/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2014-2017. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* %CopyrightEnd%
*
* hashmaps are an adaption of Rich Hickeys Persistent HashMaps
* which were an adaption of Phil Bagwells - Hash Array Mapped Tries
*
* Author: Björn-Egil Dahlberg
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include "sys.h"
#include "erl_vm.h"
#include "global.h"
#include "erl_process.h"
#include "error.h"
#define ERL_WANT_HIPE_BIF_WRAPPER__
#include "bif.h"
#undef ERL_WANT_HIPE_BIF_WRAPPER__
#include "erl_binary.h"
#include "erl_map.h"
/* BIFs
*
* DONE:
* - erlang:is_map/1
* - erlang:is_map_key/2
* - erlang:map_size/1
* - erlang:map_get/2
*
* - maps:find/2
* - maps:from_list/1
* - maps:get/2
* - maps:is_key/2
* - maps:keys/1
* - maps:merge/2
* - maps:new/0
* - maps:put/3
* - maps:remove/2
* - maps:take/2
* - maps:to_list/1
* - maps:update/3
* - maps:values/1
*
* TODO:
* - maps:foldl/3
* - maps:foldr/3
* - maps:map/3
* - maps:size/1
* - maps:without/2
*
* DEBUG: for sharing calculation
* - erts_internal:map_to_tuple_keys/1
*/
#ifndef DECL_AM
#define DECL_AM(S) Eterm AM_ ## S = am_atom_put(#S, sizeof(#S) - 1)
#endif
/* for hashmap_from_list/1 */
typedef struct {
Uint32 hx;
Uint32 skip;
Uint i;
Eterm val;
} hxnode_t;
static Eterm flatmap_merge(Process *p, Eterm nodeA, Eterm nodeB);
static BIF_RETTYPE map_merge_mixed(Process *p, Eterm flat, Eterm tree, int swap_args);
struct HashmapMergeContext_;
static BIF_RETTYPE hashmap_merge(Process *p, Eterm nodeA, Eterm nodeB, int swap_args,
struct HashmapMergeContext_*);
static Export hashmap_merge_trap_export;
static BIF_RETTYPE maps_merge_trap_1(BIF_ALIST_1);
static Uint hashmap_subtree_size(Eterm node);
static Eterm hashmap_keys(Process *p, Eterm map);
static Eterm hashmap_values(Process *p, Eterm map);
static Eterm hashmap_delete(Process *p, Uint32 hx, Eterm key, Eterm node, Eterm *value);
static Eterm flatmap_from_validated_list(Process *p, Eterm list, Uint size);
static Eterm hashmap_from_validated_list(Process *p, Eterm list, Uint size);
static Eterm hashmap_from_unsorted_array(ErtsHeapFactory*, hxnode_t *hxns, Uint n, int reject_dupkeys);
static Eterm hashmap_from_sorted_unique_array(ErtsHeapFactory*, hxnode_t *hxns, Uint n, int is_root);
static Eterm hashmap_from_chunked_array(ErtsHeapFactory*, hxnode_t *hxns, Uint n, Uint size, int is_root);
static Eterm hashmap_info(Process *p, Eterm node);
static Eterm hashmap_bld_tuple_uint(Uint **hpp, Uint *szp, Uint n, Uint nums[]);
static int hxnodecmp(hxnode_t* a, hxnode_t* b);
static int hxnodecmpkey(hxnode_t* a, hxnode_t* b);
void erts_init_map(void) {
erts_init_trap_export(&hashmap_merge_trap_export,
am_maps, am_merge_trap, 1,
&maps_merge_trap_1);
return;
}
/* erlang:map_size/1
* the corresponding instruction is implemented in:
* beam/erl_bif_guard.c
*/
BIF_RETTYPE map_size_1(BIF_ALIST_1) {
if (is_flatmap(BIF_ARG_1)) {
flatmap_t *mp = (flatmap_t*)flatmap_val(BIF_ARG_1);
BIF_RET(make_small(flatmap_get_size(mp)));
} else if (is_hashmap(BIF_ARG_1)) {
Eterm *head, *hp, res;
Uint size, hsz=0;
head = hashmap_val(BIF_ARG_1);
size = head[1];
(void) erts_bld_uint(NULL, &hsz, size);
hp = HAlloc(BIF_P, hsz);
res = erts_bld_uint(&hp, NULL, size);
BIF_RET(res);
}
BIF_P->fvalue = BIF_ARG_1;
BIF_ERROR(BIF_P, BADMAP);
}
/* maps:find/2
* return value if key *matches* a key in the map
*/
const Eterm *
erts_maps_get(Eterm key, Eterm map)
{
Uint32 hx;
if (is_flatmap(map)) {
Eterm *ks, *vs;
flatmap_t *mp;
Uint n, i;
mp = (flatmap_t *)flatmap_val(map);
n = flatmap_get_size(mp);
if (n == 0) {
return NULL;
}
ks = (Eterm *)tuple_val(mp->keys) + 1;
vs = flatmap_get_values(mp);
if (is_immed(key)) {
for (i = 0; i < n; i++) {
if (ks[i] == key) {
return &vs[i];
}
}
} else {
for (i = 0; i < n; i++) {
if (EQ(ks[i], key)) {
return &vs[i];
}
}
}
return NULL;
}
ASSERT(is_hashmap(map));
hx = hashmap_make_hash(key);
return erts_hashmap_get(hx, key, map);
}
BIF_RETTYPE maps_find_2(BIF_ALIST_2) {
if (is_map(BIF_ARG_2)) {
Eterm *hp, res;
const Eterm *value;
value = erts_maps_get(BIF_ARG_1, BIF_ARG_2);
if (value) {
hp = HAlloc(BIF_P, 3);
res = make_tuple(hp);
*hp++ = make_arityval(2);
*hp++ = am_ok;
*hp++ = *value;
BIF_RET(res);
}
BIF_RET(am_error);
}
BIF_P->fvalue = BIF_ARG_2;
BIF_ERROR(BIF_P, BADMAP);
}
/* maps:get/2 and erlang:map_get/2
* return value if key *matches* a key in the map
* exception badkey if none matches
*/
BIF_RETTYPE maps_get_2(BIF_ALIST_2) {
if (is_map(BIF_ARG_2)) {
const Eterm *value;
value = erts_maps_get(BIF_ARG_1, BIF_ARG_2);
if (value) {
BIF_RET(*value);
}
BIF_P->fvalue = BIF_ARG_1;
BIF_ERROR(BIF_P, BADKEY);
}
BIF_P->fvalue = BIF_ARG_2;
BIF_ERROR(BIF_P, BADMAP);
}
BIF_RETTYPE map_get_2(BIF_ALIST_2) {
BIF_RET(maps_get_2(BIF_CALL_ARGS));
}
/* maps:from_list/1
* List may be unsorted [{K,V}]
*/
BIF_RETTYPE maps_from_list_1(BIF_ALIST_1) {
Eterm item = BIF_ARG_1, res, *kv;
Uint size = 0;
if (is_list(item) || is_nil(item)) {
/* Calculate size and check validity */
while(is_list(item)) {
res = CAR(list_val(item));
if (is_not_tuple(res))
goto error;
kv = tuple_val(res);
if (*kv != make_arityval(2))
goto error;
size++;
item = CDR(list_val(item));
}
if (is_not_nil(item))
goto error;
if (size > MAP_SMALL_MAP_LIMIT) {
BIF_RET(hashmap_from_validated_list(BIF_P, BIF_ARG_1, size));
} else {
BIF_RET(flatmap_from_validated_list(BIF_P, BIF_ARG_1, size));
}
}
error:
BIF_ERROR(BIF_P, BADARG);
}
static Eterm flatmap_from_validated_list(Process *p, Eterm list, Uint size) {
Eterm *kv, item = list;
Eterm *hp, *thp,*vs, *ks, keys, res;
flatmap_t *mp;
Uint unused_size = 0;
Sint c = 0;
Sint idx = 0;
hp = HAlloc(p, 3 + 1 + (2 * size));
thp = hp;
keys = make_tuple(hp);
*hp++ = make_arityval(size);
ks = hp;
hp += size;
mp = (flatmap_t*)hp;
res = make_flatmap(mp);
hp += MAP_HEADER_FLATMAP_SZ;
vs = hp;
mp->thing_word = MAP_HEADER_FLATMAP;
mp->size = size; /* set later, might shrink*/
mp->keys = keys;
if (size == 0)
return res;
/* first entry */
kv = tuple_val(CAR(list_val(item)));
ks[0] = kv[1];
vs[0] = kv[2];
size = 1;
item = CDR(list_val(item));
/* insert sort key/value pairs */
while(is_list(item)) {
kv = tuple_val(CAR(list_val(item)));
/* compare ks backwards
* idx represent word index to be written (hole position).
* We cannot copy the elements when searching since we might
* have an equal key. So we search for just the index first =(
*
* It is perhaps faster to move the values in the first pass.
* Check for uniqueness during insert phase and then have a
* second phace compacting the map if duplicates are found
* during insert. .. or do someother sort .. shell-sort perhaps.
*/
idx = size;
while(idx > 0 && (c = CMP_TERM(kv[1],ks[idx-1])) < 0) { idx--; }
if (c == 0) {
/* last compare was equal,
* i.e. we have to release memory
* and overwrite that key/value
*/
ks[idx-1] = kv[1];
vs[idx-1] = kv[2];
unused_size++;
} else {
Uint i = size;
while(i > idx) {
ks[i] = ks[i-1];
vs[i] = vs[i-1];
i--;
}
ks[idx] = kv[1];
vs[idx] = kv[2];
size++;
}
item = CDR(list_val(item));
}
if (unused_size) {
/* the key tuple is embedded in the heap
* write a bignum to clear it.
