/* * * Copyright 2016 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 "test/core/util/passthru_endpoint.h" #include #include #include #include #include #include "absl/strings/str_format.h" #include "absl/strings/string_view.h" #include #include #include #include #include "src/core/lib/gprpp/debug_location.h" #include "src/core/lib/gprpp/time.h" #include "src/core/lib/iomgr/closure.h" #include "src/core/lib/iomgr/error.h" #include "src/core/lib/iomgr/exec_ctx.h" #include "src/core/lib/iomgr/iomgr_fwd.h" #include "src/core/lib/iomgr/timer.h" struct passthru_endpoint; typedef struct passthru_endpoint passthru_endpoint; typedef struct { bool is_armed; grpc_endpoint* ep; grpc_slice_buffer* slices; grpc_closure* cb; } pending_op; typedef struct { grpc_timer timer; uint64_t allowed_write_bytes; uint64_t allowed_read_bytes; std::vector actions; std::function on_complete; } grpc_passthru_endpoint_channel_effects; typedef struct { grpc_endpoint base; passthru_endpoint* parent; grpc_slice_buffer read_buffer; grpc_slice_buffer write_buffer; grpc_slice_buffer* on_read_out; grpc_closure* on_read; pending_op pending_read_op; pending_op pending_write_op; uint64_t bytes_read_so_far; uint64_t bytes_written_so_far; } half; struct passthru_endpoint { gpr_mu mu; int halves; grpc_passthru_endpoint_stats* stats; grpc_passthru_endpoint_channel_effects* channel_effects; bool simulate_channel_actions; bool shutdown; half client; half server; }; static void do_pending_read_op_locked(half* m, grpc_error_handle error) { GPR_ASSERT(m->pending_read_op.is_armed); GPR_ASSERT(m->bytes_read_so_far <= m->parent->channel_effects->allowed_read_bytes); if (m->parent->shutdown) { grpc_core::ExecCtx::Run( DEBUG_LOCATION, m->pending_read_op.cb, GRPC_ERROR_CREATE_FROM_STATIC_STRING("Already shutdown")); // Move any pending data into pending_read_op.slices so that it may be // free'ed by the executing callback. grpc_slice_buffer_move_into(&m->read_buffer, m->pending_read_op.slices); m->pending_read_op.is_armed = false; return; } if (m->bytes_read_so_far == m->parent->channel_effects->allowed_read_bytes) { // Keep it in pending state. return; } // This delayed processing should only be invoked when read_buffer has // something in it. GPR_ASSERT(m->read_buffer.count > 0); uint64_t readable_length = std::min( m->read_buffer.length, m->parent->channel_effects->allowed_read_bytes - m->bytes_read_so_far); GPR_ASSERT(readable_length > 0); grpc_slice_buffer_move_first(&m->read_buffer, readable_length, m->pending_read_op.slices); grpc_core::ExecCtx::Run(DEBUG_LOCATION, m->pending_read_op.cb, error); if (m->parent->simulate_channel_actions) { m->bytes_read_so_far += readable_length; } m->pending_read_op.is_armed = false; } static void me_read(grpc_endpoint* ep, grpc_slice_buffer* slices, grpc_closure* cb, bool /*urgent*/, int /*min_progress_size*/) { half* m = reinterpret_cast(ep); gpr_mu_lock(&m->parent->mu); if (m->parent->shutdown) { grpc_core::ExecCtx::Run( DEBUG_LOCATION, cb, GRPC_ERROR_CREATE_FROM_STATIC_STRING("Already shutdown")); } else if (m->read_buffer.count > 0) { GPR_ASSERT(!m->pending_read_op.is_armed); GPR_ASSERT(!m->on_read); m->pending_read_op.is_armed = true; m->pending_read_op.cb = cb; m->pending_read_op.ep = ep; m->pending_read_op.slices = slices; do_pending_read_op_locked(m, GRPC_ERROR_NONE); } else { GPR_ASSERT(!m->pending_read_op.is_armed); m->on_read = cb; m->on_read_out = slices; } gpr_mu_unlock(&m->parent->mu); } // Copy src slice and split the copy at n bytes into two separate slices void grpc_slice_copy_split(grpc_slice src, uint64_t n, grpc_slice& split1, grpc_slice& split2) { GPR_ASSERT(n <= GRPC_SLICE_LENGTH(src)); if (n == GRPC_SLICE_LENGTH(src)) { split1 = grpc_slice_copy(src); split2 = grpc_empty_slice(); return; } split1 = GRPC_SLICE_MALLOC(n); memcpy(GRPC_SLICE_START_PTR(split1), GRPC_SLICE_START_PTR(src), n); split2 = GRPC_SLICE_MALLOC(GRPC_SLICE_LENGTH(src) - n); memcpy(GRPC_SLICE_START_PTR(split2), GRPC_SLICE_START_PTR(src) + n, GRPC_SLICE_LENGTH(src) - n); } static half* other_half(half* h) { if (h == &h->parent->client) return &h->parent->server; return &h->parent->client; } static void do_pending_write_op_locked(half* m, grpc_error_handle error) { GPR_ASSERT(m->pending_write_op.is_armed); GPR_ASSERT(m->bytes_written_so_far <= m->parent->channel_effects->allowed_write_bytes); if (m->parent->shutdown) { grpc_core::ExecCtx::Run( DEBUG_LOCATION, m->pending_write_op.cb, GRPC_ERROR_CREATE_FROM_STATIC_STRING("Already shutdown")); m->pending_write_op.is_armed = false; grpc_slice_buffer_reset_and_unref(m->pending_write_op.slices); return; } if (m->bytes_written_so_far == m->parent->channel_effects->allowed_write_bytes) { // Keep it in pending state. return; } half* other = other_half(m); uint64_t max_writable = std::min(m->pending_write_op.slices->length, m->parent->channel_effects->allowed_write_bytes - m->bytes_written_so_far); uint64_t max_readable = other->parent->channel_effects->allowed_read_bytes - other->bytes_read_so_far; uint64_t immediate_bytes_read = other->on_read != nullptr ? std::min(max_readable, max_writable) : 0; GPR_ASSERT(max_writable > 0); GPR_ASSERT(max_readable >= 0); // At the end of this process, we should have written max_writable bytes; if (m->parent->simulate_channel_actions) { m->bytes_written_so_far += max_writable; } // Estimate if the original write would still be pending at the end of this // process bool would_write_be_pending = max_writable < m->pending_write_op.slices->length; if (!m->parent->simulate_channel_actions) { GPR_ASSERT(!would_write_be_pending); } grpc_slice_buffer* slices = m->pending_write_op.slices; grpc_slice_buffer* dest = other->on_read != nullptr ? other->on_read_out : &other->read_buffer; while (max_writable > 0) { grpc_slice slice = grpc_slice_buffer_take_first(slices); uint64_t slice_length = GPR_SLICE_LENGTH(slice); GPR_ASSERT(slice_length > 0); grpc_slice split1, split2; uint64_t split_length = 0; if (slice_length <= max_readable) { split_length = std::min(slice_length, max_writable); } else if (max_readable > 0) { // slice_length > max_readable split_length = std::min(max_readable, max_writable); } else { // slice_length still > max_readable but max_readable is 0. // In this case put the bytes into other->read_buffer. During a future // read if max_readable still remains zero at the time of read, the // pending read logic will kick in. dest = &other->read_buffer; split_length = std::min(slice_length, max_writable); } grpc_slice_copy_split(slice, split_length, split1, split2); grpc_slice_unref(slice); // Write a copy of the slice to the destination to be read grpc_slice_buffer_add_indexed(dest, split1); // Re-insert split2 into source for next iteration. if (GPR_SLICE_LENGTH(split2) > 0) { grpc_slice_buffer_undo_take_first(slices, split2); } else { grpc_slice_unref(split2); } if (max_readable > 0) { GPR_ASSERT(max_readable >= static_cast(split_length)); max_readable -= split_length; } GPR_ASSERT(max_writable >= static_cast(split_length)); max_writable -= split_length; } if (immediate_bytes_read > 0) { GPR_ASSERT(!other->pending_read_op.is_armed); if (m->parent->simulate_channel_actions) { other->bytes_read_so_far += immediate_bytes_read; } grpc_core::ExecCtx::Run(DEBUG_LOCATION, other->on_read, error); other->on_read = nullptr; } if (!would_write_be_pending) { // No slices should be left GPR_ASSERT(m->pending_write_op.slices->count == 0); grpc_slice_buffer_reset_and_unref(m->pending_write_op.slices); m->pending_write_op.is_armed = false; grpc_core::ExecCtx::Run(DEBUG_LOCATION, m->pending_write_op.cb, error); } } static void me_write(grpc_endpoint* ep, grpc_slice_buffer* slices, grpc_closure* cb, void* /*arg*/, int /*max_frame_size*/) { half* m = reinterpret_cast(ep); gpr_mu_lock(&m->parent->mu); gpr_atm_no_barrier_fetch_add(&m->parent->stats->num_writes, (gpr_atm)1); if (m->parent->shutdown) { grpc_core::ExecCtx::Run( DEBUG_LOCATION, cb, GRPC_ERROR_CREATE_FROM_STATIC_STRING("Endpoint already shutdown")); } else { GPR_ASSERT(!m->pending_write_op.is_armed); // Copy slices into m->pending_write_op.slices m->pending_write_op.slices = &m->write_buffer; GPR_ASSERT(m->pending_write_op.slices->count == 0); for (int i = 0; i < static_cast(slices->count); i++) { if (GPR_SLICE_LENGTH(slices->slices[i]) > 0) { grpc_slice_buffer_add_indexed(m->pending_write_op.slices, grpc_slice_copy(slices->slices[i])); } } if (m->pending_write_op.slices->count > 0) { m->pending_write_op.is_armed = true; m->pending_write_op.cb = cb; m->pending_write_op.ep = ep; do_pending_write_op_locked(m, GRPC_ERROR_NONE); } else { // There is nothing to write. Schedule callback to be run right away. grpc_core::ExecCtx::Run(DEBUG_LOCATION, cb, GRPC_ERROR_NONE); } } gpr_mu_unlock(&m->parent->mu); } void flush_pending_ops_locked(half* m, grpc_error_handle error) { if (m->pending_read_op.is_armed) { do_pending_read_op_locked(m, error); } if (m->pending_write_op.is_armed) { do_pending_write_op_locked(m, error); } } static void me_add_to_pollset(grpc_endpoint* /*ep*/, grpc_pollset* /*pollset*/) {} static void me_add_to_pollset_set(grpc_endpoint* /*ep*/, grpc_pollset_set* /*pollset*/) {} static void me_delete_from_pollset_set(grpc_endpoint* /*ep*/, grpc_pollset_set* /*pollset*/) {} static void shutdown_locked(half* m, grpc_error_handle why) { m->parent->shutdown = true; flush_pending_ops_locked(m, GRPC_ERROR_NONE); if (m->on_read) { grpc_core::ExecCtx::Run( DEBUG_LOCATION, m->on_read, GRPC_ERROR_CREATE_REFERENCING_FROM_STATIC_STRING("Shutdown", &why, 1)); m->on_read = nullptr; } m = other_half(m); flush_pending_ops_locked(m, GRPC_ERROR_NONE); if (m->on_read) { grpc_core::ExecCtx::Run( DEBUG_LOCATION, m->on_read, GRPC_ERROR_CREATE_REFERENCING_FROM_STATIC_STRING("Shutdown", &why, 1)); m->on_read = nullptr; } } static void me_shutdown(grpc_endpoint* ep, grpc_error_handle why) { half* m = reinterpret_cast(ep); gpr_mu_lock(&m->parent->mu); shutdown_locked(m, why); gpr_mu_unlock(&m->parent->mu); } void grpc_passthru_endpoint_destroy(passthru_endpoint* p) { gpr_mu_destroy(&p->mu); grpc_passthru_endpoint_stats_destroy(p->stats); delete p->channel_effects; grpc_slice_buffer_destroy(&p->client.read_buffer); grpc_slice_buffer_destroy(&p->server.read_buffer); grpc_slice_buffer_destroy(&p->client.write_buffer); grpc_slice_buffer_destroy(&p->server.write_buffer); gpr_free(p); } static void me_destroy(grpc_endpoint* ep) { passthru_endpoint* p = (reinterpret_cast(ep))->parent; gpr_mu_lock(&p->mu); if (0 == --p->halves && p->channel_effects->actions.empty()) { // no pending channel actions exist gpr_mu_unlock(&p->mu); grpc_passthru_endpoint_destroy(p); } else { if (p->halves == 0 && p->simulate_channel_actions) { grpc_timer_cancel(&p->channel_effects->timer); } gpr_mu_unlock(&p->mu); } } static absl::string_view me_get_peer(grpc_endpoint* ep) { passthru_endpoint* p = (reinterpret_cast(ep))->parent; return (reinterpret_cast(ep)) == &p->client ? "fake:mock_client_endpoint" : "fake:mock_server_endpoint"; } static absl::string_view me_get_local_address(grpc_endpoint* ep) { passthru_endpoint* p = (reinterpret_cast(ep))->parent; return (reinterpret_cast(ep)) == &p->client ? "fake:mock_client_endpoint" : "fake:mock_server_endpoint"; } static