/* * * Copyright 2015, 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 #include #include "src/core/channel/channel_args.h" #include "src/core/channel/client_channel.h" #include "src/core/channel/connected_channel.h" #include "src/core/iomgr/alarm.h" #include "src/core/transport/connectivity_state.h" #include "src/core/surface/channel.h" #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 typedef struct { /* all fields protected by subchannel->mu */ /** refcount */ int refs; /** parent subchannel */ grpc_subchannel *subchannel; } connection; typedef struct { grpc_iomgr_closure closure; size_t version; grpc_subchannel *subchannel; grpc_connectivity_state connectivity_state; } state_watcher; typedef struct waiting_for_connect { struct waiting_for_connect *next; grpc_iomgr_closure *notify; grpc_pollset *pollset; grpc_subchannel_call **target; grpc_subchannel *subchannel; grpc_iomgr_closure continuation; } waiting_for_connect; struct grpc_subchannel { grpc_connector *connector; /** 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; /** metadata context */ grpc_mdctx *mdctx; /** master channel - the grpc_channel instance that ultimately owns this channel_data via its channel stack. We occasionally use this to bump the refcount on the master channel to keep ourselves alive through an asynchronous operation. */ grpc_channel *master; /** have we seen a disconnection? */ int disconnected; /** set during connection */ grpc_connect_out_args connecting_result; /** callback for connection finishing */ grpc_iomgr_closure connected; /** pollset_set tracking who's interested in a connection being setup - owned by the master channel (in particular the client_channel filter there-in) */ grpc_pollset_set *pollset_set; /** mutex protecting remaining elements */ gpr_mu mu; /** active connection */ connection *active; /** version number for the active connection */ size_t active_version; /** refcount */ int refs; /** are we connecting */ int connecting; /** things waiting for a connection */ waiting_for_connect *waiting; /** connectivity state tracking */ grpc_connectivity_state_tracker state_tracker; /** 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_alarm alarm; /** current random value */ gpr_uint32 random; }; struct grpc_subchannel_call { connection *connection; gpr_refcount refs; }; #define SUBCHANNEL_CALL_TO_CALL_STACK(call) ((grpc_call_stack *)((call) + 1)) #define CHANNEL_STACK_FROM_CONNECTION(con) ((grpc_channel_stack *)((con) + 1)) static grpc_subchannel_call *create_call(connection *con); static void connectivity_state_changed_locked(grpc_subchannel *c, const char *reason); static grpc_connectivity_state compute_connectivity_locked(grpc_subchannel *c); static gpr_timespec compute_connect_deadline(grpc_subchannel *c); static void subchannel_connected(void *subchannel, int iomgr_success); static void subchannel_ref_locked( grpc_subchannel *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS); static int subchannel_unref_locked( grpc_subchannel *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) GRPC_MUST_USE_RESULT; static void connection_ref_locked(connection *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS); static grpc_subchannel *connection_unref_locked( connection *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) GRPC_MUST_USE_RESULT; static void subchannel_destroy(grpc_subchannel *c); #ifdef GRPC_SUBCHANNEL_REFCOUNT_DEBUG #define SUBCHANNEL_REF_LOCKED(p, r) \ subchannel_ref_locked((p), __FILE__, __LINE__, (r)) #define