Roll src/third_party/WebKit f298044:aa8346d (svn 202628:202629)
[chromium-blink-merge.git] / chrome / browser / media / chrome_webrtc_audio_quality_browsertest.cc
blob45debc951ed22919e7d69dd1d57c8df728327268
1 // Copyright 2013 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
5 #include <ctime>
7 #include "base/command_line.h"
8 #include "base/files/file_enumerator.h"
9 #include "base/files/file_util.h"
10 #include "base/files/scoped_temp_dir.h"
11 #include "base/process/launch.h"
12 #include "base/process/process.h"
13 #include "base/scoped_native_library.h"
14 #include "base/strings/string_number_conversions.h"
15 #include "base/strings/string_util.h"
16 #include "base/strings/stringprintf.h"
17 #include "base/strings/utf_string_conversions.h"
18 #include "chrome/browser/media/webrtc_browsertest_audio.h"
19 #include "chrome/browser/media/webrtc_browsertest_base.h"
20 #include "chrome/browser/media/webrtc_browsertest_common.h"
21 #include "chrome/browser/profiles/profile.h"
22 #include "chrome/browser/ui/browser.h"
23 #include "chrome/browser/ui/browser_tabstrip.h"
24 #include "chrome/browser/ui/tabs/tab_strip_model.h"
25 #include "chrome/common/chrome_paths.h"
26 #include "chrome/common/chrome_switches.h"
27 #include "chrome/test/base/ui_test_utils.h"
28 #include "content/public/test/browser_test_utils.h"
29 #include "media/audio/audio_parameters.h"
30 #include "media/base/media_switches.h"
31 #include "net/test/embedded_test_server/embedded_test_server.h"
32 #include "testing/perf/perf_test.h"
34 namespace {
36 static const base::FilePath::CharType kReferenceFile[] =
37 FILE_PATH_LITERAL("speech_44kHz_16bit_stereo.wav");
39 // The javascript will load the reference file relative to its location,
40 // which is in /webrtc on the web server. The files we are looking for are in
41 // webrtc/resources in the chrome/test/data folder.
42 static const char kReferenceFileRelativeUrl[] =
43 "resources/speech_44kHz_16bit_stereo.wav";
45 static const char kWebRtcAudioTestHtmlPage[] =
46 "/webrtc/webrtc_audio_quality_test.html";
48 // For the AGC test, there are 6 speech segments split on silence. If one
49 // segment is significantly different in length compared to the same segment in
50 // the reference file, there's something fishy going on.
51 const int kMaxAgcSegmentDiffMs =
52 #if defined(OS_MACOSX)
53 // Something is different on Mac; http://crbug.com/477653.
54 600;
55 #else
56 200;
57 #endif
59 #if defined(OS_LINUX) || defined(OS_WIN) || defined(OS_MACOSX)
60 #define MAYBE_WebRtcAudioQualityBrowserTest WebRtcAudioQualityBrowserTest
61 #else
62 // Not implemented on Android, ChromeOS etc.
63 #define MAYBE_WebRtcAudioQualityBrowserTest DISABLED_WebRtcAudioQualityBrowserTest
64 #endif
66 } // namespace
68 // Test we can set up a WebRTC call and play audio through it.
70 // If you're not a googler and want to run this test, you need to provide a
71 // pesq binary for your platform (and sox.exe on windows). Read more on how
72 // resources are managed in chrome/test/data/webrtc/resources/README.
74 // This test will only work on machines that have been configured to record
75 // their own input.
77 // On Linux:
78 // 1. # sudo apt-get install pavucontrol sox
79 // 2. For the user who will run the test: # pavucontrol
80 // 3. In a separate terminal, # arecord dummy
81 // 4. In pavucontrol, go to the recording tab.
82 // 5. For the ALSA plugin [aplay]: ALSA Capture from, change from <x> to
83 // <Monitor of x>, where x is whatever your primary sound device is called.
84 // 6. Try launching chrome as the target user on the target machine, try
85 // playing, say, a YouTube video, and record with # arecord -f dat tmp.dat.
86 // Verify the recording with aplay (should have recorded what you played
87 // from chrome).
89 // Note: the volume for ALL your input devices will be forced to 100% by
90 // running this test on Linux.
92 // On Mac:
93 // TODO(phoglund): download sox from gs instead.
94 // 1. Get SoundFlower: http://rogueamoeba.com/freebies/soundflower/download.php
95 // 2. Install it + reboot.
96 // 3. Install MacPorts (http://www.macports.org/).
97 // 4. Install sox: sudo port install sox.
