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|
/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2018. 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%
*/
/*
* Purpose: Implement persistent term storage.
*/
#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"
#include "erl_driver.h"
#include "bif.h"
#include "erl_map.h"
#include "erl_binary.h"
/*
* Parameters for the hash table.
*/
#define INITIAL_SIZE 8
#define LOAD_FACTOR ((Uint)50)
#define MUST_GROW(t) (((Uint)100) * t->num_entries >= LOAD_FACTOR * t->allocated)
#define MUST_SHRINK(t) (((Uint)200) * t->num_entries <= LOAD_FACTOR * t->allocated && \
t->allocated > INITIAL_SIZE)
typedef struct hash_table {
Uint allocated;
Uint num_entries;
Uint mask;
Uint first_to_delete;
Uint num_to_delete;
erts_atomic_t refc;
struct hash_table* delete_next;
ErtsThrPrgrLaterOp thr_prog_op;
Eterm term[1];
} HashTable;
typedef struct trap_data {
HashTable* table;
Uint idx;
Uint remaining;
Uint memory; /* Used by info/0 to count used memory */
} TrapData;
typedef enum {
ERTS_PERSISTENT_TERM_CPY_PLACE_START,
ERTS_PERSISTENT_TERM_CPY_PLACE_1,
ERTS_PERSISTENT_TERM_CPY_PLACE_2,
ERTS_PERSISTENT_TERM_CPY_PLACE_3
} ErtsPersistentTermCpyTableLocation;
typedef enum {
ERTS_PERSISTENT_TERM_CPY_NO_REHASH = 0,
ERTS_PERSISTENT_TERM_CPY_REHASH = 1,
ERTS_PERSISTENT_TERM_CPY_TEMP = 2
} ErtsPersistentTermCpyTableType;
typedef struct {
HashTable* old_table; /* in param */
Uint new_size; /* in param */
ErtsPersistentTermCpyTableType copy_type; /* in param */
Uint max_iterations; /* in param */
ErtsPersistentTermCpyTableLocation location; /* in/out param */
Uint iterations_done; /* in/out param */
Uint total_iterations_done; /* in/out param */
HashTable* new_table; /* out param */
} ErtsPersistentTermCpyTableCtx;
typedef enum {
PUT2_TRAP_LOCATION_NEW_KEY,
PUT2_TRAP_LOCATION_REPLACE_VALUE
} ErtsPersistentTermPut2TrapLocation;
typedef struct {
ErtsPersistentTermPut2TrapLocation trap_location;
Eterm key;
Eterm term;
Uint entry_index;
HashTable* hash_table;
Eterm heap[3];
Eterm tuple;
ErtsPersistentTermCpyTableCtx cpy_ctx;
} ErtsPersistentTermPut2Context;
typedef enum {
ERASE1_TRAP_LOCATION_TMP_COPY,
ERASE1_TRAP_LOCATION_FINAL_COPY
} ErtsPersistentTermErase1TrapLocation;
typedef struct {
ErtsPersistentTermErase1TrapLocation trap_location;
Eterm key;
HashTable* old_table;
HashTable* new_table;
Uint entry_index;
Eterm old_term;
HashTable* tmp_table;
ErtsPersistentTermCpyTableCtx cpy_ctx;
} ErtsPersistentTermErase1Context;
/*
* Declarations of local functions.
*/
static HashTable* create_initial_table(void);
static Uint lookup(HashTable* hash_table, Eterm key);
static HashTable* copy_table(ErtsPersistentTermCpyTableCtx* ctx);
static int try_seize_update_permission(Process* c_p);
static void release_update_permission(int release_updater);
static void table_updater(void* table);
static void table_deleter(void* hash_table);
static void dec_table_refc(Process* c_p, HashTable* old_table);
static void delete_table(Process* c_p, HashTable* table);
static void mark_for_deletion(HashTable* hash_table, Uint entry_index);
static ErtsLiteralArea* term_to_area(Eterm tuple);
static void suspend_updater(Process* c_p);
static Eterm do_get_all(Process* c_p, TrapData* trap_data, Eterm res);
static Eterm do_info(Process* c_p, TrapData* trap_data);
static void append_to_delete_queue(HashTable* table);
static HashTable* next_to_delete(void);
static Eterm alloc_trap_data(Process* c_p);
static int cleanup_trap_data(Binary *bp);
/*
* Traps
*/
static Export persistent_term_get_all_export;
static BIF_RETTYPE persistent_term_get_all_trap(BIF_ALIST_2);
static Export persistent_term_info_export;
static BIF_RETTYPE persistent_term_info_trap(BIF_ALIST_1);
/*
* Pointer to the current hash table.
*/
static erts_atomic_t the_hash_table;
/*
* Queue of processes waiting to update the hash table.
*/
struct update_queue_item {
Process *p;
struct update_queue_item* next;
};
static erts_mtx_t update_table_permission_mtx;
static struct update_queue_item* update_queue = NULL;
static Process* updater_process = NULL;
/* Protected by update_table_permission_mtx */
static ErtsThrPrgrLaterOp thr_prog_op;
/*
* Queue of hash tables to be deleted.
*/
static erts_mtx_t delete_queue_mtx;
static HashTable* delete_queue_head = NULL;
static HashTable** delete_queue_tail = &delete_queue_head;
/*
* The following variables are only used during crash dumping. They
* are initialized by erts_init_persistent_dumping().
*/
ErtsLiteralArea** erts_persistent_areas;
Uint erts_num_persistent_areas;
void erts_init_bif_persistent_term(void)
{
HashTable* hash_table;
/*
* Initialize the mutex protecting updates.
*/
erts_mtx_init(&update_table_permission_mtx,
"update_persistent_term_permission",
NIL,
ERTS_LOCK_FLAGS_PROPERTY_STATIC |
ERTS_LOCK_FLAGS_CATEGORY_GENERIC);
/*
* Initialize delete queue.
