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/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2014-2016. 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%
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#define ERL_BIF_UNIQUE_C__
#include "sys.h"
#include "erl_vm.h"
#include "erl_alloc.h"
#include "export.h"
#include "bif.h"
#include "erl_bif_unique.h"
#include "hash.h"
#include "erl_binary.h"
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* Reference *
\* */
static union {
erts_atomic64_t count;
char align__[ERTS_CACHE_LINE_SIZE];
} global_reference erts_align_attribute(ERTS_CACHE_LINE_SIZE);
/*
* ref[0] indicate thread creating reference as follows:
*
* - ref[0] == 0 => Non-scheduler thread;
* - else; ref[0] <= erts_no_schedulers =>
* ordinary scheduler with id == ref[0];
* - else; ref[0] <= erts_no_schedulers
* + erts_no_dirty_cpu_schedulers =>
* dirty cpu scheduler with id == 'ref[0] - erts_no_schedulers';
* - else =>
* dirty io scheduler with id == 'ref[0]
* - erts_no_schedulers
* - erts_no_dirty_cpu_schedulers'
*/
#ifdef DEBUG
static Uint32 max_thr_id;
#endif
static void init_magic_ref_tables(void);
static Uint64 ref_init_value;
static void
init_reference(void)
{
SysTimeval tv;
sys_gettimeofday(&tv);
ref_init_value = 0;
ref_init_value |= (Uint64) tv.tv_sec;
ref_init_value |= ((Uint64) tv.tv_usec) << 32;
ref_init_value *= (Uint64) 268438039;
ref_init_value += (Uint64) tv.tv_usec;
#ifdef DEBUG
max_thr_id = (Uint32) erts_no_schedulers;
#ifdef ERTS_DIRTY_SCHEDULERS
max_thr_id += (Uint32) erts_no_dirty_cpu_schedulers;
max_thr_id += (Uint32) erts_no_dirty_io_schedulers;
#endif
#endif
erts_atomic64_init_nob(&global_reference.count,
(erts_aint64_t) ref_init_value);
init_magic_ref_tables();
}
static ERTS_INLINE void
global_make_ref_in_array(Uint32 thr_id, Uint32 ref[ERTS_REF_NUMBERS])
{
Uint64 value;
value = (Uint64) erts_atomic64_inc_read_mb(&global_reference.count);
erts_set_ref_numbers(ref, thr_id, value);
}
static ERTS_INLINE void
make_ref_in_array(Uint32 ref[ERTS_REF_NUMBERS])
{
ErtsSchedulerData *esdp = erts_get_scheduler_data();
if (esdp)
erts_sched_make_ref_in_array(esdp, ref);
else
global_make_ref_in_array(0, ref);
}
void
erts_make_ref_in_array(Uint32 ref[ERTS_REF_NUMBERS])
{
make_ref_in_array(ref);
}
void
erts_make_magic_ref_in_array(Uint32 ref[ERTS_REF_NUMBERS])
{
make_ref_in_array(ref);
ASSERT(!(ref[1] & ERTS_REF1_MAGIC_MARKER_BIT__));
ref[1] |= ERTS_REF1_MAGIC_MARKER_BIT__;
}
Eterm erts_make_ref_in_buffer(Eterm buffer[ERTS_REF_THING_SIZE])
{
Eterm* hp = buffer;
Uint32 ref[ERTS_REF_NUMBERS];
make_ref_in_array(ref);
write_ref_thing(hp, ref[0], ref[1], ref[2]);
return make_internal_ref(hp);
}
Eterm erts_make_ref(Process *c_p)
{
Eterm* hp;
Uint32 ref[ERTS_REF_NUMBERS];
ERTS_SMP_LC_ASSERT(ERTS_PROC_LOCK_MAIN & erts_proc_lc_my_proc_locks(c_p));
hp = HAlloc(c_p, ERTS_REF_THING_SIZE);
make_ref_in_array(ref);
