session-android/jni/webrtc/modules/audio_coding/neteq/timestamp_scaler_unittest.cc

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/*
* 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 "webrtc/modules/audio_coding/neteq/timestamp_scaler.h"
#include "gmock/gmock.h"
#include "gtest/gtest.h"
#include "webrtc/modules/audio_coding/neteq/mock/mock_decoder_database.h"
#include "webrtc/modules/audio_coding/neteq/packet.h"
using ::testing::Return;
using ::testing::ReturnNull;
using ::testing::_;
namespace webrtc {
TEST(TimestampScaler, TestNoScaling) {
MockDecoderDatabase db;
DecoderDatabase::DecoderInfo info;
info.codec_type = kDecoderPCMu; // Does not use scaled timestamps.
static const uint8_t kRtpPayloadType = 0;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadType))
.WillRepeatedly(Return(&info));
TimestampScaler scaler(db);
// Test both sides of the timestamp wrap-around.
for (uint32_t timestamp = 0xFFFFFFFF - 5; timestamp != 5; ++timestamp) {
// Scale to internal timestamp.
EXPECT_EQ(timestamp, scaler.ToInternal(timestamp, kRtpPayloadType));
// Scale back.
EXPECT_EQ(timestamp, scaler.ToExternal(timestamp));
}
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
TEST(TimestampScaler, TestNoScalingLargeStep) {
MockDecoderDatabase db;
DecoderDatabase::DecoderInfo info;
info.codec_type = kDecoderPCMu; // Does not use scaled timestamps.
static const uint8_t kRtpPayloadType = 0;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadType))
.WillRepeatedly(Return(&info));
TimestampScaler scaler(db);
// Test both sides of the timestamp wrap-around.
static const uint32_t kStep = 160;
uint32_t start_timestamp = 0;
// |external_timestamp| will be a large positive value.
start_timestamp = start_timestamp - 5 * kStep;
for (uint32_t timestamp = start_timestamp; timestamp != 5 * kStep;
timestamp += kStep) {
// Scale to internal timestamp.
EXPECT_EQ(timestamp, scaler.ToInternal(timestamp, kRtpPayloadType));
// Scale back.
EXPECT_EQ(timestamp, scaler.ToExternal(timestamp));
}
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
TEST(TimestampScaler, TestG722) {
MockDecoderDatabase db;
DecoderDatabase::DecoderInfo info;
info.codec_type = kDecoderG722; // Uses a factor 2 scaling.
static const uint8_t kRtpPayloadType = 17;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadType))
.WillRepeatedly(Return(&info));
TimestampScaler scaler(db);
// Test both sides of the timestamp wrap-around.
uint32_t external_timestamp = 0xFFFFFFFF - 5;
uint32_t internal_timestamp = external_timestamp;
for (; external_timestamp != 5; ++external_timestamp) {
// Scale to internal timestamp.
EXPECT_EQ(internal_timestamp,
scaler.ToInternal(external_timestamp, kRtpPayloadType));
// Scale back.
EXPECT_EQ(external_timestamp, scaler.ToExternal(internal_timestamp));
internal_timestamp += 2;
}
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
TEST(TimestampScaler, TestG722LargeStep) {
MockDecoderDatabase db;
DecoderDatabase::DecoderInfo info;
info.codec_type = kDecoderG722; // Uses a factor 2 scaling.
static const uint8_t kRtpPayloadType = 17;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadType))
.WillRepeatedly(Return(&info));
TimestampScaler scaler(db);
// Test both sides of the timestamp wrap-around.
static const uint32_t kStep = 320;
uint32_t external_timestamp = 0;
// |external_timestamp| will be a large positive value.
external_timestamp = external_timestamp - 5 * kStep;
uint32_t internal_timestamp = external_timestamp;
for (; external_timestamp != 5 * kStep; external_timestamp += kStep) {
// Scale to internal timestamp.
EXPECT_EQ(internal_timestamp,
scaler.ToInternal(external_timestamp, kRtpPayloadType));
// Scale back.
