modules/rtp_rtcp/source/byte_io_unittest.cc - mirrors/cros/chromiumos/third_party/webrtc-apm - Git at Google

 /*
  *  Copyright (c) 2012 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 <limits>

 #include "modules/rtp_rtcp/source/byte_io.h"
 #include "test/gtest.h"

 namespace webrtc {
 namespace {

 class ByteIoTest : public ::testing::Test {
  protected:
   ByteIoTest() = default;
   ~ByteIoTest() override = default;

   enum { kAlignments = sizeof(uint64_t) - 1 };

   // Method to create a test value that is not the same when byte reversed.
   template <typename T>
   T CreateTestValue(bool negative, uint8_t num_bytes) {
     // Examples of output:
     // T = int32_t, negative = false, num_bytes = 4: 0x00010203
     // T = int32_t, negative = true, num_bytes = 4: 0xFFFEFDFC
     // T = int32_t, negative = false, num_bytes = 3: 0x000102
     // * T = int32_t, negative = true, num_bytes = 3: 0xFFFEFD

     T val = 0;
     for (uint8_t i = 0; i != num_bytes; ++i) {
       val = (val << 8) + (negative ? (0xFF - i) : (i + 1));
     }

     // This loop will create a sign extend mask if num_bytes if necessary.
     // For the last example (marked * above), the number needs to be sign
     // extended to be a valid int32_t. The sign extend mask is 0xFF000000.
     // Comments for each step with this example below.
     if (std::numeric_limits<T>::is_signed && negative &&
         num_bytes < sizeof(T)) {
       // Start with mask = 0xFFFFFFFF.
       T mask = static_cast<T>(-1);
       // Create a temporary for the lowest byte (0x000000FF).
       const T neg_byte = static_cast<T>(0xFF);
       for (int i = 0; i < num_bytes; ++i) {
         // And the inverse of the temporary and the mask:
         // 0xFFFFFFFF & 0xFFFFFF00 = 0xFFFFFF00.
         // 0xFFFFFF00 & 0xFFFF00FF = 0xFFFF0000.
         // 0xFFFF0000 & 0xFF00FFFF = 0xFF000000.
         mask &= ~(neg_byte << (i * 8));
       }
       // Add the sign extension mask to the actual value.
       val |= mask;
     }
     return val;
   }

   // Populate byte buffer with value, in big endian format.
   template <typename T>
   void PopulateTestData(uint8_t* data, T value, int num_bytes, bool bigendian) {
     if (bigendian) {
       for (int i = 0; i < num_bytes; ++i) {
         data[i] = (value >> ((num_bytes - i - 1) * 8)) & 0xFF;
       }
     } else {
       for (int i = 0; i < num_bytes; ++i) {
         data[i] = (value >> (i * 8)) & 0xFF;
       }
     }
   }

   // Test reading big endian numbers.
   // Template arguments: Type T, read method RM(buffer), B bytes of data.
   template <typename T, T (*RM)(const uint8_t*), int B>
   void TestRead(bool big_endian) {
     // Test both for values that are positive and negative (if signed)
     for (int neg = 0; neg < 2; ++neg) {
       bool negative = neg > 0;

       // Write test value to byte buffer, in big endian format.
       T test_value = CreateTestValue<T>(negative, B);
       uint8_t bytes[B + kAlignments];

       // Make one test for each alignment.
       for (int i = 0; i < kAlignments; ++i) {
         PopulateTestData(bytes + i, test_value, B, big_endian);

         // Check that test value is retrieved from buffer when used read method.
         EXPECT_EQ(test_value, RM(bytes + i));
       }
     }
   }

   // Test writing big endian numbers.
   // Template arguments: Type T, write method WM(buffer, value), B bytes of data
   template <typename T, void (*WM)(uint8_t*, T), int B>
   void TestWrite(bool big_endian) {
     // Test both for values that are positive and negative (if signed).
     for (int neg = 0; neg < 2; ++neg) {
       bool negative = neg > 0;

       // Write test value to byte buffer, in big endian format.
       T test_value = CreateTestValue<T>(negative, B);
       uint8_t expected_bytes[B + kAlignments];
       uint8_t bytes[B + kAlignments];