98 // 5. (For Chrome bots) Ensure sox and rec are reachable from the env the test
99 // executes in (sox and rec tends to install in /opt/, which generally isn't
100 // in the Chrome bots' env). For instance, run
101 // sudo ln -s /opt/local/bin/rec /usr/local/bin/rec
102 // sudo ln -s /opt/local/bin/sox /usr/local/bin/sox
103 // 6. In Sound Preferences, set both input and output to Soundflower (2ch).
104 // Note: You will no longer hear audio on this machine, and it will no
105 // longer use any built-in mics.
106 // 7. Try launching chrome as the target user on the target machine, try
107 // playing, say, a YouTube video, and record with 'rec test.wav trim 0 5'.
108 // Stop the video in chrome and try playing back the file; you should hear
109 // a recording of the video (note; if you play back on the target machine
110 // you must revert the changes in step 3 first).
112 // On Windows 7:
113 // 1. Control panel > Sound > Manage audio devices.
114 // 2. In the recording tab, right-click in an empty space in the pane with the
115 // devices. Tick 'show disabled devices'.
116 // 3. You should see a 'stero mix' device - this is what your speakers output.
117 // Right click > Properties.
118 // 4. In the Listen tab for the mix device, check the 'listen to this device'
119 // checkbox. Ensure the mix device is the default recording device.
120 // 5. Launch chrome and try playing a video with sound. You should see
121 // in the volume meter for the mix device. Configure the mix device to have
122 // 50 / 100 in level. Also go into the playback tab, right-click Speakers,
123 // and set that level to 50 / 100. Otherwise you will get distortion in
124 // the recording.
125 class MAYBE_WebRtcAudioQualityBrowserTest : public WebRtcTestBase {
126 public:
127 MAYBE_WebRtcAudioQualityBrowserTest() {}
128 void SetUpInProcessBrowserTestFixture() override {
129 DetectErrorsInJavaScript(); // Look for errors in our rather complex js.
132 void SetUpCommandLine(base::CommandLine* command_line) override {
133 EXPECT_FALSE(command_line->HasSwitch(
134 switches::kUseFakeUIForMediaStream));
136 // The WebAudio-based tests don't care what devices are available to
137 // getUserMedia, and the getUserMedia-based tests will play back a file
138 // through the fake device using using --use-file-for-fake-audio-capture.
139 command_line->AppendSwitch(switches::kUseFakeDeviceForMediaStream);
142 void ConfigureFakeDeviceToPlayFile(const base::FilePath& wav_file_path) {
143 base::CommandLine::ForCurrentProcess()->AppendSwitchPath(
144 switches::kUseFileForFakeAudioCapture, wav_file_path);
147 void AddAudioFileToWebAudio(const std::string& input_file_relative_url,
148 content::WebContents* tab_contents) {
149 // This calls into webaudio.js.
150 EXPECT_EQ("ok-added", ExecuteJavascript(
151 "addAudioFile('" + input_file_relative_url + "')", tab_contents));
154 void PlayAudioFileThroughWebAudio(content::WebContents* tab_contents) {
155 EXPECT_EQ("ok-playing", ExecuteJavascript("playAudioFile()", tab_contents));
158 content::WebContents* OpenPageWithoutGetUserMedia(const char* url) {
159 chrome::AddTabAt(browser(), GURL(), -1, true);
160 ui_test_utils::NavigateToURL(
161 browser(), embedded_test_server()->GetURL(url));
162 content::WebContents* tab =
163 browser()->tab_strip_model()->GetActiveWebContents();
165 // Prepare the peer connections manually in this test since we don't add
166 // getUserMedia-derived media streams in this test like the other tests.
167 EXPECT_EQ("ok-peerconnection-created",
168 ExecuteJavascript("preparePeerConnection()", tab));
169 return tab;
172 void MuteMediaElement(const std::string& element_id,
173 content::WebContents* tab_contents) {
174 EXPECT_EQ("ok-muted", ExecuteJavascript(
175 "setMediaElementMuted('" + element_id + "', true)", tab_contents));
178 protected:
179 void TestAutoGainControl(const base::FilePath::StringType& reference_filename,
180 const std::string& constraints,
181 const std::string& perf_modifier);
182 void SetupAndRecordAudioCall(const base::FilePath& reference_file,
183 const base::FilePath& recording,
184 const std::string& constraints,
185 const base::TimeDelta recording_time);
186 void TestWithFakeDeviceGetUserMedia(const std::string& constraints,
187 const std::string& perf_modifier);
190 namespace {
192 class AudioRecorder {
193 public:
194 AudioRecorder() {}
195 ~AudioRecorder() {}
197 // Starts the recording program for the specified duration. Returns true
198 // on success. We record in 16-bit 44.1 kHz Stereo (mostly because that's
199 // what SoundRecorder.exe will give us and we can't change that).
