def encoder(source, params): mask = dtype.tf_to_float(tf.cast(source, tf.bool)) hidden_size = params.hidden_size initializer = tf.random_normal_initializer(0.0, hidden_size**-0.5) source, mask = util.remove_invalid_seq(source, mask) embed_name = "embedding" if params.shared_source_target_embedding \ else "src_embedding" src_emb = tf.get_variable(embed_name, [params.src_vocab.size(), params.embed_size], initializer=initializer) src_bias = tf.get_variable("bias", [params.embed_size]) inputs = tf.gather(src_emb, source) * (hidden_size**0.5) inputs = tf.nn.bias_add(inputs, src_bias) inputs = func.add_timing_signal(inputs) inputs = util.valid_apply_dropout(inputs, params.dropout) with tf.variable_scope("encoder"): x = inputs for layer in range(params.num_encoder_layer): if params.deep_transformer_init: layer_initializer = tf.variance_scaling_initializer( params.initializer_gain * (layer + 1)**-0.5, mode="fan_avg", distribution="uniform") else: layer_initializer = None with tf.variable_scope("layer_{}".format(layer), initializer=layer_initializer): with tf.variable_scope("self_attention"): y = func.dot_attention(x, None, func.attention_bias( mask, "masking"), hidden_size, num_heads=params.num_heads, dropout=params.attention_dropout) y = y['output'] x = func.residual_fn(x, y, dropout=params.residual_dropout) x = func.layer_norm(x) with tf.variable_scope("feed_forward"): y = func.ffn_layer( x, params.filter_size, hidden_size, dropout=params.relu_dropout, ) x = func.residual_fn(x, y, dropout=params.residual_dropout) x = func.layer_norm(x) source_encodes = x x_shp = util.shape_list(x) return { "encodes": source_encodes, "decoder_initializer": { "layer_{}".format(l): { # plan aan "aan": dtype.tf_to_float(tf.zeros([x_shp[0], 1, hidden_size])), } for l in range(params.num_decoder_layer) }, "mask": mask }
def decoder(target, state, params): mask = dtype.tf_to_float(tf.cast(target, tf.bool)) hidden_size = params.hidden_size initializer = tf.random_normal_initializer(0.0, hidden_size**-0.5) is_training = ('decoder' not in state) if is_training: target, mask = util.remove_invalid_seq(target, mask) embed_name = "embedding" if params.shared_source_target_embedding \ else "tgt_embedding" tgt_emb = tf.get_variable(embed_name, [params.tgt_vocab.size(), params.embed_size], initializer=initializer) tgt_bias = tf.get_variable("bias", [params.embed_size]) inputs = tf.gather(tgt_emb, target) * (hidden_size**0.5) inputs = tf.nn.bias_add(inputs, tgt_bias) # shift if is_training: inputs = tf.pad(inputs, [[0, 0], [1, 0], [0, 0]]) inputs = inputs[:, :-1, :] inputs = func.add_timing_signal(inputs) else: inputs = tf.cond( tf.reduce_all(tf.equal(target, params.tgt_vocab.pad())), lambda: tf.zeros_like(inputs), lambda: inputs) mask = tf.ones_like(mask) inputs = func.add_timing_signal(inputs, time=dtype.tf_to_float(state['time'])) inputs = util.valid_apply_dropout(inputs, params.dropout) with tf.variable_scope("decoder"): x = inputs for layer in range(params.num_decoder_layer): if params.deep_transformer_init: layer_initializer = tf.variance_scaling_initializer( params.initializer_gain * (layer + 1)**-0.5, mode="fan_avg", distribution="uniform") else: layer_initializer = None with tf.variable_scope("layer_{}".format(layer), initializer=layer_initializer): with tf.variable_scope("average_attention"): x_fwds = [] for strategy