       // Make one test for each alignment.
       for (int i = 0; i < kAlignments; ++i) {
         PopulateTestData(expected_bytes + i, test_value, B, big_endian);

         // Zero initialize buffer and let WM populate it.
         memset(bytes, 0, B + kAlignments);
         WM(bytes + i, test_value);

         // Check that data produced by WM is big endian as expected.
         for (int j = 0; j < B; ++j) {
           EXPECT_EQ(expected_bytes[i + j], bytes[i + j]);
         }
       }
     }
   }
 };

 TEST_F(ByteIoTest, Test16UBitBigEndian) {
   TestRead<uint16_t, ByteReader<uint16_t>::ReadBigEndian, sizeof(uint16_t)>(
       true);
   TestWrite<uint16_t, ByteWriter<uint16_t>::WriteBigEndian, sizeof(uint16_t)>(
       true);
 }

 TEST_F(ByteIoTest, Test24UBitBigEndian) {
   TestRead<uint32_t, ByteReader<uint32_t, 3>::ReadBigEndian, 3>(true);
   TestWrite<uint32_t, ByteWriter<uint32_t, 3>::WriteBigEndian, 3>(true);
 }

 TEST_F(ByteIoTest, Test32UBitBigEndian) {
   TestRead<uint32_t, ByteReader<uint32_t>::ReadBigEndian, sizeof(uint32_t)>(
       true);
   TestWrite<uint32_t, ByteWriter<uint32_t>::WriteBigEndian, sizeof(uint32_t)>(
       true);
 }

 TEST_F(ByteIoTest, Test64UBitBigEndian) {
   TestRead<uint64_t, ByteReader<uint64_t>::ReadBigEndian, sizeof(uint64_t)>(
       true);
   TestWrite<uint64_t, ByteWriter<uint64_t>::WriteBigEndian, sizeof(uint64_t)>(
       true);
 }

 TEST_F(ByteIoTest, Test16SBitBigEndian) {
   TestRead<int16_t, ByteReader<int16_t>::ReadBigEndian, sizeof(int16_t)>(true);
   TestWrite<int16_t, ByteWriter<int16_t>::WriteBigEndian, sizeof(int16_t)>(
       true);
 }

 TEST_F(ByteIoTest, Test24SBitBigEndian) {
   TestRead<int32_t, ByteReader<int32_t, 3>::ReadBigEndian, 3>(true);
   TestWrite<int32_t, ByteWriter<int32_t, 3>::WriteBigEndian, 3>(true);
 }

 TEST_F(ByteIoTest, Test32SBitBigEndian) {
   TestRead<int32_t, ByteReader<int32_t>::ReadBigEndian, sizeof(int32_t)>(true);
   TestWrite<int32_t, ByteWriter<int32_t>::WriteBigEndian, sizeof(int32_t)>(
       true);
 }

 TEST_F(ByteIoTest, Test64SBitBigEndian) {
   TestRead<int64_t, ByteReader<int64_t>::ReadBigEndian, sizeof(int64_t)>(true);
   TestWrite<int64_t, ByteWriter<int64_t>::WriteBigEndian, sizeof(int64_t)>(
       true);
 }

 TEST_F(ByteIoTest, Test16UBitLittleEndian) {
   TestRead<uint16_t, ByteReader<uint16_t>::ReadLittleEndian, sizeof(uint16_t)>(
       false);
   TestWrite<uint16_t, ByteWriter<uint16_t>::WriteLittleEndian,
             sizeof(uint16_t)>(false);
 }

 TEST_F(ByteIoTest, Test24UBitLittleEndian) {
   TestRead<uint32_t, ByteReader<uint32_t, 3>::ReadLittleEndian, 3>(false);
   TestWrite<uint32_t, ByteWriter<uint32_t, 3>::WriteLittleEndian, 3>(false);
 }

