# Copyright (c) 2021 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 paddle.fluid.layer_helper import LayerHelper from paddle.fluid.framework import _non_static_mode, default_main_program from paddle.fluid.data_feeder import check_variable_and_dtype, check_dtype from paddle.fluid import core, dygraph_utils from paddle import _C_ops __all__ = [] def _verify_dropout_rate(dropout_rate): if not isinstance(dropout_rate, (float, int)): raise TypeError("dropout_rate argument should be a number") if dropout_rate < 0 or dropout_rate > 1: raise ValueError("dropout_rate argument should between 0 and 1") def fused_feedforward(x, linear1_weight, linear2_weight, linear1_bias=None, linear2_bias=None, ln1_scale=None, ln1_bias=None, ln2_scale=None, ln2_bias=None, dropout1_rate=0.5, dropout2_rate=0.5, activation="relu", ln1_epsilon=1e-5, ln2_epsilon=1e-5, pre_layer_norm=False, training=True, mode='upscale_in_train', name=None): r""" This is a fusion operator to compute feed forward layer in transformer model architecture. This operator only supports running on GPU. The function of the operator is consistent with the following pseudo code: .. code-block:: python residual = src; if pre_layer_norm: src = layer_norm(src) src = linear(dropout(activation(dropout(linear(src))))) if not pre_layer_norm: src = layer_norm(out) Args: x (Tensor): the input tensor could be 3-D tensor, the input data type could be float16, float32 or float64, the shape is`[batch\_size, sequence\_length, d_model]`. linear1_weight (Tensor): The weight of first linear, the data type is same as `x`, the shape is `[d\_model, dim\_feedforward]`. linear2_weight (Tensor): The weight of second linear, the data type is same as `x`, the shape is `[dim\_feedforward, d\_model]`. linear1_bias (Tensor, optional): The bias of first linear, the data type is same as `x`, the shape is `[dim_feedforward]`. Default None. linear2_bias (Tensor, optional): The bias of second linear, the data type is same as `x`, the shape is `[d_model]`. Default None. ln1_scale (Tensor, optional): the weight of first layer_norm, the data type is float32 or float64, the shape is same as `x`. Default None. ln1_bias (Tensor, optional): The bias of first layer_norm, the data type is float32 or float64, the shape is `[d\_model]`. Default None. ln2_scale (Tensor, optional): The weight of second layer_norm, the data type is float32 or float64, the shape is same as `x`. Default None. ln2_bias (Tensor, optional): The bias of second layer_norm, the data type is float32 or float64, the shape is `[d\_model]`. Default None. dropout1_rate (float, optional): The first dropout probability of setting units to zero. Default 0.5. dropout2_rate (float, optional): The second dropout probability of setting units to zero. Default 0.5. activation (str, optional): The activation. Default "relu". ln1_epsilon (float, optional): Small float of first layer_norm added to denominator to avoid dividing by zero. Default is 1e-5. ln2_epsilon (float, optional): Small float of second layer_norm added to denominator to avoid dividing by zero. Default is 1e-5. pre_layer_norm (bool, optional): add layer_norm in the pre-processing stage or post-processing state. training (bool, optional): A flag indicating whether it is in train phrase or not. Default True. mode (str, optional): ['upscale_in_train'(default) | 'downscale_in_infer'] 1. upscale_in_train(default), upscale the output at training time - train: out = input * mask / ( 1.0 - p ) - inference: out = input 2. downscale_in_infer, downscale the output at inference - train: out = input * mask - inference: out = input * (1.0 - p) name (str, optional): Name for the operation (optional, default is None). For more information, please refer to :ref:`api_guide_Name`. Returns: Tensor: The output Tensor, the data type and shape is same as `x`. Examples: .. code-block:: python # required: gpu import paddle import numpy as np x_data = np.random.random((1, 8, 8)).astype("float32") linear1_weight_data = np.random.random((8, 8)).astype("float32") linear2_weight_data = np.random.random((8, 8)).astype("float32") x = paddle.to_tensor(x_data) linear1_weight = paddle.to_tensor(linear1_weight_data) linear2_weight = paddle.to_tensor(linear2_weight_data) out = paddle.incubate.nn.functional.fused_feedforward(x, linear1_weight, linear2_weight) print(out.numpy().shape) # (1, 8, 8) """ _verify_dropout_rate(dropout1_rate) _verify_dropout_rate(dropout2_rate) seed = None if mode not in ('downscale_in_infer', 'upscale_in_train'): raise ValueError( "mode argument should be 'downscale_in_infer' or 'upscale_in_train'") mode = 'downgrade_in_infer' if mode == 'downscale_in_infer' else mode #semantic transfer if _non_static_mode(): if default_main_program().random_seed != 0: seed = default_main_program().random_seed out, _, _, _, _, _, _, _, _, _, _ = _C_ops.fused_feedforward( x, None, None, linear1_weight, linear1_bias, linear2_weight, linear2_bias, ln1_scale, ln1_bias, ln2_scale, ln2_bias, 'pre_layer_norm', pre_layer_norm, 'ln1_epsilon', ln1_epsilon, 'ln2_epsilon', ln2_epsilon, 'act_method', activation, 'dropout1_rate', dropout1_rate, 'dropout2_rate', dropout2_rate, "dropout1_is_test", not training, "dropout2_is_test", not training, "dropout1_fix_seed", seed is not None, "dropout2_fix_seed", seed is not None, "dropout1_seed", seed if seed is not None else 0, "dropout2_seed", seed if seed is not None else 0, 'dropout1_implementation', mode, 'dropout2_implementation', mode) return out helper = LayerHelper("fused_feedforward") dtype = x.dtype check_variable_and_dtype(x, 'x', ['float16', 'float32', 'float64'], 'fused_feedforward') check_dtype(dtype, 'dtype', ['float16', 'float32', 'float64'], 'fused_feedforward') out = helper.create_variable_for_type_inference(x.dtype) dropout1_mask = helper.create_variable_for_type_inference( 'uint8', stop_gradient=True) dropout2_mask = helper.create_variable_for_type_inference( 'uint8', stop_gradient=True) ln1_mean = helper.create_variable_for_type_inference( x.dtype, stop_gradient=True) ln1_variance = helper.create_variable_for_type_inference( x.dtype, stop_gradient=True) ln2_mean = helper.create_variable_for_type_inference( x.dtype, stop_gradient=True) ln2_variance = helper.create_variable_for_type_inference( x.dtype, stop_gradient=True) linear1_out = helper.create_variable_for_type_inference( x.dtype, stop_gradient=True) ln1_out = helper.create_variable_for_type_inference( x.dtype, stop_gradient=True) dropout1_out = helper.create_variable_for_type_inference( x.dtype, stop_gradient=True) dropout2_out = helper.create_variable_for_type_inference( x.dtype, stop_gradient=True) if (seed is None or seed == 0) and helper.main_program.random_seed != 0: seed = helper.main_program.random_seed helper.append_op( type='fused_feedforward', inputs={ 'X': x, 'Linear1Weight': linear1_weight, 'Linear1Bias': linear1_bias, 'Linear2Weight': linear2_weight, 'Linear2Bias': linear2_bias, 'Ln1Scale': ln1_scale, 