*/
erts_mtx_init(&delete_queue_mtx,
"persistent_term_delete_permission",
NIL,
ERTS_LOCK_FLAGS_PROPERTY_STATIC |
ERTS_LOCK_FLAGS_CATEGORY_GENERIC);
/*
* Allocate a small initial hash table.
*/
hash_table = create_initial_table();
erts_atomic_init_nob(&the_hash_table, (erts_aint_t)hash_table);
/*
* Initialize export entry for traps
*/
erts_init_trap_export(&persistent_term_get_all_export,
am_persistent_term, am_get_all_trap, 2,
&persistent_term_get_all_trap);
erts_init_trap_export(&persistent_term_info_export,
am_persistent_term, am_info_trap, 1,
&persistent_term_info_trap);
}
/*
* Macro used for trapping in persistent_term_put_2 and
* persistent_term_erase_1
*/
#define TRAPPING_COPY_TABLE(TABLE_DEST, OLD_TABLE, NEW_SIZE, COPY_TYPE, LOC_NAME, TRAP_CODE) \
do { \
ctx->cpy_ctx = (ErtsPersistentTermCpyTableCtx){ \
.old_table = OLD_TABLE, \
.new_size = NEW_SIZE, \
.copy_type = COPY_TYPE, \
.location = ERTS_PERSISTENT_TERM_CPY_PLACE_START \
}; \
L_ ## LOC_NAME: \
ctx->cpy_ctx.max_iterations = MAX(1, max_iterations); \
TABLE_DEST = copy_table(&ctx->cpy_ctx); \
iterations_until_trap -= ctx->cpy_ctx.total_iterations_done; \
if (TABLE_DEST == NULL) { \
ctx->trap_location = LOC_NAME; \
erts_set_gc_state(BIF_P, 0); \
BUMP_ALL_REDS(BIF_P); \
TRAP_CODE; \
} \
} while (0)
static int persistent_term_put_2_ctx_bin_dtor(Binary *context_bin)
{
ErtsPersistentTermPut2Context* ctx = ERTS_MAGIC_BIN_DATA(context_bin);
if (ctx->cpy_ctx.new_table != NULL) {
erts_free(ERTS_ALC_T_PERSISTENT_TERM, ctx->cpy_ctx.new_table);
release_update_permission(0);
}
return 1;
}
/*
* A linear congruential generator that is used in the debug emulator
* to trap after a random number of iterations in
* persistent_term_put_2 and persistent_term_erase_1.
*
* https://en.wikipedia.org/wiki/Linear_congruential_generator
*/
#define GET_SMALL_RANDOM_INT(SEED) \
(1103515245 * (SEED) + 12345) % 227
BIF_RETTYPE persistent_term_put_2(BIF_ALIST_2)
{
static const Uint ITERATIONS_PER_RED = 32;
ErtsPersistentTermPut2Context* ctx;
Eterm state_mref = THE_NON_VALUE;
long iterations_until_trap;
long max_iterations;
#define PUT_TRAP_CODE \
BIF_TRAP2(bif_export[BIF_persistent_term_put_2], BIF_P, state_mref, BIF_ARG_2)
#define TRAPPING_COPY_TABLE_PUT(TABLE_DEST, OLD_TABLE, NEW_SIZE, COPY_TYPE, LOC_NAME) \
TRAPPING_COPY_TABLE(TABLE_DEST, OLD_TABLE, NEW_SIZE, COPY_TYPE, LOC_NAME, PUT_TRAP_CODE)
#ifdef DEBUG
(void)ITERATIONS_PER_RED;
iterations_until_trap = max_iterations =
GET_SMALL_RANDOM_INT(ERTS_BIF_REDS_LEFT(BIF_P) + (Uint)&ctx);
#else
iterations_until_trap = max_iterations =
ITERATIONS_PER_RED * ERTS_BIF_REDS_LEFT(BIF_P);
#endif
if (is_internal_magic_ref(BIF_ARG_1) &&
(ERTS_MAGIC_BIN_DESTRUCTOR(erts_magic_ref2bin(BIF_ARG_1)) ==
persistent_term_put_2_ctx_bin_dtor)) {
/* Restore state after a trap */
Binary* state_bin;
state_mref = BIF_ARG_1;
state_bin = erts_magic_ref2bin(state_mref);
ctx = ERTS_MAGIC_BIN_DATA(state_bin);
ASSERT(BIF_P->flags & F_DISABLE_GC);
erts_set_gc_state(BIF_P, 1);
switch (ctx->trap_location) {
case PUT2_TRAP_LOCATION_NEW_KEY:
goto L_PUT2_TRAP_LOCATION_NEW_KEY;
case PUT2_TRAP_LOCATION_REPLACE_VALUE:
goto L_PUT2_TRAP_LOCATION_REPLACE_VALUE;
}
} else {
/* Save state in magic bin in case trapping is necessary */
Eterm* hp;
Binary* state_bin = erts_create_magic_binary(sizeof(ErtsPersistentTermPut2Context),
persistent_term_put_2_ctx_bin_dtor);
hp = HAlloc(BIF_P, ERTS_MAGIC_REF_THING_SIZE);
