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bazel / bazel / da75b719e3bd1173ce4f86ba84045e1b472b4a54 / . / third_party / grpc / src / core / client_config / subchannel.c
blob: 0a996a1e8bc8b47ffe82da87bfd18f9c2b81d30c [file] [log] [blame]
/*
*
* Copyright 2015-2016, Google Inc.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following disclaimer
* in the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Google Inc. nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
*/
#include "src/core/client_config/subchannel.h"
#include <string.h>
#include <grpc/support/alloc.h>
#include "src/core/channel/channel_args.h"
#include "src/core/channel/client_channel.h"
#include "src/core/channel/connected_channel.h"
#include "src/core/client_config/initial_connect_string.h"
#include "src/core/iomgr/timer.h"
#include "src/core/profiling/timers.h"
#include "src/core/surface/channel.h"
#include "src/core/transport/connectivity_state.h"
#include "src/core/transport/connectivity_state.h"
#define INTERNAL_REF_BITS 16
#define STRONG_REF_MASK (~(gpr_atm)((1 << INTERNAL_REF_BITS) - 1))
#define GRPC_SUBCHANNEL_MIN_CONNECT_TIMEOUT_SECONDS 20
#define GRPC_SUBCHANNEL_INITIAL_CONNECT_BACKOFF_SECONDS 1
#define GRPC_SUBCHANNEL_RECONNECT_BACKOFF_MULTIPLIER 1.6
#define GRPC_SUBCHANNEL_RECONNECT_MAX_BACKOFF_SECONDS 120
#define GRPC_SUBCHANNEL_RECONNECT_JITTER 0.2
#define GET_CONNECTED_SUBCHANNEL(subchannel, barrier) \
((grpc_connected_subchannel *)(gpr_atm_##barrier##_load( \
&(subchannel)->connected_subchannel)))
typedef struct {
grpc_closure closure;
grpc_subchannel *subchannel;
grpc_connectivity_state connectivity_state;
} state_watcher;
typedef struct external_state_watcher {
grpc_subchannel *subchannel;
grpc_pollset_set *pollset_set;
grpc_closure *notify;
grpc_closure closure;
struct external_state_watcher *next;
struct external_state_watcher *prev;
} external_state_watcher;
struct grpc_subchannel {
grpc_connector *connector;
/** refcount
- lower INTERNAL_REF_BITS bits are for internal references:
these do not keep the subchannel open.
- upper remaining bits are for public references: these do
keep the subchannel open */
gpr_atm ref_pair;
/** non-transport related channel filters */
const grpc_channel_filter **filters;
size_t num_filters;
/** channel arguments */
grpc_channel_args *args;
/** address to connect to */
struct sockaddr *addr;
size_t addr_len;
/** initial string to send to peer */
gpr_slice initial_connect_string;
/** set during connection */
grpc_connect_out_args connecting_result;
/** callback for connection finishing */
grpc_closure connected;
/** pollset_set tracking who's interested in a connection
being setup */
grpc_pollset_set pollset_set;
/** active connection, or null; of type grpc_connected_subchannel */
gpr_atm connected_subchannel;
/** mutex protecting remaining elements */
gpr_mu mu;
/** have we seen a disconnection? */
int disconnected;
/** are we connecting */
int connecting;
/** connectivity state tracking */
grpc_connectivity_state_tracker state_tracker;
external_state_watcher root_external_state_watcher;
/** next connect attempt time */
gpr_timespec next_attempt;
/** amount to backoff each failure */
gpr_timespec backoff_delta;
