from functools import partial import numpy as np import paddle.fluid as fluid import paddle.fluid.layers as layers # Set seed for CE dropout_seed = None def wrap_layer_with_block(layer, block_idx): """ Make layer define support indicating block, by which we can add layers to other blocks within current block. This will make it easy to define cache among while loop. """ class BlockGuard(object): """ BlockGuard class. BlockGuard class is used to switch to the given block in a program by using the Python `with` keyword. """ def __init__(self, block_idx=None, main_program=None): self.main_program = fluid.default_main_program( ) if main_program is None else main_program self.old_block_idx = self.main_program.current_block().idx self.new_block_idx = block_idx def __enter__(self): self.main_program.current_block_idx = self.new_block_idx def __exit__(self, exc_type, exc_val, exc_tb): self.main_program.current_block_idx = self.old_block_idx if exc_type is not None: return False # re-raise exception return True def layer_wrapper(*args, **kwargs): with BlockGuard(block_idx): return layer(*args, **kwargs) return layer_wrapper def position_encoding_init(n_position, d_pos_vec): """ Generate the initial values for the sinusoid position encoding table. """ channels = d_pos_vec position = np.arange(n_position) num_timescales = channels // 2 log_timescale_increment = (np.log(float(1e4) / float(1)) / (num_timescales - 1)) inv_timescales = np.exp(np.arange( num_timescales)) * -log_timescale_increment scaled_time = np.expand_dims(position, 1) * np.expand_dims(inv_timescales, 0) signal = np.concatenate([np.sin(scaled_time), np.cos(scaled_time)], axis=1) signal = np.pad(signal, [[0, 0], [0, np.mod(channels, 2)]], 'constant') position_enc = signal return position_enc.astype("float32") def multi_head_attention(queries, keys, values, attn_bias, d_key, d_value, d_model, n_head=1, dropout_rate=0., cache=None, gather_idx=None, static_kv=False): """ Multi-Head Attention. Note that attn_bias is added to the logit before computing softmax activiation to mask certain selected positions so that they will not considered in attention weights. """ keys = queries if keys is None else keys values = keys if values is None else values if not (len(queries.shape) == len(keys.shape) == len(values.shape) == 3): raise ValueError( "Inputs: quries, keys and values should all be 3-D tensors.") def __compute_qkv(queries, keys, values, n_head, d_key, d_value): """ Add linear projection to queries, keys, and values. """ q = layers.fc(input=queries, size=d_key * n_head, bias_attr=False, num_flatten_dims=2) # For encoder-decoder attention in inference, insert the ops and vars # into global block to use as cache among beam search. fc_layer = wrap_layer_with_block( layers.fc, fluid.default_main_program().current_block() .parent_idx) if cache is not None and static_kv else layers.fc k = fc_layer( input=keys, size=d_key * n_head, bias_attr=False, num_flatten_dims=2) v = fc_layer( input=values, size=d_value * n_head, bias_attr=False, num_flatten_dims=2) return q, k, v def __split_heads_qkv(queries, keys, values, n_head, d_key, d_value): """ Reshape input tensors at the last dimension to split multi-heads and then transpose. Specifically, transform the input tensor with shape [bs, max_sequence_length, n_head * hidden_dim] to the output tensor with shape [bs, n_head, max_sequence_length, hidden_dim]. """ # The value 0 in shape attr means copying the corresponding dimension # size of the input as the output dimension size. reshaped_q = layers.reshape( x=queries, shape=[0, 0, n_head, d_key], inplace=True) # permuate the dimensions into: # [batch_size, n_head, max_sequence_len, hidden_size_per_head] q = layers.transpose(x=reshaped_q, perm=[0, 2, 1, 3]) # For encoder-decoder attention in inference, insert the ops and vars # into global block to use as cache among beam search. reshape_layer = wrap_layer_with_block( layers.reshape, fluid.default_main_program().current_block() .parent_idx) if cache is not None and static_kv else layers.reshape transpose_layer = wrap_layer_with_block( layers.transpose, fluid.default_main_program().current_block(). parent_idx) if cache is not None and static_kv else layers.transpose reshaped_k = reshape_layer( x=keys, shape=[0, 0, n_head, d_key], inplace=True) k = transpose_layer(x=reshaped_k, perm=[0, 2, 1, 3]) reshaped_v = reshape_layer( x=values, shape=[0, 0, n_head, d_value], inplace=True) v = transpose_layer(x=reshaped_v, perm=[0, 2, 1, 3]) if cache is not None: # only for faster inference if static_kv: # For encoder-decoder attention in inference cache_k, cache_v = cache["static_k"], cache["static_v"] # To init the static_k and static_v in cache. # Maybe we can use condition_op(if_else) to do these at the first # step in while loop to replace these, however it might be less # efficient. static_cache_init = wrap_layer_with_block( layers.assign, fluid.default_main_program().current_block().parent_idx) static_cache_init(k, cache_k) static_cache_init(v, cache_v) else: # For decoder self-attention in inference cache_k, cache_v = cache["k"], cache["v"] # gather cell states corresponding to selected parent select_k = layers.gather(cache_k, index=gather_idx) select_v = layers.gather(cache_v, index=gather_idx) if not static_kv: # For self attention in inference, use cache and concat time steps. select_k = layers.concat([select_k, k], axis=2) select_v = layers.concat([select_v, v], axis=2) # update cell states(caches) cached in global block layers.assign(select_k, cache_k) layers.assign(select_v, cache_v) return q, select_k, select_v return q, k, v def __combine_heads(x): """ Transpose and then reshape the last two dimensions of inpunt tensor x so that it becomes one dimension, which is reverse to __split_heads. """ if len(x.shape) != 4: raise ValueError("Input(x) should be a 4-D Tensor.") trans_x = layers.transpose(x, perm=[0, 2, 1, 3]) # The value 0 in shape attr means copying the corresponding dimension # size of the input as the output dimension size. return layers.reshape( x=trans_x, shape=[0, 0, trans_x.shape[2] * trans_x.shape[3]], inplace=True) def scaled_dot_product_attention(q, k, v, attn_bias, d_key, dropout_rate): """ Scaled Dot-Product Attention """ # print(q) # print(k) product = layers.matmul(x=q, y=k, transpose_y=True, alpha=d_key**-0.5) if attn_bias: product += attn_bias weights = layers.softmax(product) if dropout_rate: weights = layers.dropout( weights, dropout_prob=dropout_rate, seed=dropout_seed, is_test=False) out = layers.matmul(weights, v) return out q, k, v = __compute_qkv(queries, keys, values, n_head, d_key, d_value) q, k, v = __split_heads_qkv(q, k, v, n_head, d_key, d_value) ctx_multiheads = scaled_dot_product_attention(q, k, v, attn_bias, d_model, dropout_rate) out = __combine_heads(ctx_multiheads) # Project back to the model size. proj_out = layers.fc(input=out, size=d_model, bias_attr=False, num_flatten_dims=2) return proj_out def positionwise_feed_forward(x, d_inner_hid, d_hid, dropout_rate): """ Position-wise Feed-Forward Networks. This module consists of two linear transformations with a ReLU activation in between, which is applied to each position separately and identically. """ hidden = layers.fc(input=x, size=d_inner_hid, num_flatten_dims=2, act="relu") if dropout_rate: hidden = layers.dropout( hidden, dropout_prob=dropout_rate, seed=dropout_seed, is_test=False) out = layers.fc(input=hidden, size=d_hid, num_flatten_dims=2) return out def pre_post_process_layer(prev_out, out, process_cmd, dropout_rate=0.): """ Add residual connection, layer normalization and droput to the out tensor optionally according to the value of process_cmd. This will be used before or after multi-head attention and position-wise feed-forward networks. """ for cmd in process_cmd: if cmd == "a": # add residual connection out = out + prev_out if prev_out else out elif cmd == "n": # add layer normalization out = layers.layer_norm( out, begin_norm_axis=len(out.shape) - 1, param_attr=fluid.initializer.Constant(1.), bias_attr=fluid.initializer.Constant(0.)) elif cmd == "d": # add dropout if dropout_rate: out = layers.dropout( out, dropout_prob=dropout_rate, seed=dropout_seed, is_test=False) return out pre_process_layer = partial(pre_post_process_layer, None) post_process_layer = pre_post_process_layer def prepare_encoder( src_word, #[b,t,c] src_pos, src_vocab_size, src_emb_dim, src_max_len, dropout_rate=0., bos_idx=0, word_emb_param_name=None, pos_enc_param_name=None): """Add word embeddings and position encodings. The output tensor has a shape of: [batch_size, max_src_length_in_batch, d_model]. This module is used at the bottom of the encoder stacks. """ src_word_emb = src_word #layers.concat(res,axis=1) src_word_emb = layers.cast(src_word_emb, 'float32') # print("src_word_emb",src_word_emb) src_word_emb = layers.scale(x=src_word_emb, scale=src_emb_dim**0.5) src_pos_enc = layers.embedding( src_pos, size=[src_max_len, src_emb_dim], param_attr=fluid.ParamAttr( name=pos_enc_param_name, trainable=False)) src_pos_enc.stop_gradient = True enc_input = src_word_emb + src_pos_enc return layers.dropout( enc_input, dropout_prob=dropout_rate, seed=dropout_seed, is_test=False) if dropout_rate else enc_input def prepare_decoder(src_word, src_pos, src_vocab_size, src_emb_dim, src_max_len, dropout_rate=0., bos_idx=0, word_emb_param_name=None, pos_enc_param_name=None): """Add word embeddings and position encodings. The output tensor has a shape of: [batch_size, max_src_length_in_batch, d_model]. This module is used at the bottom of the encoder stacks. """ src_word_emb = layers.embedding( src_word, size=[src_vocab_size, src_emb_dim], padding_idx=bos_idx, # set embedding of bos to 0 param_attr=fluid.ParamAttr( name=word_emb_param_name, initializer=fluid.initializer.Normal(0., src_emb_dim**-0.5))) # print("target_word_emb",src_word_emb) src_word_emb = layers.scale(x=src_word_emb, scale=src_emb_dim**0.5) src_pos_enc = layers.embedding( src_pos, size=[src_max_len, src_emb_dim], param_attr=fluid.ParamAttr( name=pos_enc_param_name, trainable=False)) src_pos_enc.stop_gradient = True enc_input = src_word_emb + src_pos_enc return layers.dropout( enc_input, dropout_prob=dropout_rate, seed=dropout_seed, is_test=False) if dropout_rate else enc_input # prepare_encoder = partial( # prepare_encoder_decoder, pos_enc_param_name=pos_enc_param_names[0]) # prepare_decoder = partial( # prepare_encoder_decoder, pos_enc_param_name=pos_enc_param_names[1]) def encoder_layer(enc_input, attn_bias, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd="n", postprocess_cmd="da"): """The encoder layers that can be stacked to form a deep encoder. This module consits of a multi-head (self) attention followed by position-wise feed-forward networks and both the two components companied with the post_process_layer to add residual connection, layer normalization and droput. """ attn_output = multi_head_attention( pre_process_layer(enc_input, preprocess_cmd, prepostprocess_dropout), None, None, attn_bias, d_key, d_value, d_model, n_head, attention_dropout) attn_output = post_process_layer(enc_input, attn_output, postprocess_cmd, prepostprocess_dropout) ffd_output = positionwise_feed_forward( pre_process_layer(attn_output, preprocess_cmd, prepostprocess_dropout), d_inner_hid, d_model, relu_dropout) return post_process_layer(attn_output, ffd_output, postprocess_cmd, prepostprocess_dropout) def encoder(enc_input, attn_bias, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd="n", postprocess_cmd="da"): """ The encoder is composed of a stack of identical layers returned by calling encoder_layer. """ for i in range(n_layer): enc_output = encoder_layer( enc_input, attn_bias, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, ) enc_input = enc_output enc_output = pre_process_layer(enc_output, preprocess_cmd, prepostprocess_dropout) return enc_output def decoder_layer(dec_input, enc_output, slf_attn_bias, dec_enc_attn_bias, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, cache=None, gather_idx=None): """ The layer to be stacked in decoder part. The structure of this module is similar to that in the encoder part except a multi-head attention is added to implement encoder-decoder attention. """ slf_attn_output = multi_head_attention( pre_process_layer(dec_input, preprocess_cmd, prepostprocess_dropout), None, None, slf_attn_bias, d_key, d_value, d_model, n_head, attention_dropout, cache=cache, gather_idx=gather_idx) slf_attn_output = post_process_layer( dec_input, slf_attn_output, postprocess_cmd, prepostprocess_dropout, ) enc_attn_output = multi_head_attention( pre_process_layer(slf_attn_output, preprocess_cmd, prepostprocess_dropout), enc_output, enc_output, dec_enc_attn_bias, d_key, d_value, d_model, n_head, attention_dropout, cache=cache, gather_idx=gather_idx, static_kv=True) enc_attn_output = post_process_layer( slf_attn_output, enc_attn_output, postprocess_cmd, prepostprocess_dropout, ) ffd_output = positionwise_feed_forward( pre_process_layer(enc_attn_output, preprocess_cmd, prepostprocess_dropout), d_inner_hid, d_model, relu_dropout, ) dec_output = post_process_layer( enc_attn_output, ffd_output, postprocess_cmd, prepostprocess_dropout, ) return dec_output def decoder(dec_input, enc_output, dec_slf_attn_bias, dec_enc_attn_bias, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, caches=None, gather_idx=None): """ The decoder is composed of a stack of identical decoder_layer layers. """ for i in range(n_layer): dec_output = decoder_layer( dec_input, enc_output, dec_slf_attn_bias, dec_enc_attn_bias, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, cache=None if caches is None else caches[i], gather_idx=gather_idx) dec_input = dec_output dec_output = pre_process_layer(dec_output, preprocess_cmd, prepostprocess_dropout) return dec_output def make_all_inputs(input_fields): """ Define the input data layers for the transformer model. """ inputs = [] for input_field in input_fields: input_var = layers.data( name=input_field, shape=input_descs[input_field][0], dtype=input_descs[input_field][1], lod_level=input_descs[input_field][2] if len(input_descs[input_field]) == 3 else 0, append_batch_size=False) inputs.append(input_var) return inputs def make_all_py_reader_inputs(input_fields, is_test=False): reader = layers.py_reader( capacity=20, name="test_reader" if is_test else "train_reader", shapes=[input_descs[input_field][0] for input_field in input_fields], dtypes=[input_descs[input_field][1] for input_field in input_fields], lod_levels=[ input_descs[input_field][2] if len(input_descs[input_field]) == 3 else 0 for input_field in input_fields ]) return layers.read_file(reader), reader def transformer(src_vocab_size, trg_vocab_size, max_length, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, weight_sharing, label_smooth_eps, bos_idx=0, use_py_reader=False, is_test=False): if