*/
/* release values as normal since they are on the top of the heap */
ks[size] = make_pos_bignum_header(unused_size - 1);
HRelease(p, vs + size + unused_size, vs + size);
}
*thp = make_arityval(size);
mp->size = size;
return res;
}
#define swizzle32(D,S) \
do { \
(D) = ((S) & 0x0000000f) << 28 | ((S) & 0x000000f0) << 20 \
| ((S) & 0x00000f00) << 12 | ((S) & 0x0000f000) << 4 \
| ((S) & 0x000f0000) >> 4 | ((S) & 0x00f00000) >> 12 \
| ((S) & 0x0f000000) >> 20 | ((S) & 0xf0000000) >> 28; \
} while(0)
#define maskval(V,L) (((V) >> ((7 - (L))*4)) & 0xf)
#define cdepth(V1,V2) (hashmap_clz((V1) ^ (V2)) >> 2)
static Eterm hashmap_from_validated_list(Process *p, Eterm list, Uint size) {
Eterm item = list;
Eterm *hp;
Eterm *kv, res;
Uint32 sw, hx;
Uint ix = 0;
hxnode_t *hxns;
ErtsHeapFactory factory;
DeclareTmpHeap(tmp,2,p);
ASSERT(size > 0);
hp = HAlloc(p, (2 * size));
/* create tmp hx values and leaf ptrs */
hxns = (hxnode_t *)erts_alloc(ERTS_ALC_T_TMP, size * sizeof(hxnode_t));
UseTmpHeap(2,p);
while(is_list(item)) {
res = CAR(list_val(item));
kv = tuple_val(res);
hx = hashmap_restore_hash(tmp,0,kv[1]);
swizzle32(sw,hx);
hxns[ix].hx = sw;
hxns[ix].val = CONS(hp, kv[1], kv[2]); hp += 2;
hxns[ix].skip = 1; /* will be reassigned in from_array */
hxns[ix].i = ix;
ix++;
item = CDR(list_val(item));
}
UnUseTmpHeap(2,p);
erts_factory_proc_init(&factory, p);
res = hashmap_from_unsorted_array(&factory, hxns, size, 0);
erts_factory_close(&factory);
erts_free(ERTS_ALC_T_TMP, (void *) hxns);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(p);
if (hashmap_size(res) <= MAP_SMALL_MAP_LIMIT) {
DECLARE_WSTACK(wstack);
Eterm *kv, *ks, *vs;
flatmap_t *mp;
Eterm keys;
Uint n = hashmap_size(res);
/* build flat structure */
hp = HAlloc(p, 3 + 1 + (2 * n));
keys = make_tuple(hp);
*hp++ = make_arityval(n);
ks = hp;
hp += n;
mp = (flatmap_t*)hp;
hp += MAP_HEADER_FLATMAP_SZ;
vs = hp;
mp->thing_word = MAP_HEADER_FLATMAP;
mp->size = n;
mp->keys = keys;
hashmap_iterator_init(&wstack, res, 0);
while ((kv=hashmap_iterator_next(&wstack)) != NULL) {
*ks++ = CAR(kv);
*vs++ = CDR(kv);
}
/* it cannot have multiple keys */
erts_validate_and_sort_flatmap(mp);
DESTROY_WSTACK(wstack);
return make_flatmap(mp);
}
return res;
}
Eterm erts_hashmap_from_array(ErtsHeapFactory* factory, Eterm *leafs, Uint n,
int reject_dupkeys) {
Uint32 sw, hx;
Uint ix;
hxnode_t *hxns;
Eterm res;
/* create tmp hx values and leaf ptrs */
hxns = (hxnode_t *)erts_alloc(ERTS_ALC_T_TMP, n * sizeof(hxnode_t));
for (ix = 0; ix < n; ix++) {
hx = hashmap_make_hash(*leafs);
swizzle32(sw,hx);
hxns[ix].hx = sw;
hxns[ix].val = make_list(leafs);
hxns[ix].skip = 1;
hxns[ix].i = ix;
leafs += 2;
}
res = hashmap_from_unsorted_array(factory, hxns, n, reject_dupkeys);
erts_free(ERTS_ALC_T_TMP, (void *) hxns);
return res;
}
Eterm erts_map_from_ks_and_vs(ErtsHeapFactory *factory, Eterm *ks0, Eterm *vs0, Uint n)
{
if (n < MAP_SMALL_MAP_LIMIT) {
Eterm *ks, *vs, *hp;
flatmap_t *mp;
Eterm keys;
hp = erts_produce_heap(factory, 3 + 1 + (2 * n), 0);
keys = make_tuple(hp);
*hp++ = make_arityval(n);
ks = hp;
hp += n;
mp = (flatmap_t*)hp;
hp += MAP_HEADER_FLATMAP_SZ;
vs = hp;
mp->thing_word = MAP_HEADER_FLATMAP;
mp->size = n;
mp->keys = keys;
sys_memcpy(ks, ks0, n * sizeof(Eterm));
sys_memcpy(vs, vs0, n * sizeof(Eterm));
if (!erts_validate_and_sort_flatmap(mp)) {
return THE_NON_VALUE;
}
return make_flatmap(mp);
} else {
return erts_hashmap_from_ks_and_vs(factory, ks0, vs0, n);
}
return THE_NON_VALUE;
}
Eterm erts_hashmap_from_ks_and_vs_extra(ErtsHeapFactory *factory,
Eterm *ks, Eterm *vs, Uint n,
Eterm key, Eterm value) {
Uint32 sw, hx;
Uint i,sz;
hxnode_t *hxns;
Eterm *hp, res;
sz = (key == THE_NON_VALUE) ? n : (n + 1);
ASSERT(sz > MAP_SMALL_MAP_LIMIT);
hp = erts_produce_heap(factory, 2 * sz, 0);
/* create tmp hx values and leaf ptrs */
hxns = (hxnode_t *)erts_alloc(ERTS_ALC_T_TMP, sz * sizeof(hxnode_t));
for(i = 0; i < n; i++) {
hx = hashmap_make_hash(ks[i]);
swizzle32(sw,hx);
hxns[i].hx = sw;
hxns[i].val = CONS(hp, ks[i], vs[i]); hp += 2;
hxns[i].skip = 1; /* will be reassigned in from_array */
hxns[i].i = i;
}
if (key != THE_NON_VALUE) {
hx = hashmap_make_hash(key);
swizzle32(sw,hx);
hxns[i].hx = sw;
hxns[i].val = CONS(hp, key, value); hp += 2;
hxns[i].skip = 1;
hxns[i].i = i;
}
res = hashmap_from_unsorted_array(factory, hxns, sz, 0);
erts_free(ERTS_ALC_T_TMP, (void *) hxns);
return res;
}
static Eterm hashmap_from_unsorted_array(ErtsHeapFactory* factory,
hxnode_t *hxns, Uint n,
int reject_dupkeys) {
Uint jx = 0, ix = 0, lx, cx;
Eterm res;
if (n == 0) {
Eterm *hp;
hp = erts_produce_heap(factory, 2, 0);
hp[0] = MAP_HEADER_HAMT_HEAD_BITMAP(0);
hp[1] = 0;
return make_hashmap(hp);
}
/* sort and compact array (remove non-unique entries) */
qsort(hxns, n, sizeof(hxnode_t), (int (*)(const void *, const void *)) hxnodecmp);
ix = 0, cx = 0;
while(ix < n - 1) {
if (hxns[ix].hx == hxns[ix+1].hx) {
/* find region of equal hash values */
jx = ix + 1;
while(jx < n && hxns[ix].hx == hxns[jx].hx) { jx++; }
/* find all correct keys from region
* (last in list but now hash sorted so we check highest id instead) */
/* resort with keys instead of hash value within region */
qsort(&hxns[ix], jx - ix, sizeof(hxnode_t),
(int (*)(const void *, const void *)) hxnodecmpkey);
while(ix < jx) {
lx = ix;
while(++ix < jx && EQ(CAR(list_val(hxns[ix].val)),
CAR(list_val(hxns[lx].val)))) {
if (reject_dupkeys)
return THE_NON_VALUE;
if (hxns[ix].i > hxns[lx].i) {
lx = ix;
}
}
hxns[cx].hx = hxns[lx].hx;
hxns[cx].val = hxns[lx].val;
cx++;
}
ix = jx;
continue;
}
if (ix > cx) {
hxns[cx].hx = hxns[ix].hx;
hxns[cx].val = hxns[ix].val;
}
cx++;
ix++;
}
if (ix < n) {
hxns[cx].hx = hxns[ix].hx;
hxns[cx].val = hxns[ix].val;
cx++;
}
if (cx > 1) {
/* recursive decompose array */
res = hashmap_from_sorted_unique_array(factory, hxns, cx, 0);
} else {
Eterm *hp;
/* we only have one item, either because n was 1 or
* because we hade multiples of the same key.
*
* hash value has been swizzled, need to drag it down to get the
* correct slot. */
hp = erts_produce_heap(factory, HAMT_HEAD_BITMAP_SZ(1), 0);
hp[0] = MAP_HEADER_HAMT_HEAD_BITMAP(1 << ((hxns[0].hx >> 0x1c) & 0xf));
hp[1] = 1;
hp[2] = hxns[0].val;
res = make_hashmap(hp);
}
return res;
}
static Eterm hashmap_from_sorted_unique_array(ErtsHeapFactory* factory,
hxnode_t *hxns, Uint n, int lvl) {
Eterm res = NIL;
Uint i,ix,jx,elems;
Uint32 sw, hx;
Eterm val;
hxnode_t *tmp;
DeclareTmpHeapNoproc(th,2);
UseTmpHeapNoproc(2);
ASSERT(lvl < 32);
ix = 0;
elems = 1;
while (ix < n - 1) {
if (hxns[ix].hx == hxns[ix+1].hx) {
jx = ix + 1;
while (jx < n && hxns[ix].hx == hxns[jx].hx) { jx++; }
tmp = (hxnode_t *)erts_alloc(ERTS_ALC_T_TMP, ((jx - ix)) * sizeof(hxnode_t));
for(i = 0; i < jx - ix; i++) {
val = hxns[i + ix].val;
hx = hashmap_restore_hash(th, lvl + 8, CAR(list_val(val)));
swizzle32(sw,hx);
tmp[i].hx = sw;
tmp[i].val = val;
tmp[i].i = i;
tmp[i].skip = 1;
}
qsort(tmp, jx - ix, sizeof(hxnode_t), (int (*)(const void *, const void *)) hxnodecmp);
hxns[ix].skip = jx - ix;
hxns[ix].val = hashmap_from_sorted_unique_array(factory, tmp, jx - ix, lvl + 8);
erts_free(ERTS_ALC_T_TMP, (void *) tmp);
ix = jx;
if (ix < n) { elems++; }
continue;
}
hxns[ix].skip = 1;
elems++;
ix++;
}
res = hashmap_from_chunked_array(factory, hxns, elems, n, !lvl);
ERTS_FACTORY_HOLE_CHECK(factory);
UnUseTmpHeapNoproc(2);
return res;
}
#define HALLOC_EXTRA 200
static Eterm hashmap_from_chunked_array(ErtsHeapFactory *factory, hxnode_t *hxns, Uint n,
Uint size, int is_root) {
Uint ix, d, dn, dc, slot, elems;
Uint32 v, vp, vn, hdr;
Uint bp, sz;
DECLARE_ESTACK(stack);
Eterm res = NIL, *hp = NULL, *nhp;
/* if we get here with only one element then
* we have eight levels of collisions
*/
if (n == 1) {
res = hxns[0].val;
v = hxns[0].hx;
for (d = 7; d > 0; d--) {
slot = maskval(v,d);
hp = erts_produce_heap(factory, HAMT_NODE_BITMAP_SZ(1), HALLOC_EXTRA);
hp[0] = MAP_HEADER_HAMT_NODE_BITMAP(1 << slot);
hp[1] = res;
res = make_hashmap(hp);
}
slot = maskval(v,0);
hp = erts_produce_heap(factory, (is_root ? 3 : 2), 0);
if (is_root) {
hp[0] = MAP_HEADER_HAMT_HEAD_BITMAP(1 << slot);
hp[1] = size;
hp[2] = res;
} else {
hp[0] = MAP_HEADER_HAMT_NODE_BITMAP(1 << slot);
hp[1] = res;
}
return make_hashmap(hp);
}
/* push initial nodes on the stack,
* this is the starting depth */
ix = 0;
d = 0;
vp = hxns[ix].hx;
v = hxns[ix + hxns[ix].skip].hx;
ASSERT(vp > v);
slot = maskval(vp,d);
while(slot == maskval(v,d)) {
ESTACK_PUSH(stack, 1 << slot);
d++;
slot = maskval(vp,d);
}
res = hxns[ix].val;
if (hxns[ix].skip > 1) {
dc = 7;
/* build collision nodes */
while (dc > d) {
hp = erts_produce_heap(factory, HAMT_NODE_BITMAP_SZ(1), HALLOC_EXTRA);
hp[0] = MAP_HEADER_HAMT_NODE_BITMAP(1 << maskval(vp,dc));
hp[1] = res;
res = make_hashmap(hp);
dc--;
}
}
ESTACK_PUSH2(stack,res,1 << slot);
/* all of the other nodes .. */
elems = n - 2; /* remove first and last elements */
while(elems--) {
hdr = ESTACK_POP(stack);
ix = ix + hxns[ix].skip;
/* determine if node or subtree should be built by looking
* at the next value. */
vn = hxns[ix + hxns[ix].skip].hx;
dn = cdepth(v,vn);
ASSERT(v > vn);
res = hxns[ix].val;
if (hxns[ix].skip > 1) {
int wat = (d > dn) ? d : dn;
dc = 7;
/* build collision nodes */
while (dc > wat) {
hp = erts_produce_heap(factory, HAMT_NODE_BITMAP_SZ(1), HALLOC_EXTRA);
hp[0] = MAP_HEADER_HAMT_NODE_BITMAP(1 << maskval(v,dc));
hp[1] = res;
res = make_hashmap(hp);
dc--;
}
}
/* next depth is higher (implies collision) */
if (d < dn) {
/* hdr is the popped one initially */
while(d < dn) {
slot = maskval(v, d);
bp = 1 << slot;
ESTACK_PUSH(stack, hdr | bp);
d++;
hdr = 0; /* clear hdr for all other collisions */
}
slot = maskval(v, d);
bp = 1 << slot;
/* no more collisions */
ESTACK_PUSH2(stack,res,bp);
} else if (d == dn) {
/* no collisions at all */
slot = maskval(v, d);
bp = 1 << slot;
ESTACK_PUSH2(stack,res,hdr | bp);
} else {
/* dn < n, we have a drop and we are done