/** do we have an active alarm? */
int have_alarm;
/** our alarm */
grpc_timer alarm;
/** current random value */
uint32_t random;
};
struct grpc_subchannel_call {
grpc_connected_subchannel *connection;
};
#define SUBCHANNEL_CALL_TO_CALL_STACK(call) ((grpc_call_stack *)((call) + 1))
#define CHANNEL_STACK_FROM_CONNECTION(con) ((grpc_channel_stack *)(con))
#define CALLSTACK_TO_SUBCHANNEL_CALL(callstack) \
(((grpc_subchannel_call *)(callstack)) - 1)
static gpr_timespec compute_connect_deadline(grpc_subchannel *c);
static void subchannel_connected(grpc_exec_ctx *exec_ctx, void *subchannel,
bool iomgr_success);
#ifdef GRPC_STREAM_REFCOUNT_DEBUG
#define REF_REASON reason
#define REF_LOG(name, p) \
gpr_log(file, line, GPR_LOG_SEVERITY_DEBUG, "%s: %p ref %d -> %d %s", \
(name), (p), (p)->refs.count, (p)->refs.count + 1, reason)
#define UNREF_LOG(name, p) \
gpr_log(file, line, GPR_LOG_SEVERITY_DEBUG, "%s: %p unref %d -> %d %s", \
(name), (p), (p)->refs.count, (p)->refs.count - 1, reason)
#define REF_MUTATE_EXTRA_ARGS \
GRPC_SUBCHANNEL_REF_EXTRA_ARGS, const char *purpose
#define REF_MUTATE_PURPOSE(x) , file, line, reason, x
#else
#define REF_REASON ""
#define REF_LOG(name, p) \
do { \
} while (0)
#define UNREF_LOG(name, p) \
do { \
} while (0)
#define REF_MUTATE_EXTRA_ARGS
#define REF_MUTATE_PURPOSE(x)
#endif
/*
* connection implementation
*/
static void connection_destroy(grpc_exec_ctx *exec_ctx, void *arg,
bool success) {
grpc_connected_subchannel *c = arg;
grpc_channel_stack_destroy(exec_ctx, CHANNEL_STACK_FROM_CONNECTION(c));
gpr_free(c);
}
void grpc_connected_subchannel_ref(grpc_connected_subchannel *c
GRPC_SUBCHANNEL_REF_EXTRA_ARGS) {
GRPC_CHANNEL_STACK_REF(CHANNEL_STACK_FROM_CONNECTION(c), REF_REASON);
}
void grpc_connected_subchannel_unref(grpc_exec_ctx *exec_ctx,
grpc_connected_subchannel *c
GRPC_SUBCHANNEL_REF_EXTRA_ARGS) {
GRPC_CHANNEL_STACK_UNREF(exec_ctx, CHANNEL_STACK_FROM_CONNECTION(c),
REF_REASON);
}
/*
* grpc_subchannel implementation
*/
static void subchannel_destroy(grpc_exec_ctx *exec_ctx, void *arg,
bool success) {
grpc_subchannel *c = arg;
gpr_free((void *)c->filters);
grpc_channel_args_destroy(c->args);
gpr_free(c->addr);
gpr_slice_unref(c->initial_connect_string);
grpc_connectivity_state_destroy(exec_ctx, &c->state_tracker);
grpc_connector_unref(exec_ctx, c->connector);
grpc_pollset_set_destroy(&c->pollset_set);
gpr_free(c);
}
static gpr_atm ref_mutate(grpc_subchannel *c, gpr_atm delta,
int barrier REF_MUTATE_EXTRA_ARGS) {
gpr_atm old_val = barrier ? gpr_atm_full_fetch_add(&c->ref_pair, delta)
: gpr_atm_no_barrier_fetch_add(&c->ref_pair, delta);
#ifdef GRPC_STREAM_REFCOUNT_DEBUG
gpr_log(file, line, GPR_LOG_SEVERITY_DEBUG,
"SUBCHANNEL: %p % 12s 0x%08x -> 0x%08x [%s]", c, purpose, old_val,
old_val + delta, reason);
#endif
return old_val;
}
void grpc_subchannel_ref(grpc_subchannel *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) {
gpr_atm old_refs;
old_refs = ref_mutate(c, (1 << INTERNAL_REF_BITS),
0 REF_MUTATE_PURPOSE("STRONG_REF"));
GPR_ASSERT((old_refs & STRONG_REF_MASK) != 0);
}
void grpc_subchannel_weak_ref(grpc_subchannel *c
GRPC_SUBCHANNEL_REF_EXTRA_ARGS) {
gpr_atm old_refs;
