def _align_waves(self, real_path, synt_path):
"""
Align two ``wav`` files.
Return a pair:
1. a success bool flag
2. the computed alignment map, that is,
a list of pairs of floats, each representing
corresponding time instants
in the real and synt wave, respectively
``[real_time, synt_time]``
"""
self._log("Aligning waves")
try:
self._log("Creating DTWAligner object")
aligner = DTWAligner(real_path, synt_path, logger=self.logger)
self._log("Computing MFCC...")
aligner.compute_mfcc()
self._log("Computing MFCC... done")
self._log("Computing path...")
aligner.compute_path()
self._log("Computing path... done")
self._log("Computing map...")
computed_map = aligner.computed_map
self._log("Computing map... done")
return (True, computed_map)
except:
return (False, None)
def _align_waves(self, real_wave_mfcc, synt_wave_mfcc, synt_anchors):
"""
Align two AudioFileMFCC objects,
representing WAVE files.
Return a list of boundary indices.
"""
self.log(u"Creating DTWAligner...")
aligner = DTWAligner(real_wave_mfcc, synt_wave_mfcc, rconf=self.rconf, logger=self.logger)
self.log(u"Creating DTWAligner... done")
self.log(u"Computing boundary indices...")
boundary_indices = aligner.compute_boundaries(synt_anchors)
self.log(u"Computing boundary indices... done")
return boundary_indices
def test_set_synt_wave_mfcc(self):
af = AudioFileMFCC(self.AUDIO_FILE)
aligner = DTWAligner(synt_wave_mfcc=af)
self.assertIsNone(aligner.real_wave_mfcc)
self.assertIsNotNone(aligner.synt_wave_mfcc)
self.assertIsNone(aligner.real_wave_path)
self.assertIsNone(aligner.synt_wave_path)
def _align_waves(self, real_wave_mfcc, synt_wave_mfcc, synt_anchors):
"""
Align two AudioFileMFCC objects,
representing WAVE files.
Return a list of boundary indices.
"""
self.log(u"Creating DTWAligner...")
aligner = DTWAligner(real_wave_mfcc,
synt_wave_mfcc,
rconf=self.rconf,
logger=self.logger)
self.log(u"Creating DTWAligner... done")
self.log(u"Computing boundary indices...")
boundary_indices = aligner.compute_boundaries(synt_anchors)
self.log(u"Computing boundary indices... done")
return boundary_indices
def _align_waves(self, real_path, synt_path):
"""
Align two ``wav`` files.
Return a pair:
1. a success bool flag
2. the computed alignment map, that is,
a list of pairs of floats, each representing
corresponding time instants
in the real and synt wave, respectively
``[real_time, synt_time]``
"""
self._log("Aligning waves")
try:
self._log("Creating DTWAligner object")
aligner = DTWAligner(real_path, synt_path, logger=self.logger)
self._log("Computing MFCC...")
aligner.compute_mfcc()
self._log("Computing MFCC... done")
self._log("Computing path...")
aligner.compute_path()
self._log("Computing path... done")
self._log("Computing map...")