* build nodes and subtree */
while (dn != d) {
slot = maskval(v, d);
bp = 1 << slot;
/* OR bitposition before sz calculation to handle
* redundant collisions */
hdr |= bp;
sz = hashmap_bitcount(hdr);
hp = erts_produce_heap(factory, HAMT_NODE_BITMAP_SZ(sz), HALLOC_EXTRA);
nhp = hp;
*hp++ = MAP_HEADER_HAMT_NODE_BITMAP(hdr);
*hp++ = res; sz--;
while (sz--) { *hp++ = ESTACK_POP(stack); }
ASSERT((hp - nhp) < 18);
res = make_hashmap(nhp);
/* we need to pop the next hdr and push if we don't need it */
hdr = ESTACK_POP(stack);
d--;
}
ESTACK_PUSH2(stack,res,hdr);
}
vp = v;
v = vn;
d = dn;
ERTS_FACTORY_HOLE_CHECK(factory);
}
/* v and vp are reused from above */
dn = cdepth(vp,v);
ix = ix + hxns[ix].skip;
res = hxns[ix].val;
if (hxns[ix].skip > 1) {
dc = 7;
/* build collision nodes */
while (dc > dn) {
hp = erts_produce_heap(factory, HAMT_NODE_BITMAP_SZ(1), HALLOC_EXTRA);
hp[0] = MAP_HEADER_HAMT_NODE_BITMAP(1 << maskval(v,dc));
hp[1] = res;
res = make_hashmap(hp);
dc--;
}
}
hdr = ESTACK_POP(stack);
/* pop remaining subtree if any */
while (dn) {
slot = maskval(v, dn);
bp = 1 << slot;
/* OR bitposition before sz calculation to handle
* redundant collisions */
hdr |= bp;
sz = hashmap_bitcount(hdr);
hp = erts_produce_heap(factory, HAMT_NODE_BITMAP_SZ(sz), HALLOC_EXTRA);
nhp = hp;
*hp++ = MAP_HEADER_HAMT_NODE_BITMAP(hdr);
*hp++ = res; sz--;
while (sz--) { *hp++ = ESTACK_POP(stack); }
res = make_hashmap(nhp);
hdr = ESTACK_POP(stack);
dn--;
}
/* and finally the root .. */
slot = maskval(v, dn);
bp = 1 << slot;
hdr |= bp;
sz = hashmap_bitcount(hdr);
hp = erts_produce_heap(factory, sz + /* hdr + item */ (is_root ? 2 : 1), 0);
nhp = hp;
if (is_root) {
*hp++ = (hdr == 0xffff) ? MAP_HEADER_HAMT_HEAD_ARRAY : MAP_HEADER_HAMT_HEAD_BITMAP(hdr);
*hp++ = size;
} else {
*hp++ = MAP_HEADER_HAMT_NODE_BITMAP(hdr);
}
*hp++ = res; sz--;
while (sz--) { *hp++ = ESTACK_POP(stack); }
res = make_hashmap(nhp);
ASSERT(ESTACK_COUNT(stack) == 0);
DESTROY_ESTACK(stack);
ERTS_FACTORY_HOLE_CHECK(factory);
return res;
}
#undef HALLOC_EXTRA
static int hxnodecmpkey(hxnode_t *a, hxnode_t *b) {
Sint c = CMP_TERM(CAR(list_val(a->val)), CAR(list_val(b->val)));
#if ERTS_SIZEOF_ETERM <= SIZEOF_INT
return c;
#else
return c > 0 ? 1 : (c < 0 ? -1 : 0);
#endif
}
static int hxnodecmp(hxnode_t *a, hxnode_t *b) {
if (a->hx < b->hx)
return 1;
else if (a->hx == b->hx)
return 0;
else
return -1;
}
/* maps:is_key/2 and erlang:is_map_key/2 */
BIF_RETTYPE maps_is_key_2(BIF_ALIST_2) {
if (is_map(BIF_ARG_2)) {
BIF_RET(erts_maps_get(BIF_ARG_1, BIF_ARG_2) ? am_true : am_false);
}
BIF_P->fvalue = BIF_ARG_2;
BIF_ERROR(BIF_P, BADMAP);
}
BIF_RETTYPE is_map_key_2(BIF_ALIST_2) {
BIF_RET(maps_is_key_2(BIF_CALL_ARGS));
}
/* maps:keys/1 */
BIF_RETTYPE maps_keys_1(BIF_ALIST_1) {
if (is_flatmap(BIF_ARG_1)) {
Eterm *hp, *ks, res = NIL;
flatmap_t *mp;
Uint n;
mp = (flatmap_t*)flatmap_val(BIF_ARG_1);
n = flatmap_get_size(mp);
if (n == 0)
BIF_RET(res);
hp = HAlloc(BIF_P, (2 * n));
ks = flatmap_get_keys(mp);
while(n--) {
res = CONS(hp, ks[n], res); hp += 2;
}
BIF_RET(res);
} else if (is_hashmap(BIF_ARG_1)) {
BIF_RET(hashmap_keys(BIF_P, BIF_ARG_1));
}
BIF_P->fvalue = BIF_ARG_1;
BIF_ERROR(BIF_P, BADMAP);
}
/* maps:merge/2 */
HIPE_WRAPPER_BIF_DISABLE_GC(maps_merge, 2)
BIF_RETTYPE maps_merge_2(BIF_ALIST_2) {
if (is_flatmap(BIF_ARG_1)) {
if (is_flatmap(BIF_ARG_2)) {
BIF_RET(flatmap_merge(BIF_P, BIF_ARG_1, BIF_ARG_2));
} else if (is_hashmap(BIF_ARG_2)) {
/* Will always become a tree */
return map_merge_mixed(BIF_P, BIF_ARG_1, BIF_ARG_2, 0);
}
BIF_P->fvalue = BIF_ARG_2;
} else if (is_hashmap(BIF_ARG_1)) {
if (is_hashmap(BIF_ARG_2)) {
return hashmap_merge(BIF_P, BIF_ARG_1, BIF_ARG_2, 0, NULL);
} else if (is_flatmap(BIF_ARG_2)) {
/* Will always become a tree */
return map_merge_mixed(BIF_P, BIF_ARG_2, BIF_ARG_1, 1);
}
BIF_P->fvalue = BIF_ARG_2;
} else {
BIF_P->fvalue = BIF_ARG_1;
}
BIF_ERROR(BIF_P, BADMAP);
}
static Eterm flatmap_merge(Process *p, Eterm nodeA, Eterm nodeB) {
Eterm *hp,*thp;
Eterm tup;
Eterm *ks,*vs,*ks1,*vs1,*ks2,*vs2;
flatmap_t *mp1,*mp2,*mp_new;
Uint n,n1,n2,i1,i2,need,unused_size=0;
Sint c = 0;
mp1 = (flatmap_t*)flatmap_val(nodeA);
mp2 = (flatmap_t*)flatmap_val(nodeB);
n1 = flatmap_get_size(mp1);
n2 = flatmap_get_size(mp2);
need = MAP_HEADER_FLATMAP_SZ + 1 + 2 * (n1 + n2);
hp = HAlloc(p, need);
thp = hp;
tup = make_tuple(thp);
ks = hp + 1; hp += 1 + n1 + n2;
mp_new = (flatmap_t*)hp; hp += MAP_HEADER_FLATMAP_SZ;
vs = hp; hp += n1 + n2;
mp_new->thing_word = MAP_HEADER_FLATMAP;
mp_new->size = 0;
mp_new->keys = tup;
i1 = 0; i2 = 0;
ks1 = flatmap_get_keys(mp1);
vs1 = flatmap_get_values(mp1);
ks2 = flatmap_get_keys(mp2);
vs2 = flatmap_get_values(mp2);
while(i1 < n1 && i2 < n2) {
c = CMP_TERM(ks1[i1],ks2[i2]);
if (c == 0) {
/* use righthand side arguments map value,
* but advance both maps */
*ks++ = ks2[i2];
*vs++ = vs2[i2];
i1++, i2++, unused_size++;
} else if (c < 0) {
*ks++ = ks1[i1];
*vs++ = vs1[i1];
i1++;
} else {
*ks++ = ks2[i2];
*vs++ = vs2[i2];
i2++;
}
}
/* copy remaining */
while (i1 < n1) {
*ks++ = ks1[i1];
*vs++ = vs1[i1];
i1++;
}
while (i2 < n2) {
*ks++ = ks2[i2];
*vs++ = vs2[i2];
i2++;
}
if (unused_size) {
/* the key tuple is embedded in the heap, write a bignum to clear it.
*
* release values as normal since they are on the top of the heap
* size = n1 + n1 - unused_size
*/
*ks = make_pos_bignum_header(unused_size - 1);
HRelease(p, vs + unused_size, vs);
}
n = n1 + n2 - unused_size;
*thp = make_arityval(n);
mp_new->size = n;
/* Reshape map to a hashmap if the map exceeds the limit */
if (n > MAP_SMALL_MAP_LIMIT) {
Uint32 hx,sw;
Uint i;
Eterm res;
hxnode_t *hxns;
ErtsHeapFactory factory;
ks = flatmap_get_keys(mp_new);
vs = flatmap_get_values(mp_new);
hp = HAlloc(p, 2 * n);
hxns = (hxnode_t *)erts_alloc(ERTS_ALC_T_TMP,n * sizeof(hxnode_t));
for (i = 0; i < n; i++) {
hx = hashmap_make_hash(ks[i]);
swizzle32(sw,hx);
hxns[i].hx = sw;
hxns[i].val = CONS(hp, ks[i], vs[i]); hp += 2;
hxns[i].skip = 1;
hxns[i].i = i;
}
erts_factory_proc_init(&factory, p);
res = hashmap_from_unsorted_array(&factory, hxns, n, 0);
erts_factory_close(&factory);
erts_free(ERTS_ALC_T_TMP, (void *) hxns);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(p);
return res;
}
return make_flatmap(mp_new);
}
static Eterm map_merge_mixed(Process *p, Eterm flat, Eterm tree, int swap_args) {
Eterm *ks, *vs, *hp, res;
flatmap_t *mp;
Uint n, i;
hxnode_t *hxns;
Uint32 sw, hx;
ErtsHeapFactory factory;
/* convert flat to tree */
ASSERT(is_flatmap(flat));
ASSERT(is_hashmap(tree));
mp = (flatmap_t*)flatmap_val(flat);
n = flatmap_get_size(mp);
ks = flatmap_get_keys(mp);
vs = flatmap_get_values(mp);
hp = HAlloc(p, 2 * n);
hxns = (hxnode_t *)erts_alloc(ERTS_ALC_T_TMP, n * sizeof(hxnode_t));
for (i = 0; i < n; i++) {
hx = hashmap_make_hash(ks[i]);
swizzle32(sw,hx);
hxns[i].hx = sw;
hxns[i].val = CONS(hp, ks[i], vs[i]); hp += 2;
hxns[i].skip = 1;
hxns[i].i = i;
}
erts_factory_proc_init(&factory, p);
res = hashmap_from_unsorted_array(&factory, hxns, n, 0);
erts_factory_close(&factory);
erts_free(ERTS_ALC_T_TMP, (void *) hxns);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(p);
return hashmap_merge(p, res, tree, swap_args, NULL);
}
#define PSTACK_TYPE struct HashmapMergePStackType
struct HashmapMergePStackType {
Eterm nodeA, nodeB;
Eterm *srcA, *srcB;
Uint32 abm, bbm, rbm; /* node bitmaps */
int mix; /* &1: there are unique A stuff in node
* &2: there are unique B stuff in node */
int ix;
Eterm array[16]; /* temp node construction area */
};
typedef struct HashmapMergeContext_ {
Uint size; /* total key-value counter */
unsigned int lvl;
Eterm trap_bin;
ErtsPStack pstack;
#ifdef DEBUG
Eterm dbg_map_A, dbg_map_B;
#endif
} HashmapMergeContext;
static int hashmap_merge_ctx_destructor(Binary* ctx_bin)
{
HashmapMergeContext* ctx = (HashmapMergeContext*) ERTS_MAGIC_BIN_DATA(ctx_bin);
ASSERT(ERTS_MAGIC_BIN_DESTRUCTOR(ctx_bin) == hashmap_merge_ctx_destructor);
PSTACK_DESTROY_SAVED(&ctx->pstack);
return 1;
}
BIF_RETTYPE maps_merge_trap_1(BIF_ALIST_1) {
Binary* ctx_bin = erts_magic_ref2bin(BIF_ARG_1);
ASSERT(ERTS_MAGIC_BIN_DESTRUCTOR(ctx_bin) == hashmap_merge_ctx_destructor);
return hashmap_merge(BIF_P, NIL, NIL, 0,
(HashmapMergeContext*) ERTS_MAGIC_BIN_DATA(ctx_bin));
}
#define HALLOC_EXTRA 200
#define MAP_MERGE_LOOP_FACTOR 8
static BIF_RETTYPE hashmap_merge(Process *p, Eterm map_A, Eterm map_B,
int swap_args, HashmapMergeContext* ctx) {
#define PSTACK_TYPE struct HashmapMergePStackType
PSTACK_DECLARE(s, 4);
HashmapMergeContext local_ctx;
struct HashmapMergePStackType* sp;
Uint32 hx;
Eterm res = THE_NON_VALUE;
Eterm hdrA, hdrB;
Eterm *hp, *nhp;
Eterm trap_ret;
Sint initial_reds = (Sint) (ERTS_BIF_REDS_LEFT(p) * MAP_MERGE_LOOP_FACTOR);
Sint reds = initial_reds;
DeclareTmpHeap(th,2,p);
UseTmpHeap(2,p);
/*
* Strategy: Do depth-first traversal of both trees (at the same time)
* and merge each pair of nodes.
*/
PSTACK_CHANGE_ALLOCATOR(s, ERTS_ALC_T_SAVED_ESTACK);
if (ctx == NULL) { /* first call */
hashmap_head_t* a = (hashmap_head_t*) hashmap_val(map_A);
hashmap_head_t* b = (hashmap_head_t*) hashmap_val(map_B);
sp = PSTACK_PUSH(s);
sp->srcA = swap_args ? &map_B : &map_A;
sp->srcB = swap_args ? &map_A : &map_B;
sp->mix = 0;
local_ctx.size = a->size + b->size;
local_ctx.lvl = 0;
#ifdef DEBUG
local_ctx.dbg_map_A = map_A;
local_ctx.dbg_map_B = map_B;
local_ctx.trap_bin = THE_NON_VALUE;
#endif
ctx = &local_ctx;
}
else {
PSTACK_RESTORE(s, &ctx->pstack);
sp = PSTACK_TOP(s);
goto resume_from_trap;
}
recurse:
sp->nodeA = *sp->srcA;
sp->nodeB = *sp->srcB;
if (sp->nodeA == sp->nodeB) {
res = sp->nodeA;
ctx->size -= is_list(sp->nodeB) ? 1 : hashmap_subtree_size(sp->nodeB);
}
else {
if (is_list(sp->nodeA)) { /* A is LEAF */
Eterm keyA = CAR(list_val(sp->nodeA));
if (is_list(sp->nodeB)) { /* LEAF + LEAF */
Eterm keyB = CAR(list_val(sp->nodeB));
if (EQ(keyA, keyB)) {
--ctx->size;
res = sp->nodeB;
sp->mix = 2; /* We assume values differ.
+ Don't spend time comparing big values.