old_refs = ref_mutate(c, 1, 0 REF_MUTATE_PURPOSE("WEAK_REF"));
GPR_ASSERT(old_refs != 0);
}
static void disconnect(grpc_exec_ctx *exec_ctx, grpc_subchannel *c) {
grpc_connected_subchannel *con;
gpr_mu_lock(&c->mu);
GPR_ASSERT(!c->disconnected);
c->disconnected = 1;
grpc_connector_shutdown(exec_ctx, c->connector);
con = GET_CONNECTED_SUBCHANNEL(c, no_barrier);
if (con != NULL) {
GRPC_CONNECTED_SUBCHANNEL_UNREF(exec_ctx, con, "connection");
gpr_atm_no_barrier_store(&c->connected_subchannel, 0xdeadbeef);
}
gpr_mu_unlock(&c->mu);
}
void grpc_subchannel_unref(grpc_exec_ctx *exec_ctx,
grpc_subchannel *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) {
gpr_atm old_refs;
old_refs = ref_mutate(c, (gpr_atm)1 - (gpr_atm)(1 << INTERNAL_REF_BITS),
1 REF_MUTATE_PURPOSE("STRONG_UNREF"));
if ((old_refs & STRONG_REF_MASK) == (1 << INTERNAL_REF_BITS)) {
disconnect(exec_ctx, c);
}
GRPC_SUBCHANNEL_WEAK_UNREF(exec_ctx, c, "strong-unref");
}
void grpc_subchannel_weak_unref(grpc_exec_ctx *exec_ctx,
grpc_subchannel *c
GRPC_SUBCHANNEL_REF_EXTRA_ARGS) {
gpr_atm old_refs;
old_refs = ref_mutate(c, -(gpr_atm)1, 1 REF_MUTATE_PURPOSE("WEAK_UNREF"));
if (old_refs == 1) {
grpc_exec_ctx_enqueue(exec_ctx, grpc_closure_create(subchannel_destroy, c),
true, NULL);
}
}
static uint32_t random_seed() {
return (uint32_t)(gpr_time_to_millis(gpr_now(GPR_CLOCK_MONOTONIC)));
}
grpc_subchannel *grpc_subchannel_create(grpc_connector *connector,
grpc_subchannel_args *args) {
grpc_subchannel *c = gpr_malloc(sizeof(*c));
memset(c, 0, sizeof(*c));
gpr_atm_no_barrier_store(&c->ref_pair, 1 << INTERNAL_REF_BITS);
c->connector = connector;
grpc_connector_ref(c->connector);
c->num_filters = args->filter_count;
if (c->num_filters > 0) {
c->filters = gpr_malloc(sizeof(grpc_channel_filter *) * c->num_filters);
memcpy((void *)c->filters, args->filters,
sizeof(grpc_channel_filter *) * c->num_filters);
} else {
c->filters = NULL;
}
c->addr = gpr_malloc(args->addr_len);
memcpy(c->addr, args->addr, args->addr_len);
grpc_pollset_set_init(&c->pollset_set);
c->addr_len = args->addr_len;
grpc_set_initial_connect_string(&c->addr, &c->addr_len,
&c->initial_connect_string);
c->args = grpc_channel_args_copy(args->args);
c->random = random_seed();
c->root_external_state_watcher.next = c->root_external_state_watcher.prev =
&c->root_external_state_watcher;
grpc_closure_init(&c->connected, subchannel_connected, c);
grpc_connectivity_state_init(&c->state_tracker, GRPC_CHANNEL_IDLE,
"subchannel");
gpr_mu_init(&c->mu);
return c;
}
static void continue_connect(grpc_exec_ctx *exec_ctx, grpc_subchannel *c) {
grpc_connect_in_args args;
args.interested_parties = &c->pollset_set;
args.addr = c->addr;
args.addr_len = c->addr_len;
args.deadline = compute_connect_deadline(c);
args.channel_args = c->args;
args.initial_connect_string = c->initial_connect_string;
grpc_connectivity_state_set(exec_ctx, &c->state_tracker,
GRPC_CHANNEL_CONNECTING, "state_change");
grpc_connector_connect(exec_ctx, c->connector, &args, &c->connecting_result,
&c->connected);
}
static void start_connect(grpc_exec_ctx *exec_ctx, grpc_subchannel *c) {
c->backoff_delta = gpr_time_from_seconds(
GRPC_SUBCHANNEL_INITIAL_CONNECT_BACKOFF_SECONDS, GPR_TIMESPAN);
c->next_attempt =
