// Copyright 2013 The Chromium Authors // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "net/spdy/spdy_read_queue.h" #include #include #include #include #include #include "base/functional/bind.h" #include "base/functional/callback.h" #include "net/spdy/spdy_buffer.h" #include "testing/gtest/include/gtest/gtest.h" namespace net::test { namespace { const char kData[] = "SPDY read queue test data.\0Some more data."; const size_t kDataSize = std::size(kData); // Enqueues |data| onto |queue| in chunks of at most |max_buffer_size| // bytes. void EnqueueString(const std::string& data, size_t max_buffer_size, SpdyReadQueue* queue) { ASSERT_GT(data.size(), 0u); ASSERT_GT(max_buffer_size, 0u); size_t old_total_size = queue->GetTotalSize(); for (size_t i = 0; i < data.size();) { size_t buffer_size = std::min(data.size() - i, max_buffer_size); queue->Enqueue(std::make_unique(data.data() + i, buffer_size)); i += buffer_size; EXPECT_FALSE(queue->IsEmpty()); EXPECT_EQ(old_total_size + i, queue->GetTotalSize()); } } // Dequeues all bytes in |queue| in chunks of at most // |max_buffer_size| bytes and returns the data as a string. std::string DrainToString(size_t max_buffer_size, SpdyReadQueue* queue) { std::string data; // Pad the buffer so we can detect out-of-bound writes. size_t padding = std::max(static_cast(4096), queue->GetTotalSize()); size_t buffer_size_with_padding = padding + max_buffer_size + padding; auto buffer = std::make_unique(buffer_size_with_padding); std::memset(buffer.get(), 0, buffer_size_with_padding); char* buffer_data = buffer.get() + padding; while (!queue->IsEmpty()) { size_t old_total_size = queue->GetTotalSize(); EXPECT_GT(old_total_size, 0u); size_t dequeued_bytes = queue->Dequeue(buffer_data, max_buffer_size); // Make sure |queue| doesn't write past either end of its given // boundaries. for (int i = 1; i <= static_cast(padding); ++i) { EXPECT_EQ('\0', buffer_data[-i]) << -i; } for (size_t i = 0; i < padding; ++i) { EXPECT_EQ('\0', buffer_data[max_buffer_size + i]) << i; } data.append(buffer_data, dequeued_bytes); EXPECT_EQ(dequeued_bytes, std::min(max_buffer_size, dequeued_bytes)); EXPECT_EQ(queue->GetTotalSize(), old_total_size - dequeued_bytes); } EXPECT_TRUE(queue->IsEmpty()); return data; } // Enqueue a test string with the given enqueue/dequeue max buffer // sizes. void RunEnqueueDequeueTest(size_t enqueue_max_buffer_size, size_t dequeue_max_buffer_size) { std::string data(kData, kDataSize); SpdyReadQueue read_queue; EnqueueString(data, enqueue_max_buffer_size, &read_queue); const std::string& drained_data = DrainToString(dequeue_max_buffer_size, &read_queue); EXPECT_EQ(data, drained_data); } void OnBufferDiscarded(bool* discarded, size_t* discarded_bytes, size_t delta, SpdyBuffer::ConsumeSource consume_source) { EXPECT_EQ(SpdyBuffer::DISCARD, consume_source); *discarded = true; *discarded_bytes = delta; } } // namespace class SpdyReadQueueTest : public ::testing::Test {}; // Call RunEnqueueDequeueTest() with various buffer size combinatinos. TEST_F(SpdyReadQueueTest, LargeEnqueueAndDequeueBuffers) { RunEnqueueDequeueTest(2 * kDataSize, 2 * kDataSize); } TEST_F(SpdyReadQueueTest, OneByteEnqueueAndDequeueBuffers) { RunEnqueueDequeueTest(1, 1); } TEST_F(SpdyReadQueueTest, CoprimeBufferSizes) { RunEnqueueDequeueTest(2, 3); RunEnqueueDequeueTest(3, 2); } TEST_F(SpdyReadQueueTest, Clear) { auto buffer = std::make_unique(kData, kDataSize); bool discarded = false; size_t discarded_bytes = 0; buffer->AddConsumeCallback( base::BindRepeating(&OnBufferDiscarded, &discarded, &discarded_bytes)); SpdyReadQueue read_queue; read_queue.Enqueue(std::move(buffer)); EXPECT_FALSE(discarded); EXPECT_EQ(0u, discarded_bytes); EXPECT_FALSE(read_queue.IsEmpty()); read_queue.Clear(); EXPECT_TRUE(discarded); EXPECT_EQ(kDataSize, discarded_bytes); EXPECT_TRUE(read_queue.IsEmpty()); } } // namespace net::test