third_party/grpc/src/core/channel/client_channel.c - bazel - Git at Google

 /*
  *
  * 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/channel/client_channel.h"

 #include <stdio.h>
 #include <string.h>

 #include <grpc/support/alloc.h>
 #include <grpc/support/log.h>
 #include <grpc/support/sync.h>
 #include <grpc/support/useful.h>

 #include "src/core/channel/channel_args.h"
 #include "src/core/channel/connected_channel.h"
 #include "src/core/channel/subchannel_call_holder.h"
 #include "src/core/iomgr/iomgr.h"
 #include "src/core/profiling/timers.h"
 #include "src/core/support/string.h"
 #include "src/core/surface/channel.h"
 #include "src/core/transport/connectivity_state.h"

 /* Client channel implementation */

 typedef grpc_subchannel_call_holder call_data;

 typedef struct client_channel_channel_data {
   /** resolver for this channel */
   grpc_resolver *resolver;
   /** have we started resolving this channel */
   int started_resolving;

   /** mutex protecting client configuration, including all
       variables below in this data structure */
   gpr_mu mu_config;
   /** currently active load balancer - guarded by mu_config */
   grpc_lb_policy *lb_policy;
   /** incoming configuration - set by resolver.next
       guarded by mu_config */
   grpc_client_config *incoming_configuration;
   /** a list of closures that are all waiting for config to come in */
   grpc_closure_list waiting_for_config_closures;
   /** resolver callback */
   grpc_closure on_config_changed;
   /** connectivity state being tracked */
   grpc_connectivity_state_tracker state_tracker;
   /** when an lb_policy arrives, should we try to exit idle */
   int exit_idle_when_lb_policy_arrives;
   /** owning stack */
   grpc_channel_stack *owning_stack;
   /** interested parties */
   grpc_pollset_set interested_parties;
 } channel_data;

 /** We create one watcher for each new lb_policy that is returned from a
    resolver,
     to watch for state changes from the lb_policy. When a state change is seen,
    we
     update the channel, and create a new watcher */
 typedef struct {
   channel_data *chand;
   grpc_closure on_changed;
   grpc_connectivity_state state;
   grpc_lb_policy *lb_policy;
 } lb_policy_connectivity_watcher;

 typedef struct {
   grpc_closure closure;
   grpc_call_element *elem;
 } waiting_call;

 static char *cc_get_peer(grpc_exec_ctx *exec_ctx, grpc_call_element *elem) {
   return grpc_subchannel_call_holder_get_peer(exec_ctx, elem->call_data);
 }

 static void cc_start_transport_stream_op(grpc_exec_ctx *exec_ctx,
                                          grpc_call_element *elem,
                                          grpc_transport_stream_op *op) {
   GRPC_CALL_LOG_OP(GPR_INFO, elem, op);
   grpc_subchannel_call_holder_perform_op(exec_ctx, elem->call_data, op);
 }

 static void watch_lb_policy(grpc_exec_ctx *exec_ctx, channel_data *chand,
                             grpc_lb_policy *lb_policy,
                             grpc_connectivity_state current_state);

 static void on_lb_policy_state_changed_locked(
     grpc_exec_ctx *exec_ctx, lb_policy_connectivity_watcher *w) {
   grpc_connectivity_state publish_state = w->state;
   /* check if the notification is for a stale policy */
   if (w->lb_policy != w->chand->lb_policy) return;

   if (publish_state == GRPC_CHANNEL_FATAL_FAILURE &&
       w->chand->resolver != NULL) {
     publish_state = GRPC_CHANNEL_TRANSIENT_FAILURE;
     grpc_resolver_channel_saw_error(exec_ctx, w->chand->resolver);
     GRPC_LB_POLICY_UNREF(exec_ctx, w->chand->lb_policy, "channel");
     w->chand->lb_policy = NULL;
   }
   grpc_connectivity_state_set(exec_ctx, &w->chand->state_tracker, publish_state,
                               "lb_changed");
   if (w->state != GRPC_CHANNEL_FATAL_FAILURE) {
     watch_lb_policy(exec_ctx, w->chand, w->lb_policy, w->state);
   }
 }

 static void on_lb_policy_state_changed(grpc_exec_ctx *exec_ctx, void *arg,
                                        bool iomgr_success) {
   lb_policy_connectivity_watcher *w = arg;

   gpr_mu_lock(&w->chand->mu_config);
   on_lb_policy_state_changed_locked(exec_ctx, w);
   gpr_mu_unlock(&w->chand->mu_config);

   GRPC_CHANNEL_STACK_UNREF(exec_ctx, w->chand->owning_stack, "watch_lb_policy");
   gpr_free(w);
 }

 static void watch_lb_policy(grpc_exec_ctx *exec_ctx, channel_data *chand,
                             grpc_lb_policy *lb_policy,
                             grpc_connectivity_state current_state) {
   lb_policy_connectivity_watcher *w = gpr_malloc(sizeof(*w));
   GRPC_CHANNEL_STACK_REF(chand->owning_stack, "watch_lb_policy");

   w->chand = chand;
   grpc_closure_init(&w->on_changed, on_lb_policy_state_changed, w);
   w->state = current_state;
   w->lb_policy = lb_policy;
   grpc_lb_policy_notify_on_state_change(exec_ctx, lb_policy, &w->state,
                                         &w->on_changed);
 }