'Ln1Bias': ln1_bias, 'Ln2Scale': ln2_scale, 'Ln2Bias': ln2_bias, }, outputs={ 'Out': out, 'Dropout1Mask': dropout1_mask, 'Dropout2Mask': dropout2_mask, 'Ln1Mean': ln1_mean, 'Ln1Variance': ln1_variance, 'Ln2Mean': ln2_mean, 'Ln2Variance': ln2_variance, 'Linear1Out': linear1_out, 'Ln1Out': ln1_out, 'Dropout1Out': dropout1_out, 'Dropout2Out': dropout2_out, }, attrs={ 'dropout1_rate': dropout1_rate, 'dropout2_rate': dropout2_rate, 'act_method': activation, 'pre_layer_norm': pre_layer_norm, 'ln1_epsilon': ln1_epsilon, 'ln2_epsilon': ln2_epsilon, 'dropout1_is_test': not training, 'dropout2_is_test': not training, 'dropout1_fix_seed': seed is not None, 'dropout2_fix_seed': seed is not None, 'dropout1_seed': seed if seed is not None else 0, 'dropout2_seed': seed if seed is not None else 0, 'dropout1_implementation': mode, 'dropout2_implementation': mode }) return out def fused_multi_head_attention(x, qkv_weight, linear_weight, pre_layer_norm=False, pre_ln_scale=None, pre_ln_bias=None, ln_scale=None, ln_bias=None, pre_ln_epsilon=1e-05, qkv_bias=None, linear_bias=None, cache_kv=None, attn_mask=None, dropout_rate=0.5, attn_dropout_rate=0.5, ln_epsilon=1e-05, training=True, mode='upscale_in_train', ring_id=-1, name=None): r""" Attention mapps queries and a set of key-value pairs to outputs, and Multi-Head Attention performs multiple parallel attention to jointly attending to information from different representation subspaces. This API only support self_attention. The pseudo code is as follows: .. code-block:: python if pre_layer_norm: out = layer_norm(x) out = linear(out) + qkv) + bias else: out = linear(x) + bias out = transpose(out, perm=[2, 0, 3, 1, 4]) # extract q, k and v from out. q = out[0:1,::] k = out[1:2,::] v = out[2:3,::] out = q * k^t out = attn_mask + out out = softmax(out) out = dropout(out) out = out * v out = transpose(out, perm=[0, 2, 1, 3]) out = out_linear(out) if pre_layer_norm: out = x + dropout(linear_bias + out) else: out = layer_norm(x + dropout(linear_bias + out)) Parameters: x (Tensor): The input tensor of fused_multi_head_attention. The shape is `[batch\_size, sequence\_len, embed\_dim]`. qkv_weight (Tensor): The qkv weight tensor. The shape is `[3, num_head, dim_head, dim_embed]`. linear_weight (Tensor): The linear weight tensor. The shape is `[embed_dim, embed_dim]`. pre_layer_norm (bool, optional): whether it is pre_layer_norm (True) or post_layer_norm architecture (False). Default False. pre_ln_scale (Tensor, optional): The weight tensor of pre layernorm. Default None. pre_ln_bias (Tensor, optional): The bias tensor of pre layernorm. Default None. ln_scale (Tensor, optional): The weight tensor of layernorm. Default None. ln_bias (Tensor, optional): The bias tensor of layernorm. Default None. pre_ln_epsilon (float, optional): Small float value added to denominator of the pre layer_norm to avoid dividing by zero. Default is 1e-5. qkv_bias (Tensor, optional): The bias of qkv computation. The shape is `[3, num_head, dim_head]`. Default None. linear_bias (Tensor, optional): The bias of linear. The shape is `[embed_dim]`. Default None. cache_kv (Tensor, optional): For generation model, cache structure. The shape is `[2, bsz, num_head, seq_len, head_dim]`. Default None. attn_mask (Tensor, optional): A tensor used in multi-head attention to prevents attention to some unwanted positions, usually the paddings or the subsequent positions. It is a tensor with shape broadcasted to `[batch_size, n_head, sequence_length, sequence_length]`. When the data type is bool, the unwanted positions have `False` values and the others have `True` values. When the data type is int, the unwanted positions have 0 values and the others have 1 values. When the data type is float, the unwanted positions have `-INF` values and the others have 0 values. It can be None when nothing wanted or needed to be prevented attention to. Default None. dropout_rate (float, optional): The dropout probability used on attention weights to drop some attention targets for the dropout after attention. 0 for no dropout. Default 0.5. attn_dropout_rate (float, optional): The dropout probability used on attention weights to drop some attention targets for the dropout in attention. 0 for no dropout. Default 0.5. ln_epsilon (float, optional): Small float value added to denominator of layer_norm to avoid dividing by zero. Default is 1e-5. training (bool, optional): A flag indicating whether it is in train phrase or not. Default True. mode (str, optional): ['upscale_in_train'(default) | 'downscale_in_infer'] 1. upscale_in_train(default), upscale the output at training time - train: out = input * mask / ( 1.0 - p ) - inference: out = input 2. downscale_in_infer, downscale the output at inference - train: out = input * mask - inference: out = input * (1.0 - p) ring_id (int, optional): For distributed forward in mp, only support NCCL and forward. Default is -1, means not using mp name (str, optional): Name for the operation (optional, default is None). For more information, please refer to :ref:`api_guide_Name`. Returns: Tensor: The output Tensor, the data type and shape is same as `x`. Examples: .. code-block:: python # required: gpu import paddle import paddle.incubate.nn.functional as F # input: [batch_size, seq_len, embed_dim] x = paddle.rand(shape=(2, 4, 128), dtype="float32") # qkv_weight: [3, num_head, head_dim, embed_dim] qkv_weight = paddle.rand(shape=(3, 4, 32, 128), dtype="float32") # qkv_bias: [3, num_head, head_dim] qkv_bias = paddle.rand(shape=(3, 4, 32), dtype="float32") # linear_weight: [embed_dim, embed_dim] linear_weight = paddle.rand(shape=(128, 128), dtype="float32") # linear_bias: [embed_dim] linear_bias = paddle.rand(shape=[128], dtype="float32") # self attention mask: [batch_size, num_heads, seq_len, seq_len] attn_mask = paddle.rand(shape=(2, 4, 4, 4), dtype="float32") # output: [batch_size, seq_len, embed_dim] output = F.fused_multi_head_attention( x, qkv_weight, linear_weight, False, None, None, None, None, 1e-5, qkv_bias, linear_bias, None, attn_mask) # [2, 4, 128] print(output.shape) """ seed = None if mode not in ('downscale_in_infer', 'upscale_in_train'): raise ValueError( "mode argument should be 'downscale_in_infer' or 'upscale_in_train'") mode = 'downgrade_in_infer' if mode == 'downscale_in_infer' else mode #semantic transfer if _non_static_mode(): if default_main_program().random_seed != 0: seed = default_main_program().random_seed # pre_ln_mean, pre_ln_variance, pre_ln_out, qkv_out, qkv_bias_out, transpose_out, qk_out, # qktv_out, softmax_out, attn_dropout_mask_out, attn_dropout_out, attn_mask_out, fmha_out, # linear_out, dropout_mask_out, ln_mean_out, ln_var_out, bias_dropout_residual_out, final_out assert len(qkv_weight.shape ) == 4, "The dims of the shape of qkv_weight should be 4." assert qkv_weight.shape[ 0] == 3, "The shape of qkv_weight should be [3, num_head, head_dim, embed_dim]." assert qkv_weight.shape[3] == x.shape[ 2], "The 