SUBCHANNEL_UNREF_LOCKED(p, r) \ subchannel_unref_locked((p), __FILE__, __LINE__, (r)) #define CONNECTION_REF_LOCKED(p, r) \ connection_ref_locked((p), __FILE__, __LINE__, (r)) #define CONNECTION_UNREF_LOCKED(p, r) \ connection_unref_locked((p), __FILE__, __LINE__, (r)) #define REF_PASS_ARGS , file, line, reason #define REF_LOG(name, p) \ gpr_log(file, line, GPR_LOG_SEVERITY_DEBUG, "%s: %p ref %d -> %d %s", \ (name), (p), (p)->refs, (p)->refs + 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, (p)->refs - 1, reason) #else #define SUBCHANNEL_REF_LOCKED(p, r) subchannel_ref_locked((p)) #define SUBCHANNEL_UNREF_LOCKED(p, r) subchannel_unref_locked((p)) #define CONNECTION_REF_LOCKED(p, r) connection_ref_locked((p)) #define CONNECTION_UNREF_LOCKED(p, r) connection_unref_locked((p)) #define REF_PASS_ARGS #define REF_LOG(name, p) \ do { \ } while (0) #define UNREF_LOG(name, p) \ do { \ } while (0) #endif /* * connection implementation */ static void connection_destroy(connection *c) { GPR_ASSERT(c->refs == 0); grpc_channel_stack_destroy(CHANNEL_STACK_FROM_CONNECTION(c)); gpr_free(c); } static void connection_ref_locked( connection *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) { REF_LOG("CONNECTION", c); subchannel_ref_locked(c->subchannel REF_PASS_ARGS); ++c->refs; } static grpc_subchannel *connection_unref_locked( connection *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) { grpc_subchannel *destroy = NULL; UNREF_LOG("CONNECTION", c); if (subchannel_unref_locked(c->subchannel REF_PASS_ARGS)) { destroy = c->subchannel; } if (--c->refs == 0 && c->subchannel->active != c) { connection_destroy(c); } return destroy; } /* * grpc_subchannel implementation */ static void subchannel_ref_locked( grpc_subchannel *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) { REF_LOG("SUBCHANNEL", c); ++c->refs; } static int subchannel_unref_locked( grpc_subchannel *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) { UNREF_LOG("SUBCHANNEL", c); return --c->refs == 0; } void grpc_subchannel_ref(grpc_subchannel *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) { gpr_mu_lock(&c->mu); subchannel_ref_locked(c REF_PASS_ARGS); gpr_mu_unlock(&c->mu); } void grpc_subchannel_unref(grpc_subchannel *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) { int destroy; gpr_mu_lock(&c->mu); destroy = subchannel_unref_locked(c REF_PASS_ARGS); gpr_mu_unlock(&c->mu); if (destroy) subchannel_destroy(c); } static void subchannel_destroy(grpc_subchannel *c) { if (c->active != NULL) { connection_destroy(c->active); } gpr_free(c->filters); grpc_channel_args_destroy(c->args); gpr_free(c->addr); grpc_mdctx_unref(c->mdctx); grpc_connectivity_state_destroy(&c->state_tracker); grpc_connector_unref(c->connector); gpr_free(c); } void grpc_subchannel_add_interested_party(grpc_subchannel *c, grpc_pollset *pollset) { grpc_pollset_set_add_pollset(c->pollset_set, pollset); } void grpc_subchannel_del_interested_party(grpc_subchannel *c, grpc_pollset *pollset) { grpc_pollset_set_del_pollset(c->pollset_set, pollset); } static gpr_uint32 random_seed() { return (gpr_uint32)(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)); grpc_channel_element *parent_elem = grpc_channel_stack_last_element( grpc_channel_get_channel_stack(args->master)); memset(c, 0, sizeof(*c)); c->refs = 1; c->connector = connector; grpc_connector_ref(c->connector); c->num_filters = args->filter_count; c->filters = gpr_malloc(sizeof(grpc_channel_filter *) * c->num_filters); memcpy(c->filters, args->filters, sizeof(grpc_channel_filter *) * c->num_filters); c->addr = gpr_malloc(args->addr_len); memcpy(c->addr, args->addr, args->addr_len); c->addr_len = args->addr_len; c->args = grpc_channel_args_copy(args->args); c->mdctx = args->mdctx; c->master = args->master; c->pollset_set = grpc_client_channel_get_connecting_pollset_set(parent_elem); c->random = random_seed(); grpc_mdctx_ref(c->mdctx); grpc_iomgr_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_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.metadata_context = c->mdctx; grpc_connector_connect(c->connector, &args, &c->connecting_result, &c->connected); } static void start_connect(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(c); } static void continue_creating_call(void *arg, int iomgr_success) { waiting_for_connect *w4c = arg; grpc_subchannel_del_interested_party(w4c->subchannel, w4c->pollset); grpc_subchannel_create_call(w4c->subchannel, w4c->pollset, w4c->target, w4c->notify); GRPC_SUBCHANNEL_UNREF(w4c->subchannel, "waiting_for_connect"); gpr_free(w4c); } void grpc_subchannel_create_call(grpc_subchannel *c, grpc_pollset *pollset, grpc_subchannel_call **target, grpc_iomgr_closure *notify) { connection *con; gpr_mu_lock(&c->mu); if (c->active != NULL) { con = c->active; CONNECTION_REF_LOCKED(con, "call"); gpr_mu_unlock(&c->mu); *target = create_call(con); notify->cb(notify->cb_arg, 1); } else { waiting_for_connect *w4c = gpr_malloc(sizeof(*w4c)); w4c->next = c->waiting; w4c->notify = notify; w4c->pollset = pollset; w4c->target = target; w4c->subchannel = c; /* released when clearing w4c */ SUBCHANNEL_REF_LOCKED(c, "waiting_for_connect"); grpc_iomgr_closure_init(&w4c->continuation, continue_creating_call, w4c); c->waiting = w4c; grpc_subchannel_add_interested_party(c, pollset); if (!c->connecting) { c->connecting = 1; connectivity_state_changed_locked(c, "create_call"); /* released by connection */ SUBCHANNEL_REF_LOCKED(c, "connecting"); GRPC_CHANNEL_INTERNAL_REF(c->master, "connecting"); gpr_mu_unlock(&c->mu); start_connect(c); } else { gpr_mu_unlock(&c->mu); } } } 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; } void grpc_subchannel_notify_on_state_change(grpc_subchannel *c, grpc_connectivity_state *state, grpc_iomgr_closure *notify) { int do_connect = 0; gpr_mu_lock(&c->mu); if (grpc_connectivity_state_notify_on_state_change(&c->state_tracker, state, notify)) { do_connect = 1; c->connecting = 1; /* released by connection */ SUBCHANNEL_REF_LOCKED(c, "connecting"); GRPC_CHANNEL_INTERNAL_REF(c->master, "connecting"); connectivity_state_changed_locked(c, "state_change"); } gpr_mu_unlock(&c->mu); if (do_connect) { start_connect(c); } } void grpc_subchannel_process_transport_op(grpc_subchannel *c, grpc_transport_op *op) { connection *con = NULL; grpc_subchannel *destroy; int cancel_alarm = 0; gpr_mu_lock(&c->mu); if (op->disconnect) { c->disconnected = 1; connectivity_state_changed_locked(c, "disconnect"); if (c->have_alarm) { cancel_alarm = 1; } } if (c->active != NULL) { con = c->active; CONNECTION_REF_LOCKED(con, "transport-op"); } gpr_mu_unlock(&c->mu); if (con != NULL) { 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(top_elem, op); gpr_mu_lock(&c->mu); destroy = CONNECTION_UNREF_LOCKED(con, "transport-op"); gpr_mu_unlock(&c->mu); if (destroy) { subchannel_destroy(destroy); } } if (cancel_alarm) { grpc_alarm_cancel(&c->alarm); } if (op->disconnect) { grpc_connector_shutdown(c->connector); } } static