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webrtc_m130/webrtc/base/buffer_unittest.cc
ossu b01c7816a8 Added functional variants of Buffer::SetData and Buffer::AppendData. 
They are invoked with the maximum size of the data to be added, and a
callable that generates that data, like this:

buffer.AppendData(10, [] (rtc::ArrayView<uint8_t> av) {
    for (uint8_t i = 0; i != 5; ++i)
      av[i] = i;

    return 5;
  });

The callable returns the number of bytes actually written, and the
final Buffer size will be adjusted accordingly. SetData and AppendData
both return the number of bytes added (i.e. the return value of the
callable).

These versions will be useful when converting AudioEncoder::Encode to use Buffer rather than raw pointers.

Also added a few tests for the new functionality.

Review URL: https://codereview.webrtc.org/1717273002

Cr-Commit-Position: refs/heads/master@{#11733}
2016-02-24 09:06:02 +00:00

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/*
* Copyright 2004 The WebRTC Project Authors. All rights reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "webrtc/base/buffer.h"
#include "webrtc/base/gunit.h"
#include <algorithm> // std::swap (pre-C++11)
#include <utility> // std::swap (C++11 and later)
namespace rtc {
namespace {
// clang-format off
const uint8_t kTestData[] = {0x0, 0x1, 0x2, 0x3, 0x4, 0x5, 0x6, 0x7,
0x8, 0x9, 0xa, 0xb, 0xc, 0xd, 0xe, 0xf};
// clang-format on
void TestBuf(const Buffer& b1, size_t size, size_t capacity) {
EXPECT_EQ(b1.size(), size);
EXPECT_EQ(b1.capacity(), capacity);
}
} // namespace
TEST(BufferTest, TestConstructEmpty) {
TestBuf(Buffer(), 0, 0);
TestBuf(Buffer(Buffer()), 0, 0);
TestBuf(Buffer(0), 0, 0);
// We can't use a literal 0 for the first argument, because C++ will allow
// that to be considered a null pointer, which makes the call ambiguous.
TestBuf(Buffer(0 + 0, 10), 0, 10);
TestBuf(Buffer(kTestData, 0), 0, 0);
TestBuf(Buffer(kTestData, 0, 20), 0, 20);
}
TEST(BufferTest, TestConstructData) {
Buffer buf(kTestData, 7);
EXPECT_EQ(buf.size(), 7u);
EXPECT_EQ(buf.capacity(), 7u);
EXPECT_EQ(0, memcmp(buf.data(), kTestData, 7));
}
TEST(BufferTest, TestConstructDataWithCapacity) {
Buffer buf(kTestData, 7, 14);
EXPECT_EQ(buf.size(), 7u);
EXPECT_EQ(buf.capacity(), 14u);
EXPECT_EQ(0, memcmp(buf.data(), kTestData, 7));
}
TEST(BufferTest, TestConstructArray) {
Buffer buf(kTestData);
EXPECT_EQ(buf.size(), 16u);
EXPECT_EQ(buf.capacity(), 16u);
EXPECT_EQ(0, memcmp(buf.data(), kTestData, 16));
}
TEST(BufferTest, TestConstructCopy) {
Buffer buf1(kTestData), buf2(buf1);
EXPECT_EQ(buf2.size(), 16u);
EXPECT_EQ(buf2.capacity(), 16u);
EXPECT_EQ(0, memcmp(buf2.data(), kTestData, 16));
