/* * Copyright 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 "pc/dtmfsender.h" #include #include #include #include #include "pc/audiotrack.h" #include "rtc_base/fakeclock.h" #include "rtc_base/gunit.h" #include "rtc_base/timeutils.h" using webrtc::AudioTrackInterface; using webrtc::AudioTrack; using webrtc::DtmfProviderInterface; using webrtc::DtmfSender; using webrtc::DtmfSenderObserverInterface; static const char kTestAudioLabel[] = "test_audio_track"; // TODO(deadbeef): Even though this test now uses a fake clock, it has a // generous 3-second timeout for every test case. The timeout could be tuned // to each test based on the tones sent, instead. static const int kMaxWaitMs = 3000; class FakeDtmfObserver : public DtmfSenderObserverInterface { public: FakeDtmfObserver() : completed_(false) {} // Implements DtmfSenderObserverInterface. void OnToneChange(const std::string& tone) override { tones_.push_back(tone); if (tone.empty()) { completed_ = true; } } // getters const std::vector& tones() const { return tones_; } bool completed() const { return completed_; } private: std::vector tones_; bool completed_; }; class FakeDtmfProvider : public DtmfProviderInterface { public: struct DtmfInfo { DtmfInfo(int code, int duration, int gap) : code(code), duration(duration), gap(gap) {} int code; int duration; int gap; }; FakeDtmfProvider() : last_insert_dtmf_call_(0) {} ~FakeDtmfProvider() { SignalDestroyed(); } // Implements DtmfProviderInterface. bool CanInsertDtmf() override { return can_insert_; } bool InsertDtmf(int code, int duration) override { int gap = 0; // TODO(ronghuawu): Make the timer (basically the rtc::TimeNanos) // mockable and use a fake timer in the unit tests. if (last_insert_dtmf_call_ > 0) { gap = static_cast(rtc::TimeMillis() - last_insert_dtmf_call_); } last_insert_dtmf_call_ = rtc::TimeMillis(); dtmf_info_queue_.push_back(DtmfInfo(code, duration, gap)); return true; } sigslot::signal0<>* GetOnDestroyedSignal() override { return &SignalDestroyed; } // getter and setter const std::vector& dtmf_info_queue() const { return dtmf_info_queue_; } // helper functions void SetCanInsertDtmf(bool can_insert) { can_insert_ = can_insert; } private: bool can_insert_ = false; std::vector dtmf_info_queue_; int64_t last_insert_dtmf_call_; sigslot::signal0<> SignalDestroyed; }; class DtmfSenderTest : public testing::Test { protected: DtmfSenderTest() : track_(AudioTrack::Create(kTestAudioLabel, NULL)), observer_(new rtc::RefCountedObject()), provider_(new FakeDtmfProvider()) { provider_->SetCanInsertDtmf(true); dtmf_ = DtmfSender::Create(track_, rtc::Thread::Current(), provider_.get()); dtmf_->RegisterObserver(observer_.get()); } ~DtmfSenderTest() { if (dtmf_.get()) { dtmf_->UnregisterObserver(); } } // Constructs a list of DtmfInfo from |tones|, |duration| and // |inter_tone_gap|. void GetDtmfInfoFromString(const std::string& tones, int duration, int inter_tone_gap, std::vector* dtmfs) { // Init extra_delay as -inter_tone_gap - duration to ensure the first // DtmfInfo's gap field will be 0. int extra_delay = -1 * (inter_tone_gap + duration); std::string::const_iterator it = tones.begin(); for (; it != tones.end(); ++it) { char tone = *it; int code = 0; webrtc::GetDtmfCode(tone, &code); if (tone == ',') { extra_delay = 2000; // 2 