/* Public API */
grpc_resource_quota *grpc_resource_quota_create(const char *name) {
grpc_resource_quota *resource_quota = gpr_malloc(sizeof(*resource_quota));
gpr_ref_init(&resource_quota->refs, 1);
resource_quota->combiner = grpc_combiner_create(NULL);
resource_quota->free_pool = INT64_MAX;
resource_quota->size = INT64_MAX;
resource_quota->step_scheduled = false;
resource_quota->reclaiming = false;
gpr_atm_no_barrier_store(&resource_quota->memory_usage_estimation, 0);
if (name != NULL) {
resource_quota->name = gpr_strdup(name);
} else {
gpr_asprintf(&resource_quota->name, "anonymous_pool_%" PRIxPTR,
(intptr_t)resource_quota);
}
grpc_closure_init(
&resource_quota->rq_step_closure, rq_step, resource_quota,
grpc_combiner_finally_scheduler(resource_quota->combiner, true));
grpc_closure_init(&resource_quota->rq_reclamation_done_closure,
rq_reclamation_done, resource_quota,
grpc_combiner_scheduler(resource_quota->combiner, false));
for (int i = 0; i < GRPC_RULIST_COUNT; i++) {
resource_quota->roots[i] = NULL;
}
return resource_quota;
}
int main(int argc, char **argv) {
grpc_test_init(argc, argv);
grpc_init();
gpr_mu_init(&g_mu);
g_combiner = grpc_combiner_create();
grpc_resolve_address = my_resolve_address;
grpc_dns_lookup_ares = my_dns_lookup_ares;
grpc_channel_args *result = (grpc_channel_args *)1;
grpc_exec_ctx exec_ctx = GRPC_EXEC_CTX_INIT;
grpc_resolver *resolver = create_resolver(&exec_ctx, "dns:test");
gpr_event ev1;
gpr_event_init(&ev1);
call_resolver_next_after_locking(
&exec_ctx, resolver, &result,
GRPC_CLOSURE_CREATE(on_done, &ev1, grpc_schedule_on_exec_ctx));
grpc_exec_ctx_flush(&exec_ctx);
GPR_ASSERT(wait_loop(5, &ev1));
GPR_ASSERT(result == NULL);
gpr_event ev2;
gpr_event_init(&ev2);
call_resolver_next_after_locking(
&exec_ctx, resolver, &result,
GRPC_CLOSURE_CREATE(on_done, &ev2, grpc_schedule_on_exec_ctx));
grpc_exec_ctx_flush(&exec_ctx);
GPR_ASSERT(wait_loop(30, &ev2));
GPR_ASSERT(result != NULL);
grpc_channel_args_destroy(&exec_ctx, result);
GRPC_RESOLVER_UNREF(&exec_ctx, resolver, "test");
GRPC_COMBINER_UNREF(&exec_ctx, g_combiner, "test");
grpc_exec_ctx_finish(&exec_ctx);
grpc_shutdown();
gpr_mu_destroy(&g_mu);
}
static void test_fake_resolver() {
grpc_exec_ctx exec_ctx = GRPC_EXEC_CTX_INIT;
grpc_combiner *combiner = grpc_combiner_create(NULL);
// Create resolver.
grpc_fake_resolver_response_generator *response_generator =
grpc_fake_resolver_response_generator_create();
grpc_resolver *resolver =
build_fake_resolver(&exec_ctx, combiner, response_generator);
GPR_ASSERT(resolver != NULL);
// Setup expectations.
grpc_uri *uris[] = {grpc_uri_parse(&exec_ctx, "ipv4:10.2.1.1:1234", true),
grpc_uri_parse(&exec_ctx, "ipv4:127.0.0.1:4321", true)};
char *balancer_names[] = {"name1", "name2"};
const bool is_balancer[] = {true, false};
grpc_lb_addresses *addresses = grpc_lb_addresses_create(3, NULL);
for (size_t i = 0; i < GPR_ARRAY_SIZE(uris); ++i) {
grpc_lb_addresses_set_address_from_uri(
addresses, i, uris[i], is_balancer[i], balancer_names[i], NULL);
grpc_uri_destroy(uris[i]);
}
const grpc_arg addresses_arg =
grpc_lb_addresses_create_channel_arg(addresses);
grpc_channel_args *results =
grpc_channel_args_copy_and_add(NULL, &addresses_arg, 1);
grpc_lb_addresses_destroy(&exec_ctx, addresses);
on_resolution_arg on_res_arg;
memset(&on_res_arg, 0, sizeof(on_res_arg));
on_res_arg.expected_resolver_result = results;
grpc_closure *on_resolution = grpc_closure_create(
on_resolution_cb, &on_res_arg, grpc_combiner_scheduler(combiner, false));
// Set resolver results and trigger first resolution. on_resolution_cb
// performs the checks.
grpc_fake_resolver_response_generator_set_response(
&exec_ctx, response_generator, results);
grpc_resolver_next_locked(&exec_ctx, resolver, &on_res_arg.resolver_result,
on_resolution);
grpc_exec_ctx_flush(&exec_ctx);
GPR_ASSERT(on_res_arg.was_called);
// Setup update.
grpc_uri *uris_update[] = {
grpc_uri_parse(&exec_ctx, "ipv4:192.168.1.0:31416", true)};
char *balancer_names_update[] = {"name3"};
const bool is_balancer_update[] = {false};
grpc_lb_addresses *addresses_update = grpc_lb_addresses_create(1, NULL);
for (size_t i = 0; i < GPR_ARRAY_SIZE(uris_update); ++i) {
grpc_lb_addresses_set_address_from_uri(addresses_update, i, uris_update[i],
is_balancer_update[i],
balancer_names_update[i], NULL);
grpc_uri_destroy(uris_update[i]);
}
grpc_arg addresses_update_arg =
grpc_lb_addresses_create_channel_arg(addresses_update);
grpc_channel_args *results_update =
grpc_channel_args_copy_and_add(NULL, &addresses_update_arg, 1);
grpc_lb_addresses_destroy(&exec_ctx, addresses_update);
// Setup expectations for the update.
on_resolution_arg on_res_arg_update;
memset(&on_res_arg_update, 0, sizeof(on_res_arg_update));
on_res_arg_update.expected_resolver_result = results_update;
on_resolution = grpc_closure_create(on_resolution_cb, &on_res_arg_update,
grpc_combiner_scheduler(combiner, false));
// Set updated resolver results and trigger a second resolution.
grpc_fake_resolver_response_generator_set_response(
&exec_ctx, response_generator, results_update);
grpc_resolver_next_locked(&exec_ctx, resolver,
&on_res_arg_update.resolver_result, on_resolution);
grpc_exec_ctx_flush(&exec_ctx);
GPR_ASSERT(on_res_arg.was_called);
// Requesting a new resolution without re-senting the response shouldn't
// trigger the resolution callback.
memset(&on_res_arg, 0, sizeof(on_res_arg));
grpc_resolver_next_locked(&exec_ctx, resolver, &on_res_arg.resolver_result,
on_resolution);
grpc_exec_ctx_flush(&exec_ctx);
GPR_ASSERT(!on_res_arg.was_called);
GRPC_COMBINER_UNREF(&exec_ctx, combiner, "test_fake_resolver");
GRPC_RESOLVER_UNREF(&exec_ctx, resolver, "test_fake_resolver");
grpc_exec_ctx_finish(&exec_ctx);
grpc_fake_resolver_response_generator_unref(response_generator);
}