write_ref_thing(hp, ref[0], ref[1], ref[2]);
return make_internal_ref(hp);
}
/*
* Magic reference tables
*/
typedef struct {
HashBucket hash;
ErtsMagicBinary *mb;
Uint64 value;
Uint32 thr_id;
} ErtsMagicRefTableEntry;
typedef struct {
erts_rwmtx_t rwmtx;
Hash hash;
char name[32];
} ErtsMagicRefTable;
typedef struct {
union {
ErtsMagicRefTable table;
char align__[ERTS_ALC_CACHE_LINE_ALIGN_SIZE(sizeof(ErtsMagicRefTable))];
} u;
} ErtsAlignedMagicRefTable;
ErtsAlignedMagicRefTable *magic_ref_table;
ErtsMagicBinary *
erts_magic_ref_lookup_bin__(Uint32 refn[ERTS_REF_NUMBERS])
{
ErtsMagicRefTableEntry tmpl;
ErtsMagicRefTableEntry *tep;
ErtsMagicBinary *mb;
ErtsMagicRefTable *tblp;
ASSERT(erts_is_ref_numbers_magic(refn));
tmpl.value = erts_get_ref_numbers_value(refn);
tmpl.thr_id = erts_get_ref_numbers_thr_id(refn);
if (tmpl.thr_id > erts_no_schedulers)
tblp = &magic_ref_table[0].u.table;
else
tblp = &magic_ref_table[tmpl.thr_id].u.table;
erts_rwmtx_rlock(&tblp->rwmtx);
tep = (ErtsMagicRefTableEntry *) hash_get(&tblp->hash, &tmpl);
if (!tep)
mb = NULL;
else {
erts_aint_t refc;
mb = tep->mb;
refc = erts_refc_inc_unless(&mb->refc, 0, 0);
if (refc == 0)
mb = NULL;
}
erts_rwmtx_runlock(&tblp->rwmtx);
return mb;
}
void
erts_magic_ref_save_bin__(Eterm ref)
{
ErtsMagicRefTableEntry tmpl;
ErtsMagicRefTableEntry *tep;
ErtsMRefThing *mrtp;
ErtsMagicRefTable *tblp;
Uint32 *refn;
ASSERT(is_internal_magic_ref(ref));
mrtp = (ErtsMRefThing *) internal_ref_val(ref);
refn = mrtp->mb->refn;
tmpl.value = erts_get_ref_numbers_value(refn);
tmpl.thr_id = erts_get_ref_numbers_thr_id(refn);
if (tmpl.thr_id > erts_no_schedulers)
tblp = &magic_ref_table[0].u.table;
else
tblp = &magic_ref_table[tmpl.thr_id].u.table;
erts_rwmtx_rlock(&tblp->rwmtx);
tep = (ErtsMagicRefTableEntry *) hash_get(&tblp->hash, &tmpl);
erts_rwmtx_runlock(&tblp->rwmtx);
if (!tep) {
ErtsMagicRefTableEntry *used_tep;
ASSERT(tmpl.value == erts_get_ref_numbers_value(refn));
ASSERT(tmpl.thr_id == erts_get_ref_numbers_thr_id(refn));
if (tblp != &magic_ref_table[0].u.table) {
tep = erts_alloc(ERTS_ALC_T_MREF_NSCHED_ENT,
sizeof(ErtsNSchedMagicRefTableEntry));
}
else {
tep = erts_alloc(ERTS_ALC_T_MREF_ENT,
sizeof(ErtsMagicRefTableEntry));
tep->thr_id = tmpl.thr_id;
}
tep->value = tmpl.value;
tep->mb = mrtp->mb;
erts_rwmtx_rwlock(&tblp->rwmtx);
used_tep = hash_put(&tblp->hash, tep);
erts_rwmtx_rwunlock(&tblp->rwmtx);
if (used_tep != tep) {
if (tblp != &magic_ref_table[0].u.table)
erts_free(ERTS_ALC_T_MREF_NSCHED_ENT, (void *) tep);
else
erts_free(ERTS_ALC_T_MREF_ENT, (void *) tep);
}
}
}
void
erts_magic_ref_remove_bin(Uint32 refn[ERTS_REF_NUMBERS])
{
ErtsMagicRefTableEntry tmpl;
ErtsMagicRefTableEntry *tep;
ErtsMagicRefTable *tblp;
tmpl.value = erts_get_ref_numbers_value(refn);
tmpl.thr_id = erts_get_ref_numbers_thr_id(refn);
if (tmpl.thr_id > erts_no_schedulers)
tblp = &magic_ref_table[0].u.table;
else
tblp = &magic_ref_table[tmpl.thr_id].u.table;