 TEST_F(ByteIoTest, Test32UBitLittleEndian) {
   TestRead<uint32_t, ByteReader<uint32_t>::ReadLittleEndian, sizeof(uint32_t)>(
       false);
   TestWrite<uint32_t, ByteWriter<uint32_t>::WriteLittleEndian,
             sizeof(uint32_t)>(false);
 }

 TEST_F(ByteIoTest, Test64UBitLittleEndian) {
   TestRead<uint64_t, ByteReader<uint64_t>::ReadLittleEndian, sizeof(uint64_t)>(
       false);
   TestWrite<uint64_t, ByteWriter<uint64_t>::WriteLittleEndian,
             sizeof(uint64_t)>(false);
 }

 TEST_F(ByteIoTest, Test16SBitLittleEndian) {
   TestRead<int16_t, ByteReader<int16_t>::ReadLittleEndian, sizeof(int16_t)>(
       false);
   TestWrite<int16_t, ByteWriter<int16_t>::WriteLittleEndian, sizeof(int16_t)>(
       false);
 }

 TEST_F(ByteIoTest, Test24SBitLittleEndian) {
   TestRead<int32_t, ByteReader<int32_t, 3>::ReadLittleEndian, 3>(false);
   TestWrite<int32_t, ByteWriter<int32_t, 3>::WriteLittleEndian, 3>(false);
 }

 TEST_F(ByteIoTest, Test32SBitLittleEndian) {
   TestRead<int32_t, ByteReader<int32_t>::ReadLittleEndian, sizeof(int32_t)>(
       false);
   TestWrite<int32_t, ByteWriter<int32_t>::WriteLittleEndian, sizeof(int32_t)>(
       false);
 }

 TEST_F(ByteIoTest, Test64SBitLittleEndian) {
   TestRead<int64_t, ByteReader<int64_t>::ReadLittleEndian, sizeof(int64_t)>(
       false);
   TestWrite<int64_t, ByteWriter<int64_t>::WriteLittleEndian, sizeof(int64_t)>(
       false);
 }

 // Sets up a fixed byte array and converts N bytes from the array into a
 // uint64_t. Verifies the value with hard-coded reference.
 TEST(ByteIo, SanityCheckFixedByteArrayUnsignedReadBigEndian) {
   uint8_t data[8] = {0xFF, 0xEE, 0xDD, 0xCC, 0xBB, 0xAA, 0x99, 0x88};
   uint64_t value = ByteReader<uint64_t, 2>::ReadBigEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xFFEE), value);
   value = ByteReader<uint64_t, 3>::ReadBigEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xFFEEDD), value);
   value = ByteReader<uint64_t, 4>::ReadBigEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xFFEEDDCC), value);
   value = ByteReader<uint64_t, 5>::ReadBigEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xFFEEDDCCBB), value);
   value = ByteReader<uint64_t, 6>::ReadBigEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xFFEEDDCCBBAA), value);
   value = ByteReader<uint64_t, 7>::ReadBigEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xFFEEDDCCBBAA99), value);
   value = ByteReader<uint64_t, 8>::ReadBigEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xFFEEDDCCBBAA9988), value);
 }

 // Same as above, but for little-endian reading.
 TEST(ByteIo, SanityCheckFixedByteArrayUnsignedReadLittleEndian) {
   uint8_t data[8] = {0xFF, 0xEE, 0xDD, 0xCC, 0xBB, 0xAA, 0x99, 0x88};
   uint64_t value = ByteReader<uint64_t, 2>::ReadLittleEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xEEFF), value);
   value = ByteReader<uint64_t, 3>::ReadLittleEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xDDEEFF), value);
   value = ByteReader<uint64_t, 4>::ReadLittleEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xCCDDEEFF), value);
   value = ByteReader<uint64_t, 5>::ReadLittleEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xBBCCDDEEFF), value);
   value = ByteReader<uint64_t, 6>::ReadLittleEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0xAABBCCDDEEFF), value);
   value = ByteReader<uint64_t, 7>::ReadLittleEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0x99AABBCCDDEEFF), value);
   value = ByteReader<uint64_t, 8>::ReadLittleEndian(data);
   EXPECT_EQ(static_cast<uint64_t>(0x8899AABBCCDDEEFF), value);
 }
 }  // namespace
 }  // namespace webrtc
	/*
	* Copyright (c) 2012 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 <limits>