seconds } else { dtmfs->push_back(FakeDtmfProvider::DtmfInfo(code, duration, duration + inter_tone_gap + extra_delay)); extra_delay = 0; } } } void VerifyExpectedState(AudioTrackInterface* track, const std::string& tones, int duration, int inter_tone_gap) { EXPECT_EQ(track, dtmf_->track()); EXPECT_EQ(tones, dtmf_->tones()); EXPECT_EQ(duration, dtmf_->duration()); EXPECT_EQ(inter_tone_gap, dtmf_->inter_tone_gap()); } // Verify the provider got all the expected calls. void VerifyOnProvider(const std::string& tones, int duration, int inter_tone_gap) { std::vector dtmf_queue_ref; GetDtmfInfoFromString(tones, duration, inter_tone_gap, &dtmf_queue_ref); VerifyOnProvider(dtmf_queue_ref); } void VerifyOnProvider( const std::vector& dtmf_queue_ref) { const std::vector& dtmf_queue = provider_->dtmf_info_queue(); ASSERT_EQ(dtmf_queue_ref.size(), dtmf_queue.size()); std::vector::const_iterator it_ref = dtmf_queue_ref.begin(); std::vector::const_iterator it = dtmf_queue.begin(); while (it_ref != dtmf_queue_ref.end() && it != dtmf_queue.end()) { EXPECT_EQ(it_ref->code, it->code); EXPECT_EQ(it_ref->duration, it->duration); // Allow ~10ms error (can be small since we're using a fake clock). EXPECT_GE(it_ref->gap, it->gap - 10); EXPECT_LE(it_ref->gap, it->gap + 10); ++it_ref; ++it; } } // Verify the observer got all the expected callbacks. void VerifyOnObserver(const std::string& tones_ref) { const std::vector& tones = observer_->tones(); // The observer will get an empty string at the end. EXPECT_EQ(tones_ref.size() + 1, tones.size()); EXPECT_TRUE(tones.back().empty()); std::string::const_iterator it_ref = tones_ref.begin(); std::vector::const_iterator it = tones.begin(); while (it_ref != tones_ref.end() && it != tones.end()) { EXPECT_EQ(*it_ref, it->at(0)); ++it_ref; ++it; } } rtc::scoped_refptr track_; std::unique_ptr observer_; std::unique_ptr provider_; rtc::scoped_refptr dtmf_; rtc::ScopedFakeClock fake_clock_; }; TEST_F(DtmfSenderTest, CanInsertDtmf) { EXPECT_TRUE(dtmf_->CanInsertDtmf()); provider_->SetCanInsertDtmf(false); EXPECT_FALSE(dtmf_->CanInsertDtmf()); } TEST_F(DtmfSenderTest, InsertDtmf) { std::string tones = "@1%a&*$"; int duration = 100; int inter_tone_gap = 50; EXPECT_TRUE(dtmf_->InsertDtmf(tones, duration, inter_tone_gap)); EXPECT_TRUE_SIMULATED_WAIT(observer_->completed(), kMaxWaitMs, fake_clock_); // The unrecognized characters should be ignored. std::string known_tones = "1a*"; VerifyOnProvider(known_tones, duration, inter_tone_gap); VerifyOnObserver(known_tones); } TEST_F(DtmfSenderTest, InsertDtmfTwice) { std::string tones1 = "12"; std::string tones2 = "ab"; int duration = 100; int inter_tone_gap = 50; EXPECT_TRUE(dtmf_->InsertDtmf(tones1, duration, inter_tone_gap)); VerifyExpectedState(track_, tones1, duration, inter_tone_gap); // Wait until the first tone got sent. EXPECT_TRUE_SIMULATED_WAIT(observer_->tones().size() == 1, kMaxWaitMs, fake_clock_); VerifyExpectedState(track_, "2", duration, inter_tone_gap); // Insert with another tone buffer. EXPECT_TRUE(dtmf_->InsertDtmf(tones2, duration, inter_tone_gap)); VerifyExpectedState(track_, tones2, duration, inter_tone_gap); // Wait until it's completed. EXPECT_TRUE_SIMULATED_WAIT(observer_->completed(), kMaxWaitMs, fake_clock_); std::vector