computed_map = aligner.computed_map
self._log("Computing map... done")
self._log("Aligning waves: succeeded")
return (True, computed_map)
except Exception as e:
self._log("Aligning waves: failed")
self._log(["Message: %s", str(e)])
return (False, None)
def test_compute_acm_none(self):
aligner = DTWAligner()
with self.assertRaises(DTWAlignerNotInitialized):
aligner.compute_accumulated_cost_matrix()
def test_compute_acm_none(self):
aligner = DTWAligner()
with self.assertRaises(DTWAlignerNotInitialized):
aligner.compute_accumulated_cost_matrix()
def test_set_synt_wave_path(self):
aligner = DTWAligner(synt_wave_path=self.AUDIO_FILE)
self.assertIsNone(aligner.real_wave_mfcc)
self.assertIsNotNone(aligner.synt_wave_path)
self.assertIsNone(aligner.real_wave_path)
self.assertIsNotNone(aligner.synt_wave_mfcc)
def test_create_aligner(self):
aligner = DTWAligner()
self.assertIsNone(aligner.real_wave_mfcc)
self.assertIsNone(aligner.synt_wave_mfcc)
self.assertIsNone(aligner.real_wave_path)
self.assertIsNone(aligner.synt_wave_path)
def test_compute_path_synt_mfcc(self):
af = AudioFileMFCC(self.AUDIO_FILE)
aligner = DTWAligner(synt_wave_mfcc=af)
with self.assertRaises(DTWAlignerNotInitialized):
aligner.compute_path()
def test_compute_path_synt_path(self):
aligner = DTWAligner(synt_wave_path=self.AUDIO_FILE)
with self.assertRaises(DTWAlignerNotInitialized):
aligner.compute_path()
def _detect_start(self,
min_start_length,
max_start_length,
metric,
backwards=False):
""" Detect start """
self._log(["Min start length: %.3f", min_start_length])
self._log(["Max start length: %.3f", max_start_length])
self._log(["Metric: %s", metric])
self._log(["Backwards: %s", str(backwards)])
audio_rate = self.text_file.characters / self.audio_file.audio_length
self._log(["Audio rate: %.3f", audio_rate])
self._log("Synthesizing query...")
tmp_handler, tmp_file_path = tempfile.mkstemp(suffix=".wav",
dir=gf.custom_tmp_dir())
synt = Synthesizer(logger=self.logger)
synt_duration = max_start_length * self.QUERY_FACTOR
self._log(["Synthesizing %.3f seconds", synt_duration])
result = synt.synthesize(self.text_file,
tmp_file_path,
quit_after=synt_duration,
backwards=backwards)
self._log("Synthesizing query... done")
query_file = AudioFile(tmp_file_path)
if backwards:
self._log("Reversing query")
query_file.reverse()
self._log("Extracting MFCCs for query...")
query_file.extract_mfcc(frame_rate=self.frame_rate)
query_file.clear_data()
self._log("Extracting MFCCs for query... done")
self._log("Cleaning up...")
self._cleanup(tmp_handler, tmp_file_path)
self._log("Cleaning up... done")
query_characters = result[2]
query_len = query_file.audio_length
query_mfcc = query_file.audio_mfcc
query_rate = query_characters / query_len
stretch_factor = max(1, query_rate / audio_rate)
self._log(["Audio rate: %.3f", audio_rate])
self._log(["Query rate: %.3f", query_rate])
self._log(["Stretch factor: %.3f", stretch_factor])
audio_mfcc = self.audio_file.audio_mfcc
self._log(["Actual audio has %d frames", audio_mfcc.shape[1]])
audio_mfcc_end_index = int(max_start_length * self.AUDIO_FACTOR *
self.frame_rate)
self._log(["Limiting audio to first %d frames", audio_mfcc_end_index])
audio_mfcc_end_index = min(audio_mfcc_end_index, audio_mfcc.shape[1])
audio_mfcc = audio_mfcc[:, 0:audio_mfcc_end_index]
self._log(["Limited audio has %d frames", audio_mfcc.shape[1]])
l, o = audio_mfcc.shape
l, n = query_mfcc.shape
# minimum length of a matched interval in the real audio
stretched_match_minimum_length = int(n * stretch_factor)
self._log(["Audio has %d frames == %.3f seconds", o, self._i2t(o)])
self._log(["Query has %d frames == %.3f seconds", n, self._i2t(n)])
self._log(["Stretch factor: %.3f", stretch_factor])
self._log(
["Required minimum length: %.3f", stretched_match_minimum_length])
self._log("Speech intervals:")
for interval in self.audio_speech:
self._log([
" %d %d == %.3f %.3f",
self._t2i(interval[0]),
self._t2i(interval[1]), interval[0], interval[1]
])
admissible_intervals = [
x for x in self.audio_speech
if ((x[0] >= min_start_length) and (x[0] <= max_start_length))
]
self._log("AdmissibleSpeech intervals:")
for interval in admissible_intervals:
self._log([
" %d %d == %.3f %.3f",
self._t2i(interval[0]),
