mirror of
https://github.com/golang/go
synced 2024-11-13 18:10:24 -07:00
runtime: revert of CL 8852047: do hashmap grow work during reads.
seems to break freebsd-386. R=golang-dev, dave CC=golang-dev https://golang.org/cl/9915047
This commit is contained in:
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07b6add0ca
commit
7f0ee023ba
@ -107,9 +107,6 @@ struct Hmap
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uintptr nevacuate; // progress counter for evacuation (buckets less than this have been evacuated)
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};
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// token to store in nevacuate field when locking the table to evacuate a bucket.
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#define EVAC_LOCK ((uintptr)-1)
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// possible flags
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enum
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{
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@ -117,7 +114,7 @@ enum
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IndirectValue = 2, // storing pointers to values
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Iterator = 4, // there may be an iterator using buckets
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OldIterator = 8, // there may be an iterator using oldbuckets
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CanFreeBucket = 16, // ok to free buckets TODO: remove - unused
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CanFreeBucket = 16, // ok to free buckets
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CanFreeKey = 32, // keys are indirect and ok to free keys
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};
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@ -288,14 +285,12 @@ hash_init(MapType *t, Hmap *h, uint32 hint)
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// Moves entries in oldbuckets[i] to buckets[i] and buckets[i+2^k].
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// We leave the original bucket intact, except for the evacuated marks, so that
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// lookup and iterators can still iterate through the old buckets.
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// Multiple threads must not be evacuating the same bucket at the same time.
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// iterators can still iterate through the old buckets.
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static void
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evacuate(MapType *t, Hmap *h, uintptr oldbucket)
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{
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Bucket *b;
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Bucket *nextb;
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Bucket *mainb;
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Bucket *x, *y;
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Bucket *newx, *newy;
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uintptr xi, yi;
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@ -304,154 +299,143 @@ evacuate(MapType *t, Hmap *h, uintptr oldbucket)
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uintptr i;
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byte *k, *v;
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byte *xk, *yk, *xv, *yv;
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byte *ob;
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mainb = (Bucket*)(h->oldbuckets + oldbucket * h->bucketsize);
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b = (Bucket*)(h->oldbuckets + oldbucket * h->bucketsize);
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newbit = (uintptr)1 << (h->B - 1);
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if(evacuated(mainb)) // someone else already evacuated this bucket.
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return;
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if(!evacuated(b)) {
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// TODO: reuse overflow buckets instead of using new ones, if there
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// is no iterator using the old buckets. (If CanFreeBuckets and !OldIterator.)
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b = mainb;
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x = (Bucket*)(h->buckets + oldbucket * h->bucketsize);
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y = (Bucket*)(h->buckets + (oldbucket + newbit) * h->bucketsize);
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clearbucket(x);
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clearbucket(y);
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xi = 0;
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yi = 0;
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xk = x->data;
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yk = y->data;
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xv = xk + h->keysize * BUCKETSIZE;
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yv = yk + h->keysize * BUCKETSIZE;
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do {
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for(i = 0, k = b->data, v = k + h->keysize * BUCKETSIZE; i < BUCKETSIZE; i++, k += h->keysize, v += h->valuesize) {
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if(b->tophash[i] == 0)
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continue;
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hash = h->hash0;
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t->key->alg->hash(&hash, t->key->size, IK(h, k));
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// NOTE: if key != key, then this hash could be (and probably will be)
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// entirely different from the old hash. We effectively only update
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// the B'th bit of the hash in this case.
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if((hash & newbit) == 0) {
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if(xi == BUCKETSIZE) {
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if(checkgc) mstats.next_gc = mstats.heap_alloc;
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newx = runtime·mallocgc(h->bucketsize, 0, 1, 0);
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clearbucket(newx);
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x->overflow = newx;
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x = newx;
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xi = 0;
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xk = x->data;
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xv = xk + h->keysize * BUCKETSIZE;
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}
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x->tophash[xi] = b->tophash[i];
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if((h->flags & IndirectKey) != 0) {
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*(byte**)xk = *(byte**)k; // copy pointer
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x = (Bucket*)(h->buckets + oldbucket * h->bucketsize);
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y = (Bucket*)(h->buckets + (oldbucket + newbit) * h->bucketsize);
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clearbucket(x);
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clearbucket(y);
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xi = 0;
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yi = 0;
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xk = x->data;
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yk = y->data;
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xv = xk + h->keysize * BUCKETSIZE;
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yv = yk + h->keysize * BUCKETSIZE;
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do {
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for(i = 0, k = b->data, v = k + h->keysize * BUCKETSIZE; i < BUCKETSIZE; i++, k += h->keysize, v += h->valuesize) {
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if(b->tophash[i] == 0)
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continue;
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hash = h->hash0;
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t->key->alg->hash(&hash, t->key->size, IK(h, k));
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// NOTE: if key != key, then this hash could be (and probably will be)
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// entirely different from the old hash. We effectively only update
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// the B'th bit of the hash in this case.