weight_sharing: assert src_vocab_size == trg_vocab_size, ( "Vocabularies in source and target should be same for weight sharing." ) data_input_names = encoder_data_input_fields + \ decoder_data_input_fields[:-1] + label_data_input_fields if use_py_reader: all_inputs, reader = make_all_py_reader_inputs(data_input_names, is_test) else: all_inputs = make_all_inputs(data_input_names) # print("all inputs",all_inputs) enc_inputs_len = len(encoder_data_input_fields) dec_inputs_len = len(decoder_data_input_fields[:-1]) enc_inputs = all_inputs[0:enc_inputs_len] dec_inputs = all_inputs[enc_inputs_len:enc_inputs_len + dec_inputs_len] label = all_inputs[-2] weights = all_inputs[-1] enc_output = wrap_encoder( src_vocab_size, 64, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, weight_sharing, enc_inputs) predict = wrap_decoder( trg_vocab_size, max_length, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, weight_sharing, dec_inputs, enc_output, ) # Padding index do not contribute to the total loss. The weights is used to # cancel padding index in calculating the loss. if label_smooth_eps: label = layers.label_smooth( label=layers.one_hot( input=label, depth=trg_vocab_size), epsilon=label_smooth_eps) cost = layers.softmax_with_cross_entropy( logits=predict, label=label, soft_label=True if label_smooth_eps else False) weighted_cost = cost * weights sum_cost = layers.reduce_sum(weighted_cost) token_num = layers.reduce_sum(weights) token_num.stop_gradient = True avg_cost = sum_cost / token_num return sum_cost, avg_cost, predict, token_num, reader if use_py_reader else None def wrap_encoder_forFeature(src_vocab_size, max_length, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, weight_sharing, enc_inputs=None, bos_idx=0): """ The wrapper assembles together all needed layers for the encoder. img, src_pos, src_slf_attn_bias = enc_inputs img """ if enc_inputs is None: # This is used to implement independent encoder program in inference. conv_features, src_pos, src_slf_attn_bias = make_all_inputs( encoder_data_input_fields) else: conv_features, src_pos, src_slf_attn_bias = enc_inputs # b, t, c = conv_features.shape #""" # insert cnn #""" #import basemodel # feat = basemodel.resnet_50(img) # mycrnn = basemodel.CRNN() # feat = mycrnn.ocr_convs(img,use_cudnn=TrainTaskConfig.use_gpu) # b, c, w, h = feat.shape # src_word = layers.reshape(feat, shape=[-1, c, w * h]) #myconv8 = basemodel.conv8() #feat = myconv8.net(img ) #b , c, h, w = feat.shape#h=6 #print(feat) #layers.Print(feat,message="conv_feat",summarize=10) #feat =layers.conv2d(feat,c,filter_size =[4 , 1],act="relu") #feat = layers.pool2d(feat,pool_stride=(3,1),pool_size=(3,1)) #src_word = layers.squeeze(feat,axes=[2]) #src_word [-1,c,ww] #feat = layers.transpose(feat, [0,3,1,2]) #src_word = layers.reshape(feat,[-1,w, c*h]) #src_word = layers.im2sequence( # input=feat, # stride=[1, 1], # filter_size=[feat.shape[2], 1]) #layers.Print(src_word,message="src_word",summarize=10) # print('feat',feat) #print("src_word",src_word) enc_input = prepare_encoder( conv_features, src_pos, src_vocab_size, d_model, max_length, prepostprocess_dropout, bos_idx=bos_idx, word_emb_param_name="src_word_emb_table") enc_output = encoder( enc_input, src_slf_attn_bias, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, ) return enc_output def wrap_encoder(src_vocab_size, max_length, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, weight_sharing, enc_inputs=None, bos_idx=0): """ The wrapper assembles together all needed layers for the encoder. img, src_pos, src_slf_attn_bias = enc_inputs img """ if enc_inputs is None: # This is used to implement independent encoder program in