self._t2i(interval[1]), interval[0], interval[1]
])
candidates = []
runs_with_min_length = 0
runs_no_improvement = 0
runs_min_distortion = numpy.inf
runs_min_value = numpy.inf
for interval in admissible_intervals:
if runs_no_improvement >= self.MAX_RUNS_NO_IMPROVEMENT:
self._log(" Breaking: too many runs without improvement")
break
if runs_with_min_length >= self.MAX_RUNS_WITH_MIN_LENGTH:
self._log(
" Breaking: too many runs with minimum required length")
break
start_time = interval[0]
start_index = self._t2i(start_time)
self._log([
"Evaluating interval starting at %d == %.3f ", start_index,
start_time
])
if start_index > o:
self._log(" Breaking: start index outside audio window")
break
req_end_index = start_index + stretched_match_minimum_length
req_end_time = self._i2t(req_end_index)
if req_end_index > o:
self._log(
" Breaking: not enough audio left in shifted window")
break
end_index = min(start_index + 2 * n, o)
end_time = self._i2t(end_index)
self._log([" Start %d == %.3f", start_index, start_time])
self._log([" Req end %d == %.3f", req_end_index, req_end_time])
self._log([" Eff end %d == %.3f", end_index, end_time])
audio_mfcc_sub = audio_mfcc[:, start_index:end_index]
l, m = audio_mfcc_sub.shape
self._log("Computing DTW...")
aligner = DTWAligner(None,
None,
frame_rate=self.frame_rate,
logger=self.logger)
aligner.real_wave_full_mfcc = audio_mfcc_sub
aligner.synt_wave_full_mfcc = query_mfcc
aligner.real_wave_length = self._i2t(m)
aligner.synt_wave_length = self._i2t(n)
acm = aligner.compute_accumulated_cost_matrix()
# transpose, so we have an n x m accumulated cost matrix
acm = acm.transpose()
last_row = acm[-1, :]
self._log("Computing DTW... done")
# find the minimum, but its index must be >= stretched_match_minimum_length
candidate_argmin_index = numpy.argmin(
last_row[stretched_match_minimum_length:])
candidate_length_index = stretched_match_minimum_length + candidate_argmin_index
candidate_length_time = self._i2t(candidate_length_index)
candidate_value = last_row[candidate_length_index]
candidate_end_index = start_index + candidate_length_index
candidate_end_time = self._i2t(candidate_end_index)
candidate_distortion = candidate_value / candidate_length_index
# check if the candidate has minimum length
if candidate_length_index == stretched_match_minimum_length:
runs_with_min_length += 1
else:
runs_with_min_length = 0
# check if the candidate improved the global minimum value
if metric == SDMetric.VALUE:
if candidate_value < runs_min_value:
runs_min_value = candidate_value
runs_no_improvement = 0
else:
runs_no_improvement += 1
if metric == SDMetric.DISTORTION:
if candidate_distortion < runs_min_distortion:
runs_min_distortion = candidate_distortion
runs_no_improvement = 0
else:
runs_no_improvement += 1
# append to the list of candidates
self._log([
" Interval start: %d == %.6f", start_index, start_time
])
self._log(
[" Interval end: %d == %.6f", end_index, end_time])
self._log([
" Candidate start: %d == %.6f", start_index, start_time
])
self._log([
" Candidate end: %d == %.6f", candidate_end_index,
candidate_end_time
])
self._log([
" Candidate length: %d == %.6f", candidate_length_index,
candidate_length_time
])
self._log([" Candidate value: %.6f", candidate_value])
self._log([" Candidate distortion: %.6f", candidate_distortion])
candidates.append({
"start_index": start_index,
"length": candidate_length_index,
"value": candidate_value,
"distortion": candidate_distortion
})
# select best candidate and return its start time
# if we have no best candidate, return 0.0
best_candidate = self._select_best_candidate(candidates, metric)
if best_candidate is None:
return 0.0
sd_time = self._i2t(max(best_candidate["start_index"], 0))
self._log(["Returning time %.3f", sd_time])
return sd_time
def test_compute_acm_synt_path(self):
aligner = DTWAligner(synt_wave_path=self.AUDIO_FILE)
with self.assertRaises(DTWAlignerNotInitialized):
aligner.compute_accumulated_cost_matrix()
def test_compute_path_synt_mfcc(self):
af = AudioFileMFCC(self.AUDIO_FILE)
aligner = DTWAligner(synt_wave_mfcc=af)
with self.assertRaises(DTWAlignerNotInitialized):
aligner.compute_path()
def _detect(self, min_length, max_length, tail=False):
"""
Detect the head or tail within ``min_length`` and ``max_length`` duration.