EXPECT_NE(buf1.data(), buf2.data());
EXPECT_EQ(buf1, buf2);
}
TEST(BufferTest, TestAssign) {
Buffer buf1, buf2(kTestData, sizeof(kTestData), 256);
EXPECT_NE(buf1, buf2);
buf1 = buf2;
EXPECT_EQ(buf1, buf2);
EXPECT_NE(buf1.data(), buf2.data());
}
TEST(BufferTest, TestSetData) {
Buffer buf(kTestData + 4, 7);
buf.SetData(kTestData, 9);
EXPECT_EQ(buf.size(), 9u);
EXPECT_EQ(buf.capacity(), 9u);
EXPECT_EQ(0, memcmp(buf.data(), kTestData, 9));
}
TEST(BufferTest, TestAppendData) {
Buffer buf(kTestData + 4, 3);
buf.AppendData(kTestData + 10, 2);
const int8_t exp[] = {0x4, 0x5, 0x6, 0xa, 0xb};
EXPECT_EQ(buf, Buffer(exp));
}
TEST(BufferTest, TestSetSizeSmaller) {
Buffer buf;
buf.SetData(kTestData, 15);
buf.SetSize(10);
EXPECT_EQ(buf.size(), 10u);
EXPECT_EQ(buf.capacity(), 15u); // Hasn't shrunk.
EXPECT_EQ(buf, Buffer(kTestData, 10));
}
TEST(BufferTest, TestSetSizeLarger) {
Buffer buf;
buf.SetData(kTestData, 15);
EXPECT_EQ(buf.size(), 15u);
EXPECT_EQ(buf.capacity(), 15u);
buf.SetSize(20);
EXPECT_EQ(buf.size(), 20u);
EXPECT_EQ(buf.capacity(), 20u); // Has grown.
EXPECT_EQ(0, memcmp(buf.data(), kTestData, 15));
}
TEST(BufferTest, TestEnsureCapacitySmaller) {
Buffer buf(kTestData);
const char* data = buf.data<char>();
buf.EnsureCapacity(4);
EXPECT_EQ(buf.capacity(), 16u); // Hasn't shrunk.
EXPECT_EQ(buf.data<char>(), data); // No reallocation.
EXPECT_EQ(buf, Buffer(kTestData));
}
TEST(BufferTest, TestEnsureCapacityLarger) {
Buffer buf(kTestData, 5);
buf.EnsureCapacity(10);
const int8_t* data = buf.data<int8_t>();
EXPECT_EQ(buf.capacity(), 10u);
buf.AppendData(kTestData + 5, 5);
EXPECT_EQ(buf.data<int8_t>(), data); // No reallocation.
EXPECT_EQ(buf, Buffer(kTestData, 10));
}
TEST(BufferTest, TestMoveConstruct) {
Buffer buf1(kTestData, 3, 40);
const uint8_t* data = buf1.data();
Buffer buf2(buf1.DEPRECATED_Pass());
EXPECT_EQ(buf2.size(), 3u);
EXPECT_EQ(buf2.capacity(), 40u);
EXPECT_EQ(buf2.data(), data);
buf1.Clear();
EXPECT_EQ(buf1.size(), 0u);
EXPECT_EQ(buf1.capacity(), 0u);
EXPECT_EQ(buf1.data(), nullptr);
}
TEST(BufferTest, TestMoveAssign) {
Buffer buf1(kTestData, 3, 40);
const uint8_t* data = buf1.data();
Buffer buf2(kTestData);
buf2 = buf1.DEPRECATED_Pass();
EXPECT_EQ(buf2.size(), 3u);
EXPECT_EQ(buf2.capacity(), 40u);
EXPECT_EQ(buf2.data(), data);
buf1.Clear();
EXPECT_EQ(buf1.size(), 0u);
EXPECT_EQ(buf1.capacity(), 0u);
EXPECT_EQ(buf1.data(), nullptr);
}
TEST(BufferTest, TestSwap) {
Buffer buf1(kTestData, 3);
Buffer buf2(kTestData, 6, 40);
uint8_t* data1 = buf1.data();
uint8_t* data2 = buf2.data();
using std::swap;
swap(buf1, buf2);
EXPECT_EQ(buf1.size(), 6u);
EXPECT_EQ(buf1.capacity(), 40u);