- Might waste some heap space for internal
nodes that could otherwise be reused. */
goto merge_nodes;
}
}
hx = hashmap_restore_hash(th, ctx->lvl, keyA);
sp->abm = 1 << hashmap_index(hx);
/* keep srcA pointing at the leaf */
}
else { /* A is NODE */
sp->srcA = boxed_val(sp->nodeA);
hdrA = *sp->srcA++;
ASSERT(is_header(hdrA));
switch (hdrA & _HEADER_MAP_SUBTAG_MASK) {
case HAMT_SUBTAG_HEAD_ARRAY: {
sp->srcA++;
sp->abm = 0xffff;
break;
}
case HAMT_SUBTAG_HEAD_BITMAP: sp->srcA++;
case HAMT_SUBTAG_NODE_BITMAP: {
sp->abm = MAP_HEADER_VAL(hdrA);
break;
}
default:
erts_exit(ERTS_ABORT_EXIT, "bad header %ld\r\n", hdrA);
}
}
if (is_list(sp->nodeB)) { /* B is LEAF */
Eterm keyB = CAR(list_val(sp->nodeB));
hx = hashmap_restore_hash(th, ctx->lvl, keyB);
sp->bbm = 1 << hashmap_index(hx);
/* keep srcB pointing at the leaf */
}
else { /* B is NODE */
sp->srcB = boxed_val(sp->nodeB);
hdrB = *sp->srcB++;
ASSERT(is_header(hdrB));
switch (hdrB & _HEADER_MAP_SUBTAG_MASK) {
case HAMT_SUBTAG_HEAD_ARRAY: {
sp->srcB++;
sp->bbm = 0xffff;
break;
}
case HAMT_SUBTAG_HEAD_BITMAP: sp->srcB++;
case HAMT_SUBTAG_NODE_BITMAP: {
sp->bbm = MAP_HEADER_VAL(hdrB);
break;
}
default:
erts_exit(ERTS_ABORT_EXIT, "bad header %ld\r\n", hdrB);
}
}
}
merge_nodes:
for (;;) {
if (is_value(res)) { /* We have a complete (sub-)tree or leaf */
int child_mix;
if (ctx->lvl == 0)
break;
/* Pop from stack and continue build parent node */
ctx->lvl--;
child_mix = sp->mix;
sp = PSTACK_POP(s);
sp->array[sp->ix++] = res;
sp->mix |= child_mix;
res = THE_NON_VALUE;
if (sp->rbm) {
sp->srcA++;
sp->srcB++;
}
} else { /* Start build a node */
sp->ix = 0;
sp->rbm = sp->abm | sp->bbm;
ASSERT(!(sp->rbm == 0 && ctx->lvl > 0));
}
if (--reds <= 0) {
goto trap;
}
resume_from_trap:
while (sp->rbm) {
Uint32 next = sp->rbm & (sp->rbm-1);
Uint32 bit = sp->rbm ^ next;
sp->rbm = next;
if (sp->abm & bit) {
if (sp->bbm & bit) {
/* Bit clash. Push and resolve by recursive merge */
Eterm* srcA = sp->srcA;
Eterm* srcB = sp->srcB;
ctx->lvl++;
sp = PSTACK_PUSH(s);
sp->srcA = srcA;
sp->srcB = srcB;
sp->mix = 0;
goto recurse;
} else {
sp->array[sp->ix++] = *sp->srcA++;
sp->mix |= 1;
}
} else {
ASSERT(sp->bbm & bit);
sp->array[sp->ix++] = *sp->srcB++;
sp->mix |= 2;
}
}
switch (sp->mix) {
case 0: /* Nodes A and B contain the *EXACT* same sub-trees
=> fall through and reuse nodeA */
case 1: /* Only unique A stuff => reuse nodeA */
res = sp->nodeA;
break;
case 2: /* Only unique B stuff => reuse nodeB */
res = sp->nodeB;
break;
case 3: /* We have a mix => must build new node */
ASSERT(sp->ix == hashmap_bitcount(sp->abm | sp->bbm));
if (ctx->lvl == 0) {
nhp = HAllocX(p, HAMT_HEAD_BITMAP_SZ(sp->ix), HALLOC_EXTRA);
hp = nhp;
*hp++ = (sp->ix == 16 ? MAP_HEADER_HAMT_HEAD_ARRAY
: MAP_HEADER_HAMT_HEAD_BITMAP(sp->abm | sp->bbm));
*hp++ = ctx->size;
} else {
nhp = HAllocX(p, HAMT_NODE_BITMAP_SZ(sp->ix), HALLOC_EXTRA);
hp = nhp;
*hp++ = MAP_HEADER_HAMT_NODE_BITMAP(sp->abm | sp->bbm);
}
sys_memcpy(hp, sp->array, sp->ix * sizeof(Eterm));
res = make_boxed(nhp);
break;
default:
erts_exit(ERTS_ABORT_EXIT, "strange mix %d\r\n", sp->mix);
}
}
/* Done */
#ifdef DEBUG
{
Eterm *head = hashmap_val(res);
Uint size = head[1];
Uint real_size = hashmap_subtree_size(res);
ASSERT(size == real_size);
}
#endif
if (ctx != &local_ctx) {
ASSERT(ctx->trap_bin != THE_NON_VALUE);
ASSERT(p->flags & F_DISABLE_GC);
erts_set_gc_state(p, 1);
}
else {
ASSERT(ctx->trap_bin == THE_NON_VALUE);
ASSERT(!(p->flags & F_DISABLE_GC));
}
PSTACK_DESTROY(s);
UnUseTmpHeap(2,p);
BUMP_REDS(p, (initial_reds - reds) / MAP_MERGE_LOOP_FACTOR);
return res;
trap: /* Yield */
if (ctx == &local_ctx) {
Binary* ctx_b = erts_create_magic_binary(sizeof(HashmapMergeContext),
hashmap_merge_ctx_destructor);
ctx = ERTS_MAGIC_BIN_DATA(ctx_b);
sys_memcpy(ctx, &local_ctx, sizeof(HashmapMergeContext));
hp = HAlloc(p, ERTS_MAGIC_REF_THING_SIZE);
ASSERT(ctx->trap_bin == THE_NON_VALUE);
ctx->trap_bin = erts_mk_magic_ref(&hp, &MSO(p), ctx_b);
erts_set_gc_state(p, 0);
}
else {
ASSERT(ctx->trap_bin != THE_NON_VALUE);
ASSERT(p->flags & F_DISABLE_GC);
}
PSTACK_SAVE(s, &ctx->pstack);
BUMP_ALL_REDS(p);
ERTS_BIF_PREP_TRAP1(trap_ret, &hashmap_merge_trap_export,
p, ctx->trap_bin);
UnUseTmpHeap(2,p);
return trap_ret;
}
static Uint hashmap_subtree_size(Eterm node) {
DECLARE_WSTACK(stack);
Uint size = 0;
hashmap_iterator_init(&stack, node, 0);
while (hashmap_iterator_next(&stack)) {
size++;
}
DESTROY_WSTACK(stack);
return size;
}
static int hash_cmp(Uint32 ha, Uint32 hb)
{
int i;
for (i=0; i<8; i++) {
int cmp = (int)(ha & 0xF) - (int)(hb & 0xF);
if (cmp)
return cmp;
ha >>= 4;
hb >>= 4;
}
return 0;
}
int hashmap_key_hash_cmp(Eterm* ap, Eterm* bp)
{
unsigned int lvl = 0;
DeclareTmpHeapNoproc(th,2);
UseTmpHeapNoproc(2);
if (ap && bp) {
ASSERT(CMP_TERM(CAR(ap), CAR(bp)) != 0);
for (;;) {
Uint32 ha = hashmap_restore_hash(th, lvl, CAR(ap));
Uint32 hb = hashmap_restore_hash(th, lvl, CAR(bp));
int cmp = hash_cmp(ha, hb);
if (cmp) {
UnUseTmpHeapNoproc(2);
return cmp;
}
lvl += 8;
}
}
UnUseTmpHeapNoproc(2);
return ap ? -1 : 1;
}
/* maps:new/0 */
BIF_RETTYPE maps_new_0(BIF_ALIST_0) {
Eterm* hp;
Eterm tup;
flatmap_t *mp;
hp = HAlloc(BIF_P, (MAP_HEADER_FLATMAP_SZ + 1));
tup = make_tuple(hp);
*hp++ = make_arityval(0);
mp = (flatmap_t*)hp;
mp->thing_word = MAP_HEADER_FLATMAP;
mp->size = 0;
mp->keys = tup;
BIF_RET(make_flatmap(mp));
}
/* maps:put/3 */
BIF_RETTYPE maps_put_3(BIF_ALIST_3) {
if (is_map(BIF_ARG_3)) {
BIF_RET(erts_maps_put(BIF_P, BIF_ARG_1, BIF_ARG_2, BIF_ARG_3));
}
BIF_P->fvalue = BIF_ARG_3;
BIF_ERROR(BIF_P, BADMAP);
}
/* maps:take/2 */
BIF_RETTYPE maps_take_2(BIF_ALIST_2) {
if (is_map(BIF_ARG_2)) {
Eterm res, map, val;
if (erts_maps_take(BIF_P, BIF_ARG_1, BIF_ARG_2, &map, &val)) {
Eterm *hp = HAlloc(BIF_P, 3);
res = make_tuple(hp);
*hp++ = make_arityval(2);
*hp++ = val;
*hp++ = map;
BIF_RET(res);
}
BIF_RET(am_error);
}
BIF_P->fvalue = BIF_ARG_2;
BIF_ERROR(BIF_P, BADMAP);
}
/* maps:remove/2 */
BIF_RETTYPE maps_remove_2(BIF_ALIST_2) {
if (is_map(BIF_ARG_2)) {
Eterm res;
(void) erts_maps_take(BIF_P, BIF_ARG_1, BIF_ARG_2, &res, NULL);
BIF_RET(res);
}
BIF_P->fvalue = BIF_ARG_2;
BIF_ERROR(BIF_P, BADMAP);
}
/* erts_maps_take
* return 1 if key is found, otherwise 0
* If the key is not found res (output map) will be map (input map)
*/
int erts_maps_take(Process *p, Eterm key, Eterm map,
Eterm *res, Eterm *value) {
Uint32 hx;
Eterm ret;
if (is_flatmap(map)) {
Sint n;
Uint need;
Eterm *hp_start;
Eterm *thp, *mhp;
Eterm *ks, *vs, tup;
flatmap_t *mp = (flatmap_t*)flatmap_val(map);
n = flatmap_get_size(mp);
if (n == 0) {
*res = map;
return 0;
}
ks = flatmap_get_keys(mp);
vs = flatmap_get_values(mp);
/* Assume key exists.
* Release allocated if it didn't.
* Allocate key tuple first.
*/
need = n + 1 - 1 + 3 + n - 1; /* tuple - 1 + map - 1 */
hp_start = HAlloc(p, need);
thp = hp_start;
mhp = thp + n; /* offset with tuple heap size */
tup = make_tuple(thp);
*thp++ = make_arityval(n - 1);
*res = make_flatmap(mhp);
*mhp++ = MAP_HEADER_FLATMAP;
*mhp++ = n - 1;
*mhp++ = tup;
if (is_immed(key)) {
while (1) {
if (*ks == key) {
if (value) *value = *vs;
goto found_key;
} else if (--n) {
*mhp++ = *vs++;
*thp++ = *ks++;
} else
break;
}
} else {
while(1) {
if (EQ(*ks, key)) {
if (value) *value = *vs;
goto found_key;
} else if (--n) {
*mhp++ = *vs++;
*thp++ = *ks++;
} else
break;
}
}
/* Not found, remove allocated memory
* and return previous map.