erts_rwmtx_rlock(&tblp->rwmtx);
tep = (ErtsMagicRefTableEntry *) hash_get(&tblp->hash, &tmpl);
erts_rwmtx_runlock(&tblp->rwmtx);
if (tep) {
ASSERT(tmpl.value == erts_get_ref_numbers_value(refn));
ASSERT(tmpl.thr_id == erts_get_ref_numbers_thr_id(refn));
erts_rwmtx_rwlock(&tblp->rwmtx);
tep = hash_remove(&tblp->hash, &tmpl);
ASSERT(tep);
erts_rwmtx_rwunlock(&tblp->rwmtx);
if (tblp != &magic_ref_table[0].u.table)
erts_free(ERTS_ALC_T_MREF_NSCHED_ENT, (void *) tep);
else
erts_free(ERTS_ALC_T_MREF_ENT, (void *) tep);
}
}
static int nsched_mreft_cmp(void *ve1, void *ve2)
{
ErtsNSchedMagicRefTableEntry *e1 = ve1;
ErtsNSchedMagicRefTableEntry *e2 = ve2;
return e1->value != e2->value;
}
static int non_nsched_mreft_cmp(void *ve1, void *ve2)
{
ErtsMagicRefTableEntry *e1 = ve1;
ErtsMagicRefTableEntry *e2 = ve2;
return e1->value != e2->value || e1->thr_id != e2->thr_id;
}
static HashValue nsched_mreft_hash(void *ve)
{
ErtsNSchedMagicRefTableEntry *e = ve;
return (HashValue) e->value;
}
static HashValue non_nsched_mreft_hash(void *ve)
{
ErtsMagicRefTableEntry *e = ve;
HashValue h;
h = (HashValue) e->thr_id;
h *= 268440163;
h += (HashValue) e->value;
return h;
}
static void *mreft_alloc(void *ve)
{
/*
* We allocate the element before
* hash_put() and pass it as
* template which we get as
* input...
*/
return ve;
}
static void mreft_free(void *ve)
{
/*
* We free the element ourselves
* after hash_remove()...
*/
}
static void *mreft_meta_alloc(int i, size_t size)
{
return erts_alloc(ERTS_ALC_T_MREF_TAB_BKTS, size);
}
static void mreft_meta_free(int i, void *ptr)
{
erts_free(ERTS_ALC_T_MREF_TAB_BKTS, ptr);
}
static void
init_magic_ref_tables(void)
{
HashFunctions hash_funcs;
int i;
ErtsMagicRefTable *tblp;
magic_ref_table = erts_alloc_permanent_cache_aligned(ERTS_ALC_T_MREF_TAB,
(sizeof(ErtsAlignedMagicRefTable)
* (erts_no_schedulers + 1)));
hash_funcs.hash = non_nsched_mreft_hash;
hash_funcs.cmp = non_nsched_mreft_cmp;
hash_funcs.alloc = mreft_alloc;
hash_funcs.free = mreft_free;
hash_funcs.meta_alloc = mreft_meta_alloc;
hash_funcs.meta_free = mreft_meta_free;
hash_funcs.meta_print = erts_print;
tblp = &magic_ref_table[0].u.table;
erts_snprintf(&tblp->name[0], sizeof(tblp->name),
"magic_ref_table_0");
hash_init(0, &tblp->hash, &tblp->name[0], 1, hash_funcs);
erts_rwmtx_init(&tblp->rwmtx, "magic_ref_table");
hash_funcs.hash = nsched_mreft_hash;
hash_funcs.cmp = nsched_mreft_cmp;
for (i = 1; i <= erts_no_schedulers; i++) {
ErtsMagicRefTable *tblp = &magic_ref_table[i].u.table;
erts_snprintf(&tblp->name[0], sizeof(tblp->name),
"magic_ref_table_%d", i);
hash_init(0, &tblp->hash, &tblp->name[0], 1, hash_funcs);
erts_rwmtx_init(&tblp->rwmtx, "magic_ref_table");
}
}
void erts_ref_bin_free(ErtsMagicBinary *mb)
{
erts_bin_free((Binary *) mb);
}
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* Unique Integer *
\* */
static struct {
union {
struct {
int left_shift;