200 bool StartRecording(base::TimeDelta recording_time,
201 const base::FilePath& output_file) {
202 EXPECT_FALSE(recording_application_.IsValid())
203 << "Tried to record, but is already recording.";
205 int duration_sec = static_cast<int>(recording_time.InSeconds());
206 base::CommandLine command_line(base::CommandLine::NO_PROGRAM);
208 #if defined(OS_WIN)
209 // This disable is required to run SoundRecorder.exe on 64-bit Windows
210 // from a 32-bit binary. We need to load the wow64 disable function from
211 // the DLL since it doesn't exist on Windows XP.
212 base::ScopedNativeLibrary kernel32_lib(base::FilePath(L"kernel32"));
213 if (kernel32_lib.is_valid()) {
214 typedef BOOL (WINAPI* Wow64DisableWow64FSRedirection)(PVOID*);
215 Wow64DisableWow64FSRedirection wow_64_disable_wow_64_fs_redirection;
216 wow_64_disable_wow_64_fs_redirection =
217 reinterpret_cast<Wow64DisableWow64FSRedirection>(
218 kernel32_lib.GetFunctionPointer(
219 "Wow64DisableWow64FsRedirection"));
220 if (wow_64_disable_wow_64_fs_redirection != NULL) {
221 PVOID* ignored = NULL;
222 wow_64_disable_wow_64_fs_redirection(ignored);
226 char duration_in_hms[128] = {0};
227 struct tm duration_tm = {0};
228 duration_tm.tm_sec = duration_sec;
229 EXPECT_NE(0u, strftime(duration_in_hms, arraysize(duration_in_hms),
230 "%H:%M:%S", &duration_tm));
232 command_line.SetProgram(
233 base::FilePath(FILE_PATH_LITERAL("SoundRecorder.exe")));
234 command_line.AppendArg("/FILE");
235 command_line.AppendArgPath(output_file);
236 command_line.AppendArg("/DURATION");
237 command_line.AppendArg(duration_in_hms);
238 #elif defined(OS_MACOSX)
239 command_line.SetProgram(base::FilePath("rec"));
240 command_line.AppendArg("-b");
241 command_line.AppendArg("16");
242 command_line.AppendArg("-q");
243 command_line.AppendArgPath(output_file);
244 command_line.AppendArg("trim");
245 command_line.AppendArg("0");
246 command_line.AppendArg(base::IntToString(duration_sec));
247 #else
248 command_line.SetProgram(base::FilePath("arecord"));
249 command_line.AppendArg("-d");
250 command_line.AppendArg(base::IntToString(duration_sec));
251 command_line.AppendArg("-f");
252 command_line.AppendArg("cd");
253 command_line.AppendArg("-c");
254 command_line.AppendArg("2");
255 command_line.AppendArgPath(output_file);
256 #endif
258 DVLOG(0) << "Running " << command_line.GetCommandLineString();
259 recording_application_ =
260 base::LaunchProcess(command_line, base::LaunchOptions());
261 return recording_application_.IsValid();
264 // Joins the recording program. Returns true on success.
265 bool WaitForRecordingToEnd() {
266 int exit_code = -1;
267 recording_application_.WaitForExit(&exit_code);
268 return exit_code == 0;
270 private:
271 base::Process recording_application_;
274 bool ForceMicrophoneVolumeTo100Percent() {
275 #if defined(OS_WIN)
276 // Note: the force binary isn't in tools since it's one of our own.
277 base::CommandLine command_line(test::GetReferenceFilesDir().Append(
278 FILE_PATH_LITERAL("force_mic_volume_max.exe")));
279 DVLOG(0) << "Running " << command_line.GetCommandLineString();
280 std::string result;
281 if (!base::GetAppOutput(command_line, &result)) {
282 LOG(ERROR) << "Failed to set source volume: output was " << result;
283 return false;
285 #elif defined(OS_MACOSX)
286 base::CommandLine command_line(
287 base::FilePath(FILE_PATH_LITERAL("osascript")));
288 command_line.AppendArg("-e");
289 command_line.AppendArg("set volume input volume 100");
290 command_line.AppendArg("-e");
291 command_line.AppendArg("set volume output volume 85");
293 std::string result;
294 if (!base::GetAppOutput(command_line, &result)) {
295 LOG(ERROR) << "Failed to set source volume: output was " << result;
296 return false;
298 #else
299 // Just force the volume of, say the first 5 devices. A machine will rarely
300 // have more input sources than that. This is way easier than finding the
301 // input device we happen to be using.