*/
HRelease(p, hp_start + need, hp_start);
*res = map;
return 0;
found_key:
/* Copy rest of keys and values */
if (--n) {
sys_memcpy(mhp, vs+1, n*sizeof(Eterm));
sys_memcpy(thp, ks+1, n*sizeof(Eterm));
}
return 1;
}
ASSERT(is_hashmap(map));
hx = hashmap_make_hash(key);
ret = hashmap_delete(p, hx, key, map, value);
if (is_value(ret)) {
*res = ret;
return 1;
}
*res = map;
return 0;
}
int erts_maps_update(Process *p, Eterm key, Eterm value, Eterm map, Eterm *res) {
Uint32 hx;
if (is_flatmap(map)) {
Sint n,i;
Eterm* hp,*shp;
Eterm *ks,*vs;
flatmap_t *mp = (flatmap_t*)flatmap_val(map);
if ((n = flatmap_get_size(mp)) == 0) {
return 0;
}
ks = flatmap_get_keys(mp);
vs = flatmap_get_values(mp);
/* only allocate for values,
* assume key-tuple will be intact
*/
hp = HAlloc(p, MAP_HEADER_FLATMAP_SZ + n);
shp = hp;
*hp++ = MAP_HEADER_FLATMAP;
*hp++ = n;
*hp++ = mp->keys;
if (is_immed(key)) {
for( i = 0; i < n; i ++) {
if (ks[i] == key) {
goto found_key;
} else {
*hp++ = *vs++;
}
}
} else {
for( i = 0; i < n; i ++) {
if (EQ(ks[i], key)) {
goto found_key;
} else {
*hp++ = *vs++;
}
}
}
HRelease(p, shp + MAP_HEADER_FLATMAP_SZ + n, shp);
return 0;
found_key:
*hp++ = value;
vs++;
if (++i < n)
sys_memcpy(hp, vs, (n - i)*sizeof(Eterm));
*res = make_flatmap(shp);
return 1;
}
ASSERT(is_hashmap(map));
hx = hashmap_make_hash(key);
*res = erts_hashmap_insert(p, hx, key, value, map, 1);
if (is_value(*res))
return 1;
return 0;
}
Eterm erts_maps_put(Process *p, Eterm key, Eterm value, Eterm map) {
Uint32 hx;
Eterm res;
if (is_flatmap(map)) {
Sint n,i;
Sint c = 0;
Eterm* hp, *shp;
Eterm *ks, *vs, tup;
flatmap_t *mp = (flatmap_t*)flatmap_val(map);
n = flatmap_get_size(mp);
if (n == 0) {
hp = HAlloc(p, MAP_HEADER_FLATMAP_SZ + 1 + 2);
tup = make_tuple(hp);
*hp++ = make_arityval(1);
*hp++ = key;
res = make_flatmap(hp);
*hp++ = MAP_HEADER_FLATMAP;
*hp++ = 1;
*hp++ = tup;
*hp++ = value;
return res;
}
ks = flatmap_get_keys(mp);
vs = flatmap_get_values(mp);
/* only allocate for values,
* assume key-tuple will be intact
*/
hp = HAlloc(p, MAP_HEADER_FLATMAP_SZ + n);
shp = hp; /* save hp, used if optimistic update fails */
res = make_flatmap(hp);
*hp++ = MAP_HEADER_FLATMAP;
*hp++ = n;
*hp++ = mp->keys;
if (is_immed(key)) {
for( i = 0; i < n; i ++) {
if (ks[i] == key) {
*hp++ = value;
vs++;
c = 1;
} else {
*hp++ = *vs++;
}
}
} else {
for( i = 0; i < n; i ++) {
if (EQ(ks[i], key)) {
*hp++ = value;
vs++;
c = 1;
} else {
*hp++ = *vs++;
}
}
}
if (c)
return res;
/* the map will grow */
if (n >= MAP_SMALL_MAP_LIMIT) {
ErtsHeapFactory factory;
HRelease(p, shp + MAP_HEADER_FLATMAP_SZ + n, shp);
ks = flatmap_get_keys(mp);
vs = flatmap_get_values(mp);
erts_factory_proc_init(&factory, p);
res = erts_hashmap_from_ks_and_vs_extra(&factory,ks,vs,n,key,value);
erts_factory_close(&factory);
return res;
}
/* still a small map. need to make a new tuple,
* use old hp since it needs to be recreated anyway. */
tup = make_tuple(shp);
*shp++ = make_arityval(n+1);
hp = HAlloc(p, 3 + n + 1);
res = make_flatmap(hp);
*hp++ = MAP_HEADER_FLATMAP;
*hp++ = n + 1;
*hp++ = tup;
ks = flatmap_get_keys(mp);
vs = flatmap_get_values(mp);
ASSERT(n >= 0);
/* copy map in order */
while (n && ((c = CMP_TERM(*ks, key)) < 0)) {
*shp++ = *ks++;
*hp++ = *vs++;
n--;
}
*shp++ = key;
*hp++ = value;
ASSERT(n >= 0);
while(n--) {
*shp++ = *ks++;
*hp++ = *vs++;
}
/* we have one word remaining
* this will work out fine once we get the size word
* in the header.
*/
*shp = make_pos_bignum_header(0);
return res;
}
ASSERT(is_hashmap(map));
hx = hashmap_make_hash(key);
res = erts_hashmap_insert(p, hx, key, value, map, 0);
ASSERT(is_hashmap(res));
return res;
}
/* maps:update/3 */
BIF_RETTYPE maps_update_3(BIF_ALIST_3) {
if (is_not_map(BIF_ARG_3)) {
BIF_P->fvalue = BIF_ARG_3;
BIF_ERROR(BIF_P, BADMAP);
} else {
Eterm res;
if (erts_maps_update(BIF_P, BIF_ARG_1, BIF_ARG_2, BIF_ARG_3, &res)) {
BIF_RET(res);
}
BIF_P->fvalue = BIF_ARG_1;
BIF_ERROR(BIF_P, BADKEY);
}
}
/* maps:values/1 */
BIF_RETTYPE maps_values_1(BIF_ALIST_1) {
if (is_flatmap(BIF_ARG_1)) {
Eterm *hp, *vs, res = NIL;
flatmap_t *mp;
Uint n;
mp = (flatmap_t*)flatmap_val(BIF_ARG_1);
n = flatmap_get_size(mp);
if (n == 0)
BIF_RET(res);
hp = HAlloc(BIF_P, (2 * n));
vs = flatmap_get_values(mp);
while(n--) {
res = CONS(hp, vs[n], res); hp += 2;
}
BIF_RET(res);
} else if (is_hashmap(BIF_ARG_1)) {
BIF_RET(hashmap_values(BIF_P, BIF_ARG_1));
}
BIF_P->fvalue = BIF_ARG_1;
BIF_ERROR(BIF_P, BADMAP);
}
static ERTS_INLINE
Uint hashmap_node_size(Eterm hdr, Eterm **nodep)
{
Uint sz;
switch(hdr & _HEADER_MAP_SUBTAG_MASK) {
case HAMT_SUBTAG_HEAD_ARRAY:
sz = 16;
if (nodep) ++*nodep;
break;
case HAMT_SUBTAG_HEAD_BITMAP:
if (nodep) ++*nodep;
case HAMT_SUBTAG_NODE_BITMAP:
sz = hashmap_bitcount(MAP_HEADER_VAL(hdr));
ASSERT(sz < 17);
break;
default:
erts_exit(ERTS_ABORT_EXIT, "bad header");
}
return sz;
}
void hashmap_iterator_init(ErtsWStack* s, Eterm node, int reverse) {
Eterm hdr = *hashmap_val(node);
Uint sz = hashmap_node_size(hdr, NULL);
WSTACK_PUSH3((*s), (UWord)THE_NON_VALUE, /* end marker */
(UWord)(!reverse ? 0 : sz+1),
(UWord)node);
}
Eterm* hashmap_iterator_next(ErtsWStack* s) {
Eterm node, *ptr, hdr;
Uint32 sz;
Uint idx;
for (;;) {
ASSERT(!WSTACK_ISEMPTY((*s)));
node = (Eterm) WSTACK_POP((*s));
if (is_non_value(node)) {
return NULL;
}
idx = (Uint) WSTACK_POP((*s));
for (;;) {
ASSERT(is_boxed(node));
ptr = boxed_val(node);
hdr = *ptr;
ASSERT(is_header(hdr));
sz = hashmap_node_size(hdr, &ptr);
idx++;
if (idx <= sz) {
WSTACK_PUSH2((*s), (UWord)idx, (UWord)node);
if (is_list(ptr[idx])) {
return list_val(ptr[idx]);
}
ASSERT(is_boxed(ptr[idx]));
node = ptr[idx];
idx = 0;
}
else
break; /* and pop parent node */
}
}
}
Eterm* hashmap_iterator_prev(ErtsWStack* s) {
Eterm node, *ptr, hdr;
Uint32 sz;
Uint idx;
for (;;) {
ASSERT(!WSTACK_ISEMPTY((*s)));
node = (Eterm) WSTACK_POP((*s));
if (is_non_value(node)) {
return NULL;
}
idx = (Uint) WSTACK_POP((*s));
for (;;) {
ASSERT(is_boxed(node));
ptr = boxed_val(node);
hdr = *ptr;
ASSERT(is_header(hdr));
sz = hashmap_node_size(hdr, &ptr);
if (idx > sz)
idx = sz;
else
idx--;
if (idx >= 1) {
WSTACK_PUSH2((*s), (UWord)idx, (UWord)node);
if (is_list(ptr[idx])) {
return list_val(ptr[idx]);
}
ASSERT(is_boxed(ptr[idx]));
node = ptr[idx];
idx = 17;
}
else
break; /* and pop parent node */
}
}
}
const Eterm *
erts_hashmap_get(Uint32 hx, Eterm key, Eterm node)
{
Eterm *ptr, hdr, *res;
Uint ix, lvl = 0;
Uint32 hval,bp;
DeclareTmpHeapNoproc(th,2);
UseTmpHeapNoproc(2);
ASSERT(is_boxed(node));
ptr = boxed_val(node);
hdr = *ptr;
ASSERT(is_header(hdr));
ASSERT(is_hashmap_header_head(hdr));
ptr++;
for (;;) {
hval = MAP_HEADER_VAL(hdr);
ix = hashmap_index(hx);
if (hval != 0xffff) {
bp = 1 << ix;
if (!(bp & hval)) {
/* not occupied */
res = NULL;
break;
}
ix = hashmap_bitcount(hval & (bp - 1));
}
node = ptr[ix+1];
if (is_list(node)) { /* LEAF NODE [K|V] */
ptr = list_val(node);
res = EQ(CAR(ptr), key) ? &(CDR(ptr)) : NULL;
break;
}
hx = hashmap_shift_hash(th,hx,lvl,key);
ASSERT(is_boxed(node));
ptr = boxed_val(node);
hdr = *ptr;
ASSERT(is_header(hdr));
ASSERT(!is_hashmap_header_head(hdr));
}
UnUseTmpHeapNoproc(2);
return res;
}
Eterm erts_hashmap_insert(Process *p, Uint32 hx, Eterm key, Eterm value,
Eterm map, int is_update) {
Uint size, upsz;
Eterm *hp, res = THE_NON_VALUE;
DECLARE_ESTACK(stack);
if (erts_hashmap_insert_down(hx, key, map, &size, &upsz, &stack, is_update)) {
hp = HAlloc(p, size);
res = erts_hashmap_insert_up(hp, key, value, &upsz, &stack);
}
DESTROY_ESTACK(stack);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(p);
ERTS_HOLE_CHECK(p);
return res;
}
int erts_hashmap_insert_down(Uint32 hx, Eterm key, Eterm node, Uint *sz,
Uint *update_size, ErtsEStack *sp, int is_update) {
Eterm *ptr;
Eterm hdr, ckey;
Uint32 ix, cix, bp, hval, chx;
Uint slot, lvl = 0, clvl;
Uint size = 0, n = 0;
DeclareTmpHeapNoproc(th,2);
*update_size = 1;
UseTmpHeapNoproc(2);
for (;;) {
switch(primary_tag(node)) {
case TAG_PRIMARY_LIST: /* LEAF NODE [K|V] */
ptr = list_val(node);
ckey = CAR(ptr);
if (EQ(ckey, key)) {
*update_size = 0;
goto unroll;
}
if (is_update) {
UnUseTmpHeapNoproc(2);
return 0;
}
goto insert_subnodes;
case TAG_PRIMARY_BOXED:
ptr = boxed_val(node);
hdr = *ptr;
ASSERT(is_header(hdr));
switch(hdr & _HEADER_MAP_SUBTAG_MASK) {
case HAMT_SUBTAG_HEAD_ARRAY:
ix = hashmap_index(hx);
hx = hashmap_shift_hash(th,hx,lvl,key);
size += HAMT_HEAD_ARRAY_SZ;
ESTACK_PUSH2(*sp, ix, node);
node = ptr[ix+2];
break;
case HAMT_SUBTAG_NODE_BITMAP:
hval = MAP_HEADER_VAL(hdr);
ix = hashmap_index(hx);
bp = 1 << ix;
if (hval == 0xffff) {
slot = ix;
n = 16;
} else {
slot = hashmap_bitcount(hval & (bp - 1));
n = hashmap_bitcount(hval);
}
ESTACK_PUSH4(*sp, n, bp, slot, node);
if (!(bp & hval)) { /* not occupied */
if (is_update) {
UnUseTmpHeapNoproc(2);
return 0;
}
size += HAMT_NODE_BITMAP_SZ(n+1);
goto unroll;
}
hx = hashmap_shift_hash(th,hx,lvl,key);
node = ptr[slot+1];
ASSERT(HAMT_NODE_BITMAP_SZ(n) <= 17);
size += HAMT_NODE_BITMAP_SZ(n);
break;
case HAMT_SUBTAG_HEAD_BITMAP:
hval = MAP_HEADER_VAL(hdr);
ix = hashmap_index(hx);
bp = 1 << ix;
slot = hashmap_bitcount(hval & (bp - 1));
n = hashmap_bitcount(hval);
ESTACK_PUSH4(*sp, n, bp, slot, node);
/* occupied */
if (bp & hval) {
hx = hashmap_shift_hash(th,hx,lvl,key);
node = ptr[slot+2];
ASSERT(HAMT_HEAD_BITMAP_SZ(n) <= 18);
size += HAMT_HEAD_BITMAP_SZ(n);
break;
}
/* not occupied */
if (is_update) {
UnUseTmpHeapNoproc(2);
return 0;
}
size += HAMT_HEAD_BITMAP_SZ(n+1);
goto unroll;
default:
erts_exit(ERTS_ERROR_EXIT, "bad header tag %ld\r\n", hdr & _HEADER_MAP_SUBTAG_MASK);
break;
}
break;
default:
erts_exit(ERTS_ERROR_EXIT, "bad primary tag %p\r\n", node);
break;
}
}
insert_subnodes:
clvl = lvl;
chx = hashmap_restore_hash(th,clvl,ckey);
size += HAMT_NODE_BITMAP_SZ(2);
ix = hashmap_index(hx);
cix = hashmap_index(chx);
while (cix == ix) {
ESTACK_PUSH4(*sp, 0, 1 << ix, 0, MAP_HEADER_HAMT_NODE_BITMAP(0));
size += HAMT_NODE_BITMAP_SZ(1);
hx = hashmap_shift_hash(th,hx,lvl,key);
chx = hashmap_shift_hash(th,chx,clvl,ckey);
