#!/usr/bin/env python3 # Copyright 2018 Mitsubishi Electric Research Labs (Takaaki Hori) # Apache 2.0 (http://www.apache.org/licenses/LICENSE-2.0) import numpy as np import six import torch class CTCPrefixScoreTH(object): """Batch processing of CTCPrefixScore which is based on Algorithm 2 in WATANABE et al. "HYBRID CTC/ATTENTION ARCHITECTURE FOR END-TO-END SPEECH RECOGNITION," but extended to efficiently compute the label probablities for multiple hypotheses simultaneously See also Seki et al. "Vectorized Beam Search for CTC-Attention-Based Speech Recognition," In INTERSPEECH (pp. 3825-3829), 2019. """ def __init__(self, x, xlens, blank, eos, margin=0): """Construct CTC prefix scorer :param torch.Tensor x: input label posterior sequences (B, T, O) :param torch.Tensor xlens: input lengths (B,) :param int blank: blank label id :param int eos: end-of-sequence id :param int margin: margin parameter for windowing (0 means no windowing) """ # In the comment lines, # we assume T: input_length, B: batch size, W: beam width, O: output dim. self.logzero = -10000000000.0 self.blank = blank self.eos = eos self.batch = x.size(0) self.input_length = x.size(1) self.odim = x.size(2) self.dtype = x.dtype self.device = ( torch.device("cuda:%d" % x.get_device()) if x.is_cuda else torch.device("cpu") ) # Pad the rest of posteriors in the batch # TODO(takaaki-hori): need a better way without for-loops for i, l in enumerate(xlens): if l < self.input_length: x[i, l:, :] = self.logzero x[i, l:, blank] = 0 # Reshape input x xn = x.transpose(0, 1) # (B, T, O) -> (T, B, O) xb = xn[:, :, self.blank].unsqueeze(2).expand(-1, -1, self.odim) self.x = torch.stack([xn, xb]) # (2, T, B, O) self.end_frames = torch.as_tensor(xlens) - 1 # Setup CTC windowing self.margin = margin if margin > 0: self.frame_ids = torch.arange( self.input_length, dtype=self.dtype, device=self.device ) # Base indices for index conversion self.idx_bh = None self.idx_b = torch.arange(self.batch, device=self.device) self.idx_bo = (self.idx_b * self.odim).unsqueeze(1) def __call__(self, y, state, scoring_ids=None, att_w=None): """Compute CTC prefix scores for next labels :param list y: prefix label sequences :param tuple state: previous CTC state :param torch.Tensor pre_scores: scores for pre-selection of hypotheses (BW, O) :param torch.Tensor att_w: attention weights to decide CTC window :return new_state, ctc_local_scores (BW, O) """ output_length = len(y[0]) - 1 # ignore sos last_ids = [yi[-1] for yi in y] # last output label ids n_bh = len(last_ids) # batch * hyps n_hyps = n_bh // self.batch # assuming each utterance has the same # of hyps self.scoring_num = scoring_ids.size(-1) if scoring_ids is not None else 0 # prepare state info if state is None: r_prev = torch.full( (self.input_length, 2, self.batch, n_hyps), self.logzero, dtype=self.dtype, device=self.device, ) r_prev[:, 1] = torch.cumsum(self.x[0, :, :, self.blank], 0).unsqueeze(2) r_prev = r_prev.view(-1, 2, n_bh) s_prev = 0.0 f_min_prev = 0 f_max_prev = 1 else: r_prev, s_prev, f_min_prev, f_max_prev = state # select input dimensions for scoring if self.scoring_num > 0: scoring_idmap = torch.full( (n_bh, self.odim), -1, dtype=torch.long, device=self.device ) snum = self.scoring_num if self.idx_bh is None or n_bh > len(self.idx_bh): self.idx_bh = torch.arange(n_bh, device=self.device).view(-1, 1) scoring_idmap[self.idx_bh[:n_bh], scoring_ids] = torch.arange( snum, device=self.device ) scoring_idx = ( scoring_ids + self.idx_bo.repeat(1, n_hyps).view(-1, 1) ).view(-1) x_ = torch.index_select( self.x.view(2, -1, self.batch * self.odim), 2, scoring_idx ).view(2, -1, n_bh, snum) else: scoring_ids = None scoring_idmap = None snum = self.odim x_ = self.x.unsqueeze(3).repeat(1, 1, 1, n_hyps, 1).view(2, -1, n_bh, snum) # new CTC forward probs are prepared as a (T x 2 x BW x S) tensor # that corresponds to r_t^n(h) and r_t^b(h) in a batch. r = torch.full( (self.input_length, 2, n_bh, snum), self.logzero, dtype=self.dtype, device=self.device, ) if output_length == 0: r[0, 0] = x_[0, 0] r_sum = torch.logsumexp(r_prev, 1) log_phi = r_sum.unsqueeze(2).repeat(1, 1, snum) if scoring_ids is not None: for idx in range(n_bh): pos = scoring_idmap[idx, last_ids[idx]] if pos >= 0: log_phi[:, idx, pos] = r_prev[:, 1, idx] else: for idx in range(n_bh): log_phi[:, idx, last_ids[idx]] = r_prev[:, 1, idx] # decide start and end frames based on attention weights if att_w is not None and self.margin > 0: f_arg = torch.matmul(att_w, self.frame_ids) f_min = max(int(f_arg.min().cpu()), f_min_prev) f_max = max(int(f_arg.max().cpu()), f_max_prev) start = min(f_max_prev, max(f_min - self.margin, output_length, 1)) end = min(f_max + self.margin, self.input_length) else: f_min = f_max = 0 start = max(output_length, 1) end = self.input_length # compute forward probabilities log(r_t^n(h)) and log(r_t^b(h)) for t in range(start, end): rp = r[t - 1] rr = torch.stack([rp[0], log_phi[t - 1], rp[0], rp[1]]).view( 2, 2, n_bh, snum ) r[t] = torch.logsumexp(rr, 1) + x_[:, t] # compute log prefix probabilities log(psi) log_phi_x = torch.cat((log_phi[0].unsqueeze(0), log_phi[:-1]), dim=0) + x_[0] if scoring_ids is not None: log_psi = torch.full( (n_bh, self.odim), self.logzero, dtype=self.dtype, device=self.device ) log_psi_ = torch.logsumexp( torch.cat((log_phi_x[start:end], r[start - 1, 0].unsqueeze(0)), dim=0), dim=0, ) for si in range(n_bh): log_psi[si, scoring_ids[si]] = log_psi_[si] else: log_psi = torch.logsumexp( torch.cat((log_phi_x[start:end], r[start - 1, 0].unsqueeze(0)), dim=0), dim=0, ) for si in range(n_bh): log_psi[si, self.eos] = r_sum[self.end_frames[si // n_hyps], si] # exclude blank probs log_psi[:, self.blank] = self.logzero return (log_psi - s_prev), (r, log_psi, f_min, f_max, scoring_idmap) def index_select_state(self, state, best_ids): """Select CTC states according to best ids :param state : CTC state :param best_ids : index numbers selected by beam pruning (B, W) :return selected_state """ r, s, f_min, f_max, scoring_idmap = state # convert ids to BHO space n_bh = len(s) n_hyps = n_bh // self.batch vidx = (best_ids + (self.idx_b * (n_hyps * self.odim)).view(-1, 1)).view(-1) # select hypothesis scores s_new = torch.index_select(s.view(-1), 0, vidx) s_new = s_new.view(-1, 1).repeat(1, self.odim).view(n_bh, self.odim) # convert ids to BHS space (S: scoring_num) if scoring_idmap is not None: snum = self.scoring_num hyp_idx = (best_ids // self.odim + (self.idx_b * n_hyps).view(-1, 1)).view( -1 ) label_ids = torch.fmod(best_ids, self.odim).view(-1) score_idx = scoring_idmap[hyp_idx, label_ids] score_idx[score_idx == -1] = 0 vidx = score_idx + hyp_idx * snum else: snum = self.odim # select forward probabilities r_new = torch.index_select(r.view(-1, 2, n_bh * snum), 2, vidx).view( -1, 2, n_bh ) return r_new, s_new, f_min, f_max def extend_prob(self, x): """Extend CTC prob. :param torch.Tensor x: input label posterior sequences (B, T, O) """ if self.x.shape[1] < x.shape[1]: # self.x (2,T,B,O); x (B,T,O) # Pad the rest of posteriors in the batch # TODO(takaaki-hori): need a better way without for-loops xlens = [x.size(1)] for i, l in enumerate(xlens): if l < self.input_length: x[i, l:, :] = self.logzero