gpr_time_add(gpr_now(GPR_CLOCK_MONOTONIC), c->backoff_delta);
continue_connect(exec_ctx, c);
}
grpc_connectivity_state grpc_subchannel_check_connectivity(grpc_subchannel *c) {
grpc_connectivity_state state;
gpr_mu_lock(&c->mu);
state = grpc_connectivity_state_check(&c->state_tracker);
gpr_mu_unlock(&c->mu);
return state;
}
static void on_external_state_watcher_done(grpc_exec_ctx *exec_ctx, void *arg,
bool success) {
external_state_watcher *w = arg;
grpc_closure *follow_up = w->notify;
if (w->pollset_set != NULL) {
grpc_pollset_set_del_pollset_set(exec_ctx, &w->subchannel->pollset_set,
w->pollset_set);
}
gpr_mu_lock(&w->subchannel->mu);
w->next->prev = w->prev;
w->prev->next = w->next;
gpr_mu_unlock(&w->subchannel->mu);
GRPC_SUBCHANNEL_WEAK_UNREF(exec_ctx, w->subchannel, "external_state_watcher");
gpr_free(w);
follow_up->cb(exec_ctx, follow_up->cb_arg, success);
}
void grpc_subchannel_notify_on_state_change(
grpc_exec_ctx *exec_ctx, grpc_subchannel *c,
grpc_pollset_set *interested_parties, grpc_connectivity_state *state,
grpc_closure *notify) {
int do_connect = 0;
external_state_watcher *w;
if (state == NULL) {
gpr_mu_lock(&c->mu);
for (w = c->root_external_state_watcher.next;
w != &c->root_external_state_watcher; w = w->next) {
if (w->notify == notify) {
grpc_connectivity_state_notify_on_state_change(
exec_ctx, &c->state_tracker, NULL, &w->closure);
}
}
gpr_mu_unlock(&c->mu);
} else {
w = gpr_malloc(sizeof(*w));
w->subchannel = c;
w->pollset_set = interested_parties;
w->notify = notify;
grpc_closure_init(&w->closure, on_external_state_watcher_done, w);
if (interested_parties != NULL) {
grpc_pollset_set_add_pollset_set(exec_ctx, &c->pollset_set,
interested_parties);
}
GRPC_SUBCHANNEL_WEAK_REF(c, "external_state_watcher");
gpr_mu_lock(&c->mu);
w->next = &c->root_external_state_watcher;
w->prev = w->next->prev;
w->next->prev = w->prev->next = w;
if (grpc_connectivity_state_notify_on_state_change(
exec_ctx, &c->state_tracker, state, &w->closure)) {
do_connect = 1;
c->connecting = 1;
/* released by connection */
GRPC_SUBCHANNEL_WEAK_REF(c, "connecting");
}
gpr_mu_unlock(&c->mu);
}
if (do_connect) {
start_connect(exec_ctx, c);
}
}
void grpc_connected_subchannel_process_transport_op(
grpc_exec_ctx *exec_ctx, grpc_connected_subchannel *con,
grpc_transport_op *op) {
grpc_channel_stack *channel_stack = CHANNEL_STACK_FROM_CONNECTION(con);
grpc_channel_element *top_elem = grpc_channel_stack_element(channel_stack, 0);
top_elem->filter->start_transport_op(exec_ctx, top_elem, op);
}
static void subchannel_on_child_state_changed(grpc_exec_ctx *exec_ctx, void *p,
bool iomgr_success) {
state_watcher *sw = p;
grpc_subchannel *c = sw->subchannel;
gpr_mu *mu = &c->mu;
gpr_mu_lock(mu);
/* if we failed just leave this closure */
if (iomgr_success) {
if (sw->connectivity_state == GRPC_CHANNEL_TRANSIENT_FAILURE) {
/* any errors on a subchannel ==> we're done, create a new one */
sw->connectivity_state = GRPC_CHANNEL_FATAL_FAILURE;
}
grpc_connectivity_state_set(exec_ctx, &c->state_tracker,
sw->connectivity_state, "reflect_child");
if (sw->connectivity_state != GRPC_CHANNEL_FATAL_FAILURE) {
grpc_connected_subchannel_notify_on_state_change(
