video-libs / opencv /sources /samples /dnn /speech_recognition.py

ffmpeg (v6.0/v7.x), gensim, numpy, opencv

be94e5d verified 10 months ago

23.8 kB

	import numpy as np
	import cv2 as cv
	import argparse
	import os

	'''
	You can download the converted onnx model from https://drive.google.com/drive/folders/1wLtxyao4ItAg8tt4Sb63zt6qXzhcQoR6?usp=sharing
	or convert the model yourself.

	You can get the original pre-trained Jasper model from NVIDIA : https://ngc.nvidia.com/catalog/models/nvidia:jasper_pyt_onnx_fp16_amp/files
	Download and unzip : `$ wget --content-disposition https://api.ngc.nvidia.com/v2/models/nvidia/jasper_pyt_onnx_fp16_amp/versions/20.10.0/zip -O jasper_pyt_onnx_fp16_amp_20.10.0.zip && unzip -o ./jasper_pyt_onnx_fp16_amp_20.10.0.zip && unzip -o ./jasper_pyt_onnx_fp16_amp.zip`

	you can get the script to convert the model here : https://gist.github.com/spazewalker/507f1529e19aea7e8417f6e935851a01

	You can convert the model using the following steps:
	1. Import onnx and load the original model
	```
	import onnx
	model = onnx.load("./jasper-onnx/1/model.onnx")
	```

	3. Change data type of input layer
	```
	inp = model.graph.input[0]
	model.graph.input.remove(inp)
	inp.type.tensor_type.elem_type = 1
	model.graph.input.insert(0,inp)
	```

	4. Change the data type of output layer
	```
	out = model.graph.output[0]
	model.graph.output.remove(out)
	out.type.tensor_type.elem_type = 1
	model.graph.output.insert(0,out)
	```

	5. Change the data type of every initializer and cast it's values from FP16 to FP32
	```
	for i,init in enumerate(model.graph.initializer):
	model.graph.initializer.remove(init)
	init.data_type = 1
	init.raw_data = np.frombuffer(init.raw_data, count=np.product(init.dims), dtype=np.float16).astype(np.float32).tobytes()
	model.graph.initializer.insert(i,init)
	```

	6. Add an additional reshape node to handle the inconsistent input from python and c++ of openCV.
	see https://github.com/opencv/opencv/issues/19091
	Make & insert a new node with 'Reshape' operation & required initializer
	```
	tensor = numpy_helper.from_array(np.array([0,64,-1]),name='shape_reshape')
	model.graph.initializer.insert(0,tensor)
	node = onnx.helper.make_node(op_type='Reshape',inputs=['input__0','shape_reshape'], outputs=['input_reshaped'], name='reshape__0')
	model.graph.node.insert(0,node)
	model.graph.node[1].input[0] = 'input_reshaped'
	```

	7. Finally save the model
	```
	with open('jasper_dynamic_input_float.onnx','wb') as f:
	onnx.save_model(model,f)
	```

	Original Repo : https://github.com/NVIDIA/DeepLearningExamples/tree/master/PyTorch/SpeechRecognition/Jasper
	'''

	class FilterbankFeatures:
	def __init__(self,
	sample_rate=16000, window_size=0.02, window_stride=0.01,
	n_fft=512, preemph=0.97, n_filt=64, lowfreq=0,
	highfreq=None, log=True, dither=1e-5):
	'''
	Initializes pre-processing class. Default values are the values used by the Jasper
	architecture for pre-processing. For more details, refer to the paper here:
	https://arxiv.org/abs/1904.03288
	'''
	self.win_length = int(sample_rate * window_size) # frame size
	self.hop_length = int(sample_rate * window_stride) # stride
	self.n_fft = n_fft or 2 ** np.ceil(np.log2(self.win_length))
	self.log = log
	self.dither = dither
	self.n_filt = n_filt
	self.preemph = preemph
	highfreq = highfreq or sample_rate / 2
	self.window_tensor = np.hanning(self.win_length)

	self.filterbanks = self.mel(sample_rate, self.n_fft, n_mels=n_filt, fmin=lowfreq, fmax=highfreq)
	self.filterbanks.dtype=np.float32
	self.filterbanks = np.expand_dims(self.filterbanks,0)

	def normalize_batch(self, x, seq_len):
	'''
	Normalizes the features.
	'''
	x_mean = np.zeros((seq_len.shape[0], x.shape[1]), dtype=x.dtype)
	x_std = np.zeros((seq_len.shape[0], x.shape[1]), dtype=x.dtype)
	for i in range(x.shape[0]):
	x_mean[i, :] = np.mean(x[i, :, :seq_len[i]],axis=1)
	x_std[i, :] = np.std(x[i, :, :seq_len[i]],axis=1)
	# make sure x_std is not zero
	x_std += 1e-10
	return (x - np.expand_dims(x_mean,2)) / np.expand_dims(x_std,2)

	def calculate_features(self, x, seq_len):
	'''
	Calculates filterbank features.
	args:
	x : mono channel audio
	seq_len : length of the audio sample
	returns:
	x : filterbank features
	'''
	dtype = x.dtype

	seq_len = np.ceil(seq_len / self.hop_length)
	seq_len = np.array(seq_len,dtype=np.int32)