	#include "modules/rtp_rtcp/source/byte_io.h"
	#include "test/gtest.h"

	namespace webrtc {
	namespace {

	class ByteIoTest : public ::testing::Test {
	protected:
	ByteIoTest() = default;
	~ByteIoTest() override = default;

	enum { kAlignments = sizeof(uint64_t) - 1 };

	// Method to create a test value that is not the same when byte reversed.
	template <typename T>
	T CreateTestValue(bool negative, uint8_t num_bytes) {
	// Examples of output:
	// T = int32_t, negative = false, num_bytes = 4: 0x00010203
	// T = int32_t, negative = true, num_bytes = 4: 0xFFFEFDFC
	// T = int32_t, negative = false, num_bytes = 3: 0x000102
	// * T = int32_t, negative = true, num_bytes = 3: 0xFFFEFD

	T val = 0;
	for (uint8_t i = 0; i != num_bytes; ++i) {
	val = (val << 8) + (negative ? (0xFF - i) : (i + 1));
	}

	// This loop will create a sign extend mask if num_bytes if necessary.
	// For the last example (marked * above), the number needs to be sign
	// extended to be a valid int32_t. The sign extend mask is 0xFF000000.
	// Comments for each step with this example below.
	if (std::numeric_limits<T>::is_signed && negative &&
	num_bytes < sizeof(T)) {
	// Start with mask = 0xFFFFFFFF.
	T mask = static_cast<T>(-1);
	// Create a temporary for the lowest byte (0x000000FF).
	const T neg_byte = static_cast<T>(0xFF);
	for (int i = 0; i < num_bytes; ++i) {
	// And the inverse of the temporary and the mask:
	// 0xFFFFFFFF & 0xFFFFFF00 = 0xFFFFFF00.
	// 0xFFFFFF00 & 0xFFFF00FF = 0xFFFF0000.
	// 0xFFFF0000 & 0xFF00FFFF = 0xFF000000.
	mask &= ~(neg_byte << (i * 8));
	}
	// Add the sign extension mask to the actual value.
	val \|= mask;
	}
	return val;
	}

	// Populate byte buffer with value, in big endian format.
	template <typename T>
	void PopulateTestData(uint8_t* data, T value, int num_bytes, bool bigendian) {
	if (bigendian) {
	for (int i = 0; i < num_bytes; ++i) {
	data[i] = (value >> ((num_bytes - i - 1) * 8)) & 0xFF;
	}
	} else {
	for (int i = 0; i < num_bytes; ++i) {
	data[i] = (value >> (i * 8)) & 0xFF;
	}
	}
	}

	// Test reading big endian numbers.
	// Template arguments: Type T, read method RM(buffer), B bytes of data.
	template <typename T, T (RM)(const uint8_t), int B>
	void TestRead(bool big_endian) {
	// Test both for values that are positive and negative (if signed)
	for (int neg = 0; neg < 2; ++neg) {
	bool negative = neg > 0;

	// Write test value to byte buffer, in big endian format.
	T test_value = CreateTestValue<T>(negative, B);
	uint8_t bytes[B + kAlignments];

	// Make one test for each alignment.
	for (int i = 0; i < kAlignments; ++i) {
	PopulateTestData(bytes + i, test_value, B, big_endian);

	// Check that test value is retrieved from buffer when used read method.
	EXPECT_EQ(test_value, RM(bytes + i));
	}
	}
	}

	// Test writing big endian numbers.
	// Template arguments: Type T, write method WM(buffer, value), B bytes of data
	template <typename T, void (WM)(uint8_t, T), int B>
	void TestWrite(bool big_endian) {
	// Test both for values that are positive and negative (if signed).
	for (int neg = 0; neg < 2; ++neg) {
	bool negative = neg > 0;

	// Write test value to byte buffer, in big endian format.
	T test_value = CreateTestValue<T>(negative, B);
	uint8_t expected_bytes[B + kAlignments];
	uint8_t bytes[B + kAlignments];

