<2) /* okay to free subtables */
#define CanFreeKey (1<<3) /* okay to free pointers to keys */
struct Hmap { /* a hash table; initialize with hash_init() */
uint32 count; /* elements in table - must be first */
uint8 datasize; /* amount of data to store in entry */
uint8 max_power; /* max power of 2 to create sub-tables */
uint8 indirectval; /* storing pointers to values */
uint8 flag;
uint8 valoff; /* offset of value in key+value data block */
int32 changes; /* inc'ed whenever a subtable is created/grown */
uintptr hash0; /* hash seed */
struct hash_subtable *st; /* first-level table */
};
#define MaxData 255
struct hash_entry {
hash_hash_t hash; /* hash value of data */
byte data[1]; /* user data has "datasize" bytes */
@ -54,6 +61,7 @@ struct hash_subtable {
((struct hash_entry *) (((byte *) (base)) + (byte_offset)))
#define HASH_MAX_PROBES 15 /* max entries to probe before rehashing */
#define HASH_MAX_POWER 12 /* max power of 2 to create sub-tables */
/* return a hash layer with 2**power empty entries */
static struct hash_subtable *
@ -82,7 +90,7 @@ hash_subtable_new (Hmap *h, int32 power, int32 used)
}
static void
init_sizes (int64 hint, int32 *init_power, int32 *max_power)
init_sizes (int64 hint, int32 *init_power)
{
int32 log = 0;
int32 i;
@ -98,24 +106,20 @@ init_sizes (int64 hint, int32 *init_power, int32 *max_power)
} else {
*init_power = 12;
}
*max_power = 12;
}
static void
hash_init (Hmap *h, int32 datasize, int64 hint)
{
int32 init_power;
int32 max_power;
if(datasize < sizeof (void *))
datasize = sizeof (void *);
datasize = runtime·rnd(datasize, sizeof (void *));
init_sizes (hint, &init_power, &max_power);
init_sizes (hint, &init_power);
h->datasize = datasize;
h->max_power = max_power;
assert (h->datasize == datasize);
assert (h->max_power == max_power);
assert (sizeof (void *) <= h->datasize || h->max_power == 255);
assert (sizeof (void *) <= h->datasize);
h->count = 0;
h->changes = 0;
h->st = hash_subtable_new (h, init_power, 0);
@ -253,7 +257,8 @@ hash_grow (MapType *t, Hmap *h, struct hash_subtable **pst, int32 flags)
used++;
}
}
free (old_st);
if (h->flag & CanFreeTable)
free (old_st);
}
static int32
@ -266,6 +271,7 @@ hash_lookup (MapType *t, Hmap *h, void *data, void **pres)
hash_hash_t e_hash;
struct hash_entry *e;
struct hash_entry *end_e;
void *key;
bool eq;
hash = h->hash0;
@ -290,7 +296,10 @@ hash_lookup (MapType *t, Hmap *h, void *data, void **pres)
e = HASH_OFFSET (e, elemsize);
}
while (e != end_e && ((e_hash = e->hash) ^ hash) < HASH_SUBHASH) {
if (HASH_DATA_EQ (eq, t, h, data, e->data)) { /* a match */
key = e->data;
if (h->flag & IndirectKey)
key = *(void**)e->data;
if (HASH_DATA_EQ (eq, t, h, data, key)) { /* a match */
*pres = e->data;
return (1);
}
@ -312,6 +321,7 @@ hash_remove (MapType *t, Hmap *h, void *data)
struct hash_entry *e;
struct hash_entry *end_e;
bool eq;
void *key;
hash = h->hash0;
(*t->key->alg->hash) (&hash, t->key->size, data);
@ -335,8 +345,20 @@ hash_remove (MapType *t, Hmap *h, void *data)
e = HASH_OFFSET (e, elemsize);
}
while (e != end_e && ((e_hash = e->hash) ^ hash) < HASH_SUBHASH) {
if (HASH_DATA_EQ (eq, t, h, data, e->data)) { /* a match */
if (h->indirectval)
key = e->data;
if (h->flag & IndirectKey)
key = *(void**)e->data;
if (HASH_DATA_EQ (eq, t, h, data, key)) { /* a match */
// Free key if indirect, but only if reflect can't be
// holding a pointer to it. Deletions are rare,
// indirect (large) keys are rare, reflect on maps
// is rare. So in the rare, rare, rare case of deleting
// an indirect key from a map that has been reflected on,
// we leave the key for garbage collection instead of
// freeing it here.