	# dither
	if self.dither > 0:
	x += self.dither * np.random.randn(*x.shape)

	# do preemphasis
	if self.preemph is not None:
	x = np.concatenate(
	(np.expand_dims(x[0],-1), x[1:] - self.preemph * x[:-1]), axis=0)

	# Short Time Fourier Transform
	x = self.stft(x, n_fft=self.n_fft, hop_length=self.hop_length,
	win_length=self.win_length,
	fft_window=self.window_tensor)

	# get power spectrum
	x = (x**2).sum(-1)

	# dot with filterbank energies
	x = np.matmul(np.array(self.filterbanks,dtype=x.dtype), x)

	# log features if required
	if self.log:
	x = np.log(x + 1e-20)

	# normalize if required
	x = self.normalize_batch(x, seq_len).astype(dtype)
	return x

	# Mel Frequency calculation
	def hz_to_mel(self, frequencies):
	'''
	Converts frequencies from hz to mel scale. Input can be a number or a vector.
	'''
	frequencies = np.asanyarray(frequencies)

	f_min = 0.0
	f_sp = 200.0 / 3

	mels = (frequencies - f_min) / f_sp

	# Fill in the log-scale part
	min_log_hz = 1000.0 # beginning of log region (Hz)
	min_log_mel = (min_log_hz - f_min) / f_sp # same (Mels)
	logstep = np.log(6.4) / 27.0 # step size for log region

	if frequencies.ndim:
	# If we have array data, vectorize
	log_t = frequencies >= min_log_hz
	mels[log_t] = min_log_mel + np.log(frequencies[log_t] / min_log_hz) / logstep
	elif frequencies >= min_log_hz:
	# If we have scalar data, directly
	mels = min_log_mel + np.log(frequencies / min_log_hz) / logstep
	return mels

	def mel_to_hz(self, mels):
	'''
	Converts frequencies from mel to hz scale. Input can be a number or a vector.
	'''
	mels = np.asanyarray(mels)

	# Fill in the linear scale
	f_min = 0.0
	f_sp = 200.0 / 3
	freqs = f_min + f_sp * mels

	# And now the nonlinear scale
	min_log_hz = 1000.0 # beginning of log region (Hz)
	min_log_mel = (min_log_hz - f_min) / f_sp # same (Mels)
	logstep = np.log(6.4) / 27.0 # step size for log region

	if mels.ndim:
	# If we have vector data, vectorize
	log_t = mels >= min_log_mel
	freqs[log_t] = min_log_hz * np.exp(logstep * (mels[log_t] - min_log_mel))
	elif mels >= min_log_mel:
	# If we have scalar data, check directly
	freqs = min_log_hz * np.exp(logstep * (mels - min_log_mel))

	return freqs

	def mel_frequencies(self, n_mels=128, fmin=0.0, fmax=11025.0):
	'''
	Calculates n mel frequencies between 2 frequencies
	args:
	n_mels : number of bands
	fmin : min frequency
	fmax : max frequency
	returns:
	mels : vector of mel frequencies
	'''
	# 'Center freqs' of mel bands - uniformly spaced between limits
	min_mel = self.hz_to_mel(fmin)
	max_mel = self.hz_to_mel(fmax)

	mels = np.linspace(min_mel, max_mel, n_mels)

	return self.mel_to_hz(mels)

	def mel(self, sr, n_fft, n_mels=128, fmin=0.0, fmax=None, dtype=np.float32):
	'''
	Generates mel filterbank
	args:
	sr : Sampling rate
	n_fft : number of FFT components
	n_mels : number of Mel bands to generate
	fmin : lowest frequency (in Hz)
	fmax : highest frequency (in Hz). sr/2.0 if None
	dtype : the data type of the output basis.
	returns:
	mels : Mel transform matrix
	'''
	# default Max freq = half of sampling rate
	if fmax is None:
	fmax = float(sr) / 2

