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// Copyright 2020 The Pigweed 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
//
// https://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 "pw_stream/memory_stream.h"
#include "gtest/gtest.h"
#include "pw_preprocessor/compiler.h"
namespace pw::stream {
namespace {
// Size of the in-memory buffer to use for this test.
constexpr size_t kSinkBufferSize = 1013;
struct TestStruct {
uint8_t day;
uint8_t month;
uint16_t year;
};
constexpr TestStruct kExpectedStruct = {.day = 18, .month = 5, .year = 2020};
std::array<std::byte, kSinkBufferSize> memory_buffer;
TEST(MemoryWriter, BytesWritten) {
MemoryWriter memory_writer(memory_buffer);
EXPECT_EQ(memory_writer.bytes_written(), 0u);
Status status =
memory_writer.Write(&kExpectedStruct, sizeof(kExpectedStruct));
EXPECT_EQ(status, OkStatus());
EXPECT_EQ(memory_writer.bytes_written(), sizeof(kExpectedStruct));
} // namespace
TEST(MemoryWriter, ValidateContents) {
MemoryWriter memory_writer(memory_buffer);
EXPECT_TRUE(
memory_writer.Write(&kExpectedStruct, sizeof(kExpectedStruct)).ok());
std::span<const std::byte> written_data = memory_writer.WrittenData();
EXPECT_EQ(written_data.size_bytes(), sizeof(kExpectedStruct));
TestStruct temp;
std::memcpy(&temp, written_data.data(), written_data.size_bytes());
EXPECT_EQ(memcmp(&temp, &kExpectedStruct, sizeof(kExpectedStruct)), 0);
}
TEST(MemoryWriter, MultipleWrites) {
constexpr size_t kTempBufferSize = 72;
std::byte buffer[kTempBufferSize] = {};
for (std::byte& value : memory_buffer) {
value = std::byte(0);
}
MemoryWriter memory_writer(memory_buffer);
size_t counter = 0;
while (memory_writer.ConservativeWriteLimit() >= kTempBufferSize) {
for (size_t i = 0; i < sizeof(buffer); ++i) {
buffer[i] = std::byte(counter++);
}
EXPECT_EQ(memory_writer.Write(std::span(buffer)), OkStatus());
}
EXPECT_GT(memory_writer.ConservativeWriteLimit(), 0u);
EXPECT_LT(memory_writer.ConservativeWriteLimit(), kTempBufferSize);
EXPECT_EQ(memory_writer.Write(std::span(buffer)),
Status::ResourceExhausted());
EXPECT_EQ(memory_writer.bytes_written(), counter);
counter = 0;
for (const std::byte& value : memory_writer.WrittenData()) {
EXPECT_EQ(value, std::byte(counter++));
}
}
TEST(MemoryWriter, FullWriter) {
constexpr size_t kTempBufferSize = 32;
std::byte buffer[kTempBufferSize] = {};
const int fill_byte = 0x25;
memset(buffer, fill_byte, sizeof(buffer));
for (std::byte& value : memory_buffer) {
value = std::byte(0);
}
MemoryWriter memory_writer(memory_buffer);
while (memory_writer.ConservativeWriteLimit() > 0) {
size_t bytes_to_write =
std::min(sizeof(buffer), memory_writer.ConservativeWriteLimit());
EXPECT_EQ(memory_writer.Write(std::span(buffer, bytes_to_write)),
OkStatus());
}
EXPECT_EQ(memory_writer.ConservativeWriteLimit(), 0u);
EXPECT_EQ(memory_writer.Write(std::span(buffer)), Status::OutOfRange());
EXPECT_EQ(memory_writer.bytes_written(), memory_buffer.size());
for (const std::byte& value : memory_writer.WrittenData()) {
EXPECT_EQ(value, std::byte(fill_byte));
}
}
TEST(MemoryWriter, EmptyData) {
std::byte buffer[5] = {};
MemoryWriter memory_writer(memory_buffer);
EXPECT_EQ(memory_writer.Write(buffer, 0), OkStatus());
EXPECT_EQ(memory_writer.bytes_written(), 0u);
}
TEST(MemoryWriter, ValidateContents_SingleByteWrites) {
MemoryWriter memory_writer(memory_buffer);
EXPECT_TRUE(memory_writer.Write(std::byte{0x01}).ok());
EXPECT_EQ(memory_writer.bytes_written(), 1u);
EXPECT_EQ(memory_writer.data()[0], std::byte{0x01});
EXPECT_TRUE(memory_writer.Write(std::byte{0x7E}).ok());
EXPECT_EQ(memory_writer.bytes_written(), 2u);
EXPECT_EQ(memory_writer.data()[1], std::byte{0x7E});
}
#define TESTING_CHECK_FAILURES_IS_SUPPORTED 0
#if TESTING_CHECK_FAILURES_IS_SUPPORTED
// TODO(amontanez): Ensure that this test triggers an assert.