dtmf_queue_ref; GetDtmfInfoFromString("1", duration, inter_tone_gap, &dtmf_queue_ref); GetDtmfInfoFromString("ab", duration, inter_tone_gap, &dtmf_queue_ref); VerifyOnProvider(dtmf_queue_ref); VerifyOnObserver("1ab"); } TEST_F(DtmfSenderTest, InsertDtmfWhileProviderIsDeleted) { std::string tones = "@1%a&*$"; int duration = 100; int inter_tone_gap = 50; EXPECT_TRUE(dtmf_->InsertDtmf(tones, duration, inter_tone_gap)); // Wait until the first tone got sent. EXPECT_TRUE_SIMULATED_WAIT(observer_->tones().size() == 1, kMaxWaitMs, fake_clock_); // Delete provider. provider_.reset(); // The queue should be discontinued so no more tone callbacks. SIMULATED_WAIT(false, 200, fake_clock_); EXPECT_EQ(1U, observer_->tones().size()); } TEST_F(DtmfSenderTest, InsertDtmfWhileSenderIsDeleted) { std::string tones = "@1%a&*$"; int duration = 100; int inter_tone_gap = 50; EXPECT_TRUE(dtmf_->InsertDtmf(tones, duration, inter_tone_gap)); // Wait until the first tone got sent. EXPECT_TRUE_SIMULATED_WAIT(observer_->tones().size() == 1, kMaxWaitMs, fake_clock_); // Delete the sender. dtmf_ = NULL; // The queue should be discontinued so no more tone callbacks. SIMULATED_WAIT(false, 200, fake_clock_); EXPECT_EQ(1U, observer_->tones().size()); } TEST_F(DtmfSenderTest, InsertEmptyTonesToCancelPreviousTask) { std::string tones1 = "12"; std::string tones2 = ""; int duration = 100; int inter_tone_gap = 50; EXPECT_TRUE(dtmf_->InsertDtmf(tones1, duration, inter_tone_gap)); // Wait until the first tone got sent. EXPECT_TRUE_SIMULATED_WAIT(observer_->tones().size() == 1, kMaxWaitMs, fake_clock_); // Insert with another tone buffer. EXPECT_TRUE(dtmf_->InsertDtmf(tones2, duration, inter_tone_gap)); // Wait until it's completed. EXPECT_TRUE_SIMULATED_WAIT(observer_->completed(), kMaxWaitMs, fake_clock_); std::vector dtmf_queue_ref; GetDtmfInfoFromString("1", duration, inter_tone_gap, &dtmf_queue_ref); VerifyOnProvider(dtmf_queue_ref); VerifyOnObserver("1"); } TEST_F(DtmfSenderTest, InsertDtmfWithCommaAsDelay) { std::string tones = "3,4"; int duration = 100; int inter_tone_gap = 50; EXPECT_TRUE(dtmf_->InsertDtmf(tones, duration, inter_tone_gap)); EXPECT_TRUE_SIMULATED_WAIT(observer_->completed(), kMaxWaitMs, fake_clock_); VerifyOnProvider(tones, duration, inter_tone_gap); VerifyOnObserver(tones); } TEST_F(DtmfSenderTest, TryInsertDtmfWhenItDoesNotWork) { std::string tones = "3,4"; int duration = 100; int inter_tone_gap = 50; provider_->SetCanInsertDtmf(false); EXPECT_FALSE(dtmf_->InsertDtmf(tones, duration, inter_tone_gap)); } TEST_F(DtmfSenderTest, InsertDtmfWithInvalidDurationOrGap) { std::string tones = "3,4"; int duration = 40; int inter_tone_gap = 50; EXPECT_FALSE(dtmf_->InsertDtmf(tones, 6001, inter_tone_gap)); EXPECT_FALSE(dtmf_->InsertDtmf(tones, 39, inter_tone_gap)); EXPECT_FALSE(dtmf_->InsertDtmf(tones, duration, 29)); EXPECT_TRUE(dtmf_->InsertDtmf(tones, duration, inter_tone_gap)); } TEST_F(DtmfSenderTest, InsertDtmfSendsAfterWait) { std::string tones = "ABC"; int duration = 100; int inter_tone_gap = 50; EXPECT_TRUE(dtmf_->InsertDtmf(tones, duration, inter_tone_gap)); VerifyExpectedState(track_, "ABC", duration, inter_tone_gap); // Wait until the first tone got sent. EXPECT_TRUE_SIMULATED_WAIT(observer_->tones().size() == 1, kMaxWaitMs, fake_clock_); VerifyExpectedState(track_, "BC", duration, inter_tone_gap); }