	# Initialize the weights
	n_mels = int(n_mels)
	weights = np.zeros((n_mels, int(1 + n_fft // 2)), dtype=dtype)

	# Center freqs of each FFT bin
	fftfreqs = np.linspace(0, float(sr) / 2, int(1 + n_fft // 2), endpoint=True)

	# 'Center freqs' of mel bands - uniformly spaced between limits
	mel_f = self.mel_frequencies(n_mels + 2, fmin=fmin, fmax=fmax)

	fdiff = np.diff(mel_f)
	ramps = np.subtract.outer(mel_f, fftfreqs)

	for i in range(n_mels):
	# lower and upper slopes for all bins
	lower = -ramps[i] / fdiff[i]
	upper = ramps[i + 2] / fdiff[i + 1]

	# .. then intersect them with each other and zero
	weights[i] = np.maximum(0, np.minimum(lower, upper))

	# Using Slaney-style mel which is scaled to be approx constant energy per channel
	enorm = 2.0 / (mel_f[2 : n_mels + 2] - mel_f[:n_mels])
	weights *= enorm[:, np.newaxis]
	return weights

	# STFT preparation
	def pad_window_center(self, data, size, axis=-1, **kwargs):
	'''
	Centers the data and pads.
	args:
	data : Vector to be padded and centered
	size : Length to pad data
	axis : Axis along which to pad and center the data
	kwargs : arguments passed to np.pad
	return : centered and padded data
	'''
	kwargs.setdefault("mode", "constant")
	n = data.shape[axis]
	lpad = int((size - n) // 2)
	lengths = [(0, 0)] * data.ndim
	lengths[axis] = (lpad, int(size - n - lpad))
	if lpad < 0:
	raise Exception(
	("Target size ({:d}) must be at least input size ({:d})").format(size, n)
	)
	return np.pad(data, lengths, **kwargs)

	def frame(self, x, frame_length, hop_length):
	'''
	Slices a data array into (overlapping) frames.
	args:
	x : array to frame
	frame_length : length of frame
	hop_length : Number of steps to advance between frames
	return : A framed view of `x`
	'''
	if x.shape[-1] < frame_length:
	raise Exception(
	"Input is too short (n={:d})"
	" for frame_length={:d}".format(x.shape[-1], frame_length)
	)
	x = np.asfortranarray(x)
	n_frames = 1 + (x.shape[-1] - frame_length) // hop_length
	strides = np.asarray(x.strides)
	new_stride = np.prod(strides[strides > 0] // x.itemsize) * x.itemsize
	shape = list(x.shape)[:-1] + [frame_length, n_frames]
	strides = list(strides) + [hop_length * new_stride]
	return np.lib.stride_tricks.as_strided(x, shape=shape, strides=strides)

	def dtype_r2c(self, d, default=np.complex64):
	'''
	Find the complex numpy dtype corresponding to a real dtype.
	args:
	d : The real-valued dtype to convert to complex.
	default : The default complex target type, if `d` does not match a known dtype
	return : The complex dtype
	'''
	mapping = {
	np.dtype(np.float32): np.complex64,
	np.dtype(np.float64): np.complex128,
	}
	dt = np.dtype(d)
	if dt.kind == "c":
	return dt
	return np.dtype(mapping.get(dt, default))

	def stft(self, y, n_fft, hop_length=None, win_length=None, fft_window=None, pad_mode='reflect', return_complex=False):
	'''
	Short Time Fourier Transform. The STFT represents a signal in the time-frequency
	domain by computing discrete Fourier transforms (DFT) over short overlapping windows.
	args:
	y : input signal
	n_fft : length of the windowed signal after padding with zeros.
	hop_length : number of audio samples between adjacent STFT columns.
	win_length : Each frame of audio is windowed by window of length win_length and
	then padded with zeros to match n_fft
	fft_window : a vector or array of length `n_fft` having values computed by a
	window function
	pad_mode : mode while padding the signal
	return_complex : returns array with complex data type if `True`
	return : Matrix of short-term Fourier transform coefficients.
	'''
	if win_length is None:
	win_length = n_fft
	if hop_length is None:
	hop_length = int(win_length // 4)
	if y.ndim!=1:
	raise Exception(f'Invalid input shape. Only Mono Channeled audio supported. Input must have shape (Audio,). Got {y.shape}')