If detecting the tail, the real wave MFCC and the query are reversed
so that the tail detection problem reduces to a head detection problem.
Return the duration of the head or tail, in seconds.
:param min_length: estimated minimum length
:type min_length: :class:`~aeneas.exacttiming.TimeValue`
:param max_length: estimated maximum length
:type max_length: :class:`~aeneas.exacttiming.TimeValue`
:rtype: :class:`~aeneas.exacttiming.TimeValue`
:raises: TypeError: if one of the parameters is not ``None`` or a number
:raises: ValueError: if one of the parameters is negative
"""
def _sanitize(value, default, name):
if value is None:
value = default
try:
value = TimeValue(value)
except (TypeError, ValueError, InvalidOperation) as exc:
self.log_exc(u"The value of %s is not a number" % (name), exc, True, TypeError)
if value < 0:
self.log_exc(u"The value of %s is negative" % (name), None, True, ValueError)
return value
min_length = _sanitize(min_length, self.MIN_LENGTH, "min_length")
max_length = _sanitize(max_length, self.MAX_LENGTH, "max_length")
mws = self.rconf.mws
min_length_frames = int(min_length / mws)
max_length_frames = int(max_length / mws)
self.log([u"MFCC window shift s: %.3f", mws])
self.log([u"Min start length s: %.3f", min_length])
self.log([u"Min start length frames: %d", min_length_frames])
self.log([u"Max start length s: %.3f", max_length])
self.log([u"Max start length frames: %d", max_length_frames])
self.log([u"Tail?: %s", str(tail)])
self.log(u"Synthesizing query...")
synt_duration = max_length * self.QUERY_FACTOR
self.log([u"Synthesizing at least %.3f seconds", synt_duration])
tmp_handler, tmp_file_path = gf.tmp_file(suffix=u".wav", root=self.rconf[RuntimeConfiguration.TMP_PATH])
synt = Synthesizer(rconf=self.rconf, logger=self.logger)
anchors, total_time, synthesized_chars = synt.synthesize(
self.text_file,
tmp_file_path,
quit_after=synt_duration,
backwards=tail
)
self.log(u"Synthesizing query... done")
self.log(u"Extracting MFCCs for query...")
query_mfcc = AudioFileMFCC(tmp_file_path, rconf=self.rconf, logger=self.logger)
self.log(u"Extracting MFCCs for query... done")
self.log(u"Cleaning up...")
