# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from __future__ import print_function import six from . import layers __all__ = [ "simple_img_conv_pool", "sequence_conv_pool", "glu", "scaled_dot_product_attention", "img_conv_group", ] def simple_img_conv_pool(input, num_filters, filter_size, pool_size, pool_stride, pool_padding=0, pool_type='max', global_pooling=False, conv_stride=1, conv_padding=0, conv_dilation=1, conv_groups=1, param_attr=None, bias_attr=None, act=None, use_cudnn=True): """ The simple_img_conv_pool is composed with one Convolution2d and one Pool2d. Args: input (Variable): The input image with [N, C, H, W] format. num_filters(int): The number of filter. It is as same as the output feature channel. filter_size (int|list|tuple): The filter size. If filter_size is a list or tuple, it must contain two integers, (filter_size_H, filter_size_W). Otherwise, the filter_size_H = filter_size_W = filter_size. pool_size (int|list|tuple): The pooling size of Pool2d layer. If pool_size is a list or tuple, it must contain two integers, (pool_size_H, pool_size_W). Otherwise, the pool_size_H = pool_size_W = pool_size. pool_stride (int|list|tuple): The pooling stride of Pool2d layer. If pool_stride is a list or tuple, it must contain two integers, (pooling_stride_H, pooling_stride_W). Otherwise, the pooling_stride_H = pooling_stride_W = pool_stride. pool_padding (int|list|tuple): The padding of Pool2d layer. If pool_padding is a list or tuple, it must contain two integers, (pool_padding_H, pool_padding_W). Otherwise, the pool_padding_H = pool_padding_W = pool_padding. Default 0. pool_type (str): Pooling type can be :math:`max` for max-pooling and :math:`avg` for average-pooling. Default :math:`max`. global_pooling (bool): Whether to use the global pooling. If global_pooling = true, pool_size and pool_padding while be ignored. Default False conv_stride (int|list|tuple): The stride size of the Conv2d Layer. If stride is a list or tuple, it must contain two integers, (conv_stride_H, conv_stride_W). Otherwise, the conv_stride_H = conv_stride_W = conv_stride. Default: conv_stride = 1. conv_padding (int|list|tuple): The padding size of the Conv2d Layer. If padding is a list or tuple, it must contain two integers, (conv_padding_H, conv_padding_W). Otherwise, the conv_padding_H = conv_padding_W = conv_padding. Default: conv_padding = 0. conv_dilation (int|list|tuple): The dilation size of the Conv2d Layer. If dilation is a list or tuple, it must contain two integers, (conv_dilation_H, conv_dilation_W). Otherwise, the conv_dilation_H = conv_dilation_W = conv_dilation. Default: conv_dilation = 1. conv_groups (int): The groups number of the Conv2d Layer. According to grouped convolution in Alex Krizhevsky's Deep CNN paper: when group=2, the first half of the filters is only connected to the first half of the input channels, while the second half of the filters is only connected to the second half of the input channels. Default: groups=1 param_attr (ParamAttr): The parameter attribute for learnable parameters/weights of conv2d. If it is set to None, the parameter is initialized with :math:`Normal(0.0, std)`, and the :math:`std` is :math:`(\\frac{2.0 }{filter\_elem\_num})^{0.5}`. Default: None. bias_attr (ParamAttr): The parameter attribute for the bias of conv2d. If it is set to False, no bias will be added to the output units. If it is set to None, the bias is initialized zero. Default: None. act (str): Activation type for Conv2d. Default: None use_cudnn (bool): Use cudnn kernel or not, it is valid only when the cudnn library is installed. Default: True Return: Variable: The result of input after Convolution2d and Pool2d. Examples: .. code-block:: python img = fluid.layers.data(name='img', shape=[1, 28, 28], dtype='float32') conv_pool = fluid.nets.simple_img_conv_pool(input=img, filter_size=5, num_filters=20, pool_size=2, pool_stride=2, act="relu") """ conv_out = layers.conv2d( input=input, num_filters=num_filters, filter_size=filter_size, stride=conv_stride, padding=conv_padding, dilation=conv_dilation, groups=conv_groups, param_attr=param_attr, bias_attr=bias_attr, act=act, use_cudnn=use_cudnn) pool_out = layers.pool2d( input=conv_out, pool_size=pool_size, pool_type=pool_type, pool_stride=pool_stride, pool_padding=pool_padding, global_pooling=global_pooling, use_cudnn=use_cudnn) return pool_out def img_conv_group(input, conv_num_filter, pool_size, conv_padding=1, conv_filter_size=3, conv_act=None, param_attr=None, conv_with_batchnorm=False, conv_batchnorm_drop_rate=0.0, pool_stride=1, pool_type="max", use_cudnn=True): """ The Image Convolution Group is composed of Convolution2d, BatchNorm, DropOut, and Pool2d. According to the input arguments, img_conv_group will do serials of computation for Input using Convolution2d, BatchNorm, DropOut, and pass the last result to Pool2d. Args: input (Variable): The input image with [N, C, H, W] format. conv_num_filter(list|tuple): Indicates the numbers of filter of this group. pool_size (int|list|tuple): The pooling size of Pool2d Layer. If pool_size is a list or tuple, it must contain two integers, (pool_size_H, pool_size_W). Otherwise, the pool_size_H = pool_size_W = pool_size. conv_padding (int|list|tuple): The padding size of the Conv2d Layer. If padding is a list or tuple, its length must be equal to the length of conv_num_filter. Otherwise the conv_padding of all Conv2d Layers are the same. Default 1. conv_filter_size (int|list|tuple): The filter size. If filter_size is a list or tuple, its length must be equal to the length of conv_num_filter. Otherwise the conv_filter_size of all Conv2d Layers are the same. Default 3. conv_act (str): Activation type for Conv2d Layer that is not followed by BatchNorm. Default: None. param_attr (ParamAttr): The parameters to the Conv2d Layer. Default: None conv_with_batchnorm (bool|list): Indicates whether to use BatchNorm after Conv2d Layer. If conv_with_batchnorm is a list, its length must be equal to the length of conv_num_filter. Otherwise, conv_with_batchnorm indicates whether all the Conv2d Layer follows a BatchNorm. Default False. conv_batchnorm_drop_rate (float|list): Indicates the drop_rate of Dropout Layer after BatchNorm. If conv_batchnorm_drop_rate is a list, its length must be equal to the length of conv_num_filter. Otherwise, drop_rate of all Dropout Layers is conv_batchnorm_drop_rate. Default 0.0. pool_stride (int|list|tuple): The pooling stride of Pool2d layer. If pool_stride is a list or tuple, it must contain two integers, (pooling_stride_H, pooling_stride_W). Otherwise, the pooling_stride_H = pooling_stride_W = pool_stride. Default 1. pool_type (str): Pooling type can be :math:`max` for max-pooling and :math:`avg` for average-pooling. Default :math:`max`. use_cudnn (bool): Use cudnn kernel or not, it is valid only when the cudnn library is installed. Default: True Return: Variable: The final result after serial computation using Convolution2d, BatchNorm, DropOut, and Pool2d. Examples: .. code-block:: python img = fluid.layers.data(name='img', shape=[1, 28, 28], dtype='float32') conv_pool = fluid.nets.img_conv_group(input=img, num_channels=3, conv_padding=1, conv_num_filter=[3, 3], conv_filter_size=3, conv_act="relu", pool_size=2, pool_stride=2) """ tmp = input assert isinstance(conv_num_filter, list) or \ isinstance(conv_num_filter, tuple) def __extend_list__(obj): if not hasattr(obj, '__len__'): return [obj] * len(conv_num_filter) else: assert len(obj) == len(conv_num_filter) return obj conv_padding = __extend_list__(conv_padding) conv_filter_size = __extend_list__(conv_filter_size) param_attr = __extend_list__(param_attr) conv_with_batchnorm = __extend_list__(conv_with_batchnorm) conv_batchnorm_drop_rate = __extend_list__(conv_batchnorm_drop_rate) for i in six.moves.range(len(conv_num_filter)): local_conv_act = conv_act if conv_with_batchnorm[i]: local_conv_act = None tmp = layers.conv2d( input=tmp, num_filters=conv_num_filter[i], filter_size=conv_filter_size[i], padding=conv_padding[i], param_attr=param_attr[i], act=local_conv_act, use_cudnn=use_cudnn) if