int right_shift;
Uint64 mask;
Uint64 val0_max;
} o;
char align__[ERTS_CACHE_LINE_SIZE];
} r;
union {
erts_atomic64_t val1;
char align__[ERTS_CACHE_LINE_SIZE];
} w;
} unique_data erts_align_attribute(ERTS_CACHE_LINE_SIZE);
static void
init_unique_integer(void)
{
int bits;
unique_data.r.o.val0_max = (Uint64) erts_no_schedulers;
#ifdef ERTS_DIRTY_SCHEDULERS
unique_data.r.o.val0_max += (Uint64) erts_no_dirty_cpu_schedulers;
unique_data.r.o.val0_max += (Uint64) erts_no_dirty_io_schedulers;
#endif
bits = erts_fit_in_bits_int64(unique_data.r.o.val0_max);
unique_data.r.o.left_shift = bits;
unique_data.r.o.right_shift = 64 - bits;
unique_data.r.o.mask = (((Uint64) 1) << bits) - 1;
erts_atomic64_init_nob(&unique_data.w.val1, -1);
}
#define ERTS_MAX_UNIQUE_INT_HEAP_SIZE ERTS_UINT64_ARRAY_TO_BIG_MAX_HEAP_SZ(2)
static ERTS_INLINE Eterm
bld_unique_integer_term(Eterm **hpp, Uint *szp,
Uint64 val0, Uint64 val1,
int positive)
{
Uint hsz;
Uint64 unique_val[2];
unique_val[0] = ((Uint64) val0);
unique_val[0] |= ((Uint64) val1) << unique_data.r.o.left_shift;
unique_val[1] = ((Uint64) val1) >> unique_data.r.o.right_shift;
unique_val[1] &= unique_data.r.o.mask;
if (positive) {
unique_val[0]++;
if (unique_val[0] == 0)
unique_val[1]++;
}
else {
ASSERT(MIN_SMALL < 0);
if (unique_val[1] == 0
&& unique_val[0] < ((Uint64) -1*((Sint64) MIN_SMALL))) {
Sint64 s_unique_val = (Sint64) unique_val[0];
s_unique_val += MIN_SMALL;
ASSERT(MIN_SMALL <= s_unique_val && s_unique_val < 0);
if (szp)
*szp = 0;
if (!hpp)
return THE_NON_VALUE;
return make_small((Sint) s_unique_val);
}
if (unique_val[0] < ((Uint64) -1*((Sint64) MIN_SMALL))) {
ASSERT(unique_val[1] != 0);
unique_val[1] -= 1;
}
unique_val[0] += MIN_SMALL;
}
if (!unique_val[1]) {
if (unique_val[0] <= MAX_SMALL) {
if (szp)
*szp = 0;
if (!hpp)
return THE_NON_VALUE;
return make_small((Uint) unique_val[0]);
}
if (szp)
*szp = ERTS_UINT64_HEAP_SIZE(unique_val[0]);
if (!hpp)
return THE_NON_VALUE;
return erts_uint64_to_big(unique_val[0], hpp);
}
else {
Eterm tmp, *tmp_hp, res;
DeclareTmpHeapNoproc(local_heap, 2*ERTS_MAX_UNIQUE_INT_HEAP_SIZE);
UseTmpHeapNoproc(2*ERTS_MAX_UNIQUE_INT_HEAP_SIZE);
tmp_hp = local_heap;
tmp = erts_uint64_array_to_big(&tmp_hp, 0, 2, unique_val);
ASSERT(is_big(tmp));
hsz = big_arity(tmp) + 1;
ASSERT(hsz <= ERTS_MAX_UNIQUE_INT_HEAP_SIZE);
if (szp)
*szp = hsz;
if (!hpp)
res = THE_NON_VALUE;
else {
int hix;
Eterm *hp = *hpp;
tmp_hp = big_val(tmp);
for (hix = 0; hix < hsz; hix++)
hp[hix] = tmp_hp[hix];
*hpp = hp + hsz;
res = make_big(hp);
}
UnUseTmpHeapNoproc(2*ERTS_MAX_UNIQUE_INT_HEAP_SIZE);
return res;
}
}
static ERTS_INLINE Eterm unique_integer_bif(Process *c_p, int positive)
{
ErtsSchedulerData *esdp;
Uint64 thr_id, unique;
Uint hsz;
Eterm *hp;
esdp = erts_proc_sched_data(c_p);
thr_id = (Uint64) esdp->thr_id;
unique = esdp->unique++;
bld_unique_integer_term(NULL, &hsz, thr_id, unique, positive);
hp = hsz ? HAlloc(c_p, hsz) : NULL;