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if((hash & newbit) == 0) {
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if(xi == BUCKETSIZE) {
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if(checkgc) mstats.next_gc = mstats.heap_alloc;
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newx = runtime·mallocgc(h->bucketsize, 0, 1, 0);
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clearbucket(newx);
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x->overflow = newx;
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x = newx;
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xi = 0;
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xk = x->data;
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xv = xk + h->keysize * BUCKETSIZE;
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}
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x->tophash[xi] = b->tophash[i];
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if((h->flags & IndirectKey) != 0) {
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*(byte**)xk = *(byte**)k; // copy pointer
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} else {
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t->key->alg->copy(t->key->size, xk, k); // copy value
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}
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if((h->flags & IndirectValue) != 0) {
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*(byte**)xv = *(byte**)v;
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} else {
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t->elem->alg->copy(t->elem->size, xv, v);
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}
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xi++;
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xk += h->keysize;
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xv += h->valuesize;
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} else {
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t->key->alg->copy(t->key->size, xk, k); // copy value
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if(yi == BUCKETSIZE) {
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if(checkgc) mstats.next_gc = mstats.heap_alloc;
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newy = runtime·mallocgc(h->bucketsize, 0, 1, 0);
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clearbucket(newy);
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y->overflow = newy;
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y = newy;
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yi = 0;
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yk = y->data;
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yv = yk + h->keysize * BUCKETSIZE;
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}
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y->tophash[yi] = b->tophash[i];
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if((h->flags & IndirectKey) != 0) {
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*(byte**)yk = *(byte**)k;
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} else {
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t->key->alg->copy(t->key->size, yk, k);
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}
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if((h->flags & IndirectValue) != 0) {
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*(byte**)yv = *(byte**)v;
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} else {
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t->elem->alg->copy(t->elem->size, yv, v);
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}
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yi++;
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yk += h->keysize;
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yv += h->valuesize;
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}
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if((h->flags & IndirectValue) != 0) {
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*(byte**)xv = *(byte**)v;
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} else {
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t->elem->alg->copy(t->elem->size, xv, v);
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}
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// mark as evacuated so we don't do it again.
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// this also tells any iterators that this data isn't golden anymore.
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nextb = b->overflow;
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b->overflow = (Bucket*)((uintptr)nextb + 1);
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b = nextb;
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} while(b != nil);
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// Free old overflow buckets as much as we can.
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if((h->flags & OldIterator) == 0) {
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b = (Bucket*)(h->oldbuckets + oldbucket * h->bucketsize);
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if((h->flags & CanFreeBucket) != 0) {
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while((nextb = overflowptr(b)) != nil) {
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b->overflow = nextb->overflow;
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runtime·free(nextb);
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}
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xi++;
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xk += h->keysize;
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xv += h->valuesize;
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} else {
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if(yi == BUCKETSIZE) {
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if(checkgc) mstats.next_gc = mstats.heap_alloc;
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newy = runtime·mallocgc(h->bucketsize, 0, 1, 0);
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clearbucket(newy);
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y->overflow = newy;
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y = newy;
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yi = 0;
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yk = y->data;
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yv = yk + h->keysize * BUCKETSIZE;
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}
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y->tophash[yi] = b->tophash[i];
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if((h->flags & IndirectKey) != 0) {
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*(byte**)yk = *(byte**)k;
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} else {
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t->key->alg->copy(t->key->size, yk, k);
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}
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if((h->flags & IndirectValue) != 0) {
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*(byte**)yv = *(byte**)v;
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} else {
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t->elem->alg->copy(t->elem->size, yv, v);
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}
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yi++;
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yk += h->keysize;
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yv += h->valuesize;
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// can't explicitly free overflow buckets, but at least
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// we can unlink them.
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b->overflow = (Bucket*)1;
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}
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}
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b = b->overflow;
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} while(b != nil);
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// Mark main bucket as evacuated. This write commits the
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// bucket evacuation (readers can start using the new buckets).
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b = mainb->overflow;
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runtime·atomicstorep(&mainb->overflow, (Bucket*)((uintptr)b + 1));
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// Mark overflow buckets for any iterators.
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// These writes don't need to reach anyone until the next hashtable
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// modification, so they don't need to be synchronized.