inference. src_word, src_pos, src_slf_attn_bias = make_all_inputs( encoder_data_input_fields) else: src_word, src_pos, src_slf_attn_bias = enc_inputs # #""" # insert cnn #""" #import basemodel # feat = basemodel.resnet_50(img) # mycrnn = basemodel.CRNN() # feat = mycrnn.ocr_convs(img,use_cudnn=TrainTaskConfig.use_gpu) # b, c, w, h = feat.shape # src_word = layers.reshape(feat, shape=[-1, c, w * h]) #myconv8 = basemodel.conv8() #feat = myconv8.net(img ) #b , c, h, w = feat.shape#h=6 #print(feat) #layers.Print(feat,message="conv_feat",summarize=10) #feat =layers.conv2d(feat,c,filter_size =[4 , 1],act="relu") #feat = layers.pool2d(feat,pool_stride=(3,1),pool_size=(3,1)) #src_word = layers.squeeze(feat,axes=[2]) #src_word [-1,c,ww] #feat = layers.transpose(feat, [0,3,1,2]) #src_word = layers.reshape(feat,[-1,w, c*h]) #src_word = layers.im2sequence( # input=feat, # stride=[1, 1], # filter_size=[feat.shape[2], 1]) #layers.Print(src_word,message="src_word",summarize=10) # print('feat',feat) #print("src_word",src_word) enc_input = prepare_decoder( src_word, src_pos, src_vocab_size, d_model, max_length, prepostprocess_dropout, bos_idx=bos_idx, word_emb_param_name="src_word_emb_table") enc_output = encoder( enc_input, src_slf_attn_bias, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, ) return enc_output def wrap_decoder(trg_vocab_size, max_length, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, weight_sharing, dec_inputs=None, enc_output=None, caches=None, gather_idx=None, bos_idx=0): """ The wrapper assembles together all needed layers for the decoder. """ if dec_inputs is None: # This is used to implement independent decoder program in inference. trg_word, trg_pos, trg_slf_attn_bias, trg_src_attn_bias, enc_output = \ make_all_inputs(decoder_data_input_fields) else: trg_word, trg_pos, trg_slf_attn_bias, trg_src_attn_bias = dec_inputs dec_input = prepare_decoder( trg_word, trg_pos, trg_vocab_size, d_model, max_length, prepostprocess_dropout, bos_idx=bos_idx, word_emb_param_name="src_word_emb_table" if weight_sharing else "trg_word_emb_table") dec_output = decoder( dec_input, enc_output, trg_slf_attn_bias, trg_src_attn_bias, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, caches=caches, gather_idx=gather_idx) return dec_output # Reshape to 2D tensor to use GEMM instead of BatchedGEMM dec_output = layers.reshape( dec_output, shape=[-1, dec_output.shape[-1]], inplace=True) if weight_sharing: predict = layers.matmul( x=dec_output, y=fluid.default_main_program().global_block().var( "trg_word_emb_table"), transpose_y=True) else: predict = layers.fc(input=dec_output, size=trg_vocab_size, bias_attr=False) if dec_inputs is None: # Return probs for independent decoder program. predict = layers.softmax(predict) return predict def fast_decode(src_vocab_size, trg_vocab_size, max_in_len, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, weight_sharing, beam_size, max_out_len, bos_idx, eos_idx, use_py_reader=False): """ Use beam search to decode. Caches will be used to store states of history steps which can make the decoding faster. """ data_input_names = encoder_data_input_fields + fast_decoder_data_input_fields if use_py_reader: all_inputs, reader = make_all_py_reader_inputs(data_input_names) else: all_inputs = make_all_inputs(data_input_names) enc_inputs_len = len(encoder_data_input_fields) dec_inputs_len = len(fast_decoder_data_input_fields) enc_inputs = all_inputs[0:enc_inputs_len] #enc_inputs tensor dec_inputs = all_inputs[enc_inputs_len:enc_inputs_len + dec_inputs_len] #dec_inputs tensor enc_output = wrap_encoder( src_vocab_size, 64, ##to do !!!!!???? n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, weight_sharing, enc_inputs, bos_idx=bos_idx) start_tokens, init_scores, parent_idx, trg_src_attn_bias = dec_inputs def beam_search(): max_len = layers.fill_constant( shape=[1], dtype=start_tokens.dtype, value=max_out_len, force_cpu=True) step_idx = layers.fill_constant( shape=[1], dtype=start_tokens.dtype, value=0, force_cpu=True) cond = layers.less_than(x=step_idx, y=max_len) # default force_cpu=True while_op = layers.While(cond) # array states will be stored for each step. ids = layers.array_write( layers.reshape(start_tokens, (-1, 1)), step_idx) scores = layers.array_write(init_scores, step_idx) # cell states will be overwrited at each step. # caches contains states of history steps in decoder self-attention # and static encoder output projections in encoder-decoder attention # to reduce redundant computation. caches = [ { "k": # for self attention layers.fill_constant_batch_size_like( input=start_tokens, shape=[-1, n_head, 0, d_key], dtype=enc_output.dtype, value=0), "v": # for self attention layers.fill_constant_batch_size_like( input=start_tokens, shape=[-1, n_head, 0, d_value], dtype=enc_output.dtype, value=0), "static_k": # for encoder-decoder attention layers.create_tensor(dtype=enc_output.dtype), "static_v": # for encoder-decoder attention layers.create_tensor(dtype=enc_output.dtype) } for i in range(n_layer) ] with while_op.block(): pre_ids = layers.array_read(array=ids, i=step_idx) # Since beam_search_op dosen't enforce pre_ids' shape, we can do # inplace reshape here which actually change the shape of pre_ids. pre_ids = layers.reshape(pre_ids, (-1, 1, 1), inplace=True) pre_scores = layers.array_read(array=scores, i=step_idx) # gather cell states corresponding to selected parent pre_src_attn_bias = layers.gather( trg_src_attn_bias, index=parent_idx) pre_pos = layers.elementwise_mul( x=layers.fill_constant_batch_size_like( input=pre_src_attn_bias, # cann't use lod tensor here value=1, shape=[-1, 1, 1], dtype=pre_ids.dtype), y=step_idx, axis=0) logits = wrap_decoder( trg_vocab_size, max_in_len, n_layer, n_head, d_key, d_value, d_model, d_inner_hid, prepostprocess_dropout, attention_dropout, relu_dropout, preprocess_cmd, postprocess_cmd, weight_sharing, dec_inputs=(pre_ids, pre_pos, None, pre_src_attn_bias), enc_output=enc_output, caches=caches, gather_idx=parent_idx, bos_idx=bos_idx) # intra-beam topK topk_scores, topk_indices = layers.topk( input=layers.softmax(logits), k=beam_size) accu_scores = layers.elementwise_add( x=layers.log(topk_scores), y=pre_scores, axis=0) # beam_search op uses lod to differentiate branches. accu_scores = layers.lod_reset(accu_scores, pre_ids) # topK reduction across beams, also contain special handle of # end beams and end sentences(batch reduction) selected_ids, selected_scores, gather_idx = layers.beam_search( pre_ids=pre_ids, pre_scores=pre_scores, ids=topk_indices, scores=accu_scores, beam_size=beam_size, end_id=eos_idx, return_parent_idx=True) layers.increment(x=step_idx, value=1.0, in_place=True) # cell states(caches) have been updated in wrap_decoder, # only need to update beam search states here. layers.array_write(selected_ids, i=step_idx, array=ids) layers.array_write(selected_scores, i=step_idx, array=scores) layers.assign(gather_idx, parent_idx) layers.assign(pre_src_attn_bias, trg_src_attn_bias) length_cond = layers.less_than(x=step_idx, y=max_len) finish_cond = layers.logical_not(layers.is_empty(x=selected_ids)) layers.logical_and(x=length_cond, y=finish_cond, out=cond) finished_ids, finished_scores = layers.beam_search_decode( ids, scores, beam_size=beam_size, end_id=eos_idx) return finished_ids, finished_scores finished_ids, finished_scores = beam_search() return finished_ids, finished_scores, reader if use_py_reader else None