in params.strategies: with tf.variable_scope(strategy): x_fwd = average_attention_strategy( strategy, x, mask, state, layer, params) x_fwds.append(x_fwd) x_fwd = tf.add_n(x_fwds) / len(x_fwds) # FFN activation if params.use_ffn: y = func.ffn_layer( x_fwd, params.filter_size, hidden_size, dropout=params.relu_dropout, ) else: y = x_fwd # Gating layer z = func.linear(tf.concat([x, y], axis=-1), hidden_size * 2, scope="z_project") i, f = tf.split(z, 2, axis=-1) y = tf.sigmoid(i) * x + tf.sigmoid(f) * y x = func.residual_fn(x, y, dropout=params.residual_dropout) x = func.layer_norm(x) with tf.variable_scope("cross_attention"): y = func.dot_attention( x, state['encodes'], func.attention_bias(state['mask'], "masking"), hidden_size, num_heads=params.num_heads, dropout=params.attention_dropout, cache=None if is_training else state['decoder']['state']['layer_{}'.format(layer)]) if not is_training: # mk, mv state['decoder']['state']['layer_{}'.format(layer)]\ .update(y['cache']) y = y['output'] x = func.residual_fn(x, y, dropout=params.residual_dropout) x = func.layer_norm(x) with tf.variable_scope("feed_forward"): y = func.ffn_layer( x, params.filter_size, hidden_size, dropout=params.relu_dropout, ) x = func.residual_fn(x, y, dropout=params.residual_dropout) x = func.layer_norm(x) feature = x if 'dev_decode' in state: feature = x[:, -1, :] embed_name = "tgt_embedding" if params.shared_target_softmax_embedding \ else "softmax_embedding" embed_name = "embedding" if params.shared_source_target_embedding \ else embed_name softmax_emb = tf.get_variable(embed_name, [params.tgt_vocab.size(), params.embed_size], initializer=initializer) feature = tf.reshape(feature, [-1, params.embed_size]) logits = tf.matmul(feature, softmax_emb, False, True) logits = tf.cast(logits, tf.float32) soft_label, normalizer = util.label_smooth(target, util.shape_list(logits)[-1], factor=params.label_smooth) centropy = tf.nn.softmax_cross_entropy_with_logits_v2(logits=logits, labels=soft_label) centropy -= normalizer centropy = tf.reshape(centropy, tf.shape(target)) mask = tf.cast(mask, tf.float32) per_sample_loss = tf.reduce_sum(centropy * mask, -1) / tf.reduce_sum( mask, -1) loss = tf.reduce_mean(per_sample_loss) # these mask tricks mainly used to deal with zero shapes, such as [0, 1] loss = tf.cond(tf.equal(tf.shape(target)[0], 0), lambda: tf.constant(0, dtype=tf.float32), lambda: loss) return loss, logits, state, per_sample_loss
def encoder(source, params): mask = tf.to_float(tf.cast(source, tf.bool)) hidden_size = params.hidden_size source, mask = util.remove_invalid_seq(source, mask) embed_name = "embedding" if params.shared_source_target_embedding \ else "src_embedding" src_emb = tf.get_variable(embed_name, [params.src_vocab.size(), params.embed_size]) src_bias = tf.get_variable("bias", [params.embed_size]) inputs = tf.gather(src_emb, source) inputs = tf.nn.bias_add(inputs, src_bias) if util.valid_dropout(params.dropout): inputs = tf.nn.dropout(inputs, 1. - params.dropout) with tf.variable_scope("encoder"): x = inputs for layer in range(params.num_encoder_layer): with tf.variable_scope("layer_{}".format(layer)): # forward rnn with tf.variable_scope('forward'): outputs = rnn.rnn(params.cell, x, hidden_size, mask=mask, ln=params.layer_norm, sm=params.swap_memory, dp=params.dropout) output_fw, state_fw = outputs[1] if