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/*
*
* Copyright 2015 gRPC authors.
*
* 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.
*
*/
#include "src/core/lib/iomgr/executor.h"
#include <string.h>
#include <grpc/support/alloc.h>
#include <grpc/support/cpu.h>
#include <grpc/support/log.h>
#include <grpc/support/sync.h>
#include <grpc/support/thd.h>
#include <grpc/support/tls.h>
#include <grpc/support/useful.h>
#include "src/core/lib/debug/stats.h"
#include "src/core/lib/iomgr/exec_ctx.h"
#include "src/core/lib/support/spinlock.h"
#define MAX_DEPTH 2
typedef struct {
gpr_mu mu;
gpr_cv cv;
grpc_closure_list elems;
size_t depth;
bool shutdown;
bool queued_long_job;
gpr_thd_id id;
} thread_state;
static thread_state *g_thread_state;
static size_t g_max_threads;
static gpr_atm g_cur_threads;
static gpr_spinlock g_adding_thread_lock = GPR_SPINLOCK_STATIC_INITIALIZER;
GPR_TLS_DECL(g_this_thread_state);
static grpc_tracer_flag executor_trace =
GRPC_TRACER_INITIALIZER(false, "executor");
static void executor_thread(void *arg);
static size_t run_closures(grpc_exec_ctx *exec_ctx, grpc_closure_list list) {
size_t n = 0;
grpc_closure *c = list.head;
while (c != NULL) {
grpc_closure *next = c->next_data.next;
grpc_error *error = c->error_data.error;
if (GRPC_TRACER_ON(executor_trace)) {
#ifndef NDEBUG
gpr_log(GPR_DEBUG, "EXECUTOR: run %p [created by %s:%d]", c,
c->file_created, c->line_created);
#else
gpr_log(GPR_DEBUG, "EXECUTOR: run %p", c);
#endif
}
#ifndef NDEBUG
c->scheduled = false;
#endif
c->cb(exec_ctx, c->cb_arg, error);
GRPC_ERROR_UNREF(error);
c = next;
n++;
grpc_exec_ctx_flush(exec_ctx);
}
return n;
}
bool grpc_executor_is_threaded() {
return gpr_atm_no_barrier_load(&g_cur_threads) > 0;
}
void grpc_executor_set_threading(grpc_exec_ctx *exec_ctx, bool threading) {
gpr_atm cur_threads = gpr_atm_no_barrier_load(&g_cur_threads);
if (threading) {
if (cur_threads > 0) return;
g_max_threads = GPR_MAX(1, 2 * gpr_cpu_num_cores());
gpr_atm_no_barrier_store(&g_cur_threads, 1);
gpr_tls_init(&g_this_thread_state);
g_thread_state =
(thread_state *)gpr_zalloc(sizeof(thread_state) * g_max_threads);
for (size_t i = 0; i < g_max_threads; i++) {
gpr_mu_init(&g_thread_state[i].mu);
gpr_cv_init(&g_thread_state[i].cv);
g_thread_state[i].elems = GRPC_CLOSURE_LIST_INIT;
}
gpr_thd_options opt = gpr_thd_options_default();
gpr_thd_options_set_joinable(&opt);
gpr_thd_new(&g_thread_state[0].id, executor_thread, &g_thread_state[0],
&opt);
} else {
if (cur_threads == 0) return;
for (size_t i = 0; i < g_max_threads; i++) {
gpr_mu_lock(&g_thread_state[i].mu);
g_thread_state[i].shutdown = true;
gpr_cv_signal(&g_thread_state[i].cv);
gpr_mu_unlock(&g_thread_state[i].mu);
}
/* ensure no thread is adding a new thread... once this is past, then
no thread will try to add a new one either (since shutdown is true) */
gpr_spinlock_lock(&g_adding_thread_lock);
gpr_spinlock_unlock(&g_adding_thread_lock);
for (gpr_atm i = 0; i < g_cur_threads; i++) {
gpr_thd_join(g_thread_state[i].id);
}
gpr_atm_no_barrier_store(&g_cur_threads, 0);
for (size_t i = 0; i < g_max_threads; i++) {
gpr_mu_destroy(&g_thread_state[i].mu);
gpr_cv_destroy(&g_thread_state[i].cv);
run_closures(exec_ctx, g_thread_state[i].elems);
}
gpr_free(g_thread_state);
gpr_tls_destroy(&g_this_thread_state);
}
}
void grpc_executor_init(grpc_exec_ctx *exec_ctx) {
grpc_register_tracer(&executor_trace);
gpr_atm_no_barrier_store(&g_cur_threads, 0);
grpc_executor_set_threading(exec_ctx, true);
}
void grpc_executor_shutdown(grpc_exec_ctx *exec_ctx) {
grpc_executor_set_threading(exec_ctx, false);
}
static void executor_thread(void *arg) {
thread_state *ts = (thread_state *)arg;
gpr_tls_set(&g_this_thread_state, (intptr_t)ts);
grpc_exec_ctx exec_ctx =
GRPC_EXEC_CTX_INITIALIZER(0, grpc_never_ready_to_finish, NULL);
size_t subtract_depth = 0;
for (;;) {
if (GRPC_TRACER_ON(executor_trace)) {
gpr_log(GPR_DEBUG, "EXECUTOR[%d]: step (sub_depth=%" PRIdPTR ")",
(int)(ts - g_thread_state), subtract_depth);
}
gpr_mu_lock(&ts->mu);
ts->depth -= subtract_depth;
while (grpc_closure_list_empty(ts->elems) && !ts->shutdown) {
ts->queued_long_job = false;
gpr_cv_wait(&ts->cv, &ts->mu, gpr_inf_future(GPR_CLOCK_REALTIME));
}
if (ts->shutdown) {
if (GRPC_TRACER_ON(executor_trace)) {