 static void cc_on_config_changed(grpc_exec_ctx *exec_ctx, void *arg,
                                  bool iomgr_success) {
   channel_data *chand = arg;
   grpc_lb_policy *lb_policy = NULL;
   grpc_lb_policy *old_lb_policy;
   grpc_resolver *old_resolver;
   grpc_connectivity_state state = GRPC_CHANNEL_TRANSIENT_FAILURE;
   int exit_idle = 0;

   if (chand->incoming_configuration != NULL) {
     lb_policy = grpc_client_config_get_lb_policy(chand->incoming_configuration);
     if (lb_policy != NULL) {
       GRPC_LB_POLICY_REF(lb_policy, "channel");
       GRPC_LB_POLICY_REF(lb_policy, "config_change");
       state = grpc_lb_policy_check_connectivity(exec_ctx, lb_policy);
     }

     grpc_client_config_unref(exec_ctx, chand->incoming_configuration);
   }

   chand->incoming_configuration = NULL;

   if (lb_policy != NULL) {
     grpc_pollset_set_add_pollset_set(exec_ctx, &lb_policy->interested_parties,
                                      &chand->interested_parties);
   }

   gpr_mu_lock(&chand->mu_config);
   old_lb_policy = chand->lb_policy;
   chand->lb_policy = lb_policy;
   if (lb_policy != NULL || chand->resolver == NULL /* disconnected */) {
     grpc_exec_ctx_enqueue_list(exec_ctx, &chand->waiting_for_config_closures,
                                NULL);
   }
   if (lb_policy != NULL && chand->exit_idle_when_lb_policy_arrives) {
     GRPC_LB_POLICY_REF(lb_policy, "exit_idle");
     exit_idle = 1;
     chand->exit_idle_when_lb_policy_arrives = 0;
   }

   if (iomgr_success && chand->resolver) {
     grpc_resolver *resolver = chand->resolver;
     GRPC_RESOLVER_REF(resolver, "channel-next");
     grpc_connectivity_state_set(exec_ctx, &chand->state_tracker, state,
                                 "new_lb+resolver");
     if (lb_policy != NULL) {
       watch_lb_policy(exec_ctx, chand, lb_policy, state);
     }
     gpr_mu_unlock(&chand->mu_config);
     GRPC_CHANNEL_STACK_REF(chand->owning_stack, "resolver");
     grpc_resolver_next(exec_ctx, resolver, &chand->incoming_configuration,
                        &chand->on_config_changed);
     GRPC_RESOLVER_UNREF(exec_ctx, resolver, "channel-next");
   } else {
     old_resolver = chand->resolver;
     chand->resolver = NULL;
     grpc_connectivity_state_set(exec_ctx, &chand->state_tracker,
                                 GRPC_CHANNEL_FATAL_FAILURE, "resolver_gone");
     gpr_mu_unlock(&chand->mu_config);
     if (old_resolver != NULL) {
       grpc_resolver_shutdown(exec_ctx, old_resolver);
       GRPC_RESOLVER_UNREF(exec_ctx, old_resolver, "channel");
     }
   }

   if (exit_idle) {
     grpc_lb_policy_exit_idle(exec_ctx, lb_policy);
     GRPC_LB_POLICY_UNREF(exec_ctx, lb_policy, "exit_idle");
   }

   if (old_lb_policy != NULL) {
     grpc_pollset_set_del_pollset_set(exec_ctx,
                                      &old_lb_policy->interested_parties,
                                      &chand->interested_parties);
     GRPC_LB_POLICY_UNREF(exec_ctx, old_lb_policy, "channel");
   }

   if (lb_policy != NULL) {
     GRPC_LB_POLICY_UNREF(exec_ctx, lb_policy, "config_change");
   }

   GRPC_CHANNEL_STACK_UNREF(exec_ctx, chand->owning_stack, "resolver");
 }

 static void cc_start_transport_op(grpc_exec_ctx *exec_ctx,
                                   grpc_channel_element *elem,
                                   grpc_transport_op *op) {
   channel_data *chand = elem->channel_data;
   grpc_resolver *destroy_resolver = NULL;

   grpc_exec_ctx_enqueue(exec_ctx, op->on_consumed, true, NULL);

   GPR_ASSERT(op->set_accept_stream == NULL);
   if (op->bind_pollset != NULL) {
     grpc_pollset_set_add_pollset(exec_ctx, &chand->interested_parties,
                                  op->bind_pollset);
   }

   gpr_mu_lock(&chand->mu_config);
   if (op->on_connectivity_state_change != NULL) {
     grpc_connectivity_state_notify_on_state_change(
         exec_ctx, &chand->state_tracker, op->connectivity_state,
         op->on_connectivity_state_change);
     op->on_connectivity_state_change = NULL;
     op->connectivity_state = NULL;
   }

   if (op->send_ping != NULL) {
     if (chand->lb_policy == NULL) {
       grpc_exec_ctx_enqueue(exec_ctx, op->send_ping, false, NULL);
     } else {
       grpc_lb_policy_ping_one(exec_ctx, chand->lb_policy, op->send_ping);
       op->bind_pollset = NULL;
     }
     op->send_ping = NULL;
   }