state_mref = erts_mk_magic_ref(&hp, &MSO(BIF_P), state_bin);
ctx = ERTS_MAGIC_BIN_DATA(state_bin);
/*
* IMPORTANT: The following field is used to detect if
* persistent_term_put_2_ctx_bin_dtor needs to free memory
*/
ctx->cpy_ctx.new_table = NULL;
}
if (!try_seize_update_permission(BIF_P)) {
ERTS_BIF_YIELD2(bif_export[BIF_persistent_term_put_2],
BIF_P, BIF_ARG_1, BIF_ARG_2);
}
ctx->hash_table = (HashTable *) erts_atomic_read_nob(&the_hash_table);
ctx->key = BIF_ARG_1;
ctx->term = BIF_ARG_2;
ctx->entry_index = lookup(ctx->hash_table, ctx->key);
ctx->heap[0] = make_arityval(2);
ctx->heap[1] = ctx->key;
ctx->heap[2] = ctx->term;
ctx->tuple = make_tuple(ctx->heap);
if (is_nil(ctx->hash_table->term[ctx->entry_index])) {
Uint new_size = ctx->hash_table->allocated;
if (MUST_GROW(ctx->hash_table)) {
new_size *= 2;
}
TRAPPING_COPY_TABLE_PUT(ctx->hash_table,
ctx->hash_table,
new_size,
ERTS_PERSISTENT_TERM_CPY_NO_REHASH,
PUT2_TRAP_LOCATION_NEW_KEY);
ctx->entry_index = lookup(ctx->hash_table, ctx->key);
ctx->hash_table->num_entries++;
} else {
Eterm tuple = ctx->hash_table->term[ctx->entry_index];
Eterm old_term;
ASSERT(is_tuple_arity(tuple, 2));
old_term = boxed_val(tuple)[2];
if (EQ(ctx->term, old_term)) {
/* Same value. No need to update anything. */
release_update_permission(0);
BIF_RET(am_ok);
} else {
/* Mark the old term for deletion. */
mark_for_deletion(ctx->hash_table, ctx->entry_index);
TRAPPING_COPY_TABLE_PUT(ctx->hash_table,
ctx->hash_table,
ctx->hash_table->allocated,
ERTS_PERSISTENT_TERM_CPY_NO_REHASH,
PUT2_TRAP_LOCATION_REPLACE_VALUE);
}
}
{
Uint term_size;
Uint lit_area_size;
ErlOffHeap code_off_heap;
ErtsLiteralArea* literal_area;
erts_shcopy_t info;
Eterm* ptr;
/*
* Preserve internal sharing in the term by using the
* sharing-preserving functions. However, literals must
* be copied in case the module holding them are unloaded.
*/
INITIALIZE_SHCOPY(info);
info.copy_literals = 1;
term_size = copy_shared_calculate(ctx->tuple, &info);
ERTS_INIT_OFF_HEAP(&code_off_heap);
lit_area_size = ERTS_LITERAL_AREA_ALLOC_SIZE(term_size);
literal_area = erts_alloc(ERTS_ALC_T_LITERAL, lit_area_size);
ptr = &literal_area->start[0];
literal_area->end = ptr + term_size;
ctx->tuple = copy_shared_perform(ctx->tuple, term_size, &info, &ptr, &code_off_heap);
ASSERT(tuple_val(ctx->tuple) == literal_area->start);
literal_area->off_heap = code_off_heap.first;
DESTROY_SHCOPY(info);
erts_set_literal_tag(&ctx->tuple, literal_area->start, term_size);
ctx->hash_table->term[ctx->entry_index] = ctx->tuple;
erts_schedule_thr_prgr_later_op(table_updater, ctx->hash_table, &thr_prog_op);
suspend_updater(BIF_P);
}
BUMP_REDS(BIF_P, (max_iterations - iterations_until_trap) / ITERATIONS_PER_RED);
ERTS_BIF_YIELD_RETURN(BIF_P, am_ok);
}
BIF_RETTYPE persistent_term_get_0(BIF_ALIST_0)
{
HashTable* hash_table = (HashTable *) erts_atomic_read_nob(&the_hash_table);
TrapData* trap_data;
Eterm res = NIL;
Eterm magic_ref;
Binary* mbp;
magic_ref = alloc_trap_data(BIF_P);
mbp = erts_magic_ref2bin(magic_ref);
trap_data = ERTS_MAGIC_BIN_DATA(mbp);
trap_data->table = hash_table;
trap_data->idx = 0;
trap_data->remaining = hash_table->num_entries;
res = do_get_all(BIF_P, trap_data, res);
if (trap_data->remaining == 0) {
BUMP_REDS(BIF_P, hash_table->num_entries);
trap_data->table = NULL; /* Prevent refc decrement */
BIF_RET(res);
} else {
/*
* Increment the ref counter to prevent an update operation (by put/2
* or erase/1) to delete this hash table.