void on_state_changed(void *p, int iomgr_success) { state_watcher *sw = p; grpc_subchannel *c = sw->subchannel; gpr_mu *mu = &c->mu; int destroy; grpc_transport_op op; grpc_channel_element *elem; connection *destroy_connection = NULL; gpr_mu_lock(mu); /* if we failed or there is a version number mismatch, just leave this closure */ if (!iomgr_success || sw->subchannel->active_version != sw->version) { goto done; } switch (sw->connectivity_state) { case GRPC_CHANNEL_CONNECTING: case GRPC_CHANNEL_READY: case GRPC_CHANNEL_IDLE: /* all is still good: keep watching */ memset(&op, 0, sizeof(op)); op.connectivity_state = &sw->connectivity_state; op.on_connectivity_state_change = &sw->closure; elem = grpc_channel_stack_element( CHANNEL_STACK_FROM_CONNECTION(c->active), 0); elem->filter->start_transport_op(elem, &op); /* early out */ gpr_mu_unlock(mu); return; case GRPC_CHANNEL_FATAL_FAILURE: case GRPC_CHANNEL_TRANSIENT_FAILURE: /* things have gone wrong, deactivate and enter idle */ if (sw->subchannel->active->refs == 0) { destroy_connection = sw->subchannel->active; } sw->subchannel->active = NULL; grpc_connectivity_state_set( &c->state_tracker, c->disconnected ? GRPC_CHANNEL_FATAL_FAILURE : GRPC_CHANNEL_TRANSIENT_FAILURE, "connection_failed"); break; } done: connectivity_state_changed_locked(c, "transport_state_changed"); destroy = SUBCHANNEL_UNREF_LOCKED(c, "state_watcher"); gpr_free(sw); gpr_mu_unlock(mu); if (destroy) { subchannel_destroy(c); } if (destroy_connection != NULL) { connection_destroy(destroy_connection); } } static void publish_transport(grpc_subchannel *c) { size_t channel_stack_size; connection *con; grpc_channel_stack *stk; size_t num_filters; const grpc_channel_filter **filters; waiting_for_connect *w4c; grpc_transport_op op; state_watcher *sw; connection *destroy_connection = NULL; grpc_channel_element *elem; /* build final filter list */ num_filters = c->num_filters + c->connecting_result.num_filters + 1; filters = gpr_malloc(sizeof(*filters) * num_filters); memcpy(filters, c->filters, sizeof(*filters) * c->num_filters); memcpy(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(sizeof(connection) + channel_stack_size); stk = (grpc_channel_stack *)(con + 1); con->refs = 0; con->subchannel = c; grpc_channel_stack_init(filters, num_filters, c->master, c->args, c->mdctx, stk); grpc_connected_channel_bind_transport(stk, c->connecting_result.transport); gpr_free(c->connecting_result.filters); memset(&c->connecting_result, 0, sizeof(c->connecting_result)); /* initialize state watcher */ sw = gpr_malloc(sizeof(*sw)); grpc_iomgr_closure_init(&sw->closure, on_state_changed, sw); sw->subchannel = c; sw->connectivity_state = GRPC_CHANNEL_READY; gpr_mu_lock(&c->mu); if (c->disconnected) { gpr_mu_unlock(&c->mu); gpr_free(sw); gpr_free(filters); grpc_channel_stack_destroy(stk); GRPC_CHANNEL_INTERNAL_UNREF(c->master, "connecting"); GRPC_SUBCHANNEL_UNREF(c, "connecting"); return; } /* publish */ if (c->active != NULL && c->active->refs == 0) { destroy_connection = c->active; } c->active = con; c->active_version++; sw->version = c->active_version; c->connecting = 0; /* watch for changes; subchannel ref for connecting is donated to the state watcher */ memset(&op, 0, sizeof(op)); op.connectivity_state = &sw->connectivity_state; op.on_connectivity_state_change = &sw->closure; op.bind_pollset_set = c->pollset_set; SUBCHANNEL_REF_LOCKED(c, "state_watcher"); GRPC_CHANNEL_INTERNAL_UNREF(c->master, "connecting"); GPR_ASSERT(!SUBCHANNEL_UNREF_LOCKED(c, "connecting")); elem = grpc_channel_stack_element(CHANNEL_STACK_FROM_CONNECTION(c->active), 0); elem->filter->start_transport_op(elem, &op); /* signal completion */ connectivity_state_changed_locked(c, "connected"); while ((w4c = c->waiting)) { c->waiting = w4c->next; grpc_iomgr_add_callback(&w4c->continuation); } gpr_mu_unlock(&c->mu); gpr_free(filters); if (destroy_connection != NULL) { connection_destroy(destroy_connection); } } /* Generate a random number between 0 and 1. */ static double generate_uniform_random_number(grpc_subchannel *c) { c->random = (1103515245 * c->random + 12345) % ((gpr_uint32)1 << 31); return c->random / (double)((gpr_uint32)1 << 31); } /* Update backoff_delta and next_attempt in subchannel */ static void update_reconnect_parameters(grpc_subchannel *c) { gpr_int32 backoff_delta_millis, jitter; gpr_int32 max_backoff_millis = GRPC_SUBCHANNEL_RECONNECT_MAX_BACKOFF_SECONDS * 1000; double jitter_range; backoff_delta_millis = (gpr_int32)(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 = (gpr_int32)((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(void *arg, int iomgr_success) { grpc_subchannel *c = arg; gpr_mu_lock(&c->mu); c->have_alarm = 0; if (c->disconnected) { iomgr_success = 0; } connectivity_state_changed_locked(c, "alarm"); gpr_mu_unlock(&c->mu); if (iomgr_success) { update_reconnect_parameters(c); continue_connect(c); } else { GRPC_CHANNEL_INTERNAL_UNREF(c->master, "connecting"); GRPC_SUBCHANNEL_UNREF(c, "connecting"); } } static void subchannel_connected(void *arg, int iomgr_success) { grpc_subchannel *c = arg; if (c->connecting_result.transport != NULL) { publish_transport(c); } else { gpr_timespec now = gpr_now(GPR_CLOCK_MONOTONIC); gpr_mu_lock(&c->mu); GPR_ASSERT(!c->have_alarm); c->have_alarm = 1; connectivity_state_changed_locked(c, "connect_failed"); grpc_alarm_init(&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; } static grpc_connectivity_state compute_connectivity_locked(grpc_subchannel *c) { if (c->disconnected) { return GRPC_CHANNEL_FATAL_FAILURE; } if (c->connecting) { if (c->have_alarm) { return GRPC_CHANNEL_TRANSIENT_FAILURE; } return GRPC_CHANNEL_CONNECTING; } if (c->active) { return GRPC_CHANNEL_READY; } return GRPC_CHANNEL_IDLE; } static void connectivity_state_changed_locked(grpc_subchannel *c, const char *reason) { grpc_connectivity_state current = compute_connectivity_locked(c); grpc_connectivity_state_set(&c->state_tracker, current, reason); } /* * grpc_subchannel_call implementation */ void grpc_subchannel_call_ref( grpc_subchannel_call *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) { gpr_ref(&c->refs); } void grpc_subchannel_call_unref( grpc_subchannel_call *c GRPC_SUBCHANNEL_REF_EXTRA_ARGS) { if (gpr_unref(&c->refs)) { gpr_mu *mu = &c->connection->subchannel->mu; grpc_subchannel *destroy; grpc_call_stack_destroy(SUBCHANNEL_CALL_TO_CALL_STACK(c)); gpr_mu_lock(mu); destroy = CONNECTION_UNREF_LOCKED(c->connection, "call"); gpr_mu_unlock(mu); gpr_free(c); if (destroy != NULL) { subchannel_destroy(destroy); } } } char *grpc_subchannel_call_get_peer(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(top_elem); } void grpc_subchannel_call_process_op(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(top_elem, op); } grpc_subchannel_call *create_call(connection *con) { 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; gpr_ref_init(&call->refs, 1); grpc_call_stack_init(chanstk, NULL, NULL, callstk); return call; }