/* * 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 "modules/audio_coding/neteq/dtmf_buffer.h" #ifdef WIN32 #include // ntohl() #else #include // ntohl() #endif #include #include "test/gtest.h" // Modify the tests so that they pass with the modifications done to DtmfBuffer // for backwards bit-exactness. Once bit-exactness is no longer required, this // #define should be removed (and the code that it enables). #define LEGACY_BITEXACT namespace webrtc { static int sample_rate_hz = 8000; static uint32_t MakeDtmfPayload(int event, bool end, int volume, int duration) { uint32_t payload = 0; // 0 1 2 3 // 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // | event |E|R| volume | duration | // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ payload |= (event & 0x00FF) << 24; payload |= (end ? 0x00800000 : 0x00000000); payload |= (volume & 0x003F) << 16; payload |= (duration & 0xFFFF); payload = ntohl(payload); return payload; } static bool EqualEvents(const DtmfEvent& a, const DtmfEvent& b) { return (a.duration == b.duration && a.end_bit == b.end_bit && a.event_no == b.event_no && a.timestamp == b.timestamp && a.volume == b.volume); } TEST(DtmfBuffer, CreateAndDestroy) { DtmfBuffer* buffer = new DtmfBuffer(sample_rate_hz); delete buffer; } // Test the event parser. TEST(DtmfBuffer, ParseEvent) { int event_no = 7; bool end_bit = true; int volume = 17; int duration = 4711; uint32_t timestamp = 0x12345678; uint32_t payload = MakeDtmfPayload(event_no, end_bit, volume, duration); uint8_t* payload_ptr = reinterpret_cast(&payload); DtmfEvent event; EXPECT_EQ(DtmfBuffer::kOK, DtmfBuffer::ParseEvent(timestamp, payload_ptr, sizeof(payload), &event)); EXPECT_EQ(duration, event.duration); EXPECT_EQ(end_bit, event.end_bit); EXPECT_EQ(event_no, event.event_no); EXPECT_EQ(timestamp, event.timestamp); EXPECT_EQ(volume, event.volume); EXPECT_EQ(DtmfBuffer::kPayloadTooShort, DtmfBuffer::ParseEvent(timestamp, payload_ptr, 3, &event)); } TEST(DtmfBuffer, SimpleInsertAndGet) { int event_no = 7; bool end_bit = true; int volume = 17; int duration = 4711; uint32_t timestamp = 0x12345678; DtmfEvent event(timestamp, event_no, volume, duration, end_bit); DtmfBuffer buffer(sample_rate_hz); EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event)); EXPECT_EQ(1u, buffer.Length()); EXPECT_FALSE(buffer.Empty()); DtmfEvent out_event; // Too early to get event. EXPECT_FALSE(buffer.GetEvent(timestamp - 10, &out_event)); EXPECT_EQ(1u, buffer.Length()); EXPECT_FALSE(buffer.Empty()); // Get the event at its starting timestamp. EXPECT_TRUE(buffer.GetEvent(timestamp, &out_event)); EXPECT_TRUE(EqualEvents(event, out_event)); EXPECT_EQ(1u, buffer.Length()); EXPECT_FALSE(buffer.Empty()); // Get the event some time into the event. EXPECT_TRUE(buffer.GetEvent(timestamp + duration / 2, &out_event)); EXPECT_TRUE(EqualEvents(event, out_event)); EXPECT_EQ(1u, buffer.Length()); EXPECT_FALSE(buffer.Empty()); // Give a "current" timestamp after the event has ended. #ifdef LEGACY_BITEXACT EXPECT_TRUE(buffer.GetEvent(timestamp + duration + 10, &out_event)); #endif EXPECT_FALSE(buffer.GetEvent(timestamp + duration + 10, &out_event)); EXPECT_EQ(0u, buffer.Length()); EXPECT_TRUE(buffer.Empty()); } TEST(DtmfBuffer, MergingPackets) { int event_no = 0; bool end_bit = false; int volume = 17; int duration = 80; uint32_t timestamp = 0x12345678; DtmfEvent event(timestamp, event_no, volume, duration, end_bit); DtmfBuffer buffer(sample_rate_hz); EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event)); event.duration += 80; EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event)); event.duration += 80; event.end_bit = true; EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event)); EXPECT_EQ(1u, buffer.Length()); DtmfEvent out_event; EXPECT_TRUE(buffer.GetEvent(timestamp, &out_event)); EXPECT_TRUE(EqualEvents(event, out_event)); } // This test case inserts one shorter event completely overlapped by one longer // event. The expected outcome is that only the longer event is played. TEST(DtmfBuffer, OverlappingEvents) { int event_no = 0; bool end_bit = true; int volume = 1; int duration = 80; uint32_t timestamp = 0x12345678 + 80; DtmfEvent short_event(timestamp, event_no, volume, duration, end_bit); DtmfBuffer buffer(sample_rate_hz); EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(short_event)); event_no = 10; end_bit = false; timestamp = 0x12345678; DtmfEvent long_event(timestamp, event_no, volume, duration, end_bit); EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(long_event)); long_event.duration += 80; EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(long_event)); long_event.duration += 80; long_event.end_bit = true; EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(long_event)); EXPECT_EQ(2u, buffer.Length()); DtmfEvent out_event; // Expect to get the long event. EXPECT_TRUE(buffer.GetEvent(timestamp, &out_event)); EXPECT_TRUE(EqualEvents(long_event, out_event)); // Expect no more events. #ifdef LEGACY_BITEXACT EXPECT_TRUE( buffer.GetEvent(timestamp + long_event.duration + 10, &out_event)); EXPECT_TRUE(EqualEvents(long_event, out_event)); EXPECT_TRUE( buffer.GetEvent(timestamp + long_event.duration + 10, &out_event)); EXPECT_TRUE(EqualEvents(short_event, out_event)); #else EXPECT_FALSE( buffer.GetEvent(timestamp + long_event.duration + 10, &out_event)); #endif EXPECT_TRUE(buffer.Empty()); } TEST(DtmfBuffer, ExtrapolationTime) { int event_no = 0; bool end_bit = false; int volume = 1; int duration = 80; uint32_t timestamp = 0x12345678; DtmfEvent event1(timestamp, event_no, volume, duration, end_bit); DtmfBuffer buffer(sample_rate_hz); EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event1)); EXPECT_EQ(1u, buffer.Length()); DtmfEvent out_event; // Get the event at the start. EXPECT_TRUE(buffer.GetEvent(timestamp, &out_event)); EXPECT_TRUE(EqualEvents(event1, out_event)); // Also get the event 100 samples after the end of the event (since we're // missing the end bit). uint32_t timestamp_now = timestamp + duration + 100; EXPECT_TRUE(buffer.GetEvent(timestamp_now, &out_event)); EXPECT_TRUE(EqualEvents(event1, out_event)); // Insert another event starting back-to-back with the previous event. timestamp += duration; event_no = 1; DtmfEvent event2(timestamp, event_no, volume, duration, end_bit); EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event2)); EXPECT_EQ(2u, buffer.Length()); // Now we expect to get the new event when supplying `timestamp_now`. EXPECT_TRUE(buffer.GetEvent(timestamp_now, &out_event)); EXPECT_TRUE(EqualEvents(event2, out_event)); // Expect the the first event to be erased now. EXPECT_EQ(1u, buffer.Length()); // Move `timestamp_now` to more than 560 samples after the end of the second // event. Expect that event to be erased. timestamp_now = timestamp + duration + 600; #ifdef LEGACY_BITEXACT EXPECT_TRUE(buffer.GetEvent(timestamp_now, &out_event)); #endif EXPECT_FALSE(buffer.GetEvent(timestamp_now, &out_event)); EXPECT_TRUE(buffer.Empty()); } TEST(DtmfBuffer, TimestampWraparound) { int event_no = 0; bool end_bit = true; int volume = 1; int duration = 80; uint32_t timestamp1 = 0xFFFFFFFF - duration; DtmfEvent event1(timestamp1, event_no, volume, duration, end_bit); uint32_t timestamp2 = 0; DtmfEvent event2(timestamp2, event_no, volume, duration, end_bit); DtmfBuffer buffer(sample_rate_hz); EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event1)); EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event2)); EXPECT_EQ(2u, buffer.Length()); DtmfEvent out_event; EXPECT_TRUE(buffer.GetEvent(timestamp1, &out_event)); EXPECT_TRUE(EqualEvents(event1, out_event)); #ifdef LEGACY_BITEXACT EXPECT_EQ(1u, buffer.Length()); #else EXPECT_EQ(2u, buffer.Length()); #endif buffer.Flush(); // Reverse the insert order. Expect same results. EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event2)); EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event1)); EXPECT_EQ(2u, buffer.Length()); EXPECT_TRUE(buffer.GetEvent(timestamp1, &out_event)); EXPECT_TRUE(EqualEvents(event1, out_event)); #ifdef LEGACY_BITEXACT EXPECT_EQ(1u, buffer.Length()); #else EXPECT_EQ(2u, buffer.Length()); #endif } TEST(DtmfBuffer, InvalidEvents) { int event_no = 0; bool end_bit = true; int volume = 1; int duration = 80; uint32_t timestamp = 0x12345678; DtmfEvent event(timestamp, event_no, volume, duration, end_bit); DtmfBuffer buffer(sample_rate_hz); // Invalid event number. event.event_no = -1; EXPECT_EQ(DtmfBuffer::kInvalidEventParameters, buffer.InsertEvent(event)); event.event_no = 16; EXPECT_EQ(DtmfBuffer::kInvalidEventParameters, buffer.InsertEvent(event)); event.event_no = 0; // Valid value; // Invalid volume. event.volume = -1; EXPECT_EQ(DtmfBuffer::kInvalidEventParameters, buffer.InsertEvent(event)); event.volume = 64; EXPECT_EQ(DtmfBuffer::kInvalidEventParameters, buffer.InsertEvent(event)); event.volume = 0; // Valid value; // Invalid duration. event.duration = -1; EXPECT_EQ(DtmfBuffer::kInvalidEventParameters, buffer.InsertEvent(event)); event.duration = 0; EXPECT_EQ(DtmfBuffer::kInvalidEventParameters, buffer.InsertEvent(event)); event.duration = 0xFFFF + 1; EXPECT_EQ(DtmfBuffer::kInvalidEventParameters, buffer.InsertEvent(event)); event.duration = 1; // Valid value; // Finish with a valid event, just to verify that all is ok. EXPECT_EQ(DtmfBuffer::kOK, buffer.InsertEvent(event)); } } // namespace webrtc