*/
erts_atomic_inc_nob(&hash_table->refc);
BUMP_ALL_REDS(BIF_P);
BIF_TRAP2(&persistent_term_get_all_export, BIF_P, magic_ref, res);
}
}
BIF_RETTYPE persistent_term_get_1(BIF_ALIST_1)
{
Eterm key = BIF_ARG_1;
HashTable* hash_table = (HashTable *) erts_atomic_read_nob(&the_hash_table);
Uint entry_index;
Eterm term;
entry_index = lookup(hash_table, key);
term = hash_table->term[entry_index];
if (is_boxed(term)) {
ASSERT(is_tuple_arity(term, 2));
BIF_RET(tuple_val(term)[2]);
}
BIF_ERROR(BIF_P, BADARG);
}
BIF_RETTYPE persistent_term_get_2(BIF_ALIST_2)
{
Eterm key = BIF_ARG_1;
Eterm result = BIF_ARG_2;
HashTable* hash_table = (HashTable *) erts_atomic_read_nob(&the_hash_table);
Uint entry_index;
Eterm term;
entry_index = lookup(hash_table, key);
term = hash_table->term[entry_index];
if (is_boxed(term)) {
ASSERT(is_tuple_arity(term, 2));
result = tuple_val(term)[2];
}
BIF_RET(result);
}
static int persistent_term_erase_1_ctx_bin_dtor(Binary *context_bin)
{
ErtsPersistentTermErase1Context* ctx = ERTS_MAGIC_BIN_DATA(context_bin);
if (ctx->cpy_ctx.new_table != NULL) {
if (ctx->cpy_ctx.copy_type == ERTS_PERSISTENT_TERM_CPY_TEMP) {
erts_free(ERTS_ALC_T_PERSISTENT_TERM_TMP, ctx->cpy_ctx.new_table);
} else {
erts_free(ERTS_ALC_T_PERSISTENT_TERM, ctx->cpy_ctx.new_table);
}
if (ctx->tmp_table != NULL) {
erts_free(ERTS_ALC_T_PERSISTENT_TERM_TMP, ctx->tmp_table);
}
release_update_permission(0);
}
return 1;
}
BIF_RETTYPE persistent_term_erase_1(BIF_ALIST_1)
{
static const Uint ITERATIONS_PER_RED = 32;
ErtsPersistentTermErase1Context* ctx;
Eterm state_mref = THE_NON_VALUE;
long iterations_until_trap;
long max_iterations;
#ifdef DEBUG
(void)ITERATIONS_PER_RED;
iterations_until_trap = max_iterations =
GET_SMALL_RANDOM_INT(ERTS_BIF_REDS_LEFT(BIF_P) + (Uint)&ctx);
#else
iterations_until_trap = max_iterations =
ITERATIONS_PER_RED * ERTS_BIF_REDS_LEFT(BIF_P);
#endif
#define ERASE_TRAP_CODE \
BIF_TRAP1(bif_export[BIF_persistent_term_erase_1], BIF_P, state_mref);
#define TRAPPING_COPY_TABLE_ERASE(TABLE_DEST, OLD_TABLE, NEW_SIZE, REHASH, LOC_NAME) \
TRAPPING_COPY_TABLE(TABLE_DEST, OLD_TABLE, NEW_SIZE, REHASH, LOC_NAME, ERASE_TRAP_CODE)
if (is_internal_magic_ref(BIF_ARG_1) &&
(ERTS_MAGIC_BIN_DESTRUCTOR(erts_magic_ref2bin(BIF_ARG_1)) ==
persistent_term_erase_1_ctx_bin_dtor)) {
/* Restore the state after a trap */
Binary* state_bin;
state_mref = BIF_ARG_1;
state_bin = erts_magic_ref2bin(state_mref);
ctx = ERTS_MAGIC_BIN_DATA(state_bin);
ASSERT(BIF_P->flags & F_DISABLE_GC);
erts_set_gc_state(BIF_P, 1);
switch (ctx->trap_location) {
case ERASE1_TRAP_LOCATION_TMP_COPY:
goto L_ERASE1_TRAP_LOCATION_TMP_COPY;
case ERASE1_TRAP_LOCATION_FINAL_COPY:
goto L_ERASE1_TRAP_LOCATION_FINAL_COPY;
}
} else {
/* Save state in magic bin in case trapping is necessary */
Eterm* hp;
Binary* state_bin = erts_create_magic_binary(sizeof(ErtsPersistentTermErase1Context),
persistent_term_erase_1_ctx_bin_dtor);
hp = HAlloc(BIF_P, ERTS_MAGIC_REF_THING_SIZE);
state_mref = erts_mk_magic_ref(&hp, &MSO(BIF_P), state_bin);
ctx = ERTS_MAGIC_BIN_DATA(state_bin);
/*
* IMPORTANT: The following two fields are used to detect if
* persistent_term_erase_1_ctx_bin_dtor needs to free memory
*/
ctx->cpy_ctx.new_table = NULL;
ctx->tmp_table = NULL;
}
if (!try_seize_update_permission(BIF_P)) {
ERTS_BIF_YIELD1(bif_export[BIF_persistent_term_erase_1],
BIF_P, BIF_ARG_1);
}
ctx->key = BIF_ARG_1;
ctx->old_table = (HashTable *) erts_atomic_read_nob(&the_hash_table);
ctx->entry_index = lookup(ctx->old_table, ctx->key);
ctx->old_term = ctx->old_table->term[ctx->entry_index];
if (is_boxed(ctx->old_term)) {
Uint new_size;
/*
* Since we don't use any delete markers, we must rehash
* the table when deleting terms to ensure that all terms
* can still be reached if there are hash collisions.
* We can't rehash in place and it would not be safe to modify
* the old table yet, so we will first need a new
* temporary table copy of the same size as the old one.
*/
ASSERT(is_tuple_arity(ctx->old_term, 2));
TRAPPING_COPY_TABLE_ERASE(ctx->tmp_table,
ctx->old_table,
ctx->old_table->allocated,
ERTS_PERSISTENT_TERM_CPY_TEMP,
ERASE1_TRAP_LOCATION_TMP_COPY);
/*
* Delete the term from the temporary table. Then copy the
* temporary table to a new table, rehashing the entries
* while copying.
*/
ctx->tmp_table->term[ctx->entry_index] = NIL;
ctx->tmp_table->num_entries--;
new_size = ctx->tmp_table->allocated;
if (MUST_SHRINK(ctx->tmp_table)) {
new_size /= 2;
}
TRAPPING_COPY_TABLE_ERASE(ctx->new_table,
ctx->tmp_table,
new_size,
ERTS_PERSISTENT_TERM_CPY_REHASH,
ERASE1_TRAP_LOCATION_FINAL_COPY);
erts_free(ERTS_ALC_T_PERSISTENT_TERM_TMP, ctx->tmp_table);
/*
* IMPORTANT: Memory management depends on that ctx->tmp_table
* is set to NULL on the line below
*/
ctx->tmp_table = NULL;
mark_for_deletion(ctx->old_table, ctx->entry_index);
erts_schedule_thr_prgr_later_op(table_updater, ctx->new_table, &thr_prog_op);
suspend_updater(BIF_P);
BUMP_REDS(BIF_P, (max_iterations - iterations_until_trap) / ITERATIONS_PER_RED);
ERTS_BIF_YIELD_RETURN(BIF_P, am_true);
}
/*
* Key is not present. Nothing to do.
