# Copyright (c) 2022 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. import copy import paddle import paddle.nn as nn __all__ = ['fuse_conv_bn'] def fuse_conv_bn(model): is_train = False if model.training: model.eval() is_train = True fuse_list = [] tmp_pair = [None, None] for name, layer in model.named_sublayers(): if isinstance(layer, nn.Conv2D): tmp_pair[0] = name if isinstance(layer, nn.BatchNorm2D): tmp_pair[1] = name if tmp_pair[0] and tmp_pair[1] and len(tmp_pair) == 2: fuse_list.append(tmp_pair) tmp_pair = [None, None] model = fuse_layers(model, fuse_list) if is_train: model.train() return model def find_parent_layer_and_sub_name(model, name): """ Given the model and the name of a layer, find the parent layer and the sub_name of the layer. For example, if name is 'block_1/convbn_1/conv_1', the parent layer is 'block_1/convbn_1' and the sub_name is `conv_1`. Args: model(paddle.nn.Layer): the model to be quantized. name(string): the name of a layer Returns: parent_layer, subname """ assert isinstance(model, nn.Layer), \ "The model must be the instance of paddle.nn.Layer." assert len(name) > 0, "The input (name) should not be empty." last_idx = 0 idx = 0 parent_layer = model while idx < len(name): if name[idx] == '.': sub_name = name[last_idx:idx] if hasattr(parent_layer, sub_name): parent_layer = getattr(parent_layer, sub_name) last_idx = idx + 1 idx += 1 sub_name = name[last_idx:idx] return parent_layer, sub_name class Identity(nn.Layer): '''a layer to replace bn or relu layers''' def __init__(self, *args, **kwargs): super(Identity, self).__init__() def forward(self, input): return input def fuse_layers(model, layers_to_fuse, inplace=False): ''' fuse layers in layers_to_fuse Args: model(nn.Layer): The model to be fused. layers_to_fuse(list): The layers' names to be fused. For example,"fuse_list = [["conv1", "bn1"], ["conv2", "bn2"]]". A TypeError would be raised if "fuse" was set as True but "fuse_list" was None. Default: None. inplace(bool): Whether apply fusing to the input model. Default: False. Return fused_model(paddle.nn.Layer): The fused model. ''' if not inplace: model = copy.deepcopy(model) for layers_list in layers_to_fuse: layer_list = [] for layer_name in layers_list: parent_layer, sub_name = find_parent_layer_and_sub_name(model, layer_name) layer_list.append(getattr(parent_layer, sub_name)) new_layers = _fuse_func(layer_list) for i, item in enumerate(layers_list): parent_layer, sub_name = find_parent_layer_and_sub_name(model, item) setattr(parent_layer, sub_name, new_layers[i]) return model def _fuse_func(layer_list): '''choose the fuser method and fuse layers''' types = tuple(type(m) for m in layer_list) fusion_method = types_to_fusion_method.get(types, None) new_layers = [None] * len(layer_list) fused_layer = fusion_method(*layer_list) for handle_id, pre_hook_fn in layer_list[0]._forward_pre_hooks.items(): fused_layer.register_forward_pre_hook(pre_hook_fn) del layer_list[0]._forward_pre_hooks[handle_id] for handle_id, hook_fn in layer_list[-1]._forward_post_hooks.items(): fused_layer.register_forward_post_hook(hook_fn) del layer_list[-1]._forward_post_hooks[handle_id] new_layers[0] = fused_layer for i in range(1, len(layer_list)): identity = Identity() identity.training = layer_list[0].training new_layers[i] = identity return new_layers def _fuse_conv_bn(conv, bn): '''fuse conv and bn for train or eval''' assert(conv.training == bn.training),\ "Conv and BN both must be in the same mode (train or eval)." if conv.training: assert bn._num_features == conv._out_channels, 'Output channel of Conv2d must match num_features of BatchNorm2d' raise NotImplementedError else: return _fuse_conv_bn_eval(conv, bn) def _fuse_conv_bn_eval(conv, bn): '''fuse conv and bn for eval''' assert (not (conv.training or bn.training)), "Fusion only for eval!" fused_conv = copy.deepcopy(conv) fused_weight, fused_bias = _fuse_conv_bn_weights( fused_conv.weight, fused_conv.bias, bn._mean, bn._variance, bn._epsilon, bn.weight, bn.bias) fused_conv.weight.set_value(fused_weight) if fused_conv.bias is None: fused_conv.bias = paddle.create_parameter( shape=[fused_conv._out_channels], is_bias=True, dtype=bn.bias.dtype) fused_conv.bias.set_value(fused_bias) return fused_conv def _fuse_conv_bn_weights(conv_w, conv_b, bn_rm, bn_rv, bn_eps, bn_w, bn_b): '''fuse weights and bias of conv and bn''' if conv_b is None: conv_b = paddle.zeros_like(bn_rm) if bn_w is None: bn_w = paddle.ones_like(bn_rm) if bn_b is None: bn_b = paddle.zeros_like(bn_rm) bn_var_rsqrt = paddle.rsqrt(bn_rv + bn_eps) conv_w = conv_w * \ (bn_w * bn_var_rsqrt).reshape([-1] + [1] * (len(conv_w.shape) - 1)) conv_b = (conv_b - bn_rm) * bn_var_rsqrt * bn_w + bn_b return conv_w, conv_b types_to_fusion_method = {(nn.Conv2D, nn.BatchNorm2D): _fuse_conv_bn, }