return bld_unique_integer_term(&hp, NULL, thr_id, unique, positive);
}
Uint
erts_raw_unique_integer_heap_size(Uint64 val[ERTS_UNIQUE_INT_RAW_VALUES],
int positive)
{
Uint sz;
bld_unique_integer_term(NULL, &sz, val[0], val[1], positive);
return sz;
}
Eterm
erts_raw_make_unique_integer(Eterm **hpp, Uint64 val[ERTS_UNIQUE_INT_RAW_VALUES],
int positive)
{
return bld_unique_integer_term(hpp, NULL, val[0], val[1], positive);
}
void
erts_raw_get_unique_integer(Uint64 val[ERTS_UNIQUE_INT_RAW_VALUES])
{
ErtsSchedulerData *esdp = erts_get_scheduler_data();
if (esdp) {
val[0] = (Uint64) esdp->thr_id;
val[1] = esdp->unique++;
}
else {
val[0] = (Uint64) 0;
val[1] = (Uint64) erts_atomic64_inc_read_nob(&unique_data.w.val1);
}
}
Sint64
erts_get_min_unique_integer(void)
{
return (Sint64) MIN_SMALL;
}
/* --- Debug --- */
Eterm
erts_debug_make_unique_integer(Process *c_p, Eterm etval0, Eterm etval1)
{
Uint64 val0, val1;
Uint hsz;
Eterm res, *hp, *end_hp;
if (!term_to_Uint64(etval0, &val0))
return THE_NON_VALUE;
if (!term_to_Uint64(etval1, &val1))
return THE_NON_VALUE;
bld_unique_integer_term(NULL, &hsz, val0, val1, 0);
hp = HAlloc(c_p, hsz);
end_hp = hp + hsz;
res = bld_unique_integer_term(&hp, NULL, val0, val1, 0);
if (hp != end_hp)
ERTS_INTERNAL_ERROR("Heap allocation error");
return res;
}
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* Strict Monotonic Counter *
\* */
static struct {
union {
erts_atomic64_t value;
char align__[ERTS_CACHE_LINE_SIZE];
} w;
} raw_unique_monotonic_integer erts_align_attribute(ERTS_CACHE_LINE_SIZE);
#if defined(ARCH_32)
# define ERTS_UNIQUE_MONOTONIC_OFFSET ERTS_SINT64_MIN
#else
# define ERTS_UNIQUE_MONOTONIC_OFFSET MIN_SMALL
#endif
static void
init_unique_monotonic_integer(void)
{
erts_atomic64_init_nob(&raw_unique_monotonic_integer.w.value,
(erts_aint64_t) -1);
}
static ERTS_INLINE Uint64
get_raw_unique_monotonic_integer(void)
{
return (Uint64) erts_atomic64_inc_read_mb(&raw_unique_monotonic_integer.w.value);
}
static ERTS_INLINE Uint
get_unique_monotonic_integer_heap_size(Uint64 raw, int positive)
{
if (positive) {
Uint64 value = raw+1;
return ERTS_UINT64_HEAP_SIZE(value);
}
else {
Sint64 value = ((Sint64) raw) + ERTS_UNIQUE_MONOTONIC_OFFSET;
if (IS_SSMALL(value))
return 0;
#if defined(ARCH_32)
return ERTS_SINT64_HEAP_SIZE(value);
#else
return ERTS_UINT64_HEAP_SIZE((Uint64) value);
#endif
}
}
static ERTS_INLINE Eterm
make_unique_monotonic_integer_value(Eterm *hp, Uint hsz, Uint64 raw, int positive)
{
Eterm res;
#ifdef DEBUG
Eterm *end_hp = hp + hsz;
#endif
if (positive) {
Uint64 value = raw+1;
res = hsz ? erts_uint64_to_big(value, &hp) : make_small(value);
}
else {
Sint64 value = ((Sint64) raw) + ERTS_UNIQUE_MONOTONIC_OFFSET;
if (hsz == 0)
res = make_small(value);
else {
#if defined(ARCH_32)
res = erts_sint64_to_big(value, &hp);
#else
res = erts_uint64_to_big((Uint64) value, &hp);
#endif
}
}
ASSERT(end_hp == hp);
return res;