   if (op->disconnect && chand->resolver != NULL) {
     grpc_connectivity_state_set(exec_ctx, &chand->state_tracker,
                                 GRPC_CHANNEL_FATAL_FAILURE, "disconnect");
     destroy_resolver = chand->resolver;
     chand->resolver = NULL;
     if (chand->lb_policy != NULL) {
       grpc_pollset_set_del_pollset_set(exec_ctx,
                                        &chand->lb_policy->interested_parties,
                                        &chand->interested_parties);
       GRPC_LB_POLICY_UNREF(exec_ctx, chand->lb_policy, "channel");
       chand->lb_policy = NULL;
     }
   }
   gpr_mu_unlock(&chand->mu_config);

   if (destroy_resolver) {
     grpc_resolver_shutdown(exec_ctx, destroy_resolver);
     GRPC_RESOLVER_UNREF(exec_ctx, destroy_resolver, "channel");
   }
 }

 typedef struct {
   grpc_metadata_batch *initial_metadata;
   grpc_connected_subchannel **connected_subchannel;
   grpc_closure *on_ready;
   grpc_call_element *elem;
   grpc_closure closure;
 } continue_picking_args;

 static int cc_pick_subchannel(grpc_exec_ctx *exec_ctx, void *arg,
                               grpc_metadata_batch *initial_metadata,
                               grpc_connected_subchannel **connected_subchannel,
                               grpc_closure *on_ready);

 static void continue_picking(grpc_exec_ctx *exec_ctx, void *arg, bool success) {
   continue_picking_args *cpa = arg;
   if (!success) {
     grpc_exec_ctx_enqueue(exec_ctx, cpa->on_ready, false, NULL);
   } else if (cpa->connected_subchannel == NULL) {
     /* cancelled, do nothing */
   } else if (cc_pick_subchannel(exec_ctx, cpa->elem, cpa->initial_metadata,
                                 cpa->connected_subchannel, cpa->on_ready)) {
     grpc_exec_ctx_enqueue(exec_ctx, cpa->on_ready, true, NULL);
   }
   gpr_free(cpa);
 }

 static int cc_pick_subchannel(grpc_exec_ctx *exec_ctx, void *elemp,
                               grpc_metadata_batch *initial_metadata,
                               grpc_connected_subchannel **connected_subchannel,
                               grpc_closure *on_ready) {
   grpc_call_element *elem = elemp;
   channel_data *chand = elem->channel_data;
   call_data *calld = elem->call_data;
   continue_picking_args *cpa;
   grpc_closure *closure;

   GPR_ASSERT(connected_subchannel);

   gpr_mu_lock(&chand->mu_config);
   if (initial_metadata == NULL) {
     if (chand->lb_policy != NULL) {
       grpc_lb_policy_cancel_pick(exec_ctx, chand->lb_policy,
                                  connected_subchannel);
     }
     for (closure = chand->waiting_for_config_closures.head; closure != NULL;
          closure = grpc_closure_next(closure)) {
       cpa = closure->cb_arg;
       if (cpa->connected_subchannel == connected_subchannel) {
         cpa->connected_subchannel = NULL;
         grpc_exec_ctx_enqueue(exec_ctx, cpa->on_ready, false, NULL);
       }
     }
     gpr_mu_unlock(&chand->mu_config);
     return 1;
   }
   if (chand->lb_policy != NULL) {
     grpc_lb_policy *lb_policy = chand->lb_policy;
     int r;
     GRPC_LB_POLICY_REF(lb_policy, "cc_pick_subchannel");
     gpr_mu_unlock(&chand->mu_config);
     r = grpc_lb_policy_pick(exec_ctx, lb_policy, calld->pollset,
                             initial_metadata, connected_subchannel, on_ready);
     GRPC_LB_POLICY_UNREF(exec_ctx, lb_policy, "cc_pick_subchannel");
     return r;
   }
   if (chand->resolver != NULL && !chand->started_resolving) {
     chand->started_resolving = 1;
     GRPC_CHANNEL_STACK_REF(chand->owning_stack, "resolver");
     grpc_resolver_next(exec_ctx, chand->resolver,
                        &chand->incoming_configuration,
                        &chand->on_config_changed);
   }
   cpa = gpr_malloc(sizeof(*cpa));
   cpa->initial_metadata = initial_metadata;
   cpa->connected_subchannel = connected_subchannel;
   cpa->on_ready = on_ready;
   cpa->elem = elem;
   grpc_closure_init(&cpa->closure, continue_picking, cpa);
   grpc_closure_list_add(&chand->waiting_for_config_closures, &cpa->closure, 1);
   gpr_mu_unlock(&chand->mu_config);
   return 0;
 }

 /* Constructor for call_data */
 static void init_call_elem(grpc_exec_ctx *exec_ctx, grpc_call_element *elem,
                            grpc_call_element_args *args) {
   grpc_subchannel_call_holder_init(elem->call_data, cc_pick_subchannel, elem,
                                    args->call_stack);
 }

 /* Destructor for call_data */
 static void destroy_call_elem(grpc_exec_ctx *exec_ctx,
                               grpc_call_element *elem) {
   grpc_subchannel_call_holder_destroy(exec_ctx, elem->call_data);
 }

 /* Constructor for channel_data */
 static void init_channel_elem(grpc_exec_ctx *exec_ctx,
                               grpc_channel_element *elem,
                               grpc_channel_element_args *args) {
   channel_data *chand = elem->channel_data;

   memset(chand, 0, sizeof(*chand));

   GPR_ASSERT(args->is_last);
   GPR_ASSERT(elem->filter == &grpc_client_channel_filter);

   gpr_mu_init(&chand->mu_config);
   grpc_closure_init(&chand->on_config_changed, cc_on_config_changed, chand);
   chand->owning_stack = args->channel_stack;

   grpc_connectivity_state_init(&chand->state_tracker, GRPC_CHANNEL_IDLE,
                                "client_channel");
   grpc_pollset_set_init(&chand->interested_parties);
 }