TEST(MemoryWriter, NullPointer) {
MemoryWriter memory_writer(memory_buffer);
memory_writer.Write(nullptr, 21);
}
// TODO(davidrogers): Ensure that this test triggers an assert.
TEST(MemoryReader, NullSpan) {
ByteSpan dest(nullptr, 5);
MemoryReader memory_reader(memory_buffer);
memory_reader.Read(dest);
}
// TODO(davidrogers): Ensure that this test triggers an assert.
TEST(MemoryReader, NullPointer) {
MemoryReader memory_reader(memory_buffer);
memory_reader.Read(nullptr, 21);
}
#endif // TESTING_CHECK_FAILURES_IS_SUPPORTED
TEST(MemoryReader, SingleFullRead) {
constexpr size_t kTempBufferSize = 32;
std::array<std::byte, kTempBufferSize> source;
std::array<std::byte, kTempBufferSize> dest;
uint8_t counter = 0;
for (std::byte& value : source) {
value = std::byte(counter++);
}
MemoryReader memory_reader(source);
// Read exactly the available bytes.
EXPECT_EQ(memory_reader.ConservativeReadLimit(), dest.size());
Result<ByteSpan> result = memory_reader.Read(dest);
EXPECT_EQ(result.status(), OkStatus());
EXPECT_EQ(result.value().size_bytes(), dest.size());
ASSERT_EQ(source.size(), result.value().size_bytes());
for (size_t i = 0; i < source.size(); i++) {
EXPECT_EQ(source[i], result.value()[i]);
}
// Shoud be no byte remaining.
EXPECT_EQ(memory_reader.ConservativeReadLimit(), 0u);
result = memory_reader.Read(dest);
EXPECT_EQ(result.status(), Status::OutOfRange());
}
TEST(MemoryReader, EmptySpanRead) {
constexpr size_t kTempBufferSize = 32;
std::array<std::byte, kTempBufferSize> source;
// Use a span with nullptr and zero length;
ByteSpan dest(nullptr, 0);
EXPECT_EQ(dest.size_bytes(), 0u);
MemoryReader memory_reader(source);
// Read exactly the available bytes.
Result<ByteSpan> result = memory_reader.Read(dest);
EXPECT_EQ(result.status(), OkStatus());
EXPECT_EQ(result.value().size_bytes(), 0u);
EXPECT_EQ(result.value().data(), dest.data());
// Shoud be original bytes remaining.
EXPECT_EQ(memory_reader.ConservativeReadLimit(), source.size());
}
TEST(MemoryReader, SinglePartialRead) {
constexpr size_t kTempBufferSize = 32;
std::array<std::byte, kTempBufferSize> source;
std::array<std::byte, kTempBufferSize * 2> dest;
uint8_t counter = 0;
for (std::byte& value : source) {
value = std::byte(counter++);
}
MemoryReader memory_reader(source);
// Try and read double the bytes available. Use the pointer/size version of
// the API.
Result<ByteSpan> result = memory_reader.Read(dest.data(), dest.size());
EXPECT_EQ(result.status(), OkStatus());
EXPECT_EQ(result.value().size_bytes(), source.size());
ASSERT_EQ(source.size(), result.value().size_bytes());
for (size_t i = 0; i < source.size(); i++) {
EXPECT_EQ(source[i], result.value()[i]);
}
// Shoud be no byte remaining.
EXPECT_EQ(memory_reader.ConservativeReadLimit(), 0u);
result = memory_reader.Read(dest);
EXPECT_EQ(result.status(), Status::OutOfRange());
}
TEST(MemoryReader, MultipleReads) {
constexpr size_t kTempBufferSize = 32;
std::array<std::byte, kTempBufferSize * 5> source;
std::array<std::byte, kTempBufferSize> dest;
uint8_t counter = 0;
for (std::byte& value : source) {
value = std::byte(counter++);
}
MemoryReader memory_reader(source);
size_t source_chunk_base = 0;
while (memory_reader.ConservativeReadLimit() > 0) {
size_t read_limit = memory_reader.ConservativeReadLimit();
// Try and read a chunk of bytes.
Result<ByteSpan> result = memory_reader.Read(dest);
EXPECT_EQ(result.status(), OkStatus());
EXPECT_EQ(result.value().size_bytes(), dest.size());
EXPECT_EQ(memory_reader.ConservativeReadLimit(),
read_limit - result.value().size_bytes());
// Verify the chunk of byte that was read.
for (size_t i = 0; i < result.value().size_bytes(); i++) {
EXPECT_EQ(source[source_chunk_base + i], result.value()[i]);
}
source_chunk_base += result.value().size_bytes();
}
}
} // namespace
} // namespace pw::stream