if (h->flag & CanFreeKey)
free (key);
if (h->flag & IndirectVal)
free (*(void**)((byte*)e->data + h->valoff));
hash_remove_n (st, e, 1);
h->count--;
@ -385,8 +407,12 @@ hash_insert_internal (MapType *t, struct hash_subtable **pst, int32 flags, hash_
struct hash_entry *ins_e = e;
int32 ins_i = i;
hash_hash_t ins_e_hash;
void *key;
while (ins_e != end_e && ((e_hash = ins_e->hash) ^ hash) < HASH_SUBHASH) {
if (HASH_DATA_EQ (eq, t, h, data, ins_e->data)) { /* a match */
key = ins_e->data;
if (h->flag & IndirectKey)
key = *(void**)key;
if (HASH_DATA_EQ (eq, t, h, data, key)) { /* a match */
*pres = ins_e->data;
return (1);
}
@ -423,7 +449,7 @@ hash_insert_internal (MapType *t, struct hash_subtable **pst, int32 flags, hash_
return (0);
}
h->changes++;
if (st->power < h->max_power) {
if (st->power < HASH_MAX_POWER) {
hash_grow (t, h, pst, flags);
} else {
hash_conv (t, h, st, flags, hash, start_e);
@ -606,7 +632,7 @@ hash_iter_init (MapType *t, Hmap *h, struct hash_iter *it)
}
static void
clean_st (struct hash_subtable *st, int32 *slots, int32 *used)
clean_st (Hmap *h, struct hash_subtable *st, int32 *slots, int32 *used)
{
int32 elemsize = st->datasize + offsetof (struct hash_entry, data[0]);
struct hash_entry *e = st->entry;
@ -617,13 +643,14 @@ clean_st (struct hash_subtable *st, int32 *slots, int32 *used)
while (e <= last) {
hash_hash_t hash = e->hash;
if ((hash & HASH_MASK) == HASH_SUBHASH) {
clean_st (*(struct hash_subtable **)e->data, slots, used);
clean_st (h, *(struct hash_subtable **)e->data, slots, used);
} else {
lused += (hash != HASH_NIL);
}
e = HASH_OFFSET (e, elemsize);
}
free (st);
if (h->flag & CanFreeTable)
free (st);
*slots += lslots;
*used += lused;
}
@ -634,7 +661,7 @@ hash_destroy (Hmap *h)
int32 slots = 0;
int32 used = 0;
clean_st (h->st, &slots, &used);
clean_st (h, h->st, &slots, &used);
free (h);
}
@ -677,20 +704,23 @@ hash_visit (Hmap *h, void (*data_visit) (void *arg, int32 level, void *data), vo
/// interfaces to go runtime
//
// hash requires < 256 bytes of data (key+value) stored inline.
// Only basic types can be key - biggest is complex128 (16 bytes).
// Leave some room to grow, just in case.
enum {
MaxValsize = 256 - 64
};
static void**
hash_indirect(Hmap *h, void *p)
hash_valptr(Hmap *h, void *p)
{
if(h->indirectval)
p = (byte*)p + h->valoff;
if(h->flag & IndirectVal)
p = *(void**)p;
return p;
}
}
static void**
hash_keyptr(Hmap *h, void *p)
{
if(h->flag & IndirectKey)
p = *(void**)p;
return p;
}
static int32 debug = 0;
@ -699,8 +729,8 @@ Hmap*
runtime·makemap_c(MapType *typ, int64 hint)
{
Hmap *h;
int32 valsize_in_hash;
Type *key, *val;
uintptr ksize, vsize;
key = typ->key;
val = typ->elem;
@ -712,19 +742,29 @@ runtime·makemap_c(MapType *typ, int64 hint)
runtime·throw("runtime.makemap: unsupported map key type");
h = runtime·mal(sizeof(*h));
h->flag |= CanFreeTable; /* until reflect gets involved, free is okay */
valsize_in_hash = val->size;
if (val->size > MaxValsize) {
h->indirectval = 1;
valsize_in_hash = sizeof(void*);
}
ksize = runtime·rnd(key->size, sizeof(void*));
vsize = runtime·rnd(val->size, sizeof(void*));
if(ksize > MaxData || vsize > MaxData || ksize+vsize > MaxData) {
// Either key is too big, or value is, or combined they are.