x[i, l:, self.blank] = 0 tmp_x = self.x xn = x.transpose(0, 1) # (B, T, O) -> (T, B, O) xb = xn[:, :, self.blank].unsqueeze(2).expand(-1, -1, self.odim) self.x = torch.stack([xn, xb]) # (2, T, B, O) self.x[:, : tmp_x.shape[1], :, :] = tmp_x self.input_length = x.size(1) self.end_frames = torch.as_tensor(xlens) - 1 def extend_state(self, state): """Compute CTC prefix state. :param state : CTC state :return ctc_state """ if state is None: # nothing to do return state else: r_prev, s_prev, f_min_prev, f_max_prev = state r_prev_new = torch.full( (self.input_length, 2), self.logzero, dtype=self.dtype, device=self.device, ) start = max(r_prev.shape[0], 1) r_prev_new[0:start] = r_prev for t in six.moves.range(start, self.input_length): r_prev_new[t, 1] = r_prev_new[t - 1, 1] + self.x[0, t, :, self.blank] return (r_prev_new, s_prev, f_min_prev, f_max_prev) class CTCPrefixScore(object): """Compute CTC label sequence scores which is based on Algorithm 2 in WATANABE et al. "HYBRID CTC/ATTENTION ARCHITECTURE FOR END-TO-END SPEECH RECOGNITION," but extended to efficiently compute the probablities of multiple labels simultaneously """ def __init__(self, x, blank, eos, xp): self.xp = xp self.logzero = -10000000000.0 self.blank = blank self.eos = eos self.input_length = len(x) self.x = x def initial_state(self): """Obtain an initial CTC state :return: CTC state """ # initial CTC state is made of a frame x 2 tensor that corresponds to # r_t^n() and r_t^b(), where 0 and 1 of axis=1 represent # superscripts n and b (non-blank and blank), respectively. r = self.xp.full((self.input_length, 2), self.logzero, dtype=np.float32) r[0, 1] = self.x[0, self.blank] for i in six.moves.range(1, self.input_length): r[i, 1] = r[i - 1, 1] + self.x[i, self.blank] return r def __call__(self, y, cs, r_prev): """Compute CTC prefix scores for next labels :param y : prefix label sequence :param cs : array of next labels :param r_prev: previous CTC state :return ctc_scores, ctc_states """ # initialize CTC states output_length = len(y) - 1 # ignore sos # new CTC states are prepared as a frame x (n or b) x n_labels tensor # that corresponds to r_t^n(h) and r_t^b(h). r = self.xp.ndarray((self.input_length, 2, len(cs)), dtype=np.float32) xs = self.x[:, cs] if output_length == 0: r[0, 0] = xs[0] r[0, 1] = self.logzero else: r[output_length - 1] = self.logzero # prepare forward probabilities for the last label r_sum = self.xp.logaddexp( r_prev[:, 0], r_prev[:, 1] ) # log(r_t^n(g) + r_t^b(g)) last = y[-1] if output_length > 0 and last in cs: log_phi = self.xp.ndarray((self.input_length, len(cs)), dtype=np.float32) for i in six.moves.range(len(cs)): log_phi[:, i] = r_sum if cs[i] != last else r_prev[:, 1] else: log_phi = r_sum # compute forward probabilities log(r_t^n(h)), log(r_t^b(h)), # and log prefix probabilities log(psi) start = max(output_length, 1) log_psi = r[start - 1, 0] for t in six.moves.range(start, self.input_length): r[t, 0] = self.xp.logaddexp(r[t - 1, 0], log_phi[t - 1]) + xs[t] r[t, 1] = ( self.xp.logaddexp(r[t - 1, 0], r[t - 1, 1]) + self.x[t, self.blank] ) log_psi = self.xp.logaddexp(log_psi, log_phi[t - 1] + xs[t]) # get P(...eos|X) that ends with the prefix itself eos_pos = self.xp.where(cs == self.eos)[0] if len(eos_pos) > 0: log_psi[eos_pos] = r_sum[-1] # log(r_T^n(g) + r_T^b(g)) # exclude blank probs blank_pos = self.xp.where(cs == self.blank)[0] if len(blank_pos) > 0: log_psi[blank_pos] = self.logzero # return the log prefix probability and CTC states, where the label axis # of the CTC states is moved to the first axis to slice it easily return log_psi, self.xp.rollaxis(r, 2)