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333 lines
12 KiB
333 lines
12 KiB
// |
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// |
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// Copyright 2015 gRPC authors. |
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// |
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// Licensed under the Apache License, Version 2.0 (the "License"); |
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// you may not use this file except in compliance with the License. |
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// You may obtain a copy of the License at |
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// |
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// http://www.apache.org/licenses/LICENSE-2.0 |
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// |
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// Unless required by applicable law or agreed to in writing, software |
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// distributed under the License is distributed on an "AS IS" BASIS, |
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
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// See the License for the specific language governing permissions and |
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// limitations under the License. |
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// |
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// |
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#include "test/core/iomgr/endpoint_tests.h" |
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#include <grpc/slice.h> |
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#include <grpc/support/alloc.h> |
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#include <grpc/support/time.h> |
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#include <limits.h> |
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#include <stdbool.h> |
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#include <sys/types.h> |
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#include "absl/log/check.h" |
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#include "absl/log/log.h" |
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#include "src/core/lib/iomgr/error.h" |
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#include "src/core/lib/slice/slice_internal.h" |
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#include "src/core/util/crash.h" |
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#include "src/core/util/time.h" |
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#include "src/core/util/useful.h" |
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#include "test/core/test_util/test_config.h" |
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// |
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// General test notes: |
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// All tests which write data into an endpoint write i%256 into byte i, which |
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// is verified by readers. |
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// In general there are a few interesting things to vary which may lead to |
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// exercising different codepaths in an implementation: |
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// 1. Total amount of data written to the endpoint |
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// 2. Size of slice allocations |
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// 3. Amount of data we read from or write to the endpoint at once |
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// The tests here tend to parameterize these where applicable. |
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// |
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static gpr_mu* g_mu; |
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static grpc_pollset* g_pollset; |
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size_t count_slices(grpc_slice* slices, size_t nslices, int* current_data) { |
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size_t num_bytes = 0; |
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size_t i; |
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size_t j; |
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unsigned char* buf; |
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for (i = 0; i < nslices; ++i) { |
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buf = GRPC_SLICE_START_PTR(slices[i]); |
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for (j = 0; j < GRPC_SLICE_LENGTH(slices[i]); ++j) { |
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CHECK(buf[j] == *current_data); |
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*current_data = (*current_data + 1) % 256; |
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} |
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num_bytes += GRPC_SLICE_LENGTH(slices[i]); |
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} |
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return num_bytes; |
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} |
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static grpc_endpoint_test_fixture begin_test(grpc_endpoint_test_config config, |
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const char* test_name, |
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size_t slice_size) { |
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LOG(INFO) << test_name << "/" << config.name; |
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return config.create_fixture(slice_size); |
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} |
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static void end_test(grpc_endpoint_test_config config) { config.clean_up(); } |
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static grpc_slice* allocate_blocks(size_t num_bytes, size_t slice_size, |
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size_t* num_blocks, uint8_t* current_data) { |
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size_t nslices = (num_bytes / slice_size) + (num_bytes % slice_size ? 1 : 0); |
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grpc_slice* slices = |
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static_cast<grpc_slice*>(gpr_malloc(sizeof(grpc_slice) * nslices)); |
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size_t num_bytes_left = num_bytes; |
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size_t i; |
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size_t j; |
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unsigned char* buf; |
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*num_blocks = nslices; |
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for (i = 0; i < nslices; ++i) { |
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slices[i] = grpc_slice_malloc(slice_size > num_bytes_left ? num_bytes_left |
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: slice_size); |
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num_bytes_left -= GRPC_SLICE_LENGTH(slices[i]); |
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buf = GRPC_SLICE_START_PTR(slices[i]); |
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for (j = 0; j < GRPC_SLICE_LENGTH(slices[i]); ++j) { |
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buf[j] = *current_data; |
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(*current_data)++; |
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} |
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} |
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CHECK_EQ(num_bytes_left, 0u); |
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return slices; |
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} |
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struct read_and_write_test_state { |
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grpc_core::Mutex ep_mu; // Guards read_ep and write_ep. |
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grpc_endpoint* read_ep; |
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grpc_endpoint* write_ep; |
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size_t target_bytes; |
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size_t bytes_read; |
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size_t current_write_size; |
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size_t bytes_written; |
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int current_read_data; |
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uint8_t current_write_data; |
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int read_done; |
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int write_done; |
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int max_write_frame_size; |
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grpc_slice_buffer incoming; |