*/
ASSERT(is_nil(ctx->old_term));
release_update_permission(0);
BIF_RET(am_false);
}
BIF_RETTYPE erts_internal_erase_persistent_terms_0(BIF_ALIST_0)
{
HashTable* old_table;
HashTable* new_table;
if (!try_seize_update_permission(BIF_P)) {
ERTS_BIF_YIELD0(bif_export[BIF_erts_internal_erase_persistent_terms_0],
BIF_P);
}
old_table = (HashTable *) erts_atomic_read_nob(&the_hash_table);
old_table->first_to_delete = 0;
old_table->num_to_delete = old_table->allocated;
new_table = create_initial_table();
erts_schedule_thr_prgr_later_op(table_updater, new_table, &thr_prog_op);
suspend_updater(BIF_P);
ERTS_BIF_YIELD_RETURN(BIF_P, am_true);
}
BIF_RETTYPE persistent_term_info_0(BIF_ALIST_0)
{
HashTable* hash_table = (HashTable *) erts_atomic_read_nob(&the_hash_table);
TrapData* trap_data;
Eterm res = NIL;
Eterm magic_ref;
Binary* mbp;
magic_ref = alloc_trap_data(BIF_P);
mbp = erts_magic_ref2bin(magic_ref);
trap_data = ERTS_MAGIC_BIN_DATA(mbp);
trap_data->table = hash_table;
trap_data->idx = 0;
trap_data->remaining = hash_table->num_entries;
trap_data->memory = 0;
res = do_info(BIF_P, trap_data);
if (trap_data->remaining == 0) {
BUMP_REDS(BIF_P, hash_table->num_entries);
trap_data->table = NULL; /* Prevent refc decrement */
BIF_RET(res);
} else {
/*
* Increment the ref counter to prevent an update operation (by put/2
* or erase/1) to delete this hash table.
*/
erts_atomic_inc_nob(&hash_table->refc);
BUMP_ALL_REDS(BIF_P);
BIF_TRAP2(&persistent_term_info_export, BIF_P, magic_ref, res);
}
}
Uint
erts_persistent_term_count(void)
{
HashTable* hash_table = (HashTable *) erts_atomic_read_nob(&the_hash_table);
return hash_table->num_entries;
}
void
erts_init_persistent_dumping(void)
{
HashTable* hash_table = (HashTable *) erts_atomic_read_nob(&the_hash_table);
ErtsLiteralArea** area_p;
Uint i;
/*
* Overwrite the array of Eterms in the current hash table
* with pointers to literal areas.
*/
erts_persistent_areas = (ErtsLiteralArea **) hash_table->term;
erts_num_persistent_areas = hash_table->num_entries;
area_p = erts_persistent_areas;
for (i = 0; i < hash_table->allocated; i++) {
Eterm term = hash_table->term[i];
if (is_boxed(term)) {
*area_p++ = term_to_area(term);
}
}
}
/*
* Local functions.
*/
static HashTable*
create_initial_table(void)
{
HashTable* hash_table;
int i;
hash_table = (HashTable *) erts_alloc(ERTS_ALC_T_PERSISTENT_TERM,
sizeof(HashTable)+sizeof(Eterm) *
(INITIAL_SIZE-1));
hash_table->allocated = INITIAL_SIZE;
hash_table->num_entries = 0;
hash_table->mask = INITIAL_SIZE-1;
hash_table->first_to_delete = 0;
hash_table->num_to_delete = 0;
erts_atomic_init_nob(&hash_table->refc, (erts_aint_t)1);
for (i = 0; i < INITIAL_SIZE; i++) {
hash_table->term[i] = NIL;
}
return hash_table;
}
static BIF_RETTYPE
persistent_term_get_all_trap(BIF_ALIST_2)
{
TrapData* trap_data;
Eterm res = BIF_ARG_2;
Uint bump_reds;
Binary* mbp;
ASSERT(is_list(BIF_ARG_2));
mbp = erts_magic_ref2bin(BIF_ARG_1);
trap_data = ERTS_MAGIC_BIN_DATA(mbp);
bump_reds = trap_data->remaining;
res = do_get_all(BIF_P, trap_data, res);
ASSERT(is_list(res));
if (trap_data->remaining > 0) {
BUMP_ALL_REDS(BIF_P);
BIF_TRAP2(&persistent_term_get_all_export, BIF_P, BIF_ARG_1, res);
} else {
/*
* Decrement ref count (and possibly delete the hash table
* and associated literal area).
*/
dec_table_refc(BIF_P, trap_data->table);
trap_data->table = NULL; /* Prevent refc decrement */
BUMP_REDS(BIF_P, bump_reds);
BIF_RET(res);
}
}
static Eterm
do_get_all(Process* c_p, TrapData* trap_data, Eterm res)
{
HashTable* hash_table;
Uint remaining;
Uint idx;
Uint max_iter;
Uint i;
Eterm* hp;
Uint heap_size;
struct copy_term {
Uint key_size;
Eterm* tuple_ptr;
} *copy_data;
hash_table = trap_data->table;
idx = trap_data->idx;
#if defined(DEBUG) || defined(VALGRIND)
max_iter = 50;
#else
max_iter = ERTS_BIF_REDS_LEFT(c_p);
#endif
remaining = trap_data->remaining < max_iter ?