gf.delete_file(tmp_handler, tmp_file_path)
self.log(u"Cleaning up... done")
search_window = max_length * self.AUDIO_FACTOR
search_window_end = min(int(search_window / mws), self.real_wave_mfcc.all_length)
self.log([u"Query MFCC length (frames): %d", query_mfcc.all_length])
self.log([u"Real MFCC length (frames): %d", self.real_wave_mfcc.all_length])
self.log([u"Search window end (s): %.3f", search_window])
self.log([u"Search window end (frames): %d", search_window_end])
if tail:
self.log(u"Tail => reversing real_wave_mfcc and query_mfcc")
self.real_wave_mfcc.reverse()
query_mfcc.reverse()
# NOTE: VAD will be run here, if not done before
speech_intervals = self.real_wave_mfcc.intervals(speech=True, time=False)
if len(speech_intervals) < 1:
self.log(u"No speech intervals, hence no start found")
if tail:
self.real_wave_mfcc.reverse()
return TimeValue("0.000")
# generate a list of begin indices
search_end = None
candidates_begin = []
for interval in speech_intervals:
if (interval[0] >= min_length_frames) and (interval[0] <= max_length_frames):
candidates_begin.append(interval[0])
search_end = interval[1]
if search_end >= search_window_end:
break
# for each begin index, compute the acm cost
# to match the query
# note that we take the min over the last column of the acm
# meaning that we allow to match the entire query wave
# against a portion of the real wave
candidates = []
for candidate_begin in candidates_begin:
self.log([u"Candidate interval starting at %d == %.3f", candidate_begin, candidate_begin * mws])
try:
rwm = AudioFileMFCC(
mfcc_matrix=self.real_wave_mfcc.all_mfcc[:, candidate_begin:search_end],
rconf=self.rconf,
logger=self.logger
)
dtw = DTWAligner(
real_wave_mfcc=rwm,
synt_wave_mfcc=query_mfcc,
rconf=self.rconf,
logger=self.logger
)
acm = dtw.compute_accumulated_cost_matrix()
last_column = acm[:, -1]
min_value = numpy.min(last_column)
min_index = numpy.argmin(last_column)
self.log([u"Candidate interval: %d %d == %.3f %.3f", candidate_begin, search_end, candidate_begin * mws, search_end * mws])
self.log([u" Min value: %.6f", min_value])
self.log([u" Min index: %d == %.3f", min_index, min_index * mws])
candidates.append((min_value, candidate_begin, min_index))
except Exception as exc:
self.log_exc(u"An unexpected error occurred while running _detect", exc, False, None)
# reverse again the real wave
if tail:
self.log(u"Tail => reversing real_wave_mfcc again")
self.real_wave_mfcc.reverse()
# return
if len(candidates) < 1:
self.log(u"No candidates found")
return TimeValue("0.000")
self.log(u"Candidates:")
for candidate in candidates:
self.log([u" Value: %.6f Begin Time: %.3f Min Index: %d", candidate[0], candidate[1] * mws, candidate[2]])
best = sorted(candidates)[0][1]
self.log([u"Best candidate: %d == %.3f", best, best * mws])
return best * mws
def test_compute_acm_synt_path(self):
aligner = DTWAligner(synt_wave_path=self.AUDIO_FILE)
with self.assertRaises(DTWAlignerNotInitialized):
aligner.compute_accumulated_cost_matrix()
def _detect(self, min_length, max_length, tail=False):
"""
Detect the head or tail within ``min_length`` and ``max_length`` duration.
If detecting the tail, the real wave MFCC and the query are reversed
so that the tail detection problem reduces to a head detection problem.
Return the duration of the head or tail, in seconds.
:param min_length: estimated minimum length
:type min_length: :class:`~aeneas.timevalue.TimeValue`
:param max_length: estimated maximum length
:type max_length: :class:`~aeneas.timevalue.TimeValue`
:rtype: :class:`~aeneas.timevalue.TimeValue`
:raises: TypeError: if one of the parameters is not ``None`` or a number
:raises: ValueError: if one of the parameters is negative
"""
def _sanitize(value, default, name):
if value is None:
value = default
try:
value = TimeValue(value)
except (TypeError, ValueError, InvalidOperation) as exc:
self.log_exc(u"The value of %s is not a number" % (name), exc, True, TypeError)
if value < 0:
self.log_exc(u"The value of %s is negative" % (name), None, True, ValueError)
return value
min_length = _sanitize(min_length, self.MIN_LENGTH, "min_length")
max_length = _sanitize(max_length, self.MAX_LENGTH, "max_length")
mws = self.rconf.mws
min_length_frames = int(min_length / mws)
max_length_frames = int(max_length / mws)
self.log([u"MFCC window shift s: %.3f", mws])
self.log([u"Min start length s: %.3f", min_length])
self.log([u"Min start length frames: %d", min_length_frames])
self.log([u"Max start length s: %.3f", max_length])
self.log([u"Max start length frames: %d", max_length_frames])
self.log([u"Tail?: %s", str(tail)])
self.log(u"Synthesizing query...")