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while(b != nil) {
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nextb = b->overflow;
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b->overflow = (Bucket*)((uintptr)nextb + 1);
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b = nextb;
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}
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// advance evacuation mark
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if(oldbucket == h->nevacuate) {
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h->nevacuate = oldbucket + 1;
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if(oldbucket + 1 == newbit) { // newbit == # of oldbuckets
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// free main bucket array
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if((h->flags & (OldIterator | CanFreeBucket)) == CanFreeBucket) {
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ob = h->oldbuckets;
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h->oldbuckets = nil;
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runtime·free(ob);
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} else {
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h->oldbuckets = nil;
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}
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}
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}
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if(docheck)
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check(t, h);
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}
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// Ensure that bucket has been evacuated from oldbuckets so that we can modify it.
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// Not multithreaded safe - you must not call this from anywhere except hash table
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// modifications (where we're guaranteed external synchronization).
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static void
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grow_work(MapType *t, Hmap *h, uintptr bucket)
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{
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uintptr noldbuckets;
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intptr n;
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// evac the bucket we're going to need
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noldbuckets = (uintptr)1 << (h->B - 1);
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// make sure we evacuate the oldbucket corresponding
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// to the bucket we're about to use
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evacuate(t, h, bucket & (noldbuckets - 1));
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// evac another bucket to make progress
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n = h->nevacuate;
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evacuate(t, h, n);
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// record what we've done
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h->nevacuate = n + 1;
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if(n + 1 == noldbuckets)
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h->oldbuckets = nil;
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}
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// Do some work for growing the table.
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// Multithreaded-safe.
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static void
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grow_work_read(MapType *t, Hmap *h) {
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uintptr noldbuckets;
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intptr n;
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noldbuckets = (uintptr)1 << (h->B - 1);
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// Get evacuation lock. If we can't get it, fine, that means
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// someone else is making progress which is good enough.
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n = h->nevacuate;
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if(n != EVAC_LOCK && // no one has evac lock
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n != noldbuckets && // there's still work to do
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runtime·casp((void**)&h->nevacuate, (void*)n, (void*)EVAC_LOCK)) { // we acquired lock
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// We're now the exclusive evacuator.
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evacuate(t, h, n);
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// record that we're done.
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runtime·atomicstorep((void**)&h->nevacuate, (void*)(n + 1));
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if(n + 1 == noldbuckets) {
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// commit finishing of grow.
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runtime·atomicstorep(&h->oldbuckets, nil);
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// note: can't free oldbuckets, someone might be using it.
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// it will have to get GCed.
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}
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}
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// evacuate one more oldbucket to make progress on growing
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if(h->oldbuckets != nil)
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evacuate(t, h, h->nevacuate);
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}
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static void
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@ -496,7 +480,7 @@ hash_lookup(MapType *t, Hmap *h, byte **keyp)
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{
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void *key;
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uintptr hash;
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uintptr bucket;
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uintptr bucket, oldbucket;
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Bucket *b;
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uint8 top;
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uintptr i;
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@ -511,14 +495,13 @@ hash_lookup(MapType *t, Hmap *h, byte **keyp)
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hash = h->hash0;
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t->key->alg->hash(&hash, t->key->size, key);
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bucket = hash & (((uintptr)1 << h->B) - 1);
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b = runtime·atomicloadp(&h->oldbuckets);
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if(b != nil) {
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grow_work_read(t, h);
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b = (Bucket*)((byte*)b + (bucket & (((uintptr)1 << (h->B - 1)) - 1)) * h->bucketsize);
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if(((uintptr)runtime·atomicloadp(&b->overflow) & 1) != 0)
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goto newbucket;
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if(h->oldbuckets != nil) {
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oldbucket = bucket & (((uintptr)1 << (h->B - 1)) - 1);
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b = (Bucket*)(h->oldbuckets + oldbucket * h->bucketsize);
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if(evacuated(b)) {
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b = (Bucket*)(h->buckets + bucket * h->bucketsize);
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}
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} else {
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newbucket:
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b = (Bucket*)(h->buckets + bucket * h->bucketsize);
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}
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top = hash >> (sizeof(uintptr)*8 - 8);
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@ -535,7 +518,7 @@ hash_lookup(MapType *t, Hmap *h, byte **keyp)
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}
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}
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}
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b = overflowptr(b);
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b = b->overflow;
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} while(b != nil);
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return nil;
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}
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@ -829,7 +812,6 @@ hash_next(struct hash_iter *it)
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uintptr bucket, oldbucket;
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uintptr hash;
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Bucket *b;
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byte *oldbuckets;
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uintptr i;
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intptr check_bucket;
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bool eq;
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@ -851,15 +833,14 @@ next:
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it->value = nil;
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return;
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}
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if(it->B == h->B && (oldbuckets = runtime·atomicloadp(&h->oldbuckets)) != nil) {
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if(h->oldbuckets != nil && it->B == h->B) {
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// Iterator was started in the middle of a grow, and the grow isn't done yet.