exec_ctx, GET_CONNECTED_SUBCHANNEL(c, no_barrier), NULL,
&sw->connectivity_state, &sw->closure);
GRPC_SUBCHANNEL_WEAK_REF(c, "state_watcher");
sw = NULL;
}
}
gpr_mu_unlock(mu);
GRPC_SUBCHANNEL_WEAK_UNREF(exec_ctx, c, "state_watcher");
gpr_free(sw);
}
static void connected_subchannel_state_op(grpc_exec_ctx *exec_ctx,
grpc_connected_subchannel *con,
grpc_pollset_set *interested_parties,
grpc_connectivity_state *state,
grpc_closure *closure) {
grpc_transport_op op;
grpc_channel_element *elem;
memset(&op, 0, sizeof(op));
op.connectivity_state = state;
op.on_connectivity_state_change = closure;
op.bind_pollset_set = interested_parties;
elem = grpc_channel_stack_element(CHANNEL_STACK_FROM_CONNECTION(con), 0);
elem->filter->start_transport_op(exec_ctx, elem, &op);
}
void grpc_connected_subchannel_notify_on_state_change(
grpc_exec_ctx *exec_ctx, grpc_connected_subchannel *con,
grpc_pollset_set *interested_parties, grpc_connectivity_state *state,
grpc_closure *closure) {
connected_subchannel_state_op(exec_ctx, con, interested_parties, state,
closure);
}
void grpc_connected_subchannel_ping(grpc_exec_ctx *exec_ctx,
grpc_connected_subchannel *con,
grpc_closure *closure) {
grpc_transport_op op;
grpc_channel_element *elem;
memset(&op, 0, sizeof(op));
op.send_ping = closure;
elem = grpc_channel_stack_element(CHANNEL_STACK_FROM_CONNECTION(con), 0);
elem->filter->start_transport_op(exec_ctx, elem, &op);
}
static void publish_transport(grpc_exec_ctx *exec_ctx, grpc_subchannel *c) {
size_t channel_stack_size;
grpc_connected_subchannel *con;
grpc_channel_stack *stk;
size_t num_filters;
const grpc_channel_filter **filters;
state_watcher *sw_subchannel;
/* build final filter list */
num_filters = c->num_filters + c->connecting_result.num_filters + 1;
filters = gpr_malloc(sizeof(*filters) * num_filters);
if (c->num_filters > 0) {
memcpy((void *)filters, c->filters, sizeof(*filters) * c->num_filters);
}
memcpy((void *)(filters + c->num_filters), c->connecting_result.filters,
sizeof(*filters) * c->connecting_result.num_filters);
filters[num_filters - 1] = &grpc_connected_channel_filter;
/* construct channel stack */
channel_stack_size = grpc_channel_stack_size(filters, num_filters);
con = gpr_malloc(channel_stack_size);
stk = CHANNEL_STACK_FROM_CONNECTION(con);
grpc_channel_stack_init(exec_ctx, 1, connection_destroy, con, filters,
num_filters, c->connecting_result.channel_args,
"CONNECTED_SUBCHANNEL", stk);
grpc_connected_channel_bind_transport(stk, c->connecting_result.transport);
gpr_free((void *)c->connecting_result.filters);
memset(&c->connecting_result, 0, sizeof(c->connecting_result));
/* initialize state watcher */
sw_subchannel = gpr_malloc(sizeof(*sw_subchannel));
sw_subchannel->subchannel = c;
sw_subchannel->connectivity_state = GRPC_CHANNEL_READY;
grpc_closure_init(&sw_subchannel->closure, subchannel_on_child_state_changed,
sw_subchannel);
gpr_mu_lock(&c->mu);
if (c->disconnected) {
gpr_mu_unlock(&c->mu);
gpr_free(sw_subchannel);
gpr_free((void *)filters);
grpc_channel_stack_destroy(exec_ctx, stk);
gpr_free(con);
GRPC_SUBCHANNEL_WEAK_UNREF(exec_ctx, c, "connecting");
return;
}
/* publish */
/* TODO(ctiller): this full barrier seems to clear up a TSAN failure.