// Prefer to keep the key if possible, because we look at
// keys more often than values.
if(ksize > MaxData - sizeof(void*)) {
// No choice but to indirect the key.
h->flag |= IndirectKey;
h->flag |= CanFreeKey; /* until reflect gets involved, free is okay */
ksize = sizeof(void*);
}
if(vsize > MaxData - ksize) {
// Have to indirect the value.
h->flag |= IndirectVal;
vsize = sizeof(void*);
}
}
// Align value inside data so that mark-sweep gc can find it.
h->valoff = key->size;
if(valsize_in_hash >= sizeof(void*))
h->valoff = runtime·rnd(key->size, sizeof(void*));
hash_init(h, h->valoff+valsize_in_hash, hint);
h->valoff = ksize;
hash_init(h, ksize+vsize, hint);
// these calculations are compiler dependent.
// figure out offsets of map call arguments.
@ -773,7 +813,7 @@ runtime·mapaccess(MapType *t, Hmap *h, byte *ak, byte *av, bool *pres)
res = nil;
if(hash_lookup(t, h, ak, (void**)&res)) {
*pres = true;
elem->alg->copy(elem->size, av, hash_indirect(h, res+h->valoff));
elem->alg->copy(elem->size, av, hash_valptr(h, res));
} else {
*pres = false;
elem->alg->copy(elem->size, av, nil);
@ -877,10 +917,14 @@ runtime·mapassign(MapType *t, Hmap *h, byte *ak, byte *av)
res = nil;
hit = hash_insert(t, h, ak, (void**)&res);
if(!hit && h->indirectval)
*(void**)(res+h->valoff) = runtime·mal(t->elem->size);
t->key->alg->copy(t->key->size, res, ak);
t->elem->alg->copy(t->elem->size, hash_indirect(h, res+h->valoff), av);
if(!hit) {
if(h->flag & IndirectKey)
*(void**)res = runtime·mal(t->key->size);
if(h->flag & IndirectVal)
*(void**)(res+h->valoff) = runtime·mal(t->elem->size);
}
t->key->alg->copy(t->key->size, hash_keyptr(h, res), ak);
t->elem->alg->copy(t->elem->size, hash_valptr(h, res), av);
if(debug) {
runtime·prints("mapassign: map=");
@ -985,6 +1029,22 @@ runtime·mapiterinit(MapType *t, Hmap *h, struct hash_iter *it)
void
reflect·mapiterinit(MapType *t, Hmap *h, struct hash_iter *it)
{
uint8 flag;
if(h != nil && t->key->size > sizeof(void*)) {
// reflect·mapiterkey returns pointers to key data,
// and reflect holds them, so we cannot free key data
// eagerly anymore. Updating h->flag now is racy,
// but it's okay because this is the only possible store
// after creation.
flag = h->flag;
if(flag & IndirectKey)
flag &= ~CanFreeKey;
else
flag &= ~CanFreeTable;
h->flag = flag;
}
it = runtime·mal(sizeof *it);
FLUSH(&it);
runtime·mapiterinit(t, h, it);
@ -1032,7 +1092,7 @@ runtime·mapiter1(struct hash_iter *it, ...)