	# Pad the window out to n_fft size
	fft_window = self.pad_window_center(fft_window, n_fft)

	# Reshape so that the window can be broadcast
	fft_window = fft_window.reshape((-1, 1))

	# Pad the time series so that frames are centered
	y = np.pad(y, int(n_fft // 2), mode=pad_mode)

	# Window the time series.
	y_frames = self.frame(y, frame_length=n_fft, hop_length=hop_length)

	# Convert data type to complex
	dtype = self.dtype_r2c(y.dtype)

	# Pre-allocate the STFT matrix
	stft_matrix = np.empty( (int(1 + n_fft // 2), y_frames.shape[-1]), dtype=dtype, order="F")

	stft_matrix = np.fft.rfft( fft_window * y_frames, axis=0)
	return stft_matrix if return_complex==True else np.stack((stft_matrix.real,stft_matrix.imag),axis=-1)

	class Decoder:
	'''
	Used for decoding the output of jasper model.
	'''
	def __init__(self):
	labels=[' ','a','b','c','d','e','f','g','h','i','j','k','l','m','n','o','p','q','r','s','t','u','v','w','x','y','z',"'"]
	self.labels_map = {i: label for i,label in enumerate(labels)}
	self.blank_id = 28

	def decode(self,x):
	"""
	Takes output of Jasper model and performs ctc decoding algorithm to
	remove duplicates and special symbol. Returns prediction
	"""
	x = np.argmax(x,axis=-1)
	hypotheses = []
	prediction = x.tolist()
	# CTC decoding procedure
	decoded_prediction = []
	previous = self.blank_id
	for p in prediction:
	if (p != previous or previous == self.blank_id) and p != self.blank_id:
	decoded_prediction.append(p)
	previous = p
	hypothesis = ''.join([self.labels_map[c] for c in decoded_prediction])
	hypotheses.append(hypothesis)
	return hypotheses

	def predict(features, net, decoder):
	'''
	Passes the features through the Jasper model and decodes the output to english transcripts.
	args:
	features : input features, calculated using FilterbankFeatures class
	net : Jasper model dnn.net object
	decoder : Decoder object
	return : Predicted text
	'''
	# make prediction
	net.setInput(features)
	output = net.forward()

	# decode output to transcript
	prediction = decoder.decode(output.squeeze(0))
	return prediction[0]

	def readAudioFile(file, audioStream):
	cap = cv.VideoCapture(file)
	samplingRate = 16000
	params = np.asarray([cv.CAP_PROP_AUDIO_STREAM, audioStream,
	cv.CAP_PROP_VIDEO_STREAM, -1,
	cv.CAP_PROP_AUDIO_DATA_DEPTH, cv.CV_32F,
	cv.CAP_PROP_AUDIO_SAMPLES_PER_SECOND, samplingRate
	])
	cap.open(file, cv.CAP_ANY, params)
	if cap.isOpened() is False:
	print("Error : Can't read audio file:", file, "with audioStream = ", audioStream)
	return
	audioBaseIndex = int (cap.get(cv.CAP_PROP_AUDIO_BASE_INDEX))
	inputAudio = []
	while(1):
	if (cap.grab()):
	frame = np.asarray([])
	frame = cap.retrieve(frame, audioBaseIndex)
	for i in range(len(frame[1][0])):
	inputAudio.append(frame[1][0][i])
	else:
	break
	inputAudio = np.asarray(inputAudio, dtype=np.float64)
	return inputAudio, samplingRate

	def readAudioMicrophone(microTime):
	cap = cv.VideoCapture()
	samplingRate = 16000
	params = np.asarray([cv.CAP_PROP_AUDIO_STREAM, 0,
	cv.CAP_PROP_VIDEO_STREAM, -1,
	cv.CAP_PROP_AUDIO_DATA_DEPTH, cv.CV_32F,
	cv.CAP_PROP_AUDIO_SAMPLES_PER_SECOND, samplingRate
	])
	cap.open(0, cv.CAP_ANY, params)
	if cap.isOpened() is False:
	print("Error: Can't open microphone")
	print("Error: problems with audio reading, check input arguments")
	return
	audioBaseIndex = int(cap.get(cv.CAP_PROP_AUDIO_BASE_INDEX))
	cvTickFreq = cv.getTickFrequency()
	sysTimeCurr = cv.getTickCount()
	sysTimePrev = sysTimeCurr
	inputAudio = []
	while ((sysTimeCurr - sysTimePrev) / cvTickFreq < microTime):
	if (cap.grab()):
	frame = np.asarray([])
	frame = cap.retrieve(frame, audioBaseIndex)
	for i in range(len(frame[1][0])):
	inputAudio.append(frame[1][0][i])
	sysTimeCurr = cv.getTickCount()
	else:
	print("Error: Grab error")
	break
	inputAudio = np.asarray(inputAudio, dtype=np.float64)
	print("Number of samples: ", len(inputAudio))
	return inputAudio, samplingRate

	if __name__ == '__main__':