synt_duration = max_length * self.QUERY_FACTOR
self.log([u"Synthesizing at least %.3f seconds", synt_duration])
tmp_handler, tmp_file_path = gf.tmp_file(suffix=u".wav", root=self.rconf[RuntimeConfiguration.TMP_PATH])
synt = Synthesizer(rconf=self.rconf, logger=self.logger)
anchors, total_time, synthesized_chars = synt.synthesize(
self.text_file,
tmp_file_path,
quit_after=synt_duration,
backwards=tail
)
self.log(u"Synthesizing query... done")
self.log(u"Extracting MFCCs for query...")
query_mfcc = AudioFileMFCC(tmp_file_path, rconf=self.rconf, logger=self.logger)
self.log(u"Extracting MFCCs for query... done")
self.log(u"Cleaning up...")
gf.delete_file(tmp_handler, tmp_file_path)
self.log(u"Cleaning up... done")
search_window = max_length * self.AUDIO_FACTOR
search_window_end = min(int(search_window / mws), self.real_wave_mfcc.all_length)
self.log([u"Query MFCC length (frames): %d", query_mfcc.all_length])
self.log([u"Real MFCC length (frames): %d", self.real_wave_mfcc.all_length])
self.log([u"Search window end (s): %.3f", search_window])
self.log([u"Search window end (frames): %d", search_window_end])
if tail:
self.log(u"Tail => reversing real_wave_mfcc and query_mfcc")
self.real_wave_mfcc.reverse()
query_mfcc.reverse()
# NOTE: VAD will be run here, if not done before
speech_intervals = self.real_wave_mfcc.intervals(speech=True, time=False)
if len(speech_intervals) < 1:
self.log(u"No speech intervals, hence no start found")
if tail:
self.real_wave_mfcc.reverse()
return TimeValue("0.000")
# generate a list of begin indices
search_end = None
candidates_begin = []
for interval in speech_intervals:
if (interval[0] >= min_length_frames) and (interval[0] <= max_length_frames):
candidates_begin.append(interval[0])
search_end = interval[1]
if search_end >= search_window_end:
break
# for each begin index, compute the acm cost
# to match the query
# note that we take the min over the last column of the acm
# meaning that we allow to match the entire query wave
# against a portion of the real wave
candidates = []
for candidate_begin in candidates_begin:
self.log([u"Candidate interval starting at %d == %.3f", candidate_begin, candidate_begin * mws])
try:
rwm = AudioFileMFCC(
mfcc_matrix=self.real_wave_mfcc.all_mfcc[:, candidate_begin:search_end],
rconf=self.rconf,
logger=self.logger
)
dtw = DTWAligner(
real_wave_mfcc=rwm,
synt_wave_mfcc=query_mfcc,
rconf=self.rconf,
logger=self.logger
)
acm = dtw.compute_accumulated_cost_matrix()
last_column = acm[:, -1]
min_value = numpy.min(last_column)
min_index = numpy.argmin(last_column)
self.log([u"Candidate interval: %d %d == %.3f %.3f", candidate_begin, search_end, candidate_begin * mws, search_end * mws])
self.log([u" Min value: %.6f", min_value])
self.log([u" Min index: %d == %.3f", min_index, min_index * mws])
candidates.append((min_value, candidate_begin, min_index))
except Exception as exc:
self.log_exc(u"An unexpected error occurred while running _detect", exc, False, None)
# reverse again the real wave
if tail:
self.log(u"Tail => reversing real_wave_mfcc again")
self.real_wave_mfcc.reverse()
# return
if len(candidates) < 1:
self.log(u"No candidates found")
return TimeValue("0.000")
self.log(u"Candidates:")
for candidate in candidates:
self.log([u" Value: %.6f Begin Time: %.3f Min Index: %d", candidate[0], candidate[1] * mws, candidate[2]])
best = sorted(candidates)[0][1]
self.log([u"Best candidate: %d == %.3f", best, best * mws])
return best * mws
def _detect_start(self, min_start_length, max_start_length, metric, backwards=False):
""" Detect start """
self._log(["Min start length: %.3f", min_start_length])
self._log(["Max start length: %.3f", max_start_length])
self._log(["Metric: %s", metric])
self._log(["Backwards: %s", str(backwards)])
audio_rate = self.text_file.characters / self.audio_file.audio_length
self._log(["Audio rate: %.3f", audio_rate])
self._log("Synthesizing query...")