EXPECT_EQ(external_timestamp, scaler.ToExternal(internal_timestamp));
// Internal timestamp should be incremented with twice the step.
internal_timestamp += 2 * kStep;
}
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
TEST(TimestampScaler, TestG722WithCng) {
MockDecoderDatabase db;
DecoderDatabase::DecoderInfo info_g722, info_cng;
info_g722.codec_type = kDecoderG722; // Uses a factor 2 scaling.
info_cng.codec_type = kDecoderCNGwb;
static const uint8_t kRtpPayloadTypeG722 = 17;
static const uint8_t kRtpPayloadTypeCng = 13;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadTypeG722))
.WillRepeatedly(Return(&info_g722));
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadTypeCng))
.WillRepeatedly(Return(&info_cng));
TimestampScaler scaler(db);
// Test both sides of the timestamp wrap-around.
uint32_t external_timestamp = 0xFFFFFFFF - 5;
uint32_t internal_timestamp = external_timestamp;
bool next_is_cng = false;
for (; external_timestamp != 5; ++external_timestamp) {
// Alternate between G.722 and CNG every other packet.
if (next_is_cng) {
// Scale to internal timestamp.
EXPECT_EQ(internal_timestamp,
scaler.ToInternal(external_timestamp, kRtpPayloadTypeCng));
next_is_cng = false;
} else {
// Scale to internal timestamp.
EXPECT_EQ(internal_timestamp,
scaler.ToInternal(external_timestamp, kRtpPayloadTypeG722));
next_is_cng = true;
}
// Scale back.
EXPECT_EQ(external_timestamp, scaler.ToExternal(internal_timestamp));
internal_timestamp += 2;
}
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
// Make sure that the method ToInternal(Packet* packet) is wired up correctly.
// Since it is simply calling the other ToInternal method, we are not doing
// as many tests here.
TEST(TimestampScaler, TestG722Packet) {
MockDecoderDatabase db;
DecoderDatabase::DecoderInfo info;
info.codec_type = kDecoderG722; // Does uses a factor 2 scaling.
static const uint8_t kRtpPayloadType = 17;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadType))
.WillRepeatedly(Return(&info));
TimestampScaler scaler(db);
// Test both sides of the timestamp wrap-around.
uint32_t external_timestamp = 0xFFFFFFFF - 5;
uint32_t internal_timestamp = external_timestamp;
Packet packet;
packet.header.payloadType = kRtpPayloadType;
for (; external_timestamp != 5; ++external_timestamp) {
packet.header.timestamp = external_timestamp;
// Scale to internal timestamp.
scaler.ToInternal(&packet);
EXPECT_EQ(internal_timestamp, packet.header.timestamp);
internal_timestamp += 2;
}
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
// Make sure that the method ToInternal(PacketList* packet_list) is wired up
// correctly. Since it is simply calling the ToInternal(Packet* packet) method,
// we are not doing as many tests here.
TEST(TimestampScaler, TestG722PacketList) {
MockDecoderDatabase db;
DecoderDatabase::DecoderInfo info;
info.codec_type = kDecoderG722; // Uses a factor 2 scaling.
static const uint8_t kRtpPayloadType = 17;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadType))
.WillRepeatedly(Return(&info));
TimestampScaler scaler(db);
// Test both sides of the timestamp wrap-around.
uint32_t external_timestamp = 0xFFFFFFFF - 5;
uint32_t internal_timestamp = external_timestamp;
Packet packet1;
packet1.header.payloadType = kRtpPayloadType;
packet1.header.timestamp = external_timestamp;
Packet packet2;
packet2.header.payloadType = kRtpPayloadType;
packet2.header.timestamp = external_timestamp + 10;
PacketList packet_list;
packet_list.push_back(&packet1);
packet_list.push_back(&packet2);
scaler.ToInternal(&packet_list);
EXPECT_EQ(internal_timestamp, packet1.header.timestamp);
EXPECT_EQ(internal_timestamp + 20, packet2.header.timestamp);
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
TEST(TimestampScaler, TestG722Reset) {
MockDecoderDatabase db;
DecoderDatabase::DecoderInfo info;
info.codec_type = kDecoderG722; // Uses a factor 2 scaling.
static const uint8_t kRtpPayloadType = 17;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadType))
.WillRepeatedly(Return(&info));
TimestampScaler scaler(db);
// Test both sides of the timestamp wrap-around.
uint32_t external_timestamp = 0xFFFFFFFF - 5;
uint32_t internal_timestamp = external_timestamp;
for (; external_timestamp != 5; ++external_timestamp) {
// Scale to internal timestamp.