ix = hashmap_index(hx);
cix = hashmap_index(chx);
}
ESTACK_PUSH3(*sp, cix, ix, node);
unroll:
*sz = size + /* res cons */ 2;
UnUseTmpHeapNoproc(2);
return 1;
}
Eterm erts_hashmap_insert_up(Eterm *hp, Eterm key, Eterm value,
Uint *update_size, ErtsEStack *sp) {
Eterm node, *ptr, hdr;
Eterm res;
Eterm *nhp = NULL;
Uint32 ix, cix, bp, hval;
Uint slot, n;
/* Needed for halfword */
DeclareTmpHeapNoproc(fake,1);
UseTmpHeapNoproc(1);
res = CONS(hp, key, value); hp += 2;
do {
node = ESTACK_POP(*sp);
switch(primary_tag(node)) {
case TAG_PRIMARY_LIST:
ix = (Uint32) ESTACK_POP(*sp);
cix = (Uint32) ESTACK_POP(*sp);
nhp = hp;
*hp++ = MAP_HEADER_HAMT_NODE_BITMAP((1 << ix) | (1 << cix));
if (ix < cix) {
*hp++ = res;
*hp++ = node;
} else {
*hp++ = node;
*hp++ = res;
}
res = make_hashmap(nhp);
break;
case TAG_PRIMARY_HEADER:
/* subnodes, fake it */
*fake = node;
node = make_boxed(fake);
case TAG_PRIMARY_BOXED:
ptr = boxed_val(node);
hdr = *ptr;
ASSERT(is_header(hdr));
switch(hdr & _HEADER_MAP_SUBTAG_MASK) {
case HAMT_SUBTAG_HEAD_ARRAY:
slot = (Uint) ESTACK_POP(*sp);
nhp = hp;
n = HAMT_HEAD_ARRAY_SZ - 2;
*hp++ = MAP_HEADER_HAMT_HEAD_ARRAY; ptr++;
*hp++ = (*ptr++) + *update_size;
while(n--) { *hp++ = *ptr++; }
nhp[slot+2] = res;
res = make_hashmap(nhp);
break;
case HAMT_SUBTAG_NODE_BITMAP:
slot = (Uint) ESTACK_POP(*sp);
bp = (Uint32) ESTACK_POP(*sp);
n = (Uint32) ESTACK_POP(*sp);
hval = MAP_HEADER_VAL(hdr);
nhp = hp;
*hp++ = MAP_HEADER_HAMT_NODE_BITMAP(hval | bp); ptr++;
n -= slot;
while(slot--) { *hp++ = *ptr++; }
*hp++ = res;
if (hval & bp) { ptr++; n--; }
while(n--) { *hp++ = *ptr++; }
res = make_hashmap(nhp);
break;
case HAMT_SUBTAG_HEAD_BITMAP:
slot = (Uint) ESTACK_POP(*sp);
bp = (Uint32) ESTACK_POP(*sp);
n = (Uint32) ESTACK_POP(*sp);
hval = MAP_HEADER_VAL(hdr);
nhp = hp;
*hp++ = MAP_HEADER_HAMT_HEAD_BITMAP(hval | bp); ptr++;
*hp++ = (*ptr++) + *update_size;
n -= slot;
while(slot--) { *hp++ = *ptr++; }
*hp++ = res;
if (hval & bp) { ptr++; n--; }
while(n--) { *hp++ = *ptr++; }
if ((hval | bp) == 0xffff) {
*nhp = MAP_HEADER_HAMT_HEAD_ARRAY;
}
res = make_hashmap(nhp);
break;
default:
erts_exit(ERTS_ERROR_EXIT, "bad header tag %x\r\n", hdr & _HEADER_MAP_SUBTAG_MASK);
break;
}
break;
default:
erts_exit(ERTS_ERROR_EXIT, "bad primary tag %x\r\n", primary_tag(node));
break;
}
} while(!ESTACK_ISEMPTY(*sp));
UnUseTmpHeapNoproc(1);
return res;
}
static Eterm hashmap_keys(Process* p, Eterm node) {
DECLARE_WSTACK(stack);
hashmap_head_t* root;
Eterm *hp, *kv;
Eterm res = NIL;
root = (hashmap_head_t*) boxed_val(node);
hp = HAlloc(p, root->size * 2);
hashmap_iterator_init(&stack, node, 0);
while ((kv=hashmap_iterator_next(&stack)) != NULL) {
res = CONS(hp, CAR(kv), res);
hp += 2;
}
DESTROY_WSTACK(stack);
return res;
}
static Eterm hashmap_values(Process* p, Eterm node) {
DECLARE_WSTACK(stack);
hashmap_head_t* root;
Eterm *hp, *kv;
Eterm res = NIL;
root = (hashmap_head_t*) boxed_val(node);
hp = HAlloc(p, root->size * 2);
hashmap_iterator_init(&stack, node, 0);
while ((kv=hashmap_iterator_next(&stack)) != NULL) {
res = CONS(hp, CDR(kv), res);
hp += 2;
}
DESTROY_WSTACK(stack);
return res;
}
static Eterm hashmap_delete(Process *p, Uint32 hx, Eterm key,
Eterm map, Eterm *value) {
Eterm *hp = NULL, *nhp = NULL, *hp_end = NULL;
Eterm *ptr;
Eterm hdr, res = map, node = map;
Uint32 ix, bp, hval;
Uint slot, lvl = 0;
Uint size = 0, n = 0;
DECLARE_ESTACK(stack);
DeclareTmpHeapNoproc(th,2);
UseTmpHeapNoproc(2);
for (;;) {
switch(primary_tag(node)) {
case TAG_PRIMARY_LIST:
if (EQ(CAR(list_val(node)), key)) {
if (value) {
*value = CDR(list_val(node));
}
goto unroll;
}
res = THE_NON_VALUE;
goto not_found;
case TAG_PRIMARY_BOXED:
ptr = boxed_val(node);
hdr = *ptr;
ASSERT(is_header(hdr));
switch(hdr & _HEADER_MAP_SUBTAG_MASK) {
case HAMT_SUBTAG_HEAD_ARRAY:
ix = hashmap_index(hx);
hx = hashmap_shift_hash(th,hx,lvl,key);
size += HAMT_HEAD_ARRAY_SZ;
ESTACK_PUSH2(stack, ix, node);
node = ptr[ix+2];
break;
case HAMT_SUBTAG_NODE_BITMAP:
hval = MAP_HEADER_VAL(hdr);
ix = hashmap_index(hx);
bp = 1 << ix;
if (hval == 0xffff) {
slot = ix;
n = 16;
} else if (bp & hval) {
slot = hashmap_bitcount(hval & (bp - 1));
n = hashmap_bitcount(hval);
} else {
/* not occupied */
res = THE_NON_VALUE;
goto not_found;
}
ESTACK_PUSH4(stack, n, bp, slot, node);
hx = hashmap_shift_hash(th,hx,lvl,key);
node = ptr[slot+1];
ASSERT(HAMT_NODE_BITMAP_SZ(n) <= 17);
size += HAMT_NODE_BITMAP_SZ(n);
break;
case HAMT_SUBTAG_HEAD_BITMAP:
hval = MAP_HEADER_VAL(hdr);
ix = hashmap_index(hx);
bp = 1 << ix;
slot = hashmap_bitcount(hval & (bp - 1));
n = hashmap_bitcount(hval);
ESTACK_PUSH4(stack, n, bp, slot, node);
/* occupied */
if (bp & hval) {
hx = hashmap_shift_hash(th,hx,lvl,key);
node = ptr[slot+2];
ASSERT(HAMT_HEAD_BITMAP_SZ(n) <= 18);
size += HAMT_HEAD_BITMAP_SZ(n);
break;
}
/* not occupied */
res = THE_NON_VALUE;
goto not_found;
default:
erts_exit(ERTS_ERROR_EXIT, "bad header tag %ld\r\n", hdr & _HEADER_MAP_SUBTAG_MASK);
break;
}
break;
default:
erts_exit(ERTS_ERROR_EXIT, "bad primary tag %p\r\n", node);
break;
}
}
unroll:
/* the size is bounded and atleast one less than the previous size */
size -= 1;
n = hashmap_size(map) - 1;
if (n <= MAP_SMALL_MAP_LIMIT) {
DECLARE_WSTACK(wstack);
Eterm *kv, *ks, *vs;
flatmap_t *mp;
Eterm keys;
DESTROY_ESTACK(stack);
/* build flat structure */
hp = HAlloc(p, 3 + 1 + (2 * n));
keys = make_tuple(hp);
*hp++ = make_arityval(n);
ks = hp;
hp += n;
mp = (flatmap_t*)hp;
hp += MAP_HEADER_FLATMAP_SZ;
vs = hp;
mp->thing_word = MAP_HEADER_FLATMAP;
mp->size = n;
mp->keys = keys;
hashmap_iterator_init(&wstack, map, 0);
while ((kv=hashmap_iterator_next(&wstack)) != NULL) {
if (EQ(CAR(kv),key))
continue;
*ks++ = CAR(kv);
*vs++ = CDR(kv);
}
/* it cannot have multiple keys */
erts_validate_and_sort_flatmap(mp);
DESTROY_WSTACK(wstack);
UnUseTmpHeapNoproc(2);
return make_flatmap(mp);
}
hp = HAlloc(p, size);
hp_end = hp + size;
res = THE_NON_VALUE;
do {
node = ESTACK_POP(stack);
/* all nodes are things */
ptr = boxed_val(node);
hdr = *ptr;
ASSERT(is_header(hdr));
switch(hdr & _HEADER_MAP_SUBTAG_MASK) {
case HAMT_SUBTAG_HEAD_ARRAY:
ix = (Uint) ESTACK_POP(stack);
nhp = hp;
if (res == THE_NON_VALUE) {
n = 16;
n -= ix;
*hp++ = MAP_HEADER_HAMT_HEAD_BITMAP(0xffff ^ (1 << ix)); ptr++;
*hp++ = (*ptr++) - 1;
while(ix--) { *hp++ = *ptr++; }
ptr++; n--;
while(n--) { *hp++ = *ptr++; }
res = make_hashmap(nhp);
} else {
n = 16;
*hp++ = MAP_HEADER_HAMT_HEAD_ARRAY; ptr++;
*hp++ = (*ptr++) - 1;
while(n--) { *hp++ = *ptr++; }
nhp[ix+2] = res;
res = make_hashmap(nhp);
}
break;
case HAMT_SUBTAG_NODE_BITMAP:
slot = (Uint) ESTACK_POP(stack);
bp = (Uint32) ESTACK_POP(stack);
n = (Uint32) ESTACK_POP(stack);
nhp = hp;
/* bitmap change matrix
* res | none leaf bitmap
* ----------------------------
* n=1 | remove remove keep
* n=2 | other keep keep
* n>2 | shrink keep keep
*
* other: (remember, n is 2)
* shrink if the other bitmap value is a bitmap node
* remove if the other bitmap value is a leaf
*
* remove:
* this bitmap node is removed, res is moved up in tree (could be none)
* this is a special case of shrink
*
* keep:
* the current path index is still used down in the tree, need to keep it
* copy as usual with the updated res
*
* shrink:
* the current path index is no longer used down in the tree, remove it (shrink)
*/
if (res == THE_NON_VALUE) {
if (n == 1) {
break;
} else if (n == 2) {
if (slot == 0) {
ix = 2; /* off by one 'cause hdr */
} else {
ix = 1; /* off by one 'cause hdr */
}
if (primary_tag(ptr[ix]) == TAG_PRIMARY_LIST) {
res = ptr[ix];
} else {
hval = MAP_HEADER_VAL(hdr);
*hp++ = MAP_HEADER_HAMT_NODE_BITMAP(hval ^ bp);
*hp++ = ptr[ix];
res = make_hashmap(nhp);
}
} else {
/* n > 2 */
hval = MAP_HEADER_VAL(hdr);
*hp++ = MAP_HEADER_HAMT_NODE_BITMAP(hval ^ bp); ptr++;
n -= slot;
while(slot--) { *hp++ = *ptr++; }
ptr++; n--;
while(n--) { *hp++ = *ptr++; }
res = make_hashmap(nhp);
}
} else if (primary_tag(res) == TAG_PRIMARY_LIST && n == 1) {
break;
} else {
/* res is bitmap or leaf && n > 1, keep */
n -= slot;
*hp++ = *ptr++;
while(slot--) { *hp++ = *ptr++; }
*hp++ = res;
ptr++; n--;
while(n--) { *hp++ = *ptr++; }
res = make_hashmap(nhp);
}
break;
case HAMT_SUBTAG_HEAD_BITMAP:
slot = (Uint) ESTACK_POP(stack);
bp = (Uint32) ESTACK_POP(stack);
n = (Uint32) ESTACK_POP(stack);
nhp = hp;
if (res != THE_NON_VALUE) {
*hp++ = *ptr++;
*hp++ = (*ptr++) - 1;
n -= slot;
while(slot--) { *hp++ = *ptr++; }
*hp++ = res;
ptr++; n--;
while(n--) { *hp++ = *ptr++; }
} else {
hval = MAP_HEADER_VAL(hdr);
*hp++ = MAP_HEADER_HAMT_HEAD_BITMAP(hval ^ bp); ptr++;
*hp++ = (*ptr++) - 1;
n -= slot;
while(slot--) { *hp++ = *ptr++; }
ptr++; n--;
while(n--) { *hp++ = *ptr++; }
}
res = make_hashmap(nhp);
break;
default:
erts_exit(ERTS_ERROR_EXIT, "bad header tag %x\r\n", hdr & _HEADER_MAP_SUBTAG_MASK);
break;
}
} while(!ESTACK_ISEMPTY(stack));
HRelease(p, hp_end, hp);
not_found:
DESTROY_ESTACK(stack);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(p);
ERTS_HOLE_CHECK(p);
UnUseTmpHeapNoproc(2);
return res;
}
int erts_validate_and_sort_flatmap(flatmap_t* mp)
{
Eterm *ks = flatmap_get_keys(mp);
Eterm *vs = flatmap_get_values(mp);
Uint sz = flatmap_get_size(mp);
Uint ix,jx;
Eterm tmp;
Sint c;
/* sort */
for (ix = 1; ix < sz; ix++) {
jx = ix;
while( jx > 0 && (c = CMP_TERM(ks[jx],ks[jx-1])) <= 0 ) {
/* identical key -> error */
if (c == 0) return 0;
tmp = ks[jx];
ks[jx] = ks[jx - 1];
ks[jx - 1] = tmp;
tmp = vs[jx];
vs[jx] = vs[jx - 1];
vs[jx - 1] = tmp;
jx--;
}
}
return 1;
}
#if 0 /* Can't get myself to remove this beautiful piece of code
for probabilistic overestimation of nr of nodes in a hashmap */
/* Really rough estimate of sqrt(x)
* Guaranteed not to be less than sqrt(x)
*/
static int int_sqrt_ceiling(Uint x)
{
int n;
if (x <= 2)
return x;
n = erts_fit_in_bits_uint(x-1);
if (n & 1) {
/* Calc: sqrt(2^n) = 2^(n/2) * sqrt(2) ~= 2^(n/2) * 3 / 2 */
return (1 << (n/2 - 1)) * 3;
}
else {
/* Calc: sqrt(2^n) = 2^(n/2) */
return 1 << (n / 2);
}
}
/* May not be enough if hashing is broken (not uniform)
* or if hell freezes over.