 /* Destructor for channel_data */
 static void destroy_channel_elem(grpc_exec_ctx *exec_ctx,
                                  grpc_channel_element *elem) {
   channel_data *chand = elem->channel_data;

   if (chand->resolver != NULL) {
     grpc_resolver_shutdown(exec_ctx, chand->resolver);
     GRPC_RESOLVER_UNREF(exec_ctx, chand->resolver, "channel");
   }
   if (chand->lb_policy != NULL) {
     grpc_pollset_set_del_pollset_set(exec_ctx,
                                      &chand->lb_policy->interested_parties,
                                      &chand->interested_parties);
     GRPC_LB_POLICY_UNREF(exec_ctx, chand->lb_policy, "channel");
   }
   grpc_connectivity_state_destroy(exec_ctx, &chand->state_tracker);
   grpc_pollset_set_destroy(&chand->interested_parties);
   gpr_mu_destroy(&chand->mu_config);
 }

 static void cc_set_pollset(grpc_exec_ctx *exec_ctx, grpc_call_element *elem,
                            grpc_pollset *pollset) {
   call_data *calld = elem->call_data;
   calld->pollset = pollset;
 }

 const grpc_channel_filter grpc_client_channel_filter = {
     cc_start_transport_stream_op, cc_start_transport_op, sizeof(call_data),
     init_call_elem, cc_set_pollset, destroy_call_elem, sizeof(channel_data),
     init_channel_elem, destroy_channel_elem, cc_get_peer, "client-channel",
 };

 void grpc_client_channel_set_resolver(grpc_exec_ctx *exec_ctx,
                                       grpc_channel_stack *channel_stack,
                                       grpc_resolver *resolver) {
   /* post construction initialization: set the transport setup pointer */
   grpc_channel_element *elem = grpc_channel_stack_last_element(channel_stack);
   channel_data *chand = elem->channel_data;
   gpr_mu_lock(&chand->mu_config);
   GPR_ASSERT(!chand->resolver);
   chand->resolver = resolver;
   GRPC_RESOLVER_REF(resolver, "channel");
   if (!grpc_closure_list_empty(chand->waiting_for_config_closures) ||
       chand->exit_idle_when_lb_policy_arrives) {
     chand->started_resolving = 1;
     GRPC_CHANNEL_STACK_REF(chand->owning_stack, "resolver");
     grpc_resolver_next(exec_ctx, resolver, &chand->incoming_configuration,
                        &chand->on_config_changed);
   }
   gpr_mu_unlock(&chand->mu_config);
 }

 grpc_connectivity_state grpc_client_channel_check_connectivity_state(
     grpc_exec_ctx *exec_ctx, grpc_channel_element *elem, int try_to_connect) {
   channel_data *chand = elem->channel_data;
   grpc_connectivity_state out;
   gpr_mu_lock(&chand->mu_config);
   out = grpc_connectivity_state_check(&chand->state_tracker);
   if (out == GRPC_CHANNEL_IDLE && try_to_connect) {
     if (chand->lb_policy != NULL) {
       grpc_lb_policy_exit_idle(exec_ctx, chand->lb_policy);
     } else {
       chand->exit_idle_when_lb_policy_arrives = 1;
       if (!chand->started_resolving && chand->resolver != NULL) {
         GRPC_CHANNEL_STACK_REF(chand->owning_stack, "resolver");
         chand->started_resolving = 1;
         grpc_resolver_next(exec_ctx, chand->resolver,
                            &chand->incoming_configuration,
                            &chand->on_config_changed);
       }
     }
   }
   gpr_mu_unlock(&chand->mu_config);
   return out;
 }

 typedef struct {
   channel_data *chand;
   grpc_pollset *pollset;
   grpc_closure *on_complete;
   grpc_closure my_closure;
 } external_connectivity_watcher;

 static void on_external_watch_complete(grpc_exec_ctx *exec_ctx, void *arg,
                                        bool iomgr_success) {
   external_connectivity_watcher *w = arg;
   grpc_closure *follow_up = w->on_complete;
   grpc_pollset_set_del_pollset(exec_ctx, &w->chand->interested_parties,
                                w->pollset);
   GRPC_CHANNEL_STACK_UNREF(exec_ctx, w->chand->owning_stack,
                            "external_connectivity_watcher");
   gpr_free(w);
   follow_up->cb(exec_ctx, follow_up->cb_arg, iomgr_success);
 }

 void grpc_client_channel_watch_connectivity_state(
     grpc_exec_ctx *exec_ctx, grpc_channel_element *elem, grpc_pollset *pollset,
     grpc_connectivity_state *state, grpc_closure *on_complete) {
   channel_data *chand = elem->channel_data;
   external_connectivity_watcher *w = gpr_malloc(sizeof(*w));
   w->chand = chand;
   w->pollset = pollset;
   w->on_complete = on_complete;
   grpc_pollset_set_add_pollset(exec_ctx, &chand->interested_parties, pollset);
   grpc_closure_init(&w->my_closure, on_external_watch_complete, w);
   GRPC_CHANNEL_STACK_REF(w->chand->owning_stack,
                          "external_connectivity_watcher");
   gpr_mu_lock(&chand->mu_config);
   grpc_connectivity_state_notify_on_state_change(
       exec_ctx, &chand->state_tracker, state, &w->my_closure);
   gpr_mu_unlock(&chand->mu_config);
 }
	/*
	*
	* 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/channel/client_channel.h"