302 for (int device_index = 0; device_index < 5; ++device_index) {
303 std::string result;
304 const std::string kHundredPercentVolume = "65536";
305 base::CommandLine command_line(base::FilePath(FILE_PATH_LITERAL("pacmd")));
306 command_line.AppendArg("set-source-volume");
307 command_line.AppendArg(base::IntToString(device_index));
308 command_line.AppendArg(kHundredPercentVolume);
309 DVLOG(0) << "Running " << command_line.GetCommandLineString();
310 if (!base::GetAppOutput(command_line, &result)) {
311 LOG(ERROR) << "Failed to set source volume: output was " << result;
312 return false;
315 #endif
316 return true;
319 // Sox is the "Swiss army knife" of audio processing. We mainly use it for
320 // silence trimming. See http://sox.sourceforge.net.
321 base::CommandLine MakeSoxCommandLine() {
322 #if defined(OS_WIN)
323 base::FilePath sox_path = test::GetToolForPlatform("sox");
324 if (!base::PathExists(sox_path)) {
325 LOG(ERROR) << "Missing sox.exe binary in " << sox_path.value()
326 << "; you may have to provide this binary yourself.";
327 return base::CommandLine(base::CommandLine::NO_PROGRAM);
329 base::CommandLine command_line(sox_path);
330 #else
331 // TODO(phoglund): call checked-in sox rather than system sox on mac/linux.
332 // Same for rec invocations on Mac, above.
333 base::CommandLine command_line(base::FilePath(FILE_PATH_LITERAL("sox")));
334 #endif
335 return command_line;
338 // Removes silence from beginning and end of the |input_audio_file| and writes
339 // the result to the |output_audio_file|. Returns true on success.
340 bool RemoveSilence(const base::FilePath& input_file,
341 const base::FilePath& output_file) {
342 // SOX documentation for silence command: http://sox.sourceforge.net/sox.html
343 // To remove the silence from both beginning and end of the audio file, we
344 // call sox silence command twice: once on normal file and again on its
345 // reverse, then we reverse the final output.
346 // Silence parameters are (in sequence):
347 // ABOVE_PERIODS: The period for which silence occurs. Value 1 is used for
348 // silence at beginning of audio.
349 // DURATION: the amount of time in seconds that non-silence must be detected
350 // before sox stops trimming audio.
351 // THRESHOLD: value used to indicate what sample value is treats as silence.
352 const char* kAbovePeriods = "1";
353 const char* kDuration = "2";
354 const char* kTreshold = "1.5%";
356 base::CommandLine command_line = MakeSoxCommandLine();
357 if (command_line.GetProgram().empty())
358 return false;
359 command_line.AppendArgPath(input_file);
360 command_line.AppendArgPath(output_file);
361 command_line.AppendArg("silence");
362 command_line.AppendArg(kAbovePeriods);
363 command_line.AppendArg(kDuration);
364 command_line.AppendArg(kTreshold);
365 command_line.AppendArg("reverse");
366 command_line.AppendArg("silence");
367 command_line.AppendArg(kAbovePeriods);
368 command_line.AppendArg(kDuration);
369 command_line.AppendArg(kTreshold);
370 command_line.AppendArg("reverse");
372 DVLOG(0) << "Running " << command_line.GetCommandLineString();
373 std::string result;
374 bool ok = base::GetAppOutput(command_line, &result);
375 DVLOG(0) << "Output was:\n\n" << result;
376 return ok;
379 // Looks for 0.2 second audio segments surrounded by silences under 0.3% audio
380 // power and splits the input file on those silences. Output files are written
381 // according to the output file template (e.g. /tmp/out.wav writes
382 // /tmp/out001.wav, /tmp/out002.wav, etc if there are two silence-padded
383 // regions in the file). The silences between speech segments must be at
384 // least 500 ms for this to be reliable.
385 bool SplitFileOnSilence(const base::FilePath& input_file,
386 const base::FilePath& output_file_template) {
387 base::CommandLine command_line = MakeSoxCommandLine();
388 if (command_line.GetProgram().empty())
389 return false;
391 // These are experimentally determined and work on the files we use.