trap_data->remaining : max_iter;
trap_data->remaining -= remaining;
copy_data = (struct copy_term *) erts_alloc(ERTS_ALC_T_TMP,
remaining *
sizeof(struct copy_term));
i = 0;
heap_size = (2 + 3) * remaining;
while (remaining != 0) {
Eterm term = hash_table->term[idx];
if (is_tuple(term)) {
Uint key_size;
Eterm* tup_val;
ASSERT(is_tuple_arity(term, 2));
tup_val = tuple_val(term);
key_size = size_object(tup_val[1]);
copy_data[i].key_size = key_size;
copy_data[i].tuple_ptr = tup_val;
heap_size += key_size;
i++;
remaining--;
}
idx++;
}
trap_data->idx = idx;
hp = HAlloc(c_p, heap_size);
remaining = i;
for (i = 0; i < remaining; i++) {
Eterm* tuple_ptr;
Uint key_size;
Eterm key;
Eterm tup;
tuple_ptr = copy_data[i].tuple_ptr;
key_size = copy_data[i].key_size;
key = copy_struct(tuple_ptr[1], key_size, &hp, &c_p->off_heap);
tup = TUPLE2(hp, key, tuple_ptr[2]);
hp += 3;
res = CONS(hp, tup, res);
hp += 2;
}
erts_free(ERTS_ALC_T_TMP, copy_data);
return res;
}
static BIF_RETTYPE
persistent_term_info_trap(BIF_ALIST_1)
{
TrapData* trap_data = (TrapData *) BIF_ARG_1;
Eterm res;
Uint bump_reds;
Binary* mbp;
mbp = erts_magic_ref2bin(BIF_ARG_1);
trap_data = ERTS_MAGIC_BIN_DATA(mbp);
bump_reds = trap_data->remaining;
res = do_info(BIF_P, trap_data);
if (trap_data->remaining > 0) {
ASSERT(res == am_ok);
BUMP_ALL_REDS(BIF_P);
BIF_TRAP1(&persistent_term_info_export, BIF_P, BIF_ARG_1);
} else {
/*
* Decrement ref count (and possibly delete the hash table
* and associated literal area).
*/
dec_table_refc(BIF_P, trap_data->table);
trap_data->table = NULL; /* Prevent refc decrement */
BUMP_REDS(BIF_P, bump_reds);
ASSERT(is_map(res));
BIF_RET(res);
}
}
#define DECL_AM(S) Eterm AM_ ## S = am_atom_put(#S, sizeof(#S) - 1)
static Eterm
do_info(Process* c_p, TrapData* trap_data)
{
HashTable* hash_table;
Uint remaining;
Uint idx;
Uint max_iter;
hash_table = trap_data->table;
idx = trap_data->idx;
#if defined(DEBUG) || defined(VALGRIND)
max_iter = 50;
#else
max_iter = ERTS_BIF_REDS_LEFT(c_p);
#endif
remaining = trap_data->remaining < max_iter ? trap_data->remaining : max_iter;
trap_data->remaining -= remaining;
while (remaining != 0) {
if (is_boxed(hash_table->term[idx])) {
ErtsLiteralArea* area;
area = term_to_area(hash_table->term[idx]);
trap_data->memory += sizeof(ErtsLiteralArea) +
sizeof(Eterm) * (area->end - area->start - 1);
remaining--;
}
idx++;
}
trap_data->idx = idx;
if (trap_data->remaining > 0) {
return am_ok; /* Dummy return value */
} else {
Eterm* hp;
Eterm count_term;
Eterm memory_term;
Eterm res;
Uint memory;
Uint hsz = MAP_SZ(2);
memory = sizeof(HashTable) + (trap_data->table->allocated-1) *
sizeof(Eterm) + trap_data->memory;
(void) erts_bld_uint(NULL, &hsz, hash_table->num_entries);
(void) erts_bld_uint(NULL, &hsz, memory);
hp = HAlloc(c_p, hsz);
count_term = erts_bld_uint(&hp, NULL, hash_table->num_entries);
memory_term = erts_bld_uint(&hp, NULL, memory);
res = MAP2(hp, am_count, count_term, am_memory, memory_term);
return res;
}
}
#undef DECL_AM
static Eterm
alloc_trap_data(Process* c_p)
{
Binary* mbp = erts_create_magic_binary(sizeof(TrapData),
cleanup_trap_data);
Eterm* hp;
hp = HAlloc(c_p, ERTS_MAGIC_REF_THING_SIZE);
return erts_mk_magic_ref(&hp, &MSO(c_p), mbp);
}
static int
cleanup_trap_data(Binary *bp)
{
TrapData* trap_data = ERTS_MAGIC_BIN_DATA(bp);
if (trap_data->table) {
/*
* The process has been killed and is now exiting.
* Decrement the reference counter for the table.
*/
dec_table_refc(NULL, trap_data->table);
}
return 1;
}
static Uint
lookup(HashTable* hash_table, Eterm key)
{
Uint mask = hash_table->mask;
Eterm* table = hash_table->term;
Uint32 idx = make_internal_hash(key, 0);
Eterm term;
do {
idx++;
term = table[idx & mask];
} while (is_boxed(term) && !EQ(key, (tuple_val(term))[1]));
return idx & mask;
}
static HashTable*
copy_table(ErtsPersistentTermCpyTableCtx* ctx)
{
Uint old_size = ctx->old_table->allocated;
Uint i;
ErtsAlcType_t alloc_type;
ctx->total_iterations_done = 0;
switch(ctx->location) {
case ERTS_PERSISTENT_TERM_CPY_PLACE_1: goto L_copy_table_place_1;
case ERTS_PERSISTENT_TERM_CPY_PLACE_2: goto L_copy_table_place_2;
case ERTS_PERSISTENT_TERM_CPY_PLACE_3: goto L_copy_table_place_3;
case ERTS_PERSISTENT_TERM_CPY_PLACE_START:
ctx->iterations_done = 0;
}
if (ctx->copy_type == ERTS_PERSISTENT_TERM_CPY_TEMP) {
alloc_type = ERTS_ALC_T_PERSISTENT_TERM_TMP;
} else {
alloc_type = ERTS_ALC_T_PERSISTENT_TERM;
}
ctx->new_table = (HashTable *) erts_alloc(alloc_type,
sizeof(HashTable) +
sizeof(Eterm) * (ctx->new_size-1));
if (ctx->old_table->allocated == ctx->new_size &&
(ctx->copy_type == ERTS_PERSISTENT_TERM_CPY_NO_REHASH ||
ctx->copy_type == ERTS_PERSISTENT_TERM_CPY_TEMP)) {
/*
* Same size and no key deleted. Make an exact copy of the table.