	#include <stdio.h>
	#include <string.h>

	#include <grpc/support/alloc.h>
	#include <grpc/support/log.h>
	#include <grpc/support/sync.h>
	#include <grpc/support/useful.h>

	#include "src/core/channel/channel_args.h"
	#include "src/core/channel/connected_channel.h"
	#include "src/core/channel/subchannel_call_holder.h"
	#include "src/core/iomgr/iomgr.h"
	#include "src/core/profiling/timers.h"
	#include "src/core/support/string.h"
	#include "src/core/surface/channel.h"
	#include "src/core/transport/connectivity_state.h"

	/* Client channel implementation */

	typedef grpc_subchannel_call_holder call_data;

	typedef struct client_channel_channel_data {
	/** resolver for this channel */
	grpc_resolver *resolver;
	/** have we started resolving this channel */
	int started_resolving;

	/** mutex protecting client configuration, including all
	variables below in this data structure */
	gpr_mu mu_config;
	/** currently active load balancer - guarded by mu_config */
	grpc_lb_policy *lb_policy;
	/** incoming configuration - set by resolver.next
	guarded by mu_config */
	grpc_client_config *incoming_configuration;
	/** a list of closures that are all waiting for config to come in */
	grpc_closure_list waiting_for_config_closures;
	/** resolver callback */
	grpc_closure on_config_changed;
	/** connectivity state being tracked */
	grpc_connectivity_state_tracker state_tracker;
	/** when an lb_policy arrives, should we try to exit idle */
	int exit_idle_when_lb_policy_arrives;
	/** owning stack */
	grpc_channel_stack *owning_stack;
	/** interested parties */
	grpc_pollset_set interested_parties;
	} channel_data;

	/** We create one watcher for each new lb_policy that is returned from a
	resolver,
	to watch for state changes from the lb_policy. When a state change is seen,
	we
	update the channel, and create a new watcher */
	typedef struct {
	channel_data *chand;
	grpc_closure on_changed;
	grpc_connectivity_state state;
	grpc_lb_policy *lb_policy;
	} lb_policy_connectivity_watcher;

	typedef struct {
	grpc_closure closure;
	grpc_call_element *elem;
	} waiting_call;

	static char cc_get_peer(grpc_exec_ctx exec_ctx, grpc_call_element *elem) {
	return grpc_subchannel_call_holder_get_peer(exec_ctx, elem->call_data);
	}

	static void cc_start_transport_stream_op(grpc_exec_ctx *exec_ctx,
	grpc_call_element *elem,
	grpc_transport_stream_op *op) {
	GRPC_CALL_LOG_OP(GPR_INFO, elem, op);
	grpc_subchannel_call_holder_perform_op(exec_ctx, elem->call_data, op);
	}

	static void watch_lb_policy(grpc_exec_ctx exec_ctx, channel_data chand,
	grpc_lb_policy *lb_policy,
	grpc_connectivity_state current_state);

	static void on_lb_policy_state_changed_locked(
	grpc_exec_ctx exec_ctx, lb_policy_connectivity_watcher w) {
	grpc_connectivity_state publish_state = w->state;
	/* check if the notification is for a stale policy */
	if (w->lb_policy != w->chand->lb_policy) return;

	if (publish_state == GRPC_CHANNEL_FATAL_FAILURE &&
	w->chand->resolver != NULL) {
	publish_state = GRPC_CHANNEL_TRANSIENT_FAILURE;
	grpc_resolver_channel_saw_error(exec_ctx, w->chand->resolver);
	GRPC_LB_POLICY_UNREF(exec_ctx, w->chand->lb_policy, "channel");
	w->chand->lb_policy = NULL;
	}
	grpc_connectivity_state_set(exec_ctx, &w->chand->state_tracker, publish_state,
	"lb_changed");
	if (w->state != GRPC_CHANNEL_FATAL_FAILURE) {
	watch_lb_policy(exec_ctx, w->chand, w->lb_policy, w->state);
	}
	}

	static void on_lb_policy_state_changed(grpc_exec_ctx exec_ctx, void arg,
	bool iomgr_success) {
	lb_policy_connectivity_watcher *w = arg;

	gpr_mu_lock(&w->chand->mu_config);
	on_lb_policy_state_changed_locked(exec_ctx, w);
	gpr_mu_unlock(&w->chand->mu_config);

	GRPC_CHANNEL_STACK_UNREF(exec_ctx, w->chand->owning_stack, "watch_lb_policy");
	gpr_free(w);
	}

	static void watch_lb_policy(grpc_exec_ctx exec_ctx, channel_data chand,
	grpc_lb_policy *lb_policy,
	grpc_connectivity_state current_state) {
	lb_policy_connectivity_watcher w = gpr_malloc(sizeof(w));
	GRPC_CHANNEL_STACK_REF(chand->owning_stack, "watch_lb_policy");

	w->chand = chand;
	grpc_closure_init(&w->on_changed, on_lb_policy_state_changed, w);
	w->state = current_state;
	w->lb_policy = lb_policy;
	grpc_lb_policy_notify_on_state_change(exec_ctx, lb_policy, &w->state,
	&w->on_changed);
	}