I'd have expected the rel_cas below to be enough, but
seemingly it's not.
Re-evaluate if we really need this. */
gpr_atm_full_barrier();
GPR_ASSERT(gpr_atm_rel_cas(&c->connected_subchannel, 0, (gpr_atm)con));
c->connecting = 0;
/* setup subchannel watching connected subchannel for changes; subchannel ref
for connecting is donated
to the state watcher */
GRPC_SUBCHANNEL_WEAK_REF(c, "state_watcher");
GRPC_SUBCHANNEL_WEAK_UNREF(exec_ctx, c, "connecting");
grpc_connected_subchannel_notify_on_state_change(
exec_ctx, con, &c->pollset_set, &sw_subchannel->connectivity_state,
&sw_subchannel->closure);
/* signal completion */
grpc_connectivity_state_set(exec_ctx, &c->state_tracker, GRPC_CHANNEL_READY,
"connected");
gpr_mu_unlock(&c->mu);
gpr_free((void *)filters);
}
/* Generate a random number between 0 and 1. */
static double generate_uniform_random_number(grpc_subchannel *c) {
c->random = (1103515245 * c->random + 12345) % ((uint32_t)1 << 31);
return c->random / (double)((uint32_t)1 << 31);
}
/* Update backoff_delta and next_attempt in subchannel */
static void update_reconnect_parameters(grpc_subchannel *c) {
size_t i;
int32_t backoff_delta_millis, jitter;
int32_t max_backoff_millis =
GRPC_SUBCHANNEL_RECONNECT_MAX_BACKOFF_SECONDS * 1000;
double jitter_range;
if (c->args) {
for (i = 0; i < c->args->num_args; i++) {
if (0 == strcmp(c->args->args[i].key,
"grpc.testing.fixed_reconnect_backoff")) {
GPR_ASSERT(c->args->args[i].type == GRPC_ARG_INTEGER);
c->next_attempt = gpr_time_add(
gpr_now(GPR_CLOCK_MONOTONIC),
gpr_time_from_millis(c->args->args[i].value.integer, GPR_TIMESPAN));
return;
}
}
}
backoff_delta_millis =
(int32_t)(gpr_time_to_millis(c->backoff_delta) *
GRPC_SUBCHANNEL_RECONNECT_BACKOFF_MULTIPLIER);
if (backoff_delta_millis > max_backoff_millis) {
backoff_delta_millis = max_backoff_millis;
}
c->backoff_delta = gpr_time_from_millis(backoff_delta_millis, GPR_TIMESPAN);
c->next_attempt =
gpr_time_add(gpr_now(GPR_CLOCK_MONOTONIC), c->backoff_delta);
jitter_range = GRPC_SUBCHANNEL_RECONNECT_JITTER * backoff_delta_millis;
jitter =
(int32_t)((2 * generate_uniform_random_number(c) - 1) * jitter_range);
c->next_attempt =
gpr_time_add(c->next_attempt, gpr_time_from_millis(jitter, GPR_TIMESPAN));
}
static void on_alarm(grpc_exec_ctx *exec_ctx, void *arg, bool iomgr_success) {
grpc_subchannel *c = arg;
gpr_mu_lock(&c->mu);
c->have_alarm = 0;
if (c->disconnected) {
iomgr_success = 0;
}
gpr_mu_unlock(&c->mu);
if (iomgr_success) {
update_reconnect_parameters(c);
continue_connect(exec_ctx, c);
} else {
GRPC_SUBCHANNEL_WEAK_UNREF(exec_ctx, c, "connecting");
}
}
static void subchannel_connected(grpc_exec_ctx *exec_ctx, void *arg,
bool iomgr_success) {
grpc_subchannel *c = arg;
if (c->connecting_result.transport != NULL) {
publish_transport(exec_ctx, c);
} else if (c->disconnected) {
GRPC_SUBCHANNEL_WEAK_UNREF(exec_ctx, c, "connecting");
} else {
gpr_timespec now = gpr_now(GPR_CLOCK_MONOTONIC);
gpr_mu_lock(&c->mu);