*/
Uint hashmap_overestimated_node_count(Uint k)
{
/* k is nr of key-value pairs.
N(k) is expected nr of nodes in hamt.
Observation:
For uniformly distributed hash values, average of N varies between
0.3*k and 0.4*k (with a beautiful sine curve)
and standard deviation of N is about sqrt(k)/3.
Assuming normal probability distribution, we overestimate nr of nodes
by 15 std.devs above the average, which gives a probability for overrun
less than 1.0e-49 (same magnitude as a git SHA1 collision).
*/
return 2*k/5 + 1 + (15/3)*int_sqrt_ceiling(k);
}
#endif
BIF_RETTYPE erts_debug_map_info_1(BIF_ALIST_1) {
if (is_hashmap(BIF_ARG_1)) {
BIF_RET(hashmap_info(BIF_P,BIF_ARG_1));
} else if (is_flatmap(BIF_ARG_1)) {
BIF_ERROR(BIF_P, BADARG);
} else {
BIF_P->fvalue = BIF_ARG_1;
BIF_ERROR(BIF_P, BADMAP);
}
}
/*
* erts_internal:map_to_tuple_keys/1
*
* Used in erts_debug:size/1
*/
BIF_RETTYPE erts_internal_map_to_tuple_keys_1(BIF_ALIST_1) {
if (is_flatmap(BIF_ARG_1)) {
flatmap_t *mp = (flatmap_t*)flatmap_val(BIF_ARG_1);
BIF_RET(mp->keys);
} else if (is_hashmap(BIF_ARG_1)) {
BIF_ERROR(BIF_P, BADARG);
} else {
BIF_P->fvalue = BIF_ARG_1;
BIF_ERROR(BIF_P, BADMAP);
}
}
/*
* erts_internal:term_type/1
*
* Used in erts_debug:size/1
*/
BIF_RETTYPE erts_internal_term_type_1(BIF_ALIST_1) {
Eterm obj = BIF_ARG_1;
switch (primary_tag(obj)) {
case TAG_PRIMARY_LIST:
BIF_RET(ERTS_MAKE_AM("list"));
case TAG_PRIMARY_BOXED: {
Eterm hdr = *boxed_val(obj);
ASSERT(is_header(hdr));
switch (hdr & _TAG_HEADER_MASK) {
case ARITYVAL_SUBTAG:
BIF_RET(ERTS_MAKE_AM("tuple"));
case EXPORT_SUBTAG:
BIF_RET(ERTS_MAKE_AM("export"));
case FUN_SUBTAG:
BIF_RET(ERTS_MAKE_AM("fun"));
case MAP_SUBTAG:
switch (MAP_HEADER_TYPE(hdr)) {
case MAP_HEADER_TAG_FLATMAP_HEAD :
BIF_RET(ERTS_MAKE_AM("flatmap"));
case MAP_HEADER_TAG_HAMT_HEAD_BITMAP :
case MAP_HEADER_TAG_HAMT_HEAD_ARRAY :
BIF_RET(ERTS_MAKE_AM("hashmap"));
case MAP_HEADER_TAG_HAMT_NODE_BITMAP :
BIF_RET(ERTS_MAKE_AM("hashmap_node"));
default:
erts_exit(ERTS_ABORT_EXIT, "term_type: bad map header type %d\n", MAP_HEADER_TYPE(hdr));
}
case REFC_BINARY_SUBTAG:
BIF_RET(ERTS_MAKE_AM("refc_binary"));
case HEAP_BINARY_SUBTAG:
BIF_RET(ERTS_MAKE_AM("heap_binary"));
case SUB_BINARY_SUBTAG:
BIF_RET(ERTS_MAKE_AM("sub_binary"));
case BIN_MATCHSTATE_SUBTAG:
BIF_RET(ERTS_MAKE_AM("matchstate"));
case POS_BIG_SUBTAG:
case NEG_BIG_SUBTAG:
BIF_RET(ERTS_MAKE_AM("bignum"));
case REF_SUBTAG:
BIF_RET(ERTS_MAKE_AM("reference"));
case EXTERNAL_REF_SUBTAG:
BIF_RET(ERTS_MAKE_AM("external_reference"));
case EXTERNAL_PID_SUBTAG:
BIF_RET(ERTS_MAKE_AM("external_pid"));
case EXTERNAL_PORT_SUBTAG:
BIF_RET(ERTS_MAKE_AM("external_port"));
case FLOAT_SUBTAG:
BIF_RET(ERTS_MAKE_AM("hfloat"));
default:
erts_exit(ERTS_ABORT_EXIT, "term_type: Invalid tag (0x%X)\n", hdr);
}
}
case TAG_PRIMARY_IMMED1:
switch (obj & _TAG_IMMED1_MASK) {
case _TAG_IMMED1_SMALL:
BIF_RET(ERTS_MAKE_AM("fixnum"));
case _TAG_IMMED1_PID:
BIF_RET(ERTS_MAKE_AM("pid"));
case _TAG_IMMED1_PORT:
BIF_RET(ERTS_MAKE_AM("port"));
case _TAG_IMMED1_IMMED2:
switch (obj & _TAG_IMMED2_MASK) {
case _TAG_IMMED2_ATOM:
BIF_RET(ERTS_MAKE_AM("atom"));
case _TAG_IMMED2_CATCH:
BIF_RET(ERTS_MAKE_AM("catch"));
case _TAG_IMMED2_NIL:
BIF_RET(ERTS_MAKE_AM("nil"));
default:
erts_exit(ERTS_ABORT_EXIT, "term_type: Invalid tag (0x%X)\n", obj);
}
default:
erts_exit(ERTS_ABORT_EXIT, "term_type: Invalid tag (0x%X)\n", obj);
}
default:
erts_exit(ERTS_ABORT_EXIT, "term_type: Invalid tag (0x%X)\n", obj);
}
}
/*
* erts_internal:map_hashmap_children/1
*
* Used in erts_debug:size/1
*/
BIF_RETTYPE erts_internal_map_hashmap_children_1(BIF_ALIST_1) {
if (is_map(BIF_ARG_1)) {
Eterm node = BIF_ARG_1;
Eterm *ptr, hdr, *hp, res = NIL;
Uint sz = 0;
ptr = boxed_val(node);
hdr = *ptr;
ASSERT(is_header(hdr));
switch(hdr & _HEADER_MAP_SUBTAG_MASK) {
case HAMT_SUBTAG_HEAD_FLATMAP:
BIF_ERROR(BIF_P, BADARG);
case HAMT_SUBTAG_HEAD_BITMAP:
ptr++;
case HAMT_SUBTAG_NODE_BITMAP:
ptr++;
sz = hashmap_bitcount(MAP_HEADER_VAL(hdr));
break;
case HAMT_SUBTAG_HEAD_ARRAY:
sz = 16;
ptr += 2;
break;
default:
erts_exit(ERTS_ERROR_EXIT, "bad header\r\n");
break;
}
ASSERT(sz < 17);
hp = HAlloc(BIF_P, 2*sz);
while(sz--) { res = CONS(hp, *ptr++, res); hp += 2; }
BIF_RET(res);
}
BIF_P->fvalue = BIF_ARG_1;
BIF_ERROR(BIF_P, BADMAP);
}
static Eterm hashmap_info(Process *p, Eterm node) {
Eterm *hp;
Eterm res = NIL, info = NIL;
Eterm *ptr, tup, hdr;
Uint sz;
DECL_AM(depth);
DECL_AM(leafs);
DECL_AM(bitmaps);
DECL_AM(arrays);
Uint nleaf=0, nbitmap=0, narray=0;
Uint bitmap_usage[16], leaf_usage[16];
Uint lvl = 0, clvl;
DECLARE_ESTACK(stack);
for (sz = 0; sz < 16; sz++) {
bitmap_usage[sz] = 0;
leaf_usage[sz] = 0;
}
ptr = boxed_val(node);
ESTACK_PUSH(stack, 0);
ESTACK_PUSH(stack, node);
do {
node = ESTACK_POP(stack);
clvl = ESTACK_POP(stack);
if (lvl < clvl)
lvl = clvl;
switch(primary_tag(node)) {
case TAG_PRIMARY_LIST:
nleaf++;
leaf_usage[clvl] += 1;
break;
case TAG_PRIMARY_BOXED:
ptr = boxed_val(node);
hdr = *ptr;
ASSERT(is_header(hdr));
switch(hdr & _HEADER_MAP_SUBTAG_MASK) {
case HAMT_SUBTAG_NODE_BITMAP:
nbitmap++;
sz = hashmap_bitcount(MAP_HEADER_VAL(hdr));
ASSERT(sz < 17);
bitmap_usage[sz-1] += 1;
while(sz--) {
ESTACK_PUSH(stack, clvl + 1);
ESTACK_PUSH(stack, ptr[sz+1]);
}
break;
case HAMT_SUBTAG_HEAD_BITMAP:
nbitmap++;
sz = hashmap_bitcount(MAP_HEADER_VAL(hdr));
bitmap_usage[sz-1] += 1;
while(sz--) {
ESTACK_PUSH(stack, clvl + 1);
ESTACK_PUSH(stack, ptr[sz+2]);
}
break;
case HAMT_SUBTAG_HEAD_ARRAY:
narray++;
sz = 16;
while(sz--) {
ESTACK_PUSH(stack, clvl + 1);
ESTACK_PUSH(stack, ptr[sz+2]);
}
break;
default:
erts_exit(ERTS_ERROR_EXIT, "bad header\r\n");
break;
}
}
} while(!ESTACK_ISEMPTY(stack));
/* size */
sz = 0;
hashmap_bld_tuple_uint(NULL,&sz,16,leaf_usage);
hashmap_bld_tuple_uint(NULL,&sz,16,bitmap_usage);
/* alloc */
hp = HAlloc(p, 2+3 + 3*(2+4) + sz);
info = hashmap_bld_tuple_uint(&hp,NULL,16,leaf_usage);
tup = TUPLE3(hp, AM_leafs, make_small(nleaf),info); hp += 4;
res = CONS(hp, tup, res); hp += 2;
info = hashmap_bld_tuple_uint(&hp,NULL,16,bitmap_usage);
tup = TUPLE3(hp, AM_bitmaps, make_small(nbitmap), info); hp += 4;
res = CONS(hp, tup, res); hp += 2;
tup = TUPLE3(hp, AM_arrays, make_small(narray),NIL); hp += 4;
res = CONS(hp, tup, res); hp += 2;
tup = TUPLE2(hp, AM_depth, make_small(lvl)); hp += 3;
res = CONS(hp, tup, res); hp += 2;
DESTROY_ESTACK(stack);
ERTS_HOLE_CHECK(p);
return res;
}
static Eterm hashmap_bld_tuple_uint(Uint **hpp, Uint *szp, Uint n, Uint nums[]) {
Eterm res = THE_NON_VALUE;
Eterm *ts = (Eterm *)erts_alloc(ERTS_ALC_T_TMP, n * sizeof(Eterm));
Uint i;
for (i = 0; i < n; i++) {
ts[i] = erts_bld_uint(hpp, szp, nums[i]);
}
res = erts_bld_tuplev(hpp, szp, n, ts);
erts_free(ERTS_ALC_T_TMP, (void *) ts);
return res;
}
/**
* In hashmap the Path is a bit pattern that describes
* which slot we should traverse in each hashmap node.