tmp_handler, tmp_file_path = tempfile.mkstemp(
suffix=".wav",
dir=gf.custom_tmp_dir()
)
synt = Synthesizer(logger=self.logger)
synt_duration = max_start_length * self.QUERY_FACTOR
self._log(["Synthesizing %.3f seconds", synt_duration])
result = synt.synthesize(
self.text_file,
tmp_file_path,
quit_after=synt_duration,
backwards=backwards
)
self._log("Synthesizing query... done")
query_file = AudioFile(tmp_file_path)
if backwards:
self._log("Reversing query")
query_file.reverse()
self._log("Extracting MFCCs for query...")
query_file.extract_mfcc(frame_rate=self.frame_rate)
query_file.clear_data()
self._log("Extracting MFCCs for query... done")
self._log("Cleaning up...")
self._cleanup(tmp_handler, tmp_file_path)
self._log("Cleaning up... done")
query_characters = result[2]
query_len = query_file.audio_length
query_mfcc = query_file.audio_mfcc
query_rate = query_characters / query_len
stretch_factor = max(1, query_rate / audio_rate)
self._log(["Audio rate: %.3f", audio_rate])
self._log(["Query rate: %.3f", query_rate])
self._log(["Stretch factor: %.3f", stretch_factor])
audio_mfcc = self.audio_file.audio_mfcc
self._log(["Actual audio has %d frames", audio_mfcc.shape[1]])
audio_mfcc_end_index = int(max_start_length * self.AUDIO_FACTOR * self.frame_rate)
self._log(["Limiting audio to first %d frames", audio_mfcc_end_index])
audio_mfcc_end_index = min(audio_mfcc_end_index, audio_mfcc.shape[1])
audio_mfcc = audio_mfcc[:, 0:audio_mfcc_end_index]
self._log(["Limited audio has %d frames", audio_mfcc.shape[1]])
l, o = audio_mfcc.shape
l, n = query_mfcc.shape
# minimum length of a matched interval in the real audio
stretched_match_minimum_length = int(n * stretch_factor)
self._log(["Audio has %d frames == %.3f seconds", o, self._i2t(o)])
self._log(["Query has %d frames == %.3f seconds", n, self._i2t(n)])
self._log(["Stretch factor: %.3f", stretch_factor])
self._log(["Required minimum length: %.3f", stretched_match_minimum_length])
self._log("Speech intervals:")
for interval in self.audio_speech:
self._log([" %d %d == %.3f %.3f", self._t2i(interval[0]), self._t2i(interval[1]), interval[0], interval[1]])
admissible_intervals = [x for x in self.audio_speech if ((x[0] >= min_start_length) and (x[0] <= max_start_length))]
self._log("AdmissibleSpeech intervals:")
for interval in admissible_intervals:
self._log([" %d %d == %.3f %.3f", self._t2i(interval[0]), self._t2i(interval[1]), interval[0], interval[1]])
candidates = []
runs_with_min_length = 0
runs_no_improvement = 0
runs_min_distortion = numpy.inf
runs_min_value = numpy.inf
for interval in admissible_intervals:
if runs_no_improvement >= self.MAX_RUNS_NO_IMPROVEMENT:
self._log(" Breaking: too many runs without improvement")
break
if runs_with_min_length >= self.MAX_RUNS_WITH_MIN_LENGTH:
self._log(" Breaking: too many runs with minimum required length")
break
start_time = interval[0]
start_index = self._t2i(start_time)
self._log(["Evaluating interval starting at %d == %.3f ", start_index, start_time])
if start_index > o:
self._log(" Breaking: start index outside audio window")
break
req_end_index = start_index + stretched_match_minimum_length
req_end_time = self._i2t(req_end_index)
if req_end_index > o:
self._log(" Breaking: not enough audio left in shifted window")
break
end_index = min(start_index + 2 * n, o)
end_time = self._i2t(end_index)
self._log([" Start %d == %.3f", start_index, start_time])
self._log([" Req end %d == %.3f", req_end_index, req_end_time])
self._log([" Eff end %d == %.3f", end_index, end_time])
audio_mfcc_sub = audio_mfcc[:, start_index:end_index]
l, m = audio_mfcc_sub.shape
self._log("Computing DTW...")