conv_with_batchnorm[i]: tmp = layers.batch_norm(input=tmp, act=conv_act, in_place=True) drop_rate = conv_batchnorm_drop_rate[i] if abs(drop_rate) > 1e-5: tmp = layers.dropout(x=tmp, dropout_prob=drop_rate) pool_out = layers.pool2d( input=tmp, pool_size=pool_size, pool_type=pool_type, pool_stride=pool_stride, use_cudnn=use_cudnn) return pool_out def sequence_conv_pool(input, num_filters, filter_size, param_attr=None, act="sigmoid", pool_type="max"): """ The sequence_conv_pool is composed with Sequence Convolution and Pooling. Args: input (Variable): The input of sequence_conv, which supports variable-time length input sequence. The underlying of input is a matrix with shape (T, N), where T is the total time steps in this mini-batch and N is the input_hidden_size num_filters(int): The number of filter. filter_size (int): The filter size. param_attr (ParamAttr): The parameters to the Sequence_conv Layer. Default: None. act (str): Activation type for Sequence_conv Layer. Default: "sigmoid". pool_type (str): Pooling type can be :math:`max` for max-pooling, :math:`average` for average-pooling, :math:`sum` for sum-pooling, :math:`sqrt` for sqrt-pooling. Default :math:`max`. Return: Variable: The final result after Sequence Convolution and Pooling. Examples: .. code-block:: python input_dim = len(word_dict) emb_dim = 128 hid_dim = 512 data = fluid.layers.data( ame="words", shape=[1], dtype="int64", lod_level=1) emb = fluid.layers.embedding(input=data, size=[input_dim, emb_dim], is_sparse=True) seq_conv = fluid.nets.sequence_conv_pool(input=emb, num_filters=hid_dim, filter_size=3, act="tanh", pool_type="sqrt") """ conv_out = layers.sequence_conv( input=input, num_filters=num_filters, filter_size=filter_size, param_attr=param_attr, act=act) pool_out = layers.sequence_pool(input=conv_out, pool_type=pool_type) return pool_out def glu(input, dim=-1): """ The Gated Linear Units(GLU) composed by split, sigmoid activation and element-wise multiplication. Specifically, Split the input into two equal sized parts, :math:`a` and :math:`b`, along the given dimension and then compute as following: .. math:: {GLU}(a, b)= a \otimes \sigma(b) Refer to `Language Modeling with Gated Convolutional Networks `_. Args: input (Variable): The input variable which is a Tensor or LoDTensor. dim (int): The dimension along which to split. If :math:`dim < 0`, the dimension to split along is :math:`rank(input) + dim`. Default -1. Returns: Variable: Variable with half the size of input. Examples: .. code-block:: python data = fluid.layers.data(name="words", shape=[3, 6, 9], dtype="float32") output = fluid.nets.glu(input=data, dim=1) # shape of output: [3, 3, 9] """ a, b = layers.split(input, num_or_sections=2, dim=dim) act_b = layers.sigmoid(x=b) out = layers.elementwise_mul(x=a, y=act_b) return out def scaled_dot_product_attention(queries, keys, values, num_heads=1, dropout_rate=0.): """ The dot-product attention. Attention mechanism can be seen as mapping a query and a set of key-value pairs to an output. The output is computed as a weighted sum of the values, where the weight assigned to each value is computed by a compatibility function (dot-product here) of the query with the corresponding key. The dot-product attention can be implemented through (batch) matrix multipication as follows: .. math:: Attention(Q, K, V)= softmax(QK^\mathrm{T})V Refer to `Attention Is All You Need `_. Args: queries (Variable): The input variable which should be a 3-D Tensor. keys (Variable): The input variable which should be a 3-D Tensor. values (Variable): The input variable which should be a 3-D Tensor. num_heads (int): Head number to compute the scaled dot product attention. Default: 1. dropout_rate (float): The dropout rate to drop the attention weight. Default: 0.0. Returns: Variable: A 3-D Tensor computed by multi-head scaled dot product\ attention. Raises: ValueError: If input queries, keys, values are not 3-D Tensors. NOTES: 1. When num_heads > 1, three linear projections are learned respectively to map input queries, keys and values into queries', keys' and values'. queries', keys' and values' have the same shapes with queries, keys and values. 