	static void cc_on_config_changed(grpc_exec_ctx exec_ctx, void arg,
	bool iomgr_success) {
	channel_data *chand = arg;
	grpc_lb_policy *lb_policy = NULL;
	grpc_lb_policy *old_lb_policy;
	grpc_resolver *old_resolver;
	grpc_connectivity_state state = GRPC_CHANNEL_TRANSIENT_FAILURE;
	int exit_idle = 0;

	if (chand->incoming_configuration != NULL) {
	lb_policy = grpc_client_config_get_lb_policy(chand->incoming_configuration);
	if (lb_policy != NULL) {
	GRPC_LB_POLICY_REF(lb_policy, "channel");
	GRPC_LB_POLICY_REF(lb_policy, "config_change");
	state = grpc_lb_policy_check_connectivity(exec_ctx, lb_policy);
	}

	grpc_client_config_unref(exec_ctx, chand->incoming_configuration);
	}

	chand->incoming_configuration = NULL;

	if (lb_policy != NULL) {
	grpc_pollset_set_add_pollset_set(exec_ctx, &lb_policy->interested_parties,
	&chand->interested_parties);
	}

	gpr_mu_lock(&chand->mu_config);
	old_lb_policy = chand->lb_policy;
	chand->lb_policy = lb_policy;
	if (lb_policy != NULL \|\| chand->resolver == NULL /* disconnected */) {
	grpc_exec_ctx_enqueue_list(exec_ctx, &chand->waiting_for_config_closures,
	NULL);
	}
	if (lb_policy != NULL && chand->exit_idle_when_lb_policy_arrives) {
	GRPC_LB_POLICY_REF(lb_policy, "exit_idle");
	exit_idle = 1;
	chand->exit_idle_when_lb_policy_arrives = 0;
	}

	if (iomgr_success && chand->resolver) {
	grpc_resolver *resolver = chand->resolver;
	GRPC_RESOLVER_REF(resolver, "channel-next");
	grpc_connectivity_state_set(exec_ctx, &chand->state_tracker, state,
	"new_lb+resolver");
	if (lb_policy != NULL) {
	watch_lb_policy(exec_ctx, chand, lb_policy, state);
	}
	gpr_mu_unlock(&chand->mu_config);
	GRPC_CHANNEL_STACK_REF(chand->owning_stack, "resolver");
	grpc_resolver_next(exec_ctx, resolver, &chand->incoming_configuration,
	&chand->on_config_changed);
	GRPC_RESOLVER_UNREF(exec_ctx, resolver, "channel-next");
	} else {
	old_resolver = chand->resolver;
	chand->resolver = NULL;
	grpc_connectivity_state_set(exec_ctx, &chand->state_tracker,
	GRPC_CHANNEL_FATAL_FAILURE, "resolver_gone");
	gpr_mu_unlock(&chand->mu_config);
	if (old_resolver != NULL) {
	grpc_resolver_shutdown(exec_ctx, old_resolver);
	GRPC_RESOLVER_UNREF(exec_ctx, old_resolver, "channel");
	}
	}

	if (exit_idle) {
	grpc_lb_policy_exit_idle(exec_ctx, lb_policy);
	GRPC_LB_POLICY_UNREF(exec_ctx, lb_policy, "exit_idle");
	}

	if (old_lb_policy != NULL) {
	grpc_pollset_set_del_pollset_set(exec_ctx,
	&old_lb_policy->interested_parties,
	&chand->interested_parties);
	GRPC_LB_POLICY_UNREF(exec_ctx, old_lb_policy, "channel");
	}

	if (lb_policy != NULL) {
	GRPC_LB_POLICY_UNREF(exec_ctx, lb_policy, "config_change");
	}

	GRPC_CHANNEL_STACK_UNREF(exec_ctx, chand->owning_stack, "resolver");
	}

	static void cc_start_transport_op(grpc_exec_ctx *exec_ctx,
	grpc_channel_element *elem,
	grpc_transport_op *op) {
	channel_data *chand = elem->channel_data;
	grpc_resolver *destroy_resolver = NULL;

	grpc_exec_ctx_enqueue(exec_ctx, op->on_consumed, true, NULL);

	GPR_ASSERT(op->set_accept_stream == NULL);
	if (op->bind_pollset != NULL) {
	grpc_pollset_set_add_pollset(exec_ctx, &chand->interested_parties,
	op->bind_pollset);
	}

	gpr_mu_lock(&chand->mu_config);
	if (op->on_connectivity_state_change != NULL) {
	grpc_connectivity_state_notify_on_state_change(
	exec_ctx, &chand->state_tracker, op->connectivity_state,
	op->on_connectivity_state_change);
	op->on_connectivity_state_change = NULL;
	op->connectivity_state = NULL;
	}

	if (op->send_ping != NULL) {
	if (chand->lb_policy == NULL) {
	grpc_exec_ctx_enqueue(exec_ctx, op->send_ping, false, NULL);
	} else {
	grpc_lb_policy_ping_one(exec_ctx, chand->lb_policy, op->send_ping);
	op->bind_pollset = NULL;
	}
	op->send_ping = NULL;
	}

	if (op->disconnect && chand->resolver != NULL) {
	grpc_connectivity_state_set(exec_ctx, &chand->state_tracker,
	GRPC_CHANNEL_FATAL_FAILURE, "disconnect");
	destroy_resolver = chand->resolver;
	chand->resolver = NULL;
	if (chand->lb_policy != NULL) {
	grpc_pollset_set_del_pollset_set(exec_ctx,
	&chand->lb_policy->interested_parties,
	&chand->interested_parties);
	GRPC_LB_POLICY_UNREF(exec_ctx, chand->lb_policy, "channel");
	chand->lb_policy = NULL;
	}
	}
	gpr_mu_unlock(&chand->mu_config);