}
static ERTS_INLINE Eterm
unique_monotonic_integer_bif(Process *c_p, int positive)
{
Uint64 raw;
Uint hsz;
Eterm *hp;
raw = get_raw_unique_monotonic_integer();
hsz = get_unique_monotonic_integer_heap_size(raw, positive);
hp = hsz ? HAlloc(c_p, hsz) : NULL;
return make_unique_monotonic_integer_value(hp, hsz, raw, positive);
}
Sint64
erts_raw_get_unique_monotonic_integer(void)
{
return get_raw_unique_monotonic_integer();
}
Uint
erts_raw_unique_monotonic_integer_heap_size(Sint64 raw, int positive)
{
return get_unique_monotonic_integer_heap_size(raw, positive);
}
Eterm
erts_raw_make_unique_monotonic_integer_value(Eterm **hpp, Sint64 raw, int positive)
{
Uint hsz = get_unique_monotonic_integer_heap_size(raw, positive);
Eterm res = make_unique_monotonic_integer_value(*hpp, hsz, raw, positive);
*hpp += hsz;
return res;
}
Sint64
erts_get_min_unique_monotonic_integer(void)
{
return ERTS_UNIQUE_MONOTONIC_OFFSET;
}
/* --- Debug --- */
int
erts_debug_set_unique_monotonic_integer_state(Eterm et_value)
{
Sint64 value;
if (!term_to_Sint64(et_value, &value)) {
Uint64 uvalue;
if (!term_to_Uint64(et_value, &uvalue))
return 0;
value = (Sint64) uvalue;
}
erts_atomic64_set_mb(&raw_unique_monotonic_integer.w.value,
(erts_aint64_t) value);
return 1;
}
Eterm
erts_debug_get_unique_monotonic_integer_state(Process *c_p)
{
Uint64 value;
Eterm hsz, *hp;
value = (Uint64) erts_atomic64_read_mb(&raw_unique_monotonic_integer.w.value);
if (IS_USMALL(0, value))
return make_small(value);
hsz = ERTS_UINT64_HEAP_SIZE(value);
hp = HAlloc(c_p, hsz);
return erts_uint64_to_big(value, &hp);
}
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* Initilazation *
\* */
void
erts_bif_unique_init(void)
{
init_reference();
init_unique_monotonic_integer();
init_unique_integer();
}
void
erts_sched_bif_unique_init(ErtsSchedulerData *esdp)
{
esdp->unique = (Uint64) 0;
esdp->ref = (Uint64) ref_init_value;
}
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* The BIFs *
\* */
BIF_RETTYPE make_ref_0(BIF_ALIST_0)
{
BIF_RETTYPE res;
Eterm* hp;
ERTS_SMP_LC_ASSERT(ERTS_PROC_LOCK_MAIN & erts_proc_lc_my_proc_locks(BIF_P));
hp = HAlloc(BIF_P, ERTS_REF_THING_SIZE);
res = erts_sched_make_ref_in_buffer(erts_proc_sched_data(BIF_P), hp);
BIF_RET(res);
}
BIF_RETTYPE unique_integer_0(BIF_ALIST_0)
{
BIF_RET(unique_integer_bif(BIF_P, 0));
}
BIF_RETTYPE unique_integer_1(BIF_ALIST_1)
{
Eterm modlist = BIF_ARG_1;
int monotonic = 0;
int positive = 0;
BIF_RETTYPE res;
while (is_list(modlist)) {
Eterm *consp = list_val(modlist);
switch (CAR(consp)) {
case am_monotonic:
monotonic = 1;
break;
case am_positive:
positive = 1;
break;
default:
BIF_ERROR(BIF_P, BADARG);
}
modlist = CDR(consp);
}
if (is_not_nil(modlist))
BIF_ERROR(BIF_P, BADARG);
if (monotonic)
res = unique_monotonic_integer_bif(BIF_P, positive);
else
res = unique_integer_bif(BIF_P, positive);
BIF_RET(res);
}
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