	// Make one test for each alignment.
	for (int i = 0; i < kAlignments; ++i) {
	PopulateTestData(expected_bytes + i, test_value, B, big_endian);

	// Zero initialize buffer and let WM populate it.
	memset(bytes, 0, B + kAlignments);
	WM(bytes + i, test_value);

	// Check that data produced by WM is big endian as expected.
	for (int j = 0; j < B; ++j) {
	EXPECT_EQ(expected_bytes[i + j], bytes[i + j]);
	}
	}
	}
	}
	};

	TEST_F(ByteIoTest, Test16UBitBigEndian) {
	TestRead<uint16_t, ByteReader<uint16_t>::ReadBigEndian, sizeof(uint16_t)>(
	true);
	TestWrite<uint16_t, ByteWriter<uint16_t>::WriteBigEndian, sizeof(uint16_t)>(
	true);
	}

	TEST_F(ByteIoTest, Test24UBitBigEndian) {
	TestRead<uint32_t, ByteReader<uint32_t, 3>::ReadBigEndian, 3>(true);
	TestWrite<uint32_t, ByteWriter<uint32_t, 3>::WriteBigEndian, 3>(true);
	}

	TEST_F(ByteIoTest, Test32UBitBigEndian) {
	TestRead<uint32_t, ByteReader<uint32_t>::ReadBigEndian, sizeof(uint32_t)>(
	true);
	TestWrite<uint32_t, ByteWriter<uint32_t>::WriteBigEndian, sizeof(uint32_t)>(
	true);
	}

	TEST_F(ByteIoTest, Test64UBitBigEndian) {
	TestRead<uint64_t, ByteReader<uint64_t>::ReadBigEndian, sizeof(uint64_t)>(
	true);
	TestWrite<uint64_t, ByteWriter<uint64_t>::WriteBigEndian, sizeof(uint64_t)>(
	true);
	}

	TEST_F(ByteIoTest, Test16SBitBigEndian) {
	TestRead<int16_t, ByteReader<int16_t>::ReadBigEndian, sizeof(int16_t)>(true);
	TestWrite<int16_t, ByteWriter<int16_t>::WriteBigEndian, sizeof(int16_t)>(
	true);
	}

	TEST_F(ByteIoTest, Test24SBitBigEndian) {
	TestRead<int32_t, ByteReader<int32_t, 3>::ReadBigEndian, 3>(true);
	TestWrite<int32_t, ByteWriter<int32_t, 3>::WriteBigEndian, 3>(true);
	}

	TEST_F(ByteIoTest, Test32SBitBigEndian) {
	TestRead<int32_t, ByteReader<int32_t>::ReadBigEndian, sizeof(int32_t)>(true);
	TestWrite<int32_t, ByteWriter<int32_t>::WriteBigEndian, sizeof(int32_t)>(
	true);
	}

	TEST_F(ByteIoTest, Test64SBitBigEndian) {
	TestRead<int64_t, ByteReader<int64_t>::ReadBigEndian, sizeof(int64_t)>(true);
	TestWrite<int64_t, ByteWriter<int64_t>::WriteBigEndian, sizeof(int64_t)>(
	true);
	}

	TEST_F(ByteIoTest, Test16UBitLittleEndian) {
	TestRead<uint16_t, ByteReader<uint16_t>::ReadLittleEndian, sizeof(uint16_t)>(
	false);
	TestWrite<uint16_t, ByteWriter<uint16_t>::WriteLittleEndian,
	sizeof(uint16_t)>(false);
	}

	TEST_F(ByteIoTest, Test24UBitLittleEndian) {
	TestRead<uint32_t, ByteReader<uint32_t, 3>::ReadLittleEndian, 3>(false);
	TestWrite<uint32_t, ByteWriter<uint32_t, 3>::WriteLittleEndian, 3>(false);
	}

	TEST_F(ByteIoTest, Test32UBitLittleEndian) {
	TestRead<uint32_t, ByteReader<uint32_t>::ReadLittleEndian, sizeof(uint32_t)>(
	false);
	TestWrite<uint32_t, ByteWriter<uint32_t>::WriteLittleEndian,
	sizeof(uint32_t)>(false);
	}