392 const char* kAbovePeriods = "1";
393 const char* kUnderPeriods = "1";
394 const char* kDuration = "0.2";
395 const char* kTreshold = "0.5%";
396 command_line.AppendArgPath(input_file);
397 command_line.AppendArgPath(output_file_template);
398 command_line.AppendArg("silence");
399 command_line.AppendArg(kAbovePeriods);
400 command_line.AppendArg(kDuration);
401 command_line.AppendArg(kTreshold);
402 command_line.AppendArg(kUnderPeriods);
403 command_line.AppendArg(kDuration);
404 command_line.AppendArg(kTreshold);
405 command_line.AppendArg(":");
406 command_line.AppendArg("newfile");
407 command_line.AppendArg(":");
408 command_line.AppendArg("restart");
410 DVLOG(0) << "Running " << command_line.GetCommandLineString();
411 std::string result;
412 bool ok = base::GetAppOutput(command_line, &result);
413 DVLOG(0) << "Output was:\n\n" << result;
414 return ok;
417 bool CanParseAsFloat(const std::string& value) {
418 return atof(value.c_str()) != 0 || value == "0";
421 // Runs PESQ to compare |reference_file| to a |actual_file|. The |sample_rate|
422 // can be either 16000 or 8000.
424 // PESQ is only mono-aware, so the files should preferably be recorded in mono.
425 // Furthermore it expects the file to be 16 rather than 32 bits, even though
426 // 32 bits might work. The audio bandwidth of the two files should be the same
427 // e.g. don't compare a 32 kHz file to a 8 kHz file.
429 // The raw score in MOS is written to |raw_mos|, whereas the MOS-LQO score is
430 // written to mos_lqo. The scores are returned as floats in string form (e.g.
431 // "3.145", etc). Returns true on success.
432 bool RunPesq(const base::FilePath& reference_file,
433 const base::FilePath& actual_file,
434 int sample_rate, std::string* raw_mos, std::string* mos_lqo) {
435 // PESQ will break if the paths are too long (!).
436 EXPECT_LT(reference_file.value().length(), 128u);
437 EXPECT_LT(actual_file.value().length(), 128u);
439 base::FilePath pesq_path = test::GetToolForPlatform("pesq");
440 if (!base::PathExists(pesq_path)) {
441 LOG(ERROR) << "Missing PESQ binary in " << pesq_path.value()
442 << "; you may have to provide this binary yourself.";
443 return false;
446 base::CommandLine command_line(pesq_path);
447 command_line.AppendArg(base::StringPrintf("+%d", sample_rate));
448 command_line.AppendArgPath(reference_file);
449 command_line.AppendArgPath(actual_file);
451 DVLOG(0) << "Running " << command_line.GetCommandLineString();
452 std::string result;
453 if (!base::GetAppOutput(command_line, &result)) {
454 LOG(ERROR) << "Failed to run PESQ.";
455 return false;
457 DVLOG(0) << "Output was:\n\n" << result;
459 const std::string result_anchor = "Prediction (Raw MOS, MOS-LQO): = ";
460 std::size_t anchor_pos = result.find(result_anchor);
461 if (anchor_pos == std::string::npos) {
462 LOG(ERROR) << "PESQ was not able to compute a score; we probably recorded "
463 << "only silence. Please check the output/input volume levels.";
464 return false;
467 // There are two tab-separated numbers on the format x.xxx, e.g. 5 chars each.
468 std::size_t first_number_pos = anchor_pos + result_anchor.length();
469 *raw_mos = result.substr(first_number_pos, 5);
470 EXPECT_TRUE(CanParseAsFloat(*raw_mos)) << "Failed to parse raw MOS number.";
471 *mos_lqo = result.substr(first_number_pos + 5 + 1, 5);
472 EXPECT_TRUE(CanParseAsFloat(*mos_lqo)) << "Failed to parse MOS LQO number.";
474 return true;
477 base::FilePath CreateTemporaryWaveFile() {
478 base::FilePath filename;
479 EXPECT_TRUE(base::CreateTemporaryFile(&filename));
480 base::FilePath wav_filename =
481 filename.AddExtension(FILE_PATH_LITERAL(".wav"));
482 EXPECT_TRUE(base::Move(filename, wav_filename));
483 return wav_filename;
486 void DeleteFileUnlessTestFailed(const base::FilePath& path, bool recursive) {
487 if (::testing::Test::HasFailure())
488 printf("Test failed; keeping recording(s) at\n\t%" PRFilePath ".\n",
489 path.value().c_str());
490 else
491 EXPECT_TRUE(base::DeleteFile(path, recursive));
494 std::vector<base::FilePath> ListWavFilesInDir(const base::FilePath& dir) {
495 base::FileEnumerator files(dir, false, base::FileEnumerator::FILES,
496 FILE_PATH_LITERAL("*.wav"));
498 std::vector<base::FilePath> result;
499 for (base::FilePath name = files.Next(); !name.empty(); name = files.Next())
500 result.push_back(name);
501 return result;
504 // Splits |to_split| into sub-files based on silence. The file you use must have
505 // at least 500 ms periods of silence between speech segments for this to be
506 // reliable.