*/
*ctx->new_table = *ctx->old_table;
L_copy_table_place_1:
for (i = ctx->iterations_done;
i < MIN(ctx->iterations_done + ctx->max_iterations,
ctx->new_size);
i++) {
ctx->new_table->term[i] = ctx->old_table->term[i];
}
ctx->total_iterations_done = (i - ctx->iterations_done);
if (i < ctx->new_size) {
ctx->iterations_done = i;
ctx->location = ERTS_PERSISTENT_TERM_CPY_PLACE_1;
return NULL;
}
ctx->iterations_done = 0;
} else {
/*
* The size of the table has changed or an element has been
* deleted. Must rehash, by inserting all old terms into the
* new (empty) table.
*/
ctx->new_table->allocated = ctx->new_size;
ctx->new_table->num_entries = ctx->old_table->num_entries;
ctx->new_table->mask = ctx->new_size - 1;
L_copy_table_place_2:
for (i = ctx->iterations_done;
i < MIN(ctx->iterations_done + ctx->max_iterations,
ctx->new_size);
i++) {
ctx->new_table->term[i] = NIL;
}
ctx->total_iterations_done = (i - ctx->iterations_done);
ctx->max_iterations -= ctx->total_iterations_done;
if (i < ctx->new_size) {
ctx->iterations_done = i;
ctx->location = ERTS_PERSISTENT_TERM_CPY_PLACE_2;
return NULL;
}
ctx->iterations_done = 0;
L_copy_table_place_3:
for (i = ctx->iterations_done;
i < MIN(ctx->iterations_done + ctx->max_iterations,
old_size);
i++) {
if (is_tuple(ctx->old_table->term[i])) {
Eterm key = tuple_val(ctx->old_table->term[i])[1];
Uint entry_index = lookup(ctx->new_table, key);
ASSERT(is_nil(ctx->new_table->term[entry_index]));
ctx->new_table->term[entry_index] = ctx->old_table->term[i];
}
}
ctx->total_iterations_done += (i - ctx->iterations_done);
if (i < old_size) {
ctx->iterations_done = i;
ctx->location = ERTS_PERSISTENT_TERM_CPY_PLACE_3;
return NULL;
}
ctx->iterations_done = 0;
}
ctx->new_table->first_to_delete = 0;
ctx->new_table->num_to_delete = 0;
erts_atomic_init_nob(&ctx->new_table->refc, (erts_aint_t)1);
{
HashTable* new_table = ctx->new_table;
/*
* IMPORTANT: Memory management depends on that ctx->new_table is
* set to NULL on the line below
*/
ctx->new_table = NULL;
return new_table;
}
}
static void
mark_for_deletion(HashTable* hash_table, Uint entry_index)
{
hash_table->first_to_delete = entry_index;
hash_table->num_to_delete = 1;
}
static ErtsLiteralArea*
term_to_area(Eterm tuple)
{
ASSERT(is_tuple_arity(tuple, 2));
return (ErtsLiteralArea *) (((char *) tuple_val(tuple)) -
offsetof(ErtsLiteralArea, start));
}
static void
table_updater(void* data)
{
HashTable* old_table;
HashTable* new_table;
old_table = (HashTable *) erts_atomic_read_nob(&the_hash_table);
new_table = (HashTable *) data;
ASSERT(new_table->num_to_delete == 0);
erts_atomic_set_nob(&the_hash_table, (erts_aint_t)new_table);
append_to_delete_queue(old_table);
erts_schedule_thr_prgr_later_op(table_deleter,
old_table,
&old_table->thr_prog_op);
release_update_permission(1);
}
static void
table_deleter(void* data)
{
HashTable* old_table = (HashTable *) data;
dec_table_refc(NULL, old_table);
}
static void
dec_table_refc(Process* c_p, HashTable* old_table)
{
erts_aint_t refc = erts_atomic_dec_read_nob(&old_table->refc);
if (refc == 0) {
HashTable* to_delete;
while ((to_delete = next_to_delete()) != NULL) {
delete_table(c_p, to_delete);
}
}
}
static void
delete_table(Process* c_p, HashTable* table)
{
Uint idx = table->first_to_delete;
Uint n = table->num_to_delete;
/*
* There are no longer any references to this hash table.
*
* Any literals pointed for deletion can be queued for
* deletion and the table itself can be deallocated.
*/
#ifdef DEBUG
if (n == 1) {
ASSERT(is_tuple_arity(table->term[idx], 2));
}
#endif
while (n > 0) {
Eterm term = table->term[idx];
if (is_tuple_arity(term, 2)) {
if (is_immed(tuple_val(term)[2])) {
erts_release_literal_area(term_to_area(term));
} else {
erts_queue_release_literals(c_p, term_to_area(term));
}
}
idx++, n--;
}
erts_free(ERTS_ALC_T_PERSISTENT_TERM, table);
}
/*
* Caller *must* yield if this function returns 0.