gpr_log(GPR_DEBUG, "EXECUTOR[%d]: shutdown",
(int)(ts - g_thread_state));
}
gpr_mu_unlock(&ts->mu);
break;
}
GRPC_STATS_INC_EXECUTOR_QUEUE_DRAINED(&exec_ctx);
grpc_closure_list exec = ts->elems;
ts->elems = GRPC_CLOSURE_LIST_INIT;
gpr_mu_unlock(&ts->mu);
if (GRPC_TRACER_ON(executor_trace)) {
gpr_log(GPR_DEBUG, "EXECUTOR[%d]: execute", (int)(ts - g_thread_state));
}
grpc_exec_ctx_invalidate_now(&exec_ctx);
subtract_depth = run_closures(&exec_ctx, exec);
}
grpc_exec_ctx_finish(&exec_ctx);
}
static void executor_push(grpc_exec_ctx *exec_ctx, grpc_closure *closure,
grpc_error *error, bool is_short) {
bool retry_push;
if (is_short) {
GRPC_STATS_INC_EXECUTOR_SCHEDULED_SHORT_ITEMS(exec_ctx);
} else {
GRPC_STATS_INC_EXECUTOR_SCHEDULED_LONG_ITEMS(exec_ctx);
}
do {
retry_push = false;
size_t cur_thread_count = (size_t)gpr_atm_no_barrier_load(&g_cur_threads);
if (cur_thread_count == 0) {
if (GRPC_TRACER_ON(executor_trace)) {
#ifndef NDEBUG
gpr_log(GPR_DEBUG, "EXECUTOR: schedule %p (created %s:%d) inline",
closure, closure->file_created, closure->line_created);
#else
gpr_log(GPR_DEBUG, "EXECUTOR: schedule %p inline", closure);
#endif
}
grpc_closure_list_append(&exec_ctx->closure_list, closure, error);
return;
}
thread_state *ts = (thread_state *)gpr_tls_get(&g_this_thread_state);
if (ts == NULL) {
ts = &g_thread_state[GPR_HASH_POINTER(exec_ctx, cur_thread_count)];
} else {
GRPC_STATS_INC_EXECUTOR_SCHEDULED_TO_SELF(exec_ctx);
}
thread_state *orig_ts = ts;
bool try_new_thread;
for (;;) {
if (GRPC_TRACER_ON(executor_trace)) {
#ifndef NDEBUG
gpr_log(
GPR_DEBUG,
"EXECUTOR: try to schedule %p (%s) (created %s:%d) to thread %d",
closure, is_short ? "short" : "long", closure->file_created,
closure->line_created, (int)(ts - g_thread_state));
#else
gpr_log(GPR_DEBUG, "EXECUTOR: try to schedule %p (%s) to thread %d",
closure, is_short ? "short" : "long",
(int)(ts - g_thread_state));
#endif
}
gpr_mu_lock(&ts->mu);
if (ts->queued_long_job) {
// if there's a long job queued, we never queue anything else to this
// queue (since long jobs can take 'infinite' time and we need to
// guarantee no starvation)
// ... spin through queues and try again
gpr_mu_unlock(&ts->mu);
size_t idx = (size_t)(ts - g_thread_state);
ts = &g_thread_state[(idx + 1) % cur_thread_count];
if (ts == orig_ts) {
retry_push = true;
try_new_thread = true;
break;
}
continue;
}
if (grpc_closure_list_empty(ts->elems)) {
GRPC_STATS_INC_EXECUTOR_WAKEUP_INITIATED(exec_ctx);
gpr_cv_signal(&ts->cv);
}
grpc_closure_list_append(&ts->elems, closure, error);
ts->depth++;
try_new_thread = ts->depth > MAX_DEPTH &&
cur_thread_count < g_max_threads && !ts->shutdown;
if (!is_short) ts->queued_long_job = true;
gpr_mu_unlock(&ts->mu);
break;
}
if (try_new_thread && gpr_spinlock_trylock(&g_adding_thread_lock)) {
cur_thread_count = (size_t)gpr_atm_no_barrier_load(&g_cur_threads);
if (cur_thread_count < g_max_threads) {
gpr_atm_no_barrier_store(&g_cur_threads, cur_thread_count + 1);
gpr_thd_options opt = gpr_thd_options_default();
gpr_thd_options_set_joinable(&opt);
gpr_thd_new(&g_thread_state[cur_thread_count].id, executor_thread,
&g_thread_state[cur_thread_count], &opt);
}
gpr_spinlock_unlock(&g_adding_thread_lock);
}
if (retry_push) {
GRPC_STATS_INC_EXECUTOR_PUSH_RETRIES(exec_ctx);
}
} while (retry_push);
}
static void executor_push_short(grpc_exec_ctx *exec_ctx, grpc_closure *closure,
grpc_error *error) {
executor_push(exec_ctx, closure, error, true);
}
static void executor_push_long(grpc_exec_ctx *exec_ctx, grpc_closure *closure,
grpc_error *error) {
executor_push(exec_ctx, closure, error, false);
}
static const grpc_closure_scheduler_vtable executor_vtable_short = {
executor_push_short, executor_push_short, "executor"};
static grpc_closure_scheduler executor_scheduler_short = {
&executor_vtable_short};
static const grpc_closure_scheduler_vtable executor_vtable_long = {
executor_push_long, executor_push_long, "executor"};
static grpc_closure_scheduler executor_scheduler_long = {&executor_vtable_long};
grpc_closure_scheduler *grpc_executor_scheduler(
grpc_executor_job_length length) {
return length == GRPC_EXECUTOR_SHORT ? &executor_scheduler_short
: &executor_scheduler_long;
}
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