layer == 0: # backward rnn with tf.variable_scope('backward'): if not params.caencoder: outputs = rnn.rnn(params.cell, tf.reverse(x, [1]), hidden_size, mask=tf.reverse(mask, [1]), ln=params.layer_norm, sm=params.swap_memory, dp=params.dropout) output_bw, state_bw = outputs[1] else: outputs = rnn.cond_rnn(params.cell, tf.reverse(x, [1]), tf.reverse(output_fw, [1]), hidden_size, mask=tf.reverse(mask, [1]), ln=params.layer_norm, sm=params.swap_memory, num_heads=params.num_heads, one2one=True) output_bw, state_bw = outputs[1] output_bw = tf.reverse(output_bw, [1]) if not params.caencoder: y = tf.concat([output_fw, output_bw], -1) z = tf.concat([state_fw, state_bw], -1) else: y = output_bw z = state_bw else: y = output_fw z = state_fw y = func.linear(y, hidden_size, ln=False, scope="ff") # short cut via residual connection if x.get_shape()[-1].value == y.get_shape()[-1].value: x = func.residual_fn(x, y, dropout=params.dropout) else: x = y if params.layer_norm: x = func.layer_norm(x, scope="ln") with tf.variable_scope("decoder_initializer"): decoder_cell = rnn.get_cell(params.cell, hidden_size, ln=params.layer_norm) return { "encodes": x, "decoder_initializer": { "layer_{}".format(l): decoder_cell.get_init_state(x=z, scope="layer_{}".format(l)) for l in range(params.num_decoder_layer) }, "mask": mask }
def decoder(target, state, params): mask = dtype.tf_to_float(tf.cast(target, tf.bool)) hidden_size = params.hidden_size initializer = tf.random_normal_initializer(0.0, hidden_size**-0.5) is_training = ('decoder' not in state) if is_training: target, mask = util.remove_invalid_seq(target, mask) embed_name = "embedding" if params.shared_source_target_embedding \ else "tgt_embedding" tgt_emb = tf.get_variable(embed_name, [params.tgt_vocab.size(), params.embed_size], initializer=initializer) tgt_bias = tf.get_variable("bias", [params.embed_size]) inputs = tf.gather(tgt_emb, target) * (hidden_size**0.5) inputs = tf.nn.bias_add(inputs, tgt_bias) # shift if is_training: inputs = tf.pad(inputs, [[0, 0], [1, 0], [0, 0]]) inputs = inputs[:, :-1, :] inputs = func.add_timing_signal(inputs) else: inputs = tf.cond( tf.reduce_all(tf.equal(target, params.tgt_vocab.pad())), lambda: tf.zeros_like(inputs), lambda: inputs) mask = tf.ones_like(mask) inputs = func.add_timing_signal(inputs, time=dtype.tf_to_float(state['time'])) inputs = util.valid_apply_dropout(inputs, params.dropout) # Applying L0Drop # -------- source_memory = state["encodes"] source_mask = state["mask"] # source_pruning: log alpha_i = x_i w^T source_pruning = func.linear(source_memory, 1, scope="source_pruning") if is_training: # training source_memory, l0_mask = l0norm.var_train( (source_memory, source_pruning)) l0_norm_loss = tf.squeeze(l0norm.l0_norm(source_pruning), -1) l0_norm_loss = tf.reduce_sum(l0_norm_loss * source_mask, -1) / tf.reduce_sum(source_mask, -1) l0_norm_loss = tf.reduce_mean(l0_norm_loss) l0_norm_loss = l0norm.l0_regularization_loss( l0_norm_loss, reg_scalar=params.l0_norm_reg_scalar, start_reg_ramp_up=params.l0_norm_start_reg_ramp_up, end_reg_ramp_up=params.l0_norm_end_reg_ramp_up, warm_up=params.l0_norm_warm_up, ) # force the model to only attend to unmasked position source_mask = dtype.tf_to_float( tf.cast(tf.squeeze(l0_mask, -1), tf.bool)) * source_mask else: # evaluation source_memory, l0_mask = l0norm.var_eval( (source_memory, source_pruning)) l0_norm_loss = 0.0 source_memory, source_mask, count_mask = extract_encodes( source_memory, source_mask, l0_mask) count_mask = tf.expand_dims(tf.expand_dims(count_mask, 1), 1) # -------- with tf.variable_scope("decoder"): x = inputs for layer in range(params.num_decoder_layer): if params.deep_transformer_init: layer_initializer = tf.variance_scaling_initializer( params.initializer_gain * (layer + 1)**-0.5, mode="fan_avg", distribution="uniform") else: layer_initializer = None with tf.variable_scope("layer_{}".format(layer), initializer=layer_initializer): with tf.variable_scope("self_attention"): y = func.dot_attention( x, None, func.attention_bias(tf.shape(mask)[1], "causal"), hidden_size, num_heads=params.num_heads, dropout=params.attention_dropout, cache=None if is_training else state['decoder']['state']['layer_{}'.format(layer)]) if not is_training: # k, v state['decoder']['state']['layer_{}'.format(layer)] \ .update(y['cache']) y = y['output'] x = func.residual_fn(x, y, dropout=params.residual_dropout) x = func.layer_norm(x) with tf.variable_scope("cross_attention"): if is_training: y = func.dot_attention( x, source_memory, func.attention_bias(source_mask, "masking"), hidden_size, num_heads=params.num_heads, dropout=params.attention_dropout, ) else: y = dot_attention(x, source_memory, func.attention_bias( source_mask, "masking"), hidden_size, count_mask=count_mask, num_heads=params.num_heads, dropout=params.attention_dropout, cache=state['decoder']['state'][ 'layer_{}'.format(layer)]) # mk, mv state['decoder']['state']['layer_{}'.format(layer)] \ .update(y['cache']) y = y['output'] x = func.residual_fn(x, y, dropout=params.residual_dropout) x = func.layer_norm(x) with tf.variable_scope("feed_forward"): y = func.ffn_layer( x, params.filter_size, hidden_size, dropout=params.relu_dropout, ) x = func.residual_fn(x, y, dropout=params.residual_dropout) x = func.layer_norm(x) feature = x if 'dev_decode' in state: feature = x[:, -1, :] embed_name = "tgt_embedding" if params.shared_target_softmax_embedding \ else "softmax_embedding" embed_name = "embedding" if params.shared_source_target_embedding \ else embed_name softmax_emb = tf.get_variable(embed_name, [params.tgt_vocab.size(), params.embed_size], initializer=initializer) feature = tf.reshape(feature, [-1, params.embed_size]) logits = tf.matmul(feature, softmax_emb, False, True) logits = tf.cast(logits, tf.float32) soft_label, normalizer = util.label_smooth(target, util.shape_list(logits)[-1], factor=params.label_smooth) centropy = tf.nn.softmax_cross_entropy_with_logits_v2(logits=logits, labels=soft_label) centropy -= normalizer centropy = tf.reshape(centropy, tf.shape(target)) mask = tf.cast(mask, tf.float32) per_sample_loss = tf.reduce_sum(centropy * mask, -1) / tf.reduce_sum( mask, -1) loss = tf.reduce_mean(per_sample_loss) loss = loss + l0_norm_loss # these mask tricks mainly used to deal with zero shapes, such as [0, 1] loss = tf.cond(tf.equal(tf.shape(target)[0], 0), lambda: tf.constant(0, tf.float32), lambda: loss) return loss, logits, state, per_sample_loss