EXPECT_EQ(buf1.data(), data2);
EXPECT_EQ(buf2.size(), 3u);
EXPECT_EQ(buf2.capacity(), 3u);
EXPECT_EQ(buf2.data(), data1);
}
TEST(BufferTest, TestClear) {
Buffer buf;
buf.SetData(kTestData, 15);
EXPECT_EQ(buf.size(), 15u);
EXPECT_EQ(buf.capacity(), 15u);
const char *data = buf.data<char>();
buf.Clear();
EXPECT_EQ(buf.size(), 0u);
EXPECT_EQ(buf.capacity(), 15u); // Hasn't shrunk.
EXPECT_EQ(buf.data<char>(), data); // No reallocation.
}
TEST(BufferTest, TestLambdaSetAppend) {
auto setter = [] (rtc::ArrayView<uint8_t> av) {
for (int i = 0; i != 15; ++i)
av[i] = kTestData[i];
return 15;
};
Buffer buf1;
buf1.SetData(kTestData, 15);
buf1.AppendData(kTestData, 15);
Buffer buf2;
EXPECT_EQ(buf2.SetData(15, setter), 15u);
EXPECT_EQ(buf2.AppendData(15, setter), 15u);
EXPECT_EQ(buf1, buf2);
EXPECT_EQ(buf1.capacity(), buf2.capacity());
}
TEST(BufferTest, TestLambdaSetAppendSigned) {
auto setter = [] (rtc::ArrayView<int8_t> av) {
for (int i = 0; i != 15; ++i)
av[i] = kTestData[i];
return 15;
};
Buffer buf1;
buf1.SetData(kTestData, 15);
buf1.AppendData(kTestData, 15);
Buffer buf2;
EXPECT_EQ(buf2.SetData<int8_t>(15, setter), 15u);
EXPECT_EQ(buf2.AppendData<int8_t>(15, setter), 15u);
EXPECT_EQ(buf1, buf2);
EXPECT_EQ(buf1.capacity(), buf2.capacity());
}
TEST(BufferTest, TestLambdaAppendEmpty) {
auto setter = [] (rtc::ArrayView<uint8_t> av) {
for (int i = 0; i != 15; ++i)
av[i] = kTestData[i];
return 15;
};
Buffer buf1;
buf1.SetData(kTestData, 15);
Buffer buf2;
EXPECT_EQ(buf2.AppendData(15, setter), 15u);
EXPECT_EQ(buf1, buf2);
EXPECT_EQ(buf1.capacity(), buf2.capacity());
}
TEST(BufferTest, TestLambdaAppendPartial) {
auto setter = [] (rtc::ArrayView<uint8_t> av) {
for (int i = 0; i != 7; ++i)
av[i] = kTestData[i];
return 7;
};
Buffer buf;
EXPECT_EQ(buf.AppendData(15, setter), 7u);
EXPECT_EQ(buf.size(), 7u); // Size is exactly what we wrote.
EXPECT_GE(buf.capacity(), 7u); // Capacity is valid.
EXPECT_NE(buf.data<char>(), nullptr); // Data is actually stored.
}
TEST(BufferTest, TestMutableLambdaSetAppend) {
uint8_t magic_number = 17;
auto setter = [magic_number] (rtc::ArrayView<uint8_t> av) mutable {
for (int i = 0; i != 15; ++i) {
av[i] = magic_number;
++magic_number;
}
return 15;
};
EXPECT_EQ(magic_number, 17);
Buffer buf;
EXPECT_EQ(buf.SetData(15, setter), 15u);
EXPECT_EQ(buf.AppendData(15, setter), 15u);
EXPECT_EQ(buf.size(), 30u); // Size is exactly what we wrote.
EXPECT_GE(buf.capacity(), 30u); // Capacity is valid.
EXPECT_NE(buf.data<char>(), nullptr); // Data is actually stored.
for (uint8_t i = 0; i != buf.size(); ++i) {
EXPECT_EQ(buf.data()[i], magic_number + i);
}
}
} // namespace rtc
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