*/
static int
try_seize_update_permission(Process* c_p)
{
int success;
ASSERT(!erts_thr_progress_is_blocking()); /* to avoid deadlock */
ASSERT(c_p != NULL);
erts_mtx_lock(&update_table_permission_mtx);
ASSERT(updater_process != c_p);
success = (updater_process == NULL);
if (success) {
updater_process = c_p;
} else {
struct update_queue_item* qitem;
qitem = erts_alloc(ERTS_ALC_T_PERSISTENT_LOCK_Q, sizeof(*qitem));
qitem->p = c_p;
erts_proc_inc_refc(c_p);
qitem->next = update_queue;
update_queue = qitem;
erts_suspend(c_p, ERTS_PROC_LOCK_MAIN, NULL);
}
erts_mtx_unlock(&update_table_permission_mtx);
return success;
}
static void
release_update_permission(int release_updater)
{
erts_mtx_lock(&update_table_permission_mtx);
ASSERT(updater_process != NULL);
if (release_updater) {
erts_proc_lock(updater_process, ERTS_PROC_LOCK_STATUS);
if (!ERTS_PROC_IS_EXITING(updater_process)) {
erts_resume(updater_process, ERTS_PROC_LOCK_STATUS);
}
erts_proc_unlock(updater_process, ERTS_PROC_LOCK_STATUS);
}
updater_process = NULL;
while (update_queue != NULL) { /* Unleash the entire herd */
struct update_queue_item* qitem = update_queue;
erts_proc_lock(qitem->p, ERTS_PROC_LOCK_STATUS);
if (!ERTS_PROC_IS_EXITING(qitem->p)) {
erts_resume(qitem->p, ERTS_PROC_LOCK_STATUS);
}
erts_proc_unlock(qitem->p, ERTS_PROC_LOCK_STATUS);
update_queue = qitem->next;
erts_proc_dec_refc(qitem->p);
erts_free(ERTS_ALC_T_PERSISTENT_LOCK_Q, qitem);
}
erts_mtx_unlock(&update_table_permission_mtx);
}
static void
suspend_updater(Process* c_p)
{
#ifdef DEBUG
ASSERT(c_p != NULL);
erts_mtx_lock(&update_table_permission_mtx);
ASSERT(updater_process == c_p);
erts_mtx_unlock(&update_table_permission_mtx);
#endif
erts_suspend(c_p, ERTS_PROC_LOCK_MAIN, NULL);
}
static void
append_to_delete_queue(HashTable* table)
{
erts_mtx_lock(&delete_queue_mtx);
table->delete_next = NULL;
*delete_queue_tail = table;
delete_queue_tail = &table->delete_next;
erts_mtx_unlock(&delete_queue_mtx);
}
static HashTable*
next_to_delete(void)
{
HashTable* table;
erts_mtx_lock(&delete_queue_mtx);
table = delete_queue_head;
if (table) {
if (erts_atomic_read_nob(&table->refc)) {
/*
* This hash table is still referenced. Hash tables
* must be deleted in order, so we return a NULL
* pointer.
*/
table = NULL;
} else {
/*
* Remove the first hash table from the queue.
*/
delete_queue_head = table->delete_next;
if (delete_queue_head == NULL) {
delete_queue_tail = &delete_queue_head;
}
}
}
erts_mtx_unlock(&delete_queue_mtx);
return table;
}
/*
* test/debug functionality follow...
*/
static Uint accessed_literal_areas_size;
static Uint accessed_no_literal_areas;
static ErtsLiteralArea **accessed_literal_areas;
int
erts_debug_have_accessed_literal_area(ErtsLiteralArea *lap)
{
Uint i;
for (i = 0; i < accessed_no_literal_areas; i++) {
if (accessed_literal_areas[i] == lap)
return !0;
}
return 0;
}
void
erts_debug_save_accessed_literal_area(ErtsLiteralArea *lap)
{
if (accessed_no_literal_areas == accessed_literal_areas_size) {
accessed_literal_areas_size += 10;
accessed_literal_areas = erts_realloc(ERTS_ALC_T_TMP,
accessed_literal_areas,
(sizeof(ErtsLiteralArea *)
*accessed_literal_areas_size));
}
accessed_literal_areas[accessed_no_literal_areas++] = lap;
}
static void debug_foreach_off_heap(HashTable *tbl, void (*func)(ErlOffHeap *, void *), void *arg)
{
int i;
for (i = 0; i < tbl->allocated; i++) {
Eterm term = tbl->term[i];
if (is_tuple_arity(term, 2)) {
ErtsLiteralArea *lap = term_to_area(term);
ErlOffHeap oh;
if (!erts_debug_have_accessed_literal_area(lap)) {
ERTS_INIT_OFF_HEAP(&oh);
oh.first = lap->off_heap;
(*func)(&oh, arg);
erts_debug_save_accessed_literal_area(lap);
}
}
}
}
struct debug_la_oh {
void (*func)(ErlOffHeap *, void *);
void *arg;
};
static void debug_handle_table(void *vfap,
ErtsThrPrgrVal val,
void *vtbl)
{
struct debug_la_oh *fap = vfap;
HashTable *tbl = vtbl;
debug_foreach_off_heap(tbl, fap->func, fap->arg);
}
void
erts_debug_foreach_persistent_term_off_heap(void (*func)(ErlOffHeap *, void *), void *arg)
{
HashTable *tbl;
struct debug_la_oh fa;
accessed_no_literal_areas = 0;
accessed_literal_areas_size = 10;
accessed_literal_areas = erts_alloc(ERTS_ALC_T_TMP,
(sizeof(ErtsLiteralArea *)
* accessed_literal_areas_size));
tbl = (HashTable *) erts_atomic_read_nob(&the_hash_table);
debug_foreach_off_heap(tbl, func, arg);
erts_mtx_lock(&delete_queue_mtx);
for (tbl = delete_queue_head; tbl; tbl = tbl->delete_next)
debug_foreach_off_heap(tbl, func, arg);
erts_mtx_unlock(&delete_queue_mtx);
fa.func = func;
fa.arg = arg;
erts_debug_later_op_foreach(table_updater,
debug_handle_table,
(void *) &fa);
erts_debug_later_op_foreach(table_deleter,
debug_handle_table,
(void *) &fa);
erts_debug_foreach_release_literal_area_off_heap(func, arg);
erts_free(ERTS_ALC_T_TMP, accessed_literal_areas);
accessed_no_literal_areas = 0;
accessed_literal_areas_size = 0;
accessed_literal_areas = NULL;
}
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