3rd dim of qkv_weight and 2nd dim of x should be the same, i.e., embed_dim." assert qkv_weight.shape[1] * qkv_weight.shape[2] == qkv_weight.shape[ 3], "embed_dim must be divisible by num_heads." _, _, _, _, _, _, _, _, _, _, _, _, _, _, _, _, _, _, cache_kv_out, final_out = _C_ops.fused_attention( x, pre_ln_scale, pre_ln_bias, qkv_weight, qkv_bias, cache_kv, attn_mask, linear_weight, linear_bias, ln_scale, ln_bias, 'pre_layer_norm', pre_layer_norm, 'epsilon', pre_ln_epsilon, 'dropout_rate', dropout_rate, 'attn_dropout_rate', attn_dropout_rate, 'ln_epsilon', ln_epsilon, 'attn_dropout_is_test', not training, 'dropout_is_test', not training, 'attn_dropout_fix_seed', seed is not None, 'dropout_fix_seed', seed is not None, 'attn_dropout_seed', seed if seed is not None else 0, 'dropout_seed', seed if seed is not None else 0, 'attn_dropout_implementation', mode, 'dropout_implementation', mode, 'ring_id', ring_id) if cache_kv is not None: return final_out, cache_kv_out return final_out else: helper = LayerHelper('fused_multi_head_attention', **locals()) dtype = x.dtype # check dtypes check_variable_and_dtype(x, 'x', ['float16', 'float32', 'float64'], 'fused_multihead_attention') check_dtype(dtype, 'dtype', ['float16', 'float32', 'float64'], 'fused_multi_head_attention') # set inputs inputs = dict() inputs['X'] = [x] if pre_ln_scale: inputs['LnScale'] = [pre_ln_scale] if pre_ln_bias: inputs['LnBias'] = [pre_ln_bias] inputs['QKVW'] = [qkv_weight] if qkv_bias is not None: inputs['QKVBias'] = [qkv_bias] inputs['SrcMask'] = attn_mask inputs['OutLinearW'] = [linear_weight] if linear_bias is not None: inputs['OutLinearBias'] = [linear_bias] if ln_scale: inputs['Ln2Scale'] = [ln_scale] if ln_bias: inputs['Ln2Bias'] = [ln_bias] if cache_kv: inputs['CacheKV'] = [cache_kv] if (seed is None or seed == 0) and helper.main_program.random_seed != 0: seed = helper.main_program.random_seed # set attrs attrs = { 'pre_layer_norm': pre_layer_norm, 'epsilon': pre_ln_epsilon, 'ln_epsilon': ln_epsilon, 'dropout_rate': dropout_rate, 'attn_dropout_rate': attn_dropout_rate, 'attn_dropout_is_test': not training, 'dropout_is_test': not training, 'attn_dropout_fix_seed': seed is not None, 'dropout_fix_seed': seed is not None, 'attn_dropout_seed': seed if seed is not None else 0, 'dropout_seed': seed if seed is not None else 0, 'attn_dropout_implementation': mode, 'dropout_implementation': mode, 'ring_id': ring_id } # set outputs pre_ln_mean_out = helper.create_variable_for_type_inference( dtype=dtype, stop_gradient=True) pre_ln_variance_out = helper.create_variable_for_type_inference( dtype=dtype, stop_gradient=True) pre_ln_out = helper.create_variable_for_type_inference(dtype=dtype) qkv_out = helper.create_variable_for_type_inference(dtype=dtype) qkv_bias_out = helper.create_variable_for_type_inference(dtype=dtype) transpose_out = helper.create_variable_for_type_inference(dtype=dtype) qk_out = helper.create_variable_for_type_inference(dtype=dtype) qktv_out = helper.create_variable_for_type_inference(dtype=dtype) softmax_out = helper.create_variable_for_type_inference(dtype=dtype) attn_dropout_mask_out = helper.create_variable_for_type_inference( dtype=core.VarDesc.VarType.UINT8, stop_gradient=True) attn_dropout_out = helper.create_variable_for_type_inference( dtype=dtype) attn_mask_out = helper.create_variable_for_type_inference(dtype=dtype) fmha_out = helper.create_variable_for_type_inference(dtype=dtype) out_linear_out = helper.create_variable_for_type_inference(dtype=dtype) dropout_mask_out = helper.create_variable_for_type_inference( dtype=core.VarDesc.VarType.UINT8, stop_gradient=True) ln_mean_out = helper.create_variable_for_type_inference( dtype=dtype, stop_gradient=True) ln_variance_out = helper.create_variable_for_type_inference( dtype=dtype, stop_gradient=True) bias_dropout_residual_out = helper.create_variable_for_type_inference( dtype=dtype) final_out = helper.create_variable_for_type_inference(dtype=dtype) cache_kv_out = helper.create_variable_for_type_inference(dtype=dtype) helper.append_op( type='fused_attention', inputs=inputs, outputs={ "LnMean": pre_ln_mean_out, "LnVariance": pre_ln_variance_out, "LnOut": pre_ln_out, "QKVOut": qkv_out, "QKVBiasOut": qkv_bias_out, "TransposeOut2": transpose_out, "QKOut": qk_out, "QKTVOut": qktv_out, "SoftmaxOut": softmax_out, "AttnDropoutMaskOut": attn_dropout_mask_out, "AttnDropoutOut": attn_dropout_out, "SrcMaskOut": attn_mask_out, "FMHAOut": fmha_out, "OutLinearOut": out_linear_out, "DropoutMaskOut": dropout_mask_out, "Ln2Mean": ln_mean_out, "Ln2Variance": ln_variance_out, "BiasDropoutResidualOut": bias_dropout_residual_out, 'Y': final_out, 'CacheKVOut': cache_kv_out }, attrs=attrs) return (final_out, cache_kv_out) if cache_kv else final_out def fused_multi_transformer(x, ln_scales, ln_biases, qkv_weights, qkv_biases, linear_weights, linear_biases, ffn_ln_scales, ffn_ln_biases, ffn1_weights, ffn1_biases, ffn2_weights, ffn2_biases, pre_layer_norm=True, epsilon=1e-05, cache_kvs=None, time_step=None, attn_mask=None, dropout_rate=0.0, activation="gelu", training=False, mode='upscale_in_train', ring_id=-1, name=None): r""" This is a fusion operator to compute multi transformer layers in transformer model architecture. This operator only supports running on GPU. The function of the transformer layer is consistent with the following pseudo code: .. code-block:: python if pre_layer_norm: out = layer_norm(x) out = qkv_linear(out) + qkv_bias else: out = qkv_linear(x) + qkv_bias out = transpose(out, perm=[2, 0, 3, 1, 4]) # extract q, k and v from out. q = out[0:1, ::] k = out[1:2, ::] v = out[2:3, ::] out = q * k^t out = attn_mask + out out = softmax(out) out = dropout(out) out = out * v out = transpose(out, perm=[0, 2, 1, 3]) out = linear(out) if pre_layer_norm: out = x + dropout(out + bias) else: out = layer_norm(x + dropout(out + bias)) residual = out; if pre_layer_norm: out = ffn_layer_norm(out) out = ffn1_linear(out) out = dropout(activation(out + ffn1_bias)) out = ffn2_linear(out) out = residual + dropout(out + ffn2_bias) if not pre_layer_norm: out = ffn_layer_norm(out) Args: x (Tensor): the input tensor could be 3-D tensor, the input data type could be float16 or float32, the shape is `[batch\_size, sequence\_length, d\_model]`. ln_scales (list(Tensor)|tuple(Tensor)): The weight tensors of attention layer_norm, the shape is `[d\_model]`. ln_biases (list(Tensor)|tuple(Tensor)): The bias tensors of attention layer_norm. the shape is `[d\_model]`. qkv_weights (list(Tensor)|tuple(Tensor)): The weight tensors of attention qkv computation. The shape is `[3, num\_head, dim\_head, d\_model]`. qkv_biases (list(Tensor)|tuple(Tensor)|None): The bias tensors of attention qkv computation. The shape is `[3, num\_head, dim\_head]`. linear_weights (list(Tensor)|tuple(Tensor)): The weight tensors of attention linear. The shape is `[num\_head * dim\_head, d\_model]`. linear_biases (list(Tensor)|tuple(Tensor)|None): The bias