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grpc_slice_buffer outgoing; |
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grpc_closure done_read; |
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grpc_closure done_write; |
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grpc_closure read_scheduler; |
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grpc_closure write_scheduler; |
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}; |
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static void read_scheduler(void* data, grpc_error_handle error) { |
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struct read_and_write_test_state* state = |
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static_cast<struct read_and_write_test_state*>(data); |
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if (error.ok() && state->bytes_read < state->target_bytes) { |
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grpc_core::MutexLock lock(&state->ep_mu); |
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if (state->read_ep != nullptr) { |
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grpc_endpoint_read(state->read_ep, &state->incoming, &state->done_read, |
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/*urgent=*/false, /*min_progress_size=*/1); |
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return; |
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} |
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} |
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VLOG(2) << "Read handler done"; |
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gpr_mu_lock(g_mu); |
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state->read_done = 1 + error.ok(); |
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GRPC_LOG_IF_ERROR("pollset_kick", grpc_pollset_kick(g_pollset, nullptr)); |
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gpr_mu_unlock(g_mu); |
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} |
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static void read_and_write_test_read_handler(void* data, |
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grpc_error_handle error) { |
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struct read_and_write_test_state* state = |
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static_cast<struct read_and_write_test_state*>(data); |
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if (error.ok()) { |
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state->bytes_read += |
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count_slices(state->incoming.slices, state->incoming.count, |
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&state->current_read_data); |
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} |
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// We perform many reads one after another. If grpc_endpoint_read and the |
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// read_handler are both run inline, we might end up growing the stack |
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// beyond the limit. Schedule the read on ExecCtx to avoid this. |
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grpc_core::ExecCtx::Run(DEBUG_LOCATION, &state->read_scheduler, |
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std::move(error)); |
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} |
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static void write_scheduler(void* data, grpc_error_handle error) { |
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struct read_and_write_test_state* state = |
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static_cast<struct read_and_write_test_state*>(data); |
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if (error.ok() && state->current_write_size != 0) { |
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grpc_core::MutexLock lock(&state->ep_mu); |
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if (state->write_ep != nullptr) { |
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grpc_endpoint_write(state->write_ep, &state->outgoing, &state->done_write, |
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nullptr, |
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/*max_frame_size=*/state->max_write_frame_size); |
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return; |
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} |
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} |
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VLOG(2) << "Write handler done"; |
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gpr_mu_lock(g_mu); |
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state->write_done = 1 + error.ok(); |
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GRPC_LOG_IF_ERROR("pollset_kick", grpc_pollset_kick(g_pollset, nullptr)); |
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gpr_mu_unlock(g_mu); |
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} |
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static void read_and_write_test_write_handler(void* data, |
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grpc_error_handle error) { |
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struct read_and_write_test_state* state = |
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static_cast<struct read_and_write_test_state*>(data); |
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if (error.ok()) { |
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state->bytes_written += state->current_write_size; |
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if (state->target_bytes - state->bytes_written < |
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state->current_write_size) { |
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state->current_write_size = state->target_bytes - state->bytes_written; |
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} |
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if (state->current_write_size != 0) { |
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size_t nslices; |
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grpc_slice* slices = |
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allocate_blocks(state->current_write_size, 8192, &nslices, |
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&state->current_write_data); |
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grpc_slice_buffer_reset_and_unref(&state->outgoing); |
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grpc_slice_buffer_addn(&state->outgoing, slices, nslices); |
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gpr_free(slices); |
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} |
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} |
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// We perform many writes one after another. If grpc_endpoint_write and |
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// the write_handler are both run inline, we might end up growing the |
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// stack beyond the limit. Schedule the write on ExecCtx to avoid this. |
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grpc_core::ExecCtx::Run(DEBUG_LOCATION, &state->write_scheduler, |
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std::move(error)); |
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} |
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// Do both reading and writing using the grpc_endpoint API. |
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// This also includes a test of the shutdown behavior. |
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// |
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static void read_and_write_test(grpc_endpoint_test_config config, |
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size_t num_bytes, size_t write_size, |
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size_t slice_size, int max_write_frame_size, |
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bool shutdown) { |
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struct read_and_write_test_state state; |
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grpc_endpoint_test_fixture f = |
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begin_test(config, "read_and_write_test", slice_size); |
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grpc_core::ExecCtx exec_ctx; |
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auto deadline = grpc_core::Timestamp::FromTimespecRoundUp( |
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grpc_timeout_seconds_to_deadline(300)); |
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VLOG(2) << "num_bytes=" << num_bytes << " write_size=" << write_size |
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<< " slice_size=" << slice_size << " shutdown=" << shutdown; |
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if (shutdown) { |
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LOG(INFO) << "Start read and write shutdown test"; |