507 void SplitFileOnSilenceIntoDir(const base::FilePath& to_split,
508 const base::FilePath& workdir) {
509 // First trim beginning and end since they are tricky for the splitter.
510 base::FilePath trimmed_audio = CreateTemporaryWaveFile();
512 ASSERT_TRUE(RemoveSilence(to_split, trimmed_audio));
513 DVLOG(0) << "Trimmed silence: " << trimmed_audio.value() << std::endl;
515 ASSERT_TRUE(SplitFileOnSilence(
516 trimmed_audio, workdir.Append(FILE_PATH_LITERAL("output.wav"))));
517 DeleteFileUnlessTestFailed(trimmed_audio, false);
520 // Computes the difference between the actual and reference segment. A positive
521 // number x means the actual file is x dB stronger than the reference.
522 float AnalyzeOneSegment(const base::FilePath& ref_segment,
523 const base::FilePath& actual_segment,
524 int segment_number) {
525 media::AudioParameters ref_parameters;
526 media::AudioParameters actual_parameters;
527 float ref_energy =
528 test::ComputeAudioEnergyForWavFile(ref_segment, &ref_parameters);
529 float actual_energy =
530 test::ComputeAudioEnergyForWavFile(actual_segment, &actual_parameters);
532 base::TimeDelta difference_in_length = ref_parameters.GetBufferDuration() -
533 actual_parameters.GetBufferDuration();
535 EXPECT_LE(difference_in_length,
536 base::TimeDelta::FromMilliseconds(kMaxAgcSegmentDiffMs))
537 << "Segments differ " << difference_in_length.InMilliseconds() << " ms "
538 << "in length for segment " << segment_number << "; we're likely "
539 << "comparing unrelated segments or silence splitting is busted.";
541 return actual_energy - ref_energy;
544 std::string MakeTraceName(const base::FilePath& ref_filename,
545 size_t segment_number) {
546 std::string ascii_filename;
547 #if defined(OS_WIN)
548 ascii_filename = base::WideToUTF8(ref_filename.BaseName().value());
549 #else
550 ascii_filename = ref_filename.BaseName().value();
551 #endif
552 return base::StringPrintf(
553 "%s_segment_%d", ascii_filename.c_str(), (int)segment_number);
556 void AnalyzeSegmentsAndPrintResult(
557 const std::vector<base::FilePath>& ref_segments,
558 const std::vector<base::FilePath>& actual_segments,
559 const base::FilePath& reference_file,
560 const std::string& perf_modifier) {
561 ASSERT_GT(ref_segments.size(), 0u)
562 << "Failed to split reference file on silence; sox is likely broken.";
563 ASSERT_EQ(ref_segments.size(), actual_segments.size())
564 << "The recording did not result in the same number of audio segments "
565 << "after on splitting on silence; WebRTC must have deformed the audio "
566 << "too much.";
568 for (size_t i = 0; i < ref_segments.size(); i++) {
569 float difference_in_decibel = AnalyzeOneSegment(ref_segments[i],
570 actual_segments[i],
572 std::string trace_name = MakeTraceName(reference_file, i);
573 perf_test::PrintResult("agc_energy_diff", perf_modifier, trace_name,
574 difference_in_decibel, "dB", false);
578 void ComputeAndPrintPesqResults(const base::FilePath& reference_file,
579 const base::FilePath& recording,
580 const std::string& perf_modifier) {
581 base::FilePath trimmed_reference = CreateTemporaryWaveFile();
582 base::FilePath trimmed_recording = CreateTemporaryWaveFile();
584 ASSERT_TRUE(RemoveSilence(reference_file, trimmed_reference));
585 ASSERT_TRUE(RemoveSilence(recording, trimmed_recording));
587 std::string raw_mos;
588 std::string mos_lqo;
589 bool succeeded = RunPesq(trimmed_reference, trimmed_recording, 16000,
590 &raw_mos, &mos_lqo);
591 EXPECT_TRUE(succeeded) << "Failed to run PESQ.";
592 if (succeeded) {
593 perf_test::PrintResult(
594 "audio_pesq", perf_modifier, "raw_mos", raw_mos, "score", true);
595 perf_test::PrintResult(
596 "audio_pesq", perf_modifier, "mos_lqo", mos_lqo, "score", true);
599 DeleteFileUnlessTestFailed(trimmed_reference, false);
600 DeleteFileUnlessTestFailed(trimmed_recording, false);
603 } // namespace
605 // Sets up a two-way WebRTC call and records its output to |recording|, using
606 // getUserMedia.