def decoder(target, state, params): mask = tf.to_float(tf.cast(target, tf.bool)) hidden_size = params.hidden_size if 'decoder' not in state: target, mask = util.remove_invalid_seq(target, mask) embed_name = "embedding" if params.shared_source_target_embedding \ else "tgt_embedding" tgt_emb = tf.get_variable(embed_name, [params.tgt_vocab.size(), params.embed_size]) tgt_bias = tf.get_variable("bias", [params.embed_size]) inputs = tf.gather(tgt_emb, target) inputs = tf.nn.bias_add(inputs, tgt_bias) # shift if 'decoder' not in state: inputs = tf.pad(inputs, [[0, 0], [1, 0], [0, 0]]) inputs = inputs[:, :-1, :] else: inputs = tf.cond( tf.reduce_all(tf.equal(target, params.tgt_vocab.pad())), lambda: tf.zeros_like(inputs), lambda: inputs) mask = tf.ones_like(mask) if util.valid_dropout(params.dropout): inputs = tf.nn.dropout(inputs, 1. - params.dropout) with tf.variable_scope("decoder"): x = inputs for layer in range(params.num_decoder_layer): with tf.variable_scope("layer_{}".format(layer)): init_state = state["decoder_initializer"]["layer_{}".format( layer)] if 'decoder' in state: init_state = state["decoder"]["state"]["layer_{}".format( layer)] if layer == 0 or params.use_deep_att: returns = rnn.cond_rnn(params.cell, x, state["encodes"], hidden_size, init_state=init_state, mask=mask, num_heads=params.num_heads, mem_mask=state["mask"], ln=params.layer_norm, sm=params.swap_memory, one2one=False, dp=params.dropout) (_, hidden_state), (outputs, _), contexts, attentions = returns c = contexts else: if params.caencoder: returns = rnn.cond_rnn(params.cell, x, c, hidden_size, init_state=init_state, mask=mask, mem_mask=mask, ln=params.layer_norm, sm=params.swap_memory, num_heads=params.num_heads, one2one=True, dp=params.dropout) (_, hidden_state), (outputs, _), contexts, attentions = returns else: outputs = rnn.rnn(params.cell, tf.concat([x, c], -1), hidden_size, mask=mask, init_state=init_state, ln=params.layer_norm, sm=params.swap_memory, dp=params.dropout) outputs, hidden_state = outputs[1] if 'decoder' in state: state['decoder']['state']['layer_{}'.format( layer)] = hidden_state y = func.linear(outputs, hidden_size, ln=False, scope="ff") # short cut via residual connection if x.get_shape()[-1].value == y.get_shape()[-1].value: x = func.residual_fn(x, y, dropout=params.dropout) else: x = y if params.layer_norm: x = func.layer_norm(x, scope="ln") feature = func.linear(tf.concat([x, c], -1), params.embed_size, ln=params.layer_norm, scope="ff") feature = tf.nn.tanh(feature) if util.valid_dropout(params.dropout): feature = tf.nn.dropout(feature, 1. - params.dropout) if 'dev_decode' in state: feature = x[:, -1, :] embed_name = "tgt_embedding" if params.shared_target_softmax_embedding \ else "softmax_embedding" embed_name = "embedding" if params.shared_source_target_embedding \ else embed_name softmax_emb = tf.get_variable(embed_name, [params.tgt_vocab.size(), params.embed_size]) feature = tf.reshape(feature, [-1, params.embed_size]) logits = tf.matmul(feature, softmax_emb, False, True) soft_label, normalizer = util.label_smooth(target, util.shape_list(logits)[-1], factor=params.label_smooth) centropy = tf.nn.softmax_cross_entropy_with_logits_v2(logits=logits, labels=soft_label) centropy -= normalizer centropy = tf.reshape(centropy, tf.shape(target)) loss = tf.reduce_sum(centropy * mask, -1) / tf.reduce_sum(mask, -1) loss = tf.reduce_mean(loss) # these mask tricks mainly used to deal with zero shapes, such as [0, 1] loss = tf.cond(tf.equal(tf.shape(target)[0], 0), lambda: tf.constant(0, dtype=tf.float32), lambda: loss) return loss, logits, state