runtime·throw("runtime.mapiter1: key:val nil pointer");
key = it->t->key;
key->alg->copy(key->size, ak, res);
key->alg->copy(key->size, ak, hash_keyptr(h, res));
if(debug) {
runtime·prints("mapiter2: iter=");
@ -1053,7 +1113,7 @@ runtime·mapiterkey(struct hash_iter *it, void *ak)
if(res == nil)
return false;
key = it->t->key;
key->alg->copy(key->size, ak, res);
key->alg->copy(key->size, ak, hash_keyptr(it->h, res));
return true;
}
@ -1076,6 +1136,7 @@ reflect·mapiterkey(struct hash_iter *it, uintptr key, bool ok)
} else {
tkey = it->t->key;
key = 0;
res = (byte*)hash_keyptr(it->h, res);
if(tkey->size <= sizeof(key))
tkey->alg->copy(tkey->size, (byte*)&key, res);
else
@ -1117,8 +1178,8 @@ runtime·mapiter2(struct hash_iter *it, ...)
runtime·throw("runtime.mapiter2: key:val nil pointer");
h = it->h;
t->key->alg->copy(t->key->size, ak, res);
t->elem->alg->copy(t->elem->size, av, hash_indirect(h, res+h->valoff));
t->key->alg->copy(t->key->size, ak, hash_keyptr(h, res));
t->elem->alg->copy(t->elem->size, av, hash_valptr(h, res));
if(debug) {
runtime·prints("mapiter2: iter=");

View File

@ -4,7 +4,9 @@
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Test behavior of maps with large elements.
// Internally a map holds elements in up to 255 bytes of key+value.
// When key or value or both are too large, it uses pointers to key+value
// instead. Test all the combinations.
package main
@ -33,4 +35,105 @@ func main() {
cmp(m[1], seq(11, 13))
cmp(m[2], seq(2, 9))
cmp(m[3], seq(3, 17))
{
type T [1]byte
type V [1]byte
m := make(map[T]V)
m[T{}] = V{1}
m[T{1}] = V{2}
if x, y := m[T{}][0], m[T{1}][0]; x != 1 || y != 2 {
println(x, y)
panic("bad map")
}
}
{
type T [100]byte
type V [1]byte
m := make(map[T]V)
m[T{}] = V{1}
m[T{1}] = V{2}
if x, y := m[T{}][0], m[T{1}][0]; x != 1 || y != 2 {
println(x, y)
panic("bad map")
}
}
{
type T [1]byte
type V [100]byte
m := make(map[T]V)
m[T{}] = V{1}
m[T{1}] = V{2}
if x, y := m[T{}][0], m[T{1}][0]; x != 1 || y != 2 {
println(x, y)
panic("bad map")
}
}
{
type T [1000]byte
type V [1]byte
m := make(map[T]V)
m[T{}] = V{1}
m[T{1}] = V{2}
if x, y := m[T{}][0], m[T{1}][0]; x != 1 || y != 2 {
println(x, y)
panic("bad map")
}
}
{
type T [1]byte
type V [1000]byte
m := make(map[T]V)
m[T{}] = V{1}
m[T{1}] = V{2}
if x, y := m[T{}][0], m[T{1}][0]; x != 1 || y != 2 {
println(x, y)
panic("bad map")
}
}
{
type T [1000]byte
type V [1000]byte
m := make(map[T]V)
m[T{}] = V{1}
m[T{1}] = V{2}
if x, y := m[T{}][0], m[T{1}][0]; x != 1 || y != 2 {
println(x, y)
panic("bad map")
}
}
{
type T [200]byte
type V [1]byte
m := make(map[T]V)
m[T{}] = V{1}
m[T{1}] = V{2}
if x, y := m[T{}][0], m[T{1}][0]; x != 1 || y != 2 {
println(x, y)
panic("bad map")
}
}
{
type T [1]byte
type V [200]byte
m := make(map[T]V)
m[T{}] = V{1}
m[T{1}] = V{2}
if x, y := m[T{}][0], m[T{1}][0]; x != 1 || y != 2 {
println(x, y)
panic("bad map")
}
}
{
type T [200]byte
type V [200]byte
m := make(map[T]V)
m[T{}] = V{1}
m[T{1}] = V{2}
if x, y := m[T{}][0], m[T{1}][0]; x != 1 || y != 2 {
println(x, y)
panic("bad map")
}
}
}