608 // |reference_file| should have at least five seconds of silence in the
609 // beginning: otherwise all the reference audio will not be picked up by the
610 // recording. Note that the reference file will start playing as soon as the
611 // audio device is up following the getUserMedia call in the left tab. The time
612 // it takes to negotiate a call isn't deterministic, but five seconds should be
613 // plenty of time. Similarly, the recording time should be enough to catch the
614 // whole reference file. If you then silence-trim the reference file and actual
615 // file, you should end up with two time-synchronized files.
616 void MAYBE_WebRtcAudioQualityBrowserTest::SetupAndRecordAudioCall(
617 const base::FilePath& reference_file,
618 const base::FilePath& recording,
619 const std::string& constraints,
620 const base::TimeDelta recording_time) {
621 ASSERT_TRUE(embedded_test_server()->InitializeAndWaitUntilReady());
622 ASSERT_TRUE(test::HasReferenceFilesInCheckout());
623 ASSERT_TRUE(ForceMicrophoneVolumeTo100Percent());
625 ConfigureFakeDeviceToPlayFile(reference_file);
627 // Create a two-way call. Mute one of the receivers though; that way it will
628 // be receiving audio bytes, but we will not be playing out of both elements.
629 GURL test_page = embedded_test_server()->GetURL(kWebRtcAudioTestHtmlPage);
630 content::WebContents* left_tab =
631 OpenPageAndGetUserMediaInNewTabWithConstraints(test_page, constraints);
632 SetupPeerconnectionWithLocalStream(left_tab);
633 MuteMediaElement("remote-view", left_tab);
635 content::WebContents* right_tab =
636 OpenPageAndGetUserMediaInNewTabWithConstraints(test_page, constraints);
637 SetupPeerconnectionWithLocalStream(right_tab);
639 AudioRecorder recorder;
640 ASSERT_TRUE(recorder.StartRecording(recording_time, recording));
642 NegotiateCall(left_tab, right_tab);
644 ASSERT_TRUE(recorder.WaitForRecordingToEnd());
645 DVLOG(0) << "Done recording to " << recording.value() << std::endl;
647 HangUp(left_tab);
650 void MAYBE_WebRtcAudioQualityBrowserTest::TestWithFakeDeviceGetUserMedia(
651 const std::string& constraints,
652 const std::string& perf_modifier) {
653 if (OnWinXp() || OnWin8()) {
654 // http://crbug.com/379798.
655 LOG(ERROR) << "This test is not implemented for Windows XP/Win8.";
656 return;
659 base::FilePath reference_file =
660 test::GetReferenceFilesDir().Append(kReferenceFile);
661 base::FilePath recording = CreateTemporaryWaveFile();
663 ASSERT_NO_FATAL_FAILURE(SetupAndRecordAudioCall(
664 reference_file, recording, constraints,
665 base::TimeDelta::FromSeconds(30)));
667 ComputeAndPrintPesqResults(reference_file, recording, perf_modifier);
668 DeleteFileUnlessTestFailed(recording, false);
671 IN_PROC_BROWSER_TEST_F(MAYBE_WebRtcAudioQualityBrowserTest,
672 MANUAL_TestCallQualityWithAudioFromFakeDevice) {
673 TestWithFakeDeviceGetUserMedia(kAudioOnlyCallConstraints, "_getusermedia");
676 IN_PROC_BROWSER_TEST_F(MAYBE_WebRtcAudioQualityBrowserTest,
677 MANUAL_TestCallQualityWithAudioFromWebAudio) {
678 if (OnWinXp() || OnWin8()) {
679 // http://crbug.com/379798.
680 LOG(ERROR) << "This test is not implemented for Windows XP/Win8.";
681 return;
683 ASSERT_TRUE(test::HasReferenceFilesInCheckout());
684 ASSERT_TRUE(embedded_test_server()->InitializeAndWaitUntilReady());
686 ASSERT_TRUE(ForceMicrophoneVolumeTo100Percent());
688 content::WebContents* left_tab =
689 OpenPageWithoutGetUserMedia(kWebRtcAudioTestHtmlPage);
690 content::WebContents* right_tab =
691 OpenPageWithoutGetUserMedia(kWebRtcAudioTestHtmlPage);
693 AddAudioFileToWebAudio(kReferenceFileRelativeUrl, left_tab);
695 NegotiateCall(left_tab, right_tab);
697 base::FilePath recording = CreateTemporaryWaveFile();
699 // Note: the sound clip is 21.6 seconds: record for 25 seconds to get some
700 // safety margins on each side.