2. When num_heads == 1, scaled_dot_product_attention has no learnable parameters. Examples: .. code-block:: python queries = fluid.layers.data(name="queries", shape=[3, 5, 9], dtype="float32", append_batch_size=False) queries.stop_gradient = False keys = fluid.layers.data(name="keys", shape=[3, 6, 9], dtype="float32", append_batch_size=False) keys.stop_gradient = False values = fluid.layers.data(name="values", shape=[3, 6, 10], dtype="float32", append_batch_size=False) values.stop_gradient = False contexts = fluid.nets.scaled_dot_product_attention(queries, keys, values) contexts.shape # [3, 5, 10] """ 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.") if queries.shape[-1] != keys.shape[-1]: raise ValueError( "The hidden size of queries and keys should be the same.") if keys.shape[-2] != values.shape[-2]: raise ValueError( "The max sequence length in query batch and in key batch " "should be the same.") if keys.shape[-1] % num_heads != 0: raise ValueError("The hidden size of keys (%d) must be divisible " "by the number of attention heads (%d)." % (keys.shape[-1], num_heads)) if values.shape[-1] % num_heads != 0: raise ValueError("The hidden size of values (%d) must be divisible " "by the number of attention heads (%d)." % (values.shape[-1], num_heads)) def __compute_qkv(queries, keys, values, num_heads): """ Add linear projection to queries, keys, and values. Args: queries(Tensor): a 3-D input Tensor. keys(Tensor): a 3-D input Tensor. values(Tensor): a 3-D input Tensor. num_heads(int): The number of heads. Linearly project the inputs ONLY when num_heads > 1. Returns: Tensor: linearly projected output Tensors: queries', keys' and values'. They have the same shapes with queries, keys and values. """ if num_heads == 1: return queries, keys, values q = layers.fc(input=queries, size=queries.shape[-1], num_flatten_dims=2) k = layers.fc(input=keys, size=keys.shape[-1], num_flatten_dims=2) v = layers.fc(input=values, size=values.shape[-1], num_flatten_dims=2) return q, k, v def __split_heads(x, num_heads): """ Reshape the last dimension of inpunt tensor x so that it becomes two dimensions. Args: x(Tensor): a 3-D input Tensor. num_heads(int): The number of heads. Returns: Tensor: a Tensor with shape [..., n, m/num_heads], where m is size of the last dimension of x. """ if num_heads == 1: return x hidden_size = x.shape[-1] # reshape the 3-D input: [batch_size, max_sequence_length, hidden_dim] # into a 4-D output: # [batch_size, max_sequence_length, num_heads, hidden_size_per_head]. reshaped = layers.reshape( x=x, shape=list(x.shape[:-1]) + [num_heads, hidden_size // num_heads]) # permuate the dimensions into: # [batch_size, num_heads, max_sequence_len, hidden_size_per_head] return layers.transpose(x=reshaped, perm=[0, 2, 1, 3]) def __combine_heads(x): """ Reshape the last two dimensions of inpunt tensor x so that it becomes one dimension. Args: x(Tensor): a 4-D input Tensor with shape [bs, num_heads, max_sequence_length, hidden_dim]. Returns: Tensor: a Tensor with shape [bs, max_sequence_length, num_heads * hidden_dim]. """ if len(x.shape) == 3: return x 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]) return layers.reshape( x=trans_x, shape=list( map(int, [ trans_x.shape[0], trans_x.shape[1], trans_x.shape[2] * trans_x.shape[3] ]))) q, k, v = __compute_qkv(queries, keys, values, num_heads) q = __split_heads(q, num_heads) k = __split_heads(k, num_heads) v = __split_heads(v, num_heads) key_dim_per_head = keys.shape[-1] // num_heads scaled_q = layers.scale(x=q, scale=key_dim_per_head**-0.5) product = layers.matmul(x=k, y=scaled_q, transpose_y=True) weights = layers.reshape( x=layers.reshape( x=product, shape=[-1, product.shape[-1]], act="softmax"), shape=product.shape) if dropout_rate: weights = layers.dropout( weights, dropout_prob=dropout_rate, is_test=False) ctx_multiheads = layers.matmul(weights, v) return __combine_heads(ctx_multiheads)