GPR_ASSERT(!c->have_alarm);
c->have_alarm = 1;
grpc_connectivity_state_set(exec_ctx, &c->state_tracker,
GRPC_CHANNEL_TRANSIENT_FAILURE,
"connect_failed");
grpc_timer_init(exec_ctx, &c->alarm, c->next_attempt, on_alarm, c, now);
gpr_mu_unlock(&c->mu);
}
}
static gpr_timespec compute_connect_deadline(grpc_subchannel *c) {
gpr_timespec current_deadline =
gpr_time_add(c->next_attempt, c->backoff_delta);
gpr_timespec min_deadline = gpr_time_add(
gpr_now(GPR_CLOCK_MONOTONIC),
gpr_time_from_seconds(GRPC_SUBCHANNEL_MIN_CONNECT_TIMEOUT_SECONDS,
GPR_TIMESPAN));
return gpr_time_cmp(current_deadline, min_deadline) > 0 ? current_deadline
: min_deadline;
}
/*
* grpc_subchannel_call implementation
*/
static void subchannel_call_destroy(grpc_exec_ctx *exec_ctx, void *call,
bool success) {
grpc_subchannel_call *c = call;
GPR_TIMER_BEGIN("grpc_subchannel_call_unref.destroy", 0);
grpc_call_stack_destroy(exec_ctx, SUBCHANNEL_CALL_TO_CALL_STACK(c));
GRPC_CONNECTED_SUBCHANNEL_UNREF(exec_ctx, c->connection, "subchannel_call");
gpr_free(c);
GPR_TIMER_END("grpc_subchannel_call_unref.destroy", 0);
}
void grpc_subchannel_call_ref(grpc_subchannel_call *c
GRPC_SUBCHANNEL_REF_EXTRA_ARGS) {
GRPC_CALL_STACK_REF(SUBCHANNEL_CALL_TO_CALL_STACK(c), REF_REASON);
}
void grpc_subchannel_call_unref(grpc_exec_ctx *exec_ctx,
grpc_subchannel_call *c
GRPC_SUBCHANNEL_REF_EXTRA_ARGS) {
GRPC_CALL_STACK_UNREF(exec_ctx, SUBCHANNEL_CALL_TO_CALL_STACK(c), REF_REASON);
}
char *grpc_subchannel_call_get_peer(grpc_exec_ctx *exec_ctx,
grpc_subchannel_call *call) {
grpc_call_stack *call_stack = SUBCHANNEL_CALL_TO_CALL_STACK(call);
grpc_call_element *top_elem = grpc_call_stack_element(call_stack, 0);
return top_elem->filter->get_peer(exec_ctx, top_elem);
}
void grpc_subchannel_call_process_op(grpc_exec_ctx *exec_ctx,
grpc_subchannel_call *call,
grpc_transport_stream_op *op) {
grpc_call_stack *call_stack = SUBCHANNEL_CALL_TO_CALL_STACK(call);
grpc_call_element *top_elem = grpc_call_stack_element(call_stack, 0);
top_elem->filter->start_transport_stream_op(exec_ctx, top_elem, op);
}
grpc_connected_subchannel *grpc_subchannel_get_connected_subchannel(
grpc_subchannel *c) {
return GET_CONNECTED_SUBCHANNEL(c, acq);
}
grpc_subchannel_call *grpc_connected_subchannel_create_call(
grpc_exec_ctx *exec_ctx, grpc_connected_subchannel *con,
grpc_pollset *pollset) {
grpc_channel_stack *chanstk = CHANNEL_STACK_FROM_CONNECTION(con);
grpc_subchannel_call *call =
gpr_malloc(sizeof(grpc_subchannel_call) + chanstk->call_stack_size);
grpc_call_stack *callstk = SUBCHANNEL_CALL_TO_CALL_STACK(call);
call->connection = con;
GRPC_CONNECTED_SUBCHANNEL_REF(con, "subchannel_call");
grpc_call_stack_init(exec_ctx, chanstk, 1, subchannel_call_destroy, call,
NULL, NULL, callstk);
grpc_call_stack_set_pollset(exec_ctx, callstk, pollset);
return call;
}
grpc_call_stack *grpc_subchannel_call_get_call_stack(
grpc_subchannel_call *subchannel_call) {
return SUBCHANNEL_CALL_TO_CALL_STACK(subchannel_call);
}