* Since each hashmap node can only be up to 16 elements
* large we use 4 bits per level in the path.
*
* So a Path with value 0x110 will first get the 0:th
* slot in the head node, and then the 1:st slot in the
* resulting node and then finally the 1:st slot in the
* node beneath. If that slot is not a leaf, then the path
* continues down the 0:th slot until it finds a leaf.
*
* Once the leaf has been found, the return value is created
* by traversing the tree using the the stack that was built
* when searching for the first leaf to return.
*
* The index can become a bignum, which complicates the code
* a bit. However it should be very rare that this happens
* even on a 32bit system as you would need a tree of depth
* 7 or more.
*
* If the number of elements remaining in the map is greater
* than how many we want to return, we build a new Path, using
* the stack, that points to the next leaf.
*
* The third argument to this function controls how the data
* is returned.
*
* iterator: The key-value associations are to be used by
* maps:iterator. The return has this format:
* {K1,V1,{K2,V2,none | [Path | Map]}}
* this makes the maps:next function very simple
* and performant.
*
* list(): The key-value associations are to be used by
* maps:to_list. The return has this format:
* [Path, Map | [{K1,V1},{K2,V2} | BIF_ARG_3]]
* or if no more associations remain
* [{K1,V1},{K2,V2} | BIF_ARG_3]
*/
#define PATH_ELEM_SIZE 4
#define PATH_ELEM_MASK 0xf
#define PATH_ELEM(PATH) ((PATH) & PATH_ELEM_MASK)
#define PATH_ELEMS_PER_DIGIT (sizeof(ErtsDigit) * 8 / PATH_ELEM_SIZE)
BIF_RETTYPE erts_internal_map_next_3(BIF_ALIST_3) {
Eterm path, map;
enum { iterator, list } type;
path = BIF_ARG_1;
map = BIF_ARG_2;
if (!is_map(map))
BIF_ERROR(BIF_P, BADARG);
if (BIF_ARG_3 == am_iterator) {
type = iterator;
} else if (is_nil(BIF_ARG_3) || is_list(BIF_ARG_3)) {
type = list;
} else {
BIF_ERROR(BIF_P, BADARG);
}
if (is_flatmap(map)) {
Uint n;
Eterm *ks,*vs, res, *hp;
flatmap_t *mp = (flatmap_t*)flatmap_val(map);
ks = flatmap_get_keys(mp);
vs = flatmap_get_values(mp);
n = flatmap_get_size(mp);
if (!is_small(BIF_ARG_1) || n < unsigned_val(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
if (type == iterator) {
hp = HAlloc(BIF_P, 4 * n);
res = am_none;
while(n--) {
res = TUPLE3(hp, ks[n], vs[n], res); hp += 4;
}
} else {
hp = HAlloc(BIF_P, (2 + 3) * n);
res = BIF_ARG_3;
while(n--) {
Eterm tup = TUPLE2(hp, ks[n], vs[n]); hp += 3;
res = CONS(hp, tup, res); hp += 2;
}
}
BIF_RET(res);
} else {
Uint curr_path;
Uint path_length = 0;
Uint *path_rest = NULL;
int i, elems, orig_elems;
Eterm node = map, res, *path_ptr = NULL, *hp;
/* A stack WSTACK is used when traversing the hashmap.
* It contains: node, idx, sz, ptr
*
* `node` is not really needed, but it is very nice to
* have when debugging.
*
* `idx` always points to the next un-explored entry in
* a node. If there are no more un-explored entries,
* `idx` is equal to `sz`.
*
* `sz` is the number of elements in the node.
*
* `ptr` is a pointer to where the elements of the node begins.
*/
DECLARE_WSTACK(stack);
ASSERT(is_hashmap(node));
/* How many elements we return in one call depends on the number of reductions
* that the process has left to run. In debug we return fewer elements to test
* the Path implementation better.
*
* Also, when the path is 0 (i.e. for the first call) we limit the number of
* elements to MAP_SMALL_MAP_LIMIT in order to not use a huge amount of heap
* when only the first X associations in the hashmap was needed.
*/
#if defined(DEBUG)
#define FCALLS_ELEMS(BIF_P) ((BIF_P->fcalls / 4) & 0xF)
#else
#define FCALLS_ELEMS(BIF_P) (BIF_P->fcalls / 4)
#endif
if (MAX(FCALLS_ELEMS(BIF_P), 1) < hashmap_size(map))
elems = MAX(FCALLS_ELEMS(BIF_P), 1);
else
elems = hashmap_size(map);
#undef FCALLS_ELEMS
if (is_small(path)) {
curr_path = unsigned_val(path);
if (curr_path == 0 && elems > MAP_SMALL_MAP_LIMIT) {
elems = MAP_SMALL_MAP_LIMIT;
}
} else if (is_big(path)) {
Eterm *big = big_val(path);
if (bignum_header_is_neg(*big))
BIF_ERROR(BIF_P, BADARG);
path_length = BIG_ARITY(big) - 1;
curr_path = BIG_DIGIT(big, 0);
path_rest = BIG_V(big) + 1;
} else {
BIF_ERROR(BIF_P, BADARG);
}
if (type == iterator) {
/* iterator uses the format {K, V, {K, V, {K, V, [Path | Map]}}},
* so each element is 4 words large */
hp = HAlloc(BIF_P, 4 * elems);
res = am_none;
} else {
/* list used the format [Path, Map, {K,V}, {K,V} | BIF_ARG_3],
* so each element is 2+3 words large */
hp = HAlloc(BIF_P, (2 + 3) * elems);
res = BIF_ARG_3;
}
orig_elems = elems;
/* First we look for the leaf to start at using the
path given. While doing so, we push each map node
and the index onto the stack to use later. */
for (i = 1; ; i++) {
Eterm *ptr = hashmap_val(node),
hdr = *ptr++;
Uint sz;
sz = hashmap_node_size(hdr, &ptr);
if (PATH_ELEM(curr_path) >= sz)
goto badarg;
WSTACK_PUSH4(stack, node, PATH_ELEM(curr_path)+1, sz, (UWord)ptr);
/* We have found a leaf, return it and the next X elements */
if (is_list(ptr[PATH_ELEM(curr_path)])) {
Eterm *lst = list_val(ptr[PATH_ELEM(curr_path)]);
if (type == iterator) {
res = TUPLE3(hp, CAR(lst), CDR(lst), res); hp += 4;
/* Note where we should patch the Iterator is needed */
path_ptr = hp-1;
} else {
Eterm tup = TUPLE2(hp, CAR(lst), CDR(lst)); hp += 3;
res = CONS(hp, tup, res); hp += 2;
}
elems--;
break;
}
node = ptr[PATH_ELEM(curr_path)];
curr_path >>= PATH_ELEM_SIZE;
if (i == PATH_ELEMS_PER_DIGIT) {
/* Switch to next bignum word if available,
otherwise just follow 0 path */
i = 0;
if (path_length) {
curr_path = *path_rest;
path_length--;
path_rest++;
} else {
curr_path = 0;
}
}
}
/* We traverse the hashmap and return at most `elems` elements */
while(1) {
Eterm *ptr = (Eterm*)WSTACK_POP(stack);
Uint sz = (Uint)WSTACK_POP(stack);
Uint idx = (Uint)WSTACK_POP(stack);
Eterm node = (Eterm)WSTACK_POP(stack);
while (idx < sz && elems != 0 && is_list(ptr[idx])) {
Eterm *lst = list_val(ptr[idx]);
if (type == iterator) {
res = TUPLE3(hp, CAR(lst), CDR(lst), res); hp += 4;
} else {
Eterm tup = TUPLE2(hp, CAR(lst), CDR(lst)); hp += 3;
res = CONS(hp, tup, res); hp += 2;
}
elems--;
idx++;
}
if (elems == 0) {
if (idx < sz) {
/* There are more elements in this node to explore */
WSTACK_PUSH4(stack, node, idx+1, sz, (UWord)ptr);
} else {
/* pop stack to find the next value */
while (!WSTACK_ISEMPTY(stack)) {
Eterm *ptr = (Eterm*)WSTACK_POP(stack);
Uint sz = (Uint)WSTACK_POP(stack);
Uint idx = (Uint)WSTACK_POP(stack);
Eterm node = (Eterm)WSTACK_POP(stack);
if (idx < sz) {
WSTACK_PUSH4(stack, node, idx+1, sz, (UWord)ptr);
break;
}
}
}
break;
} else {
if (idx < sz) {
Eterm hdr;
/* Push next idx in current node */
WSTACK_PUSH4(stack, node, idx+1, sz, (UWord)ptr);
/* Push first idx in child node */
node = ptr[idx];
ptr = hashmap_val(ptr[idx]);
hdr = *ptr++;
sz = hashmap_node_size(hdr, &ptr);
WSTACK_PUSH4(stack, node, 0, sz, (UWord)ptr);
}
}
/* There are no more element in the hashmap */
if (WSTACK_ISEMPTY(stack)) {
break;
}
}
if (!WSTACK_ISEMPTY(stack)) {
Uint depth = WSTACK_COUNT(stack) / 4 + 1;
/* +1 because we already have the first element in curr_path */
Eterm *path_digits = NULL;
Uint curr_path = 0;
/* If the path cannot fit in a small, we allocate a bignum */
if (depth >= PATH_ELEMS_PER_DIGIT) {
/* We need multiple ErtsDigit's to represent the path */
int big_size = BIG_NEED_FOR_BITS(depth * PATH_ELEM_SIZE);
hp = HAlloc(BIF_P, big_size);
hp[0] = make_pos_bignum_header(big_size - BIG_NEED_SIZE(0));
path_digits = hp + big_size - 1;
}
/* Pop the stack to create the complete path to the next leaf */
while(!WSTACK_ISEMPTY(stack)) {
Uint idx;
(void)WSTACK_POP(stack);
(void)WSTACK_POP(stack);
idx = (Uint)WSTACK_POP(stack)-1;
/* idx - 1 because idx in the stack is pointing to
the next element to fetch. */
(void)WSTACK_POP(stack);
depth--;
if (depth % PATH_ELEMS_PER_DIGIT == 0) {
/* Switch to next bignum element */
path_digits[0] = curr_path;
path_digits--;
curr_path = 0;
}
curr_path <<= PATH_ELEM_SIZE;
curr_path |= idx;
}
if (path_digits) {
path_digits[0] = curr_path;
path = make_big(hp);
} else {
/* The Uint could be too large for a small */
path = erts_make_integer(curr_path, BIF_P);
}
if (type == iterator) {
hp = HAlloc(BIF_P, 2);
*path_ptr = CONS(hp, path, map); hp += 2;
} else {
hp = HAlloc(BIF_P, 4);
res = CONS(hp, map, res); hp += 2;
res = CONS(hp, path, res); hp += 2;
}
} else {
if (type == iterator) {
HRelease(BIF_P, hp + 4 * elems, hp);
} else {
HRelease(BIF_P, hp + (2+3) * elems, hp);
}
}
BIF_P->fcalls -= 4 * (orig_elems - elems);
DESTROY_WSTACK(stack);
BIF_RET(res);
badarg:
if (type == iterator) {
HRelease(BIF_P, hp + 4 * elems, hp);
} else {
HRelease(BIF_P, hp + (2+3) * elems, hp);
}
BIF_P->fcalls -= 4 * (orig_elems - elems);
DESTROY_WSTACK(stack);
BIF_ERROR(BIF_P, BADARG);
}
}
/* implementation of builtin emulations */
#if !ERTS_AT_LEAST_GCC_VSN__(3, 4, 0)
/* Count leading zeros emulation */
Uint32 hashmap_clz(Uint32 x) {
Uint32 y;
int n = 32;
y = x >>16; if (y != 0) {n = n -16; x = y;}
y = x >> 8; if (y != 0) {n = n - 8; x = y;}
y = x >> 4; if (y != 0) {n = n - 4; x = y;}
y = x >> 2; if (y != 0) {n = n - 2; x = y;}
y = x >> 1; if (y != 0) return n - 2;
return n - x;
}
const Uint32 SK5 = 0x55555555, SK3 = 0x33333333;
const Uint32 SKF0 = 0xF0F0F0F, SKFF = 0xFF00FF;
/* CTPOP emulation */
Uint32 hashmap_bitcount(Uint32 x) {
x -= ((x >> 1 ) & SK5);
x = (x & SK3 ) + ((x >> 2 ) & SK3 );
x = (x & SKF0) + ((x >> 4 ) & SKF0);
x += x >> 8;
return (x + (x >> 16)) & 0x3F;
}
#endif