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// If the bucket we're looking at hasn't been filled in yet (i.e. the old
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// bucket hasn't been evacuated) then we need to iterate through the old
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// bucket and only return the ones that will be migrated to this bucket.
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grow_work_read(t, h);
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oldbucket = bucket & (((uintptr)1 << (it->B - 1)) - 1);
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b = (Bucket*)(oldbuckets + oldbucket * h->bucketsize);
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if(((uintptr)runtime·atomicloadp(&b->overflow) & 1) == 0) {
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b = (Bucket*)(h->oldbuckets + oldbucket * h->bucketsize);
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if(!evacuated(b)) {
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check_bucket = bucket;
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} else {
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b = (Bucket*)(it->buckets + bucket * h->bucketsize);
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@ -17,7 +17,7 @@ void
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HASH_LOOKUP1(MapType *t, Hmap *h, KEYTYPE key, byte *value)
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{
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uintptr hash;
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uintptr bucket;
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uintptr bucket, oldbucket;
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Bucket *b;
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uintptr i;
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KEYTYPE *k;
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@ -83,14 +83,13 @@ dohash:
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hash = h->hash0;
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HASHFUNC(&hash, sizeof(KEYTYPE), &key);
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bucket = hash & (((uintptr)1 << h->B) - 1);
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b = runtime·atomicloadp(&h->oldbuckets);
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if(b != nil) {
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grow_work_read(t, h);
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b = (Bucket*)((byte*)b + (bucket & (((uintptr)1 << (h->B - 1)) - 1)) * h->bucketsize);
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if(((uintptr)runtime·atomicloadp(&b->overflow) & 1) != 0)
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goto newbucket;
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if(h->oldbuckets != nil) {
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oldbucket = bucket & (((uintptr)1 << (h->B - 1)) - 1);
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b = (Bucket*)(h->oldbuckets + oldbucket * h->bucketsize);
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if(evacuated(b)) {
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b = (Bucket*)(h->buckets + bucket * h->bucketsize);
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}
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} else {
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newbucket:
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b = (Bucket*)(h->buckets + bucket * h->bucketsize);
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}
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top = hash >> (sizeof(uintptr)*8 - 8);
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@ -104,7 +103,7 @@ dohash:
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return;
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}
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}
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b = overflowptr(b);
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b = b->overflow;
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} while(b != nil);
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}
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value = empty_value;
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@ -116,7 +115,7 @@ void
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HASH_LOOKUP2(MapType *t, Hmap *h, KEYTYPE key, byte *value, bool res)
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{
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uintptr hash;
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uintptr bucket;
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uintptr bucket, oldbucket;
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Bucket *b;
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uintptr i;
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KEYTYPE *k;
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@ -188,14 +187,13 @@ dohash:
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hash = h->hash0;
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HASHFUNC(&hash, sizeof(KEYTYPE), &key);
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bucket = hash & (((uintptr)1 << h->B) - 1);
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b = runtime·atomicloadp(&h->oldbuckets);
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if(b != nil) {
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grow_work_read(t, h);
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b = (Bucket*)((byte*)b + (bucket & (((uintptr)1 << (h->B - 1)) - 1)) * h->bucketsize);
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if(((uintptr)runtime·atomicloadp(&b->overflow) & 1) != 0)
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goto newbucket;
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if(h->oldbuckets != nil) {
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||||
oldbucket = bucket & (((uintptr)1 << (h->B - 1)) - 1);
|
||||
b = (Bucket*)(h->oldbuckets + oldbucket * h->bucketsize);
|
||||
if(evacuated(b)) {
|
||||
b = (Bucket*)(h->buckets + bucket * h->bucketsize);
|
||||
}
|
||||
} else {
|
||||
newbucket:
|
||||
b = (Bucket*)(h->buckets + bucket * h->bucketsize);
|
||||
}
|
||||
top = hash >> (sizeof(uintptr)*8 - 8);
|
||||
@ -211,7 +209,7 @@ dohash:
|
||||
return;
|
||||
}
|
||||
}
|
||||
b = overflowptr(b);
|
||||
b = b->overflow;
|
||||
} while(b != nil);
|
||||
}
|
||||
value = empty_value;
|
||||
|
Loading…
Reference in New Issue
Block a user