	if (destroy_resolver) {
	grpc_resolver_shutdown(exec_ctx, destroy_resolver);
	GRPC_RESOLVER_UNREF(exec_ctx, destroy_resolver, "channel");
	}
	}

	typedef struct {
	grpc_metadata_batch *initial_metadata;
	grpc_connected_subchannel **connected_subchannel;
	grpc_closure *on_ready;
	grpc_call_element *elem;
	grpc_closure closure;
	} continue_picking_args;

	static int cc_pick_subchannel(grpc_exec_ctx exec_ctx, void arg,
	grpc_metadata_batch *initial_metadata,
	grpc_connected_subchannel **connected_subchannel,
	grpc_closure *on_ready);

	static void continue_picking(grpc_exec_ctx exec_ctx, void arg, bool success) {
	continue_picking_args *cpa = arg;
	if (!success) {
	grpc_exec_ctx_enqueue(exec_ctx, cpa->on_ready, false, NULL);
	} else if (cpa->connected_subchannel == NULL) {
	/* cancelled, do nothing */
	} else if (cc_pick_subchannel(exec_ctx, cpa->elem, cpa->initial_metadata,
	cpa->connected_subchannel, cpa->on_ready)) {
	grpc_exec_ctx_enqueue(exec_ctx, cpa->on_ready, true, NULL);
	}
	gpr_free(cpa);
	}

	static int cc_pick_subchannel(grpc_exec_ctx exec_ctx, void elemp,
	grpc_metadata_batch *initial_metadata,
	grpc_connected_subchannel **connected_subchannel,
	grpc_closure *on_ready) {
	grpc_call_element *elem = elemp;
	channel_data *chand = elem->channel_data;
	call_data *calld = elem->call_data;
	continue_picking_args *cpa;
	grpc_closure *closure;

	GPR_ASSERT(connected_subchannel);

	gpr_mu_lock(&chand->mu_config);
	if (initial_metadata == NULL) {
	if (chand->lb_policy != NULL) {
	grpc_lb_policy_cancel_pick(exec_ctx, chand->lb_policy,
	connected_subchannel);
	}
	for (closure = chand->waiting_for_config_closures.head; closure != NULL;
	closure = grpc_closure_next(closure)) {
	cpa = closure->cb_arg;
	if (cpa->connected_subchannel == connected_subchannel) {
	cpa->connected_subchannel = NULL;
	grpc_exec_ctx_enqueue(exec_ctx, cpa->on_ready, false, NULL);
	}
	}
	gpr_mu_unlock(&chand->mu_config);
	return 1;
	}
	if (chand->lb_policy != NULL) {
	grpc_lb_policy *lb_policy = chand->lb_policy;
	int r;
	GRPC_LB_POLICY_REF(lb_policy, "cc_pick_subchannel");
	gpr_mu_unlock(&chand->mu_config);
	r = grpc_lb_policy_pick(exec_ctx, lb_policy, calld->pollset,
	initial_metadata, connected_subchannel, on_ready);
	GRPC_LB_POLICY_UNREF(exec_ctx, lb_policy, "cc_pick_subchannel");
	return r;
	}
	if (chand->resolver != NULL && !chand->started_resolving) {
	chand->started_resolving = 1;
	GRPC_CHANNEL_STACK_REF(chand->owning_stack, "resolver");
	grpc_resolver_next(exec_ctx, chand->resolver,
	&chand->incoming_configuration,
	&chand->on_config_changed);
	}
	cpa = gpr_malloc(sizeof(*cpa));
	cpa->initial_metadata = initial_metadata;
	cpa->connected_subchannel = connected_subchannel;
	cpa->on_ready = on_ready;
	cpa->elem = elem;
	grpc_closure_init(&cpa->closure, continue_picking, cpa);
	grpc_closure_list_add(&chand->waiting_for_config_closures, &cpa->closure, 1);
	gpr_mu_unlock(&chand->mu_config);
	return 0;
	}

	/* Constructor for call_data */
	static void init_call_elem(grpc_exec_ctx exec_ctx, grpc_call_element elem,
	grpc_call_element_args *args) {
	grpc_subchannel_call_holder_init(elem->call_data, cc_pick_subchannel, elem,
	args->call_stack);
	}

	/* Destructor for call_data */
	static void destroy_call_elem(grpc_exec_ctx *exec_ctx,
	grpc_call_element *elem) {
	grpc_subchannel_call_holder_destroy(exec_ctx, elem->call_data);
	}

	/* Constructor for channel_data */
	static void init_channel_elem(grpc_exec_ctx *exec_ctx,
	grpc_channel_element *elem,
	grpc_channel_element_args *args) {
	channel_data *chand = elem->channel_data;

	memset(chand, 0, sizeof(*chand));

	GPR_ASSERT(args->is_last);
	GPR_ASSERT(elem->filter == &grpc_client_channel_filter);

	gpr_mu_init(&chand->mu_config);
	grpc_closure_init(&chand->on_config_changed, cc_on_config_changed, chand);
	chand->owning_stack = args->channel_stack;

	grpc_connectivity_state_init(&chand->state_tracker, GRPC_CHANNEL_IDLE,
	"client_channel");
	grpc_pollset_set_init(&chand->interested_parties);
	}