tensors of attention linear. The shape is `[d\_model]`. ffn_ln_scales (list(Tensor)|tuple(Tensor)): The weight tensors of feedforward layer_norm, the shape is `[d\_model]` ffn_ln_biases (list(Tensor)|tuple(Tensor)): The bias tensors of feedforward layer_norm, the shape is `[d\_model]` ffn1_weights (list(Tensor)|tuple(Tensor)): The weight tensors of feedforward first linear, the shape is `[d\_model, dim\_feedforward]`. ffn1_biases (list(Tensor)|tuple(Tensor)|None): The bias tensors of feedforward first linear, the shape is `[dim\_feedforward]`. ffn2_weights (list(Tensor)|tuple(Tensor)): The weight tensors of feedforward second linear, the shape is `[dim\_feedforward, d\_model]`. ffn2_biases (list(Tensor)|tuple(Tensor)|None): The bias tensors of feedforward second linear, the shape is `[d_model]`. pre_layer_norm (bool, optional): whether it is pre_layer_norm(True) or post_layer_norm(False). Default True. epsilon (float, optional): Small float value added to denominator of the layer_norm to avoid dividing by zero. Default is 1e-5. cache_kvs (list(Tensor)|tuple(Tensor), optional): The cache structure tensors for the generation model. The shape is `[2, bsz, num\_head, max\_seq\_len, head\_dim]`. Default None. time_step (Tensor, optional): The time step tensor for the generation model. Which used in decode stage, to represent the time step, that is, the real seq_len of CacheKV. The shape is `[1]`, must be in CPUPlace. Default None. attn_mask (Tensor, optional): A tensor used in multi-head attention to prevents attention to some unwanted positions, usually the paddings or the subsequent positions. It is a tensor with shape `[batch_size, 1, sequence_length, sequence_length]`. Default None. dropout_rate (float, optional): The dropout probability of setting units to zero. Default 0.0. activation (str, optional): The activation. Default "gelu". training (bool, optional): A flag indicating whether it is in train phrase or not. Default False. mode (str, optional): ['upscale_in_train'(default) | 'downscale_in_infer'] 1. upscale_in_train(default), upscale the output at training time - train: out = input * mask / ( 1.0 - p ) - inference: out = input 2. downscale_in_infer, downscale the output at inference - train: out = input * mask - inference: out = input * (1.0 - p) ring_id (int, optional): For distributed forward in tensor model parallel, only support NCCL. Default is -1, means not using mp. name (str, optional): Name for the operation (optional, default is None). For more information, please refer to :ref:`api_guide_Name`. Returns: Tensor|tuple: If `cache_kvs` is None, return a tensor that has the same shape and data type with `x`, representing the output of Transformer layers. If `cache_kvs` is not None, return the tuple (output, cache_kvs), which output is the output of Transformer layers, cache_kvs is inplace with input `cache_kvs`. Examples: .. code-block:: python # required: gpu import paddle import paddle.incubate.nn.functional as F import numpy as np # input: [batch_size, seq_len, embed_dim] x = paddle.rand(shape=(2, 4, 128), dtype="float32") # ln_scale: [embed_dim], ln_bias: [embed_dim] ln_scale = paddle.rand(shape=(128,), dtype="float32") ln_bias = paddle.rand(shape=(128,), dtype="float32") # qkv_weight: [3, num_head, head_dim, embed_dim], qkv_bias: [3, num_head, head_dim] qkv_weight = paddle.rand(shape=(3, 4, 32, 128), dtype="float32") qkv_bias = paddle.rand(shape=(3, 4, 32), dtype="float32") # linear_weight: [embed_dim, embed_dim], linear_bias: [embed_dim] linear_weight = paddle.rand(shape=(128, 128), dtype="float32") linear_bias = paddle.rand(shape=(128,), dtype="float32") # ffn_ln_scale: [embed_dim], ffn_ln_bias: [embed_dim] ffn_ln_scale = paddle.rand(shape=(128,), dtype="float32") ffn_ln_bias = paddle.rand(shape=(128,), dtype="float32") # ffn1_weight: [embed_dim, 4*embed_dim], ffn1_bias: [4*embed_dim] ffn1_weight = paddle.rand(shape=(128, 4*128), dtype="float32") ffn1_bias = paddle.rand(shape=(4*128,), dtype="float32") # ffn2_weight: [4*embed_dim, embed_dim], ffn2_bias: [embed_dim] ffn2_weight = paddle.rand(shape=(4*128, 128), dtype="float32") ffn2_bias = paddle.rand(shape=(128,), dtype="float32") # self attention mask: [batch_size, 1, seq_len, seq_len] attn_mask = paddle.rand(shape=(2, 1, 4, 4), dtype="float32") # output: [batch_size, seq_len, embed_dim] output = F.fused_multi_transformer( x, [ln_scale], [ln_bias], [qkv_weight], [qkv_bias], [linear_weight], [linear_bias], [ffn_ln_scale], [ffn_ln_bias], [ffn1_weight], [ffn1_bias], [ffn2_weight], [ffn2_bias], attn_mask=attn_mask) # [2, 4, 128] print(output.shape) """ if mode not in ('downscale_in_infer', 'upscale_in_train'): raise ValueError( "mode argument should be 'downscale_in_infer' or 'upscale_in_train'") mode = 'downgrade_in_infer' if mode == 'downscale_in_infer' else mode #semantic transfer if _non_static_mode(): cache_kv_out, final_out = _C_ops.fused_multi_transformer( x, ln_scales, ln_biases, qkv_weights, qkv_biases, cache_kvs, time_step, attn_mask, linear_weights, linear_biases, ffn_ln_scales, ffn_ln_biases, ffn1_weights, ffn1_biases, ffn2_weights, ffn2_biases, cache_kvs, 'pre_layer_norm', pre_layer_norm, 'epsilon', epsilon, 'dropout_rate', dropout_rate, 'dropout_is_test', not training, 'dropout_implementation', mode, 'act_method', activation, 'ring_id', ring_id) if cache_kvs is not None: return final_out, cache_kv_out return final_out else: helper = LayerHelper('fused_multi_transformer', **locals()) dtype = x.dtype # check dtypes check_variable_and_dtype(x, 'x', ['float16', 'float32'], 'fused_multi_transformer') check_dtype(dtype, 'dtype', ['float16', 'float32'], 'fused_multi_transformer') # set inputs inputs = dict() inputs['X'] = [x] inputs['LnScale'] = ln_scales inputs['LnBias'] = ln_biases inputs['QKVW'] = qkv_weights if qkv_biases is not None: inputs['QKVBias'] = qkv_biases if cache_kvs is not None: assert len(cache_kvs) == len(qkv_weights) inputs['CacheKV'] = cache_kvs if time_step is not None: inputs['TimeStep'] = time_step inputs['SrcMask'] = attn_mask inputs['OutLinearW'] = linear_weights if linear_biases is not None: inputs['OutLinearBias'] = linear_biases inputs['FFNLnScale'] = ffn_ln_scales inputs['FFNLnBias'] = ffn_ln_biases inputs['FFN1Weight'] = ffn1_weights if ffn1_biases is not None: inputs['FFN1Bias'] = ffn1_biases inputs['FFN2Weight'] = ffn2_weights if ffn2_biases is not None: inputs['FFN2Bias'] = ffn2_biases # set attrs attrs = { 'pre_layer_norm': pre_layer_norm, 'epsilon': epsilon, 'dropout_rate': dropout_rate, 'dropout_is_test': not training, 'dropout_implementation': mode, 'act_method': activation, 'ring_id': ring_id } outputs = dict() final_out = helper.create_variable_for_type_inference(dtype=dtype) outputs['Out'] = final_out if cache_kvs: # NOTE: inplace outputs['CacheKVOut'] = cache_kvs helper.append_op( type='fused_multi_transformer', inputs=inputs, outputs=outputs, attrs=attrs) return (final_out, cache_kvs) if cache_kvs else final_out