EXPECT_EQ(internal_timestamp,
scaler.ToInternal(external_timestamp, kRtpPayloadType));
// Scale back.
EXPECT_EQ(external_timestamp, scaler.ToExternal(internal_timestamp));
internal_timestamp += 2;
}
// Reset the scaler. After this, we expect the internal and external to start
// over at the same value again.
scaler.Reset();
internal_timestamp = external_timestamp;
for (; external_timestamp != 15; ++external_timestamp) {
// Scale to internal timestamp.
EXPECT_EQ(internal_timestamp,
scaler.ToInternal(external_timestamp, kRtpPayloadType));
// Scale back.
EXPECT_EQ(external_timestamp, scaler.ToExternal(internal_timestamp));
internal_timestamp += 2;
}
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
// TODO(minyue): This test becomes trivial since Opus does not need a timestamp
// scaler. Therefore, this test may be removed in future. There is no harm to
// keep it, since it can be taken as a test case for the situation of a trivial
// timestamp scaler.
TEST(TimestampScaler, TestOpusLargeStep) {
MockDecoderDatabase db;
DecoderDatabase::DecoderInfo info;
info.codec_type = kDecoderOpus;
static const uint8_t kRtpPayloadType = 17;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadType))
.WillRepeatedly(Return(&info));
TimestampScaler scaler(db);
// Test both sides of the timestamp wrap-around.
static const uint32_t kStep = 960;
uint32_t external_timestamp = 0;
// |external_timestamp| will be a large positive value.
external_timestamp = external_timestamp - 5 * kStep;
uint32_t internal_timestamp = external_timestamp;
for (; external_timestamp != 5 * kStep; external_timestamp += kStep) {
// Scale to internal timestamp.
EXPECT_EQ(internal_timestamp,
scaler.ToInternal(external_timestamp, kRtpPayloadType));
// Scale back.
EXPECT_EQ(external_timestamp, scaler.ToExternal(internal_timestamp));
internal_timestamp += kStep;
}
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
TEST(TimestampScaler, TestIsacFbLargeStep) {
MockDecoderDatabase db;
DecoderDatabase::DecoderInfo info;
info.codec_type = kDecoderISACfb;
static const uint8_t kRtpPayloadType = 17;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadType))
.WillRepeatedly(Return(&info));
TimestampScaler scaler(db);
// Test both sides of the timestamp wrap-around.
static const uint32_t kStep = 960;
uint32_t external_timestamp = 0;
// |external_timestamp| will be a large positive value.
external_timestamp = external_timestamp - 5 * kStep;
uint32_t internal_timestamp = external_timestamp;
for (; external_timestamp != 5 * kStep; external_timestamp += kStep) {
// Scale to internal timestamp.
EXPECT_EQ(internal_timestamp,
scaler.ToInternal(external_timestamp, kRtpPayloadType));
// Scale back.
EXPECT_EQ(external_timestamp, scaler.ToExternal(internal_timestamp));
// Internal timestamp should be incremented with two-thirds the step.
internal_timestamp += 2 * kStep / 3;
}
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
TEST(TimestampScaler, Failures) {
static const uint8_t kRtpPayloadType = 17;
MockDecoderDatabase db;
EXPECT_CALL(db, GetDecoderInfo(kRtpPayloadType))
.WillOnce(ReturnNull()); // Return NULL to indicate unknown payload type.
TimestampScaler scaler(db);
uint32_t timestamp = 4711; // Some number.
EXPECT_EQ(timestamp, scaler.ToInternal(timestamp, kRtpPayloadType));
Packet* packet = NULL;
scaler.ToInternal(packet); // Should not crash. That's all we can test.
EXPECT_CALL(db, Die()); // Called when database object is deleted.
}
} // namespace webrtc