	/* Destructor for channel_data */
	static void destroy_channel_elem(grpc_exec_ctx *exec_ctx,
	grpc_channel_element *elem) {
	channel_data *chand = elem->channel_data;

	if (chand->resolver != NULL) {
	grpc_resolver_shutdown(exec_ctx, chand->resolver);
	GRPC_RESOLVER_UNREF(exec_ctx, chand->resolver, "channel");
	}
	if (chand->lb_policy != NULL) {
	grpc_pollset_set_del_pollset_set(exec_ctx,
	&chand->lb_policy->interested_parties,
	&chand->interested_parties);
	GRPC_LB_POLICY_UNREF(exec_ctx, chand->lb_policy, "channel");
	}
	grpc_connectivity_state_destroy(exec_ctx, &chand->state_tracker);
	grpc_pollset_set_destroy(&chand->interested_parties);
	gpr_mu_destroy(&chand->mu_config);
	}

	static void cc_set_pollset(grpc_exec_ctx exec_ctx, grpc_call_element elem,
	grpc_pollset *pollset) {
	call_data *calld = elem->call_data;
	calld->pollset = pollset;
	}

	const grpc_channel_filter grpc_client_channel_filter = {
	cc_start_transport_stream_op, cc_start_transport_op, sizeof(call_data),
	init_call_elem, cc_set_pollset, destroy_call_elem, sizeof(channel_data),
	init_channel_elem, destroy_channel_elem, cc_get_peer, "client-channel",
	};

	void grpc_client_channel_set_resolver(grpc_exec_ctx *exec_ctx,
	grpc_channel_stack *channel_stack,
	grpc_resolver *resolver) {
	/* post construction initialization: set the transport setup pointer */
	grpc_channel_element *elem = grpc_channel_stack_last_element(channel_stack);
	channel_data *chand = elem->channel_data;
	gpr_mu_lock(&chand->mu_config);
	GPR_ASSERT(!chand->resolver);
	chand->resolver = resolver;
	GRPC_RESOLVER_REF(resolver, "channel");
	if (!grpc_closure_list_empty(chand->waiting_for_config_closures) \|\|
	chand->exit_idle_when_lb_policy_arrives) {
	chand->started_resolving = 1;
	GRPC_CHANNEL_STACK_REF(chand->owning_stack, "resolver");
	grpc_resolver_next(exec_ctx, resolver, &chand->incoming_configuration,
	&chand->on_config_changed);
	}
	gpr_mu_unlock(&chand->mu_config);
	}

	grpc_connectivity_state grpc_client_channel_check_connectivity_state(
	grpc_exec_ctx exec_ctx, grpc_channel_element elem, int try_to_connect) {
	channel_data *chand = elem->channel_data;
	grpc_connectivity_state out;
	gpr_mu_lock(&chand->mu_config);
	out = grpc_connectivity_state_check(&chand->state_tracker);
	if (out == GRPC_CHANNEL_IDLE && try_to_connect) {
	if (chand->lb_policy != NULL) {
	grpc_lb_policy_exit_idle(exec_ctx, chand->lb_policy);
	} else {
	chand->exit_idle_when_lb_policy_arrives = 1;
	if (!chand->started_resolving && chand->resolver != NULL) {
	GRPC_CHANNEL_STACK_REF(chand->owning_stack, "resolver");
	chand->started_resolving = 1;
	grpc_resolver_next(exec_ctx, chand->resolver,
	&chand->incoming_configuration,
	&chand->on_config_changed);
	}
	}
	}
	gpr_mu_unlock(&chand->mu_config);
	return out;
	}

	typedef struct {
	channel_data *chand;
	grpc_pollset *pollset;
	grpc_closure *on_complete;
	grpc_closure my_closure;
	} external_connectivity_watcher;

	static void on_external_watch_complete(grpc_exec_ctx exec_ctx, void arg,
	bool iomgr_success) {
	external_connectivity_watcher *w = arg;
	grpc_closure *follow_up = w->on_complete;
	grpc_pollset_set_del_pollset(exec_ctx, &w->chand->interested_parties,
	w->pollset);
	GRPC_CHANNEL_STACK_UNREF(exec_ctx, w->chand->owning_stack,
	"external_connectivity_watcher");
	gpr_free(w);
	follow_up->cb(exec_ctx, follow_up->cb_arg, iomgr_success);
	}

	void grpc_client_channel_watch_connectivity_state(
	grpc_exec_ctx exec_ctx, grpc_channel_element elem, grpc_pollset *pollset,
	grpc_connectivity_state state, grpc_closure on_complete) {
	channel_data *chand = elem->channel_data;
	external_connectivity_watcher w = gpr_malloc(sizeof(w));
	w->chand = chand;
	w->pollset = pollset;
	w->on_complete = on_complete;
	grpc_pollset_set_add_pollset(exec_ctx, &chand->interested_parties, pollset);
	grpc_closure_init(&w->my_closure, on_external_watch_complete, w);
	GRPC_CHANNEL_STACK_REF(w->chand->owning_stack,
	"external_connectivity_watcher");
	gpr_mu_lock(&chand->mu_config);
	grpc_connectivity_state_notify_on_state_change(
	exec_ctx, &chand->state_tracker, state, &w->my_closure);
	gpr_mu_unlock(&chand->mu_config);
	}