	TEST_F(ByteIoTest, Test64UBitLittleEndian) {
	TestRead<uint64_t, ByteReader<uint64_t>::ReadLittleEndian, sizeof(uint64_t)>(
	false);
	TestWrite<uint64_t, ByteWriter<uint64_t>::WriteLittleEndian,
	sizeof(uint64_t)>(false);
	}

	TEST_F(ByteIoTest, Test16SBitLittleEndian) {
	TestRead<int16_t, ByteReader<int16_t>::ReadLittleEndian, sizeof(int16_t)>(
	false);
	TestWrite<int16_t, ByteWriter<int16_t>::WriteLittleEndian, sizeof(int16_t)>(
	false);
	}

	TEST_F(ByteIoTest, Test24SBitLittleEndian) {
	TestRead<int32_t, ByteReader<int32_t, 3>::ReadLittleEndian, 3>(false);
	TestWrite<int32_t, ByteWriter<int32_t, 3>::WriteLittleEndian, 3>(false);
	}

	TEST_F(ByteIoTest, Test32SBitLittleEndian) {
	TestRead<int32_t, ByteReader<int32_t>::ReadLittleEndian, sizeof(int32_t)>(
	false);
	TestWrite<int32_t, ByteWriter<int32_t>::WriteLittleEndian, sizeof(int32_t)>(
	false);
	}

	TEST_F(ByteIoTest, Test64SBitLittleEndian) {
	TestRead<int64_t, ByteReader<int64_t>::ReadLittleEndian, sizeof(int64_t)>(
	false);
	TestWrite<int64_t, ByteWriter<int64_t>::WriteLittleEndian, sizeof(int64_t)>(
	false);
	}

	// Sets up a fixed byte array and converts N bytes from the array into a
	// uint64_t. Verifies the value with hard-coded reference.
	TEST(ByteIo, SanityCheckFixedByteArrayUnsignedReadBigEndian) {
	uint8_t data[8] = {0xFF, 0xEE, 0xDD, 0xCC, 0xBB, 0xAA, 0x99, 0x88};
	uint64_t value = ByteReader<uint64_t, 2>::ReadBigEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xFFEE), value);
	value = ByteReader<uint64_t, 3>::ReadBigEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xFFEEDD), value);
	value = ByteReader<uint64_t, 4>::ReadBigEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xFFEEDDCC), value);
	value = ByteReader<uint64_t, 5>::ReadBigEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xFFEEDDCCBB), value);
	value = ByteReader<uint64_t, 6>::ReadBigEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xFFEEDDCCBBAA), value);
	value = ByteReader<uint64_t, 7>::ReadBigEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xFFEEDDCCBBAA99), value);
	value = ByteReader<uint64_t, 8>::ReadBigEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xFFEEDDCCBBAA9988), value);
	}

	// Same as above, but for little-endian reading.
	TEST(ByteIo, SanityCheckFixedByteArrayUnsignedReadLittleEndian) {
	uint8_t data[8] = {0xFF, 0xEE, 0xDD, 0xCC, 0xBB, 0xAA, 0x99, 0x88};
	uint64_t value = ByteReader<uint64_t, 2>::ReadLittleEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xEEFF), value);
	value = ByteReader<uint64_t, 3>::ReadLittleEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xDDEEFF), value);
	value = ByteReader<uint64_t, 4>::ReadLittleEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xCCDDEEFF), value);
	value = ByteReader<uint64_t, 5>::ReadLittleEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xBBCCDDEEFF), value);
	value = ByteReader<uint64_t, 6>::ReadLittleEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0xAABBCCDDEEFF), value);
	value = ByteReader<uint64_t, 7>::ReadLittleEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0x99AABBCCDDEEFF), value);
	value = ByteReader<uint64_t, 8>::ReadLittleEndian(data);
	EXPECT_EQ(static_cast<uint64_t>(0x8899AABBCCDDEEFF), value);
	}
	} // namespace
	} // namespace webrtc