701 AudioRecorder recorder;
702 ASSERT_TRUE(recorder.StartRecording(base::TimeDelta::FromSeconds(25),
703 recording));
705 PlayAudioFileThroughWebAudio(left_tab);
707 ASSERT_TRUE(recorder.WaitForRecordingToEnd());
708 DVLOG(0) << "Done recording to " << recording.value() << std::endl;
710 HangUp(left_tab);
712 // Compare with the reference file on disk (this is the same file we played
713 // through WebAudio earlier).
714 base::FilePath reference_file =
715 test::GetReferenceFilesDir().Append(kReferenceFile);
716 ComputeAndPrintPesqResults(reference_file, recording, "_webaudio");
720 * The auto gain control test plays a file into the fake microphone. Then it
721 * sets up a one-way WebRTC call with audio only and records Chrome's output on
722 * the receiving side using the audio loopback provided by the quality test
723 * (see the class comments for more details).
725 * Then both the recording and reference file are split on silence. This creates
726 * a number of segments with speech in them. The reason for this is to provide
727 * a kind of synchronization mechanism so the start of each speech segment is
728 * compared to the start of the corresponding speech segment. This is because we
729 * will experience inevitable clock drift between the system clock (which runs
730 * the fake microphone) and the sound card (which runs play-out). Effectively
731 * re-synchronizing on each segment mitigates this.
733 * The silence splitting is inherently sensitive to the sound file we run on.
734 * Therefore the reference file must have at least 500 ms of pure silence
735 * between speech segments; the test will fail if the output produces more
736 * segments than the reference.
738 * The test reports the difference in decibel between the reference and output
739 * file per 10 ms interval in each speech segment. A value of 6 means the
740 * output was 6 dB louder than the reference, presumably because the AGC applied
741 * gain to the signal.
743 * The test only exercises digital AGC for now.
745 * We record in CD format here (44.1 kHz) because that's what the fake input
746 * device currently supports, and we want to be able to compare directly. See
747 * http://crbug.com/421054.
749 void MAYBE_WebRtcAudioQualityBrowserTest::TestAutoGainControl(
750 const base::FilePath::StringType& reference_filename,
751 const std::string& constraints,
752 const std::string& perf_modifier) {
753 if (OnWinXp() || OnWin8()) {
754 // http://crbug.com/379798.
755 LOG(ERROR) << "This test is not implemented for Windows XP/Win8.";
756 return;
758 base::FilePath reference_file =
759 test::GetReferenceFilesDir().Append(reference_filename);
760 base::FilePath recording = CreateTemporaryWaveFile();
762 ASSERT_NO_FATAL_FAILURE(SetupAndRecordAudioCall(
763 reference_file, recording, constraints,
764 base::TimeDelta::FromSeconds(30)));
766 base::ScopedTempDir split_ref_files;
767 ASSERT_TRUE(split_ref_files.CreateUniqueTempDir());
768 ASSERT_NO_FATAL_FAILURE(
769 SplitFileOnSilenceIntoDir(reference_file, split_ref_files.path()));
770 std::vector<base::FilePath> ref_segments =
771 ListWavFilesInDir(split_ref_files.path());
773 base::ScopedTempDir split_actual_files;
774 ASSERT_TRUE(split_actual_files.CreateUniqueTempDir());
775 ASSERT_NO_FATAL_FAILURE(
776 SplitFileOnSilenceIntoDir(recording, split_actual_files.path()));
778 // Keep the recording and split files if the analysis fails.
779 base::FilePath actual_files_dir = split_actual_files.Take();
780 std::vector<base::FilePath> actual_segments =
781 ListWavFilesInDir(actual_files_dir);
783 AnalyzeSegmentsAndPrintResult(
784 ref_segments, actual_segments, reference_file, perf_modifier);
786 DeleteFileUnlessTestFailed(recording, false);
787 DeleteFileUnlessTestFailed(actual_files_dir, true);
790 // The AGC should apply non-zero gain here.
791 IN_PROC_BROWSER_TEST_F(MAYBE_WebRtcAudioQualityBrowserTest,
792 MANUAL_TestAutoGainControlOnLowAudio) {
793 ASSERT_NO_FATAL_FAILURE(TestAutoGainControl(
794 kReferenceFile, kAudioOnlyCallConstraints, "_with_agc"));
797 // Since the AGC is off here there should be no gain at all.
798 IN_PROC_BROWSER_TEST_F(MAYBE_WebRtcAudioQualityBrowserTest,
799 MANUAL_TestAutoGainIsOffWithAudioProcessingOff) {
800 const char* kAudioCallWithoutAudioProcessing =
801 "{audio: { mandatory: { echoCancellation: false } } }";
802 ASSERT_NO_FATAL_FAILURE(TestAutoGainControl(
803 kReferenceFile, kAudioCallWithoutAudioProcessing, "_no_agc"));