aligner = DTWAligner(None, None, frame_rate=self.frame_rate, logger=self.logger)
aligner.real_wave_full_mfcc = audio_mfcc_sub
aligner.synt_wave_full_mfcc = query_mfcc
aligner.real_wave_length = self._i2t(m)
aligner.synt_wave_length = self._i2t(n)
acm = aligner.compute_accumulated_cost_matrix()
# transpose, so we have an n x m accumulated cost matrix
acm = acm.transpose()
last_row = acm[-1, :]
self._log("Computing DTW... done")
# find the minimum, but its index must be >= stretched_match_minimum_length
candidate_argmin_index = numpy.argmin(last_row[stretched_match_minimum_length:])
candidate_length_index = stretched_match_minimum_length + candidate_argmin_index
candidate_length_time = self._i2t(candidate_length_index)
candidate_value = last_row[candidate_length_index]
candidate_end_index = start_index + candidate_length_index
candidate_end_time = self._i2t(candidate_end_index)
candidate_distortion = candidate_value / candidate_length_index
# check if the candidate has minimum length
if candidate_length_index == stretched_match_minimum_length:
runs_with_min_length += 1
else:
runs_with_min_length = 0
# check if the candidate improved the global minimum value
if metric == SDMetric.VALUE:
if candidate_value < runs_min_value:
runs_min_value = candidate_value
runs_no_improvement = 0
else:
runs_no_improvement += 1
if metric == SDMetric.DISTORTION:
if candidate_distortion < runs_min_distortion:
runs_min_distortion = candidate_distortion
runs_no_improvement = 0
else:
runs_no_improvement += 1
# append to the list of candidates
self._log([" Interval start: %d == %.6f", start_index, start_time])
self._log([" Interval end: %d == %.6f", end_index, end_time])
self._log([" Candidate start: %d == %.6f", start_index, start_time])
self._log([" Candidate end: %d == %.6f", candidate_end_index, candidate_end_time])
self._log([" Candidate length: %d == %.6f", candidate_length_index, candidate_length_time])
self._log([" Candidate value: %.6f", candidate_value])
self._log([" Candidate distortion: %.6f", candidate_distortion])
candidates.append({
"start_index": start_index,
"length": candidate_length_index,
"value": candidate_value,
"distortion": candidate_distortion
})
# select best candidate and return its start time
# if we have no best candidate, return 0.0
best_candidate = self._select_best_candidate(candidates, metric)
if best_candidate is None:
return 0.0
sd_time = self._i2t(max(best_candidate["start_index"], 0))
self._log(["Returning time %.3f", sd_time])
return sd_time
def test_compute_acm_synt_mfcc(self):
af = AudioFileMFCC(self.AUDIO_FILE)
aligner = DTWAligner(synt_wave_mfcc=af)
with self.assertRaises(DTWAlignerNotInitialized):
aligner.compute_accumulated_cost_matrix()
def test_compute_acm_real_mfcc(self):
af = AudioFileMFCC(self.AUDIO_FILE)
aligner = DTWAligner(real_wave_mfcc=af)
with self.assertRaises(DTWAlignerNotInitialized):
aligner.compute_accumulated_cost_matrix()
def test_compute_path_synt_path(self):
aligner = DTWAligner(synt_wave_path=self.AUDIO_FILE)
with self.assertRaises(DTWAlignerNotInitialized):
aligner.compute_path()