int me_get_fd(grpc_endpoint* /*ep*/) { return -1; } static bool me_can_track_err(grpc_endpoint* /*ep*/) { return false; } static const grpc_endpoint_vtable vtable = { me_read, me_write, me_add_to_pollset, me_add_to_pollset_set, me_delete_from_pollset_set, me_shutdown, me_destroy, me_get_peer, me_get_local_address, me_get_fd, me_can_track_err, }; static void half_init(half* m, passthru_endpoint* parent, const char* half_name) { m->base.vtable = &vtable; m->parent = parent; grpc_slice_buffer_init(&m->read_buffer); grpc_slice_buffer_init(&m->write_buffer); m->pending_write_op.slices = nullptr; m->on_read = nullptr; m->bytes_read_so_far = 0; m->bytes_written_so_far = 0; m->pending_write_op.is_armed = false; m->pending_read_op.is_armed = false; std::string name = absl::StrFormat("passthru_endpoint_%s_%p", half_name, parent); } void grpc_passthru_endpoint_create(grpc_endpoint** client, grpc_endpoint** server, grpc_passthru_endpoint_stats* stats, bool simulate_channel_actions) { passthru_endpoint* m = static_cast(gpr_malloc(sizeof(*m))); m->halves = 2; m->shutdown = false; if (stats == nullptr) { m->stats = grpc_passthru_endpoint_stats_create(); } else { gpr_ref(&stats->refs); m->stats = stats; } m->channel_effects = new grpc_passthru_endpoint_channel_effects(); m->simulate_channel_actions = simulate_channel_actions; if (!simulate_channel_actions) { m->channel_effects->allowed_read_bytes = UINT64_MAX; m->channel_effects->allowed_write_bytes = UINT64_MAX; } half_init(&m->client, m, "client"); half_init(&m->server, m, "server"); gpr_mu_init(&m->mu); *client = &m->client.base; *server = &m->server.base; } grpc_passthru_endpoint_stats* grpc_passthru_endpoint_stats_create() { grpc_passthru_endpoint_stats* stats = static_cast( gpr_malloc(sizeof(grpc_passthru_endpoint_stats))); memset(stats, 0, sizeof(*stats)); gpr_ref_init(&stats->refs, 1); return stats; } void grpc_passthru_endpoint_stats_destroy(grpc_passthru_endpoint_stats* stats) { if (gpr_unref(&stats->refs)) { gpr_free(stats); } } static void sched_next_channel_action_locked(half* m); static void do_next_sched_channel_action(void* arg, grpc_error_handle error) { half* m = reinterpret_cast(arg); gpr_mu_lock(&m->parent->mu); GPR_ASSERT(!m->parent->channel_effects->actions.empty()); if (m->parent->halves == 0) { gpr_mu_unlock(&m->parent->mu); grpc_passthru_endpoint_destroy(m->parent); return; } auto curr_action = m->parent->channel_effects->actions[0]; m->parent->channel_effects->actions.erase( m->parent->channel_effects->actions.begin()); m->parent->channel_effects->allowed_read_bytes += curr_action.add_n_readable_bytes; m->parent->channel_effects->allowed_write_bytes += curr_action.add_n_writable_bytes; flush_pending_ops_locked(m, error); flush_pending_ops_locked(other_half(m), error); sched_next_channel_action_locked(m); gpr_mu_unlock(&m->parent->mu); } static void sched_next_channel_action_locked(half* m) { if (m->parent->channel_effects->actions.empty()) { grpc_error_handle err = GRPC_ERROR_CREATE_FROM_STATIC_STRING("Channel actions complete"); shutdown_locked(m, err); return; } grpc_timer_init(&m->parent->channel_effects->timer, grpc_core::Duration::Milliseconds( m->parent->channel_effects->actions[0].wait_ms) + grpc_core::Timestamp::Now(), GRPC_CLOSURE_CREATE(do_next_sched_channel_action, m, grpc_schedule_on_exec_ctx)); } void start_scheduling_grpc_passthru_endpoint_channel_effects( grpc_endpoint* ep, const std::vector& actions) { half* m = reinterpret_cast(ep); gpr_mu_lock(&m->parent->mu); if (!m->parent->simulate_channel_actions || m->parent->shutdown) { gpr_mu_unlock(&m->parent->mu); return; } m->parent->channel_effects->actions = actions; sched_next_channel_action_locked(m); gpr_mu_unlock(&m->parent->mu); }