	# Computation backends supported by layers
	backends = (cv.dnn.DNN_BACKEND_DEFAULT, cv.dnn.DNN_BACKEND_INFERENCE_ENGINE, cv.dnn.DNN_BACKEND_OPENCV)
	# Target Devices for computation
	targets = (cv.dnn.DNN_TARGET_CPU, cv.dnn.DNN_TARGET_OPENCL, cv.dnn.DNN_TARGET_OPENCL_FP16)

	parser = argparse.ArgumentParser(description='This script runs Jasper Speech recognition model',
	formatter_class=argparse.ArgumentDefaultsHelpFormatter)
	parser.add_argument('--input_type', type=str, required=True, help='file or microphone')
	parser.add_argument('--micro_time', type=int, default=15, help='Duration of microphone work in seconds. Must be more than 6 sec')
	parser.add_argument('--input_audio', type=str, help='Path to input audio file. OR Path to a txt file with relative path to multiple audio files in different lines')
	parser.add_argument('--audio_stream', type=int, default=0, help='CAP_PROP_AUDIO_STREAM value')
	parser.add_argument('--show_spectrogram', action='store_true', help='Whether to show a spectrogram of the input audio.')
	parser.add_argument('--model', type=str, default='jasper.onnx', help='Path to the onnx file of Jasper. default="jasper.onnx"')
	parser.add_argument('--output', type=str, help='Path to file where recognized audio transcript must be saved. Leave this to print on console.')
	parser.add_argument('--backend', choices=backends, default=cv.dnn.DNN_BACKEND_DEFAULT, type=int,
	help='Select a computation backend: '
	"%d: automatically (by default) "
	"%d: OpenVINO Inference Engine "
	"%d: OpenCV Implementation " % backends)
	parser.add_argument('--target', choices=targets, default=cv.dnn.DNN_TARGET_CPU, type=int,
	help='Select a target device: '
	"%d: CPU target (by default) "
	"%d: OpenCL "
	"%d: OpenCL FP16 " % targets)

	args, _ = parser.parse_known_args()

	if args.input_audio and not os.path.isfile(args.input_audio):
	raise OSError("Input audio file does not exist")
	if not os.path.isfile(args.model):
	raise OSError("Jasper model file does not exist")

	features = []
	if args.input_type == "file":
	if args.input_audio.endswith('.txt'):
	with open(args.input_audio) as f:
	content = f.readlines()
	content = [x.strip() for x in content]
	audio_file_paths = content
	for audio_file_path in audio_file_paths:
	if not os.path.isfile(audio_file_path):
	raise OSError("Audio file({audio_file_path}) does not exist")
	else:
	audio_file_paths = [args.input_audio]
	audio_file_paths = [os.path.abspath(x) for x in audio_file_paths]

	# Read audio Files
	for audio_file_path in audio_file_paths:
	audio = readAudioFile(audio_file_path, args.audio_stream)
	if audio is None:
	raise Exception(f"Can't read {args.input_audio}. Try a different format")
	features.append(audio[0])
	elif args.input_type == "microphone":
	# Read audio from microphone
	audio = readAudioMicrophone(args.micro_time)
	if audio is None:
	raise Exception(f"Can't open microphone. Try a different format")
	features.append(audio[0])
	else:
	raise Exception(f"input_type {args.input_type} doesn't exist. Please enter 'file' or 'microphone'")

	# Get Filterbank Features
	feature_extractor = FilterbankFeatures()
	for i in range(len(features)):
	X = features[i]
	seq_len = np.array([X.shape[0]], dtype=np.int32)
	features[i] = feature_extractor.calculate_features(x=X, seq_len=seq_len)

	# Load Network
	net = cv.dnn.readNetFromONNX(args.model)
	net.setPreferableBackend(args.backend)
	net.setPreferableTarget(args.target)

	# Show spectogram if required
	if args.show_spectrogram and not args.input_audio.endswith('.txt'):
	img = cv.normalize(src=features[0][0], dst=None, alpha=0, beta=255, norm_type=cv.NORM_MINMAX, dtype=cv.CV_8U)
	img = cv.applyColorMap(img, cv.COLORMAP_JET)
	cv.imshow('spectogram', img)
	cv.waitKey(0)

	# Initialize decoder
	decoder = Decoder()

	# Make prediction
	prediction = []
	print("Predicting...")
	for feature in features:
	print(f"\rAudio file {len(prediction)+1}/{len(features)}", end='')
	prediction.append(predict(feature, net, decoder))
	print("")

	# save transcript if required
	if args.output:
	with open(args.output,'w') as f:
	for pred in prediction:
	f.write(pred+'\n')
	print("Transcript was written to {}".format(args.output))
	else:
	print(prediction)
	cv.destroyAllWindows()