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} else { |
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LOG(INFO) << "Start read and write test with " << num_bytes |
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<< " bytes, slice size " << slice_size; |
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} |
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state.read_ep = f.client_ep; |
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state.write_ep = f.server_ep; |
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state.target_bytes = num_bytes; |
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state.bytes_read = 0; |
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state.current_write_size = write_size; |
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state.max_write_frame_size = max_write_frame_size; |
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state.bytes_written = 0; |
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state.read_done = 0; |
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state.write_done = 0; |
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state.current_read_data = 0; |
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state.current_write_data = 0; |
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GRPC_CLOSURE_INIT(&state.read_scheduler, read_scheduler, &state, |
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grpc_schedule_on_exec_ctx); |
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GRPC_CLOSURE_INIT(&state.done_read, read_and_write_test_read_handler, &state, |
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grpc_schedule_on_exec_ctx); |
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GRPC_CLOSURE_INIT(&state.write_scheduler, write_scheduler, &state, |
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grpc_schedule_on_exec_ctx); |
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GRPC_CLOSURE_INIT(&state.done_write, read_and_write_test_write_handler, |
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&state, grpc_schedule_on_exec_ctx); |
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grpc_slice_buffer_init(&state.outgoing); |
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grpc_slice_buffer_init(&state.incoming); |
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// Get started by pretending an initial write completed |
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// NOTE: Sets up initial conditions so we can have the same write handler |
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// for the first iteration as for later iterations. It does the right thing |
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// even when bytes_written is unsigned. |
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state.bytes_written -= state.current_write_size; |
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read_and_write_test_write_handler(&state, absl::OkStatus()); |
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grpc_core::ExecCtx::Get()->Flush(); |
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grpc_endpoint_read(state.read_ep, &state.incoming, &state.done_read, |
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/*urgent=*/false, /*min_progress_size=*/1); |
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if (shutdown) { |
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grpc_core::MutexLock lock(&state.ep_mu); |
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VLOG(2) << "shutdown read"; |
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grpc_endpoint_destroy(state.read_ep); |
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state.read_ep = nullptr; |
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VLOG(2) << "shutdown write"; |
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grpc_endpoint_destroy(state.write_ep); |
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state.write_ep = nullptr; |
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} |
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grpc_core::ExecCtx::Get()->Flush(); |
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gpr_mu_lock(g_mu); |
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while (!state.read_done || !state.write_done) { |
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grpc_pollset_worker* worker = nullptr; |
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CHECK(grpc_core::Timestamp::Now() < deadline); |
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CHECK(GRPC_LOG_IF_ERROR("pollset_work", |
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grpc_pollset_work(g_pollset, &worker, deadline))); |
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} |
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gpr_mu_unlock(g_mu); |
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grpc_core::ExecCtx::Get()->Flush(); |
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end_test(config); |
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grpc_slice_buffer_destroy(&state.outgoing); |
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grpc_slice_buffer_destroy(&state.incoming); |
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if (!shutdown) { |
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grpc_endpoint_destroy(state.read_ep); |
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grpc_endpoint_destroy(state.write_ep); |
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} |
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} |
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static void inc_on_failure(void* arg, grpc_error_handle error) { |
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gpr_mu_lock(g_mu); |
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*static_cast<int*>(arg) += (!error.ok()); |
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CHECK(GRPC_LOG_IF_ERROR("kick", grpc_pollset_kick(g_pollset, nullptr))); |
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gpr_mu_unlock(g_mu); |
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} |
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static void wait_for_fail_count(int* fail_count, int want_fail_count) { |
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grpc_core::ExecCtx::Get()->Flush(); |
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gpr_mu_lock(g_mu); |
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grpc_core::Timestamp deadline = grpc_core::Timestamp::FromTimespecRoundUp( |
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grpc_timeout_seconds_to_deadline(10)); |
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while (grpc_core::Timestamp::Now() < deadline && |
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*fail_count < want_fail_count) { |
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grpc_pollset_worker* worker = nullptr; |
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CHECK(GRPC_LOG_IF_ERROR("pollset_work", |
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grpc_pollset_work(g_pollset, &worker, deadline))); |
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gpr_mu_unlock(g_mu); |
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grpc_core::ExecCtx::Get()->Flush(); |
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gpr_mu_lock(g_mu); |
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} |
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CHECK(*fail_count == want_fail_count); |
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gpr_mu_unlock(g_mu); |
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} |
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void grpc_endpoint_tests(grpc_endpoint_test_config config, |
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grpc_pollset* pollset, gpr_mu* mu) { |
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size_t i; |
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g_pollset = pollset; |
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g_mu = mu; |
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for (int i = 1; i <= 10000; i = i * 10) { |
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read_and_write_test(config, 10000000, 100000, 8192, i, false); |
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read_and_write_test(config, 1000000, 100000, 1, i, false); |
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read_and_write_test(config, 100000000, 100000, 1, i, true); |
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} |
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for (i = 1; i < 1000; i = std::max(i + 1, i * 5 / 4)) { |
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read_and_write_test(config, 40320, i, i, i, false); |
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} |
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g_pollset = nullptr; |
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g_mu = nullptr; |
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}
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