# Copyright (c) 2020 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.dygraph import layers from paddle.fluid import core from paddle.fluid import dygraph_utils from paddle.fluid import unique_name from paddle.fluid.param_attr import ParamAttr from paddle.fluid.framework import _varbase_creator from paddle.fluid.framework import in_dygraph_mode from paddle.fluid.initializer import Constant from paddle.fluid.data_feeder import check_variable_and_dtype from paddle.nn import functional as F __all__ = [ 'FakeQuantMovingAverage', 'FakeQuantAbsMax', 'FakeChannelWiseQuantDequantAbsMax', 'QuantizedConv2D', 'QuantizedLinear', 'QuantizedNoweightLayer', 'MovingAverageAbsMaxScale' ] class FakeQuantMovingAverage(layers.Layer): r""" FakeQuantMovingAverage layer does the moving_average_abs_max quant and then dequant. Its computational formula is described as below: :math:`scale = (moving\_rate*accum+max(abs(x)))/(moving\_rate*state+1)` :math:`range = 2^{bit\_length - 1} - 1` :math:`Out = round(X / scale * range) * scale / range` """ def __init__(self, name=None, moving_rate=0.9, quant_bits=8, dtype='float32'): super(FakeQuantMovingAverage, self).__init__() self._moving_rate = moving_rate self._quant_bits = quant_bits scale_prefix = "{}.scale".format( name) if name else 'quant_dequant.scale' scale_attr = ParamAttr( name=unique_name.generate(scale_prefix), initializer=Constant(0.001), trainable=False) self._scale = self.create_parameter( shape=[1], attr=scale_attr, dtype=dtype) self._scale.stop_gradient = True state_prefix = "{}.state".format( name) if name else 'quant_dequant.state' state_attr = ParamAttr( name=unique_name.generate(state_prefix), initializer=Constant(1), trainable=False) self._state = self.create_parameter( shape=[1], attr=state_attr, dtype=dtype) self._state.stop_gradient = True accum_prefix = "{}.accum".format( name) if name else 'quant_dequant.accum' accum_attr = ParamAttr( name=unique_name.generate(accum_prefix), initializer=Constant(1), trainable=False) self._accum = self.create_parameter( shape=[1], attr=accum_attr, dtype=dtype) self._accum.stop_gradient = True def forward(self, input): if in_dygraph_mode(): attrs = ('moving_rate', self._moving_rate, 'bit_length', self._quant_bits, 'is_test', not self.training) quant_out = _varbase_creator( type=input.type, name="{}.quantized.dequantized".format(input.name), shape=input.shape, dtype=input.dtype, persistable=False) state = self._state if self.training else None accum = self._accum if self.training else None out, _, _, _ = core.ops.fake_quantize_dequantize_moving_average_abs_max( input, self._scale, accum, state, quant_out, self._scale, state, accum, *attrs) return out check_variable_and_dtype(input, 'input', ['float32'], "FakeQuantMovingAverage") attrs = { 'moving_rate': self._moving_rate, 'bit_length': self._quant_bits, 'is_test': not self.training } inputs = {"X": [input], "InScale": [self._scale]} quant_out = self._helper.create_variable( name="{}.quantized.dequantized".format(input.name), dtype=input.dtype, type=core.VarDesc.VarType.LOD_TENSOR, persistable=False, stop_gradient=False) outputs = {"Out": [quant_out], "OutScale": [self._scale]} if self.training: inputs['InState'] = [self._state] inputs['InAccum'] = [self._accum] outputs['OutState'] = [self._state] outputs['OutAccum'] = [self._accum] self._helper.append_op( type="fake_quantize_dequantize_moving_average_abs_max", inputs=inputs, outputs=outputs, attrs=attrs) return quant_out class FakeQuantAbsMax(layers.Layer): r""" FakeQuantAbsMax layer does the abs_max quant and then dequant. Its computational formula is described as below: :math:`scale = max(abs(X))` :math:`range = 2^{bit\_length - 1} - 1` :math:`Out = round(X / scale * range) * scale / range` """ def __init__(self, name=None, quant_bits=8, dtype='float32', quant_on_weight=False): super(FakeQuantAbsMax, self).__init__() self._quant_bits = quant_bits self._name = name scale_prefix = "{}.scale".format( name) if name else 'quant_dequant.scale' self._scale_name = unique_name.generate(scale_prefix) if quant_on_weight: scale_attr = ParamAttr( name=self._scale_name, initializer=Constant(0.0), trainable=False) self._scale = self.create_parameter( shape=[1], attr=scale_attr, dtype=self._dtype) self._scale.stop_gradient = True else: self._scale = None def forward(self, input): if in_dygraph_mode(): attrs = ('bit_length', self._quant_bits) quant_out = _varbase_creator( type=input.type, name="{}.quantized.dequantized".format(input.name), shape=input.shape, dtype=input.dtype, persistable=False) out_scale = self._scale if not out_scale: out_scale = _varbase_creator( type=core.VarDesc.VarType.LOD_TENSOR, name=self._scale_name, shape=[1], dtype=self._dtype, persistable=False) out_scale.stop_gradient = True out, _, = core.ops.fake_quantize_dequantize_abs_max( input, quant_out, out_scale, *attrs) return out check_variable_and_dtype(input, 'input', ['float32'], "FakeQuantAbsMax") attrs = {'bit_length': self._quant_bits} inputs = {"X": [input]} quant_out = self._helper.create_variable( name="{}.quantized.dequantized".format(input.name), dtype=input.dtype, type=core.VarDesc.VarType.LOD_TENSOR, persistable=False, stop_gradient=False) out_scale = self._scale if not out_scale: out_scale = self._helper.create_variable( name=self._scale_name, dtype=self._dtype, type=core.VarDesc.VarType.LOD_TENSOR, persistable=False, stop_gradient=True) outputs = {"Out": [quant_out], "OutScale": [out_scale]} self._helper.append_op( type="fake_quantize_dequantize_abs_max", inputs=inputs, outputs=outputs, attrs=attrs) return quant_out class FakeChannelWiseQuantDequantAbsMax(layers.Layer): def __init__(self, name=None, channel_num=None, quant_bits=8, quant_axis=0, dtype='float32', quant_on_weight=False): assert quant_on_weight == True, "Channel_wise only can be used on weight quantization." super(FakeChannelWiseQuantDequantAbsMax, self).__init__() self._quant_bits = quant_bits self._quant_axis = quant_axis self._dtype = dtype self._name = name self._channel_num = channel_num scale_prefix = "{}.scale".format( name) if name else 'quant_dequant.scale' self._scale_name = unique_name.generate(scale_prefix) if quant_on_weight: scale_attr = ParamAttr( name=self._scale_name, initializer=Constant(0.0), trainable=False) self._scale = self.create_parameter( shape=[self._channel_num], attr=scale_attr, dtype=self._dtype) self._scale.stop_gradient = True else: self._scale = None def forward(self, input): if in_dygraph_mode(): attrs = ('bit_length', self._quant_bits, 'quant_axis', self._quant_axis) quant_out = _varbase_creator( type=input.type, name="{}.quantized.dequantized".format(input.name), shape=input.shape, dtype=input.dtype, persistable=False) out_scale = self._scale if out_scale is None: out_scale = _varbase_creator( type=core.VarDesc.VarType.LOD_TENSOR, name=self._scale_name, shape=[self._channel_num], dtype=self._dtype, persistable=False) out_scale.stop_gradient = True out, _, = core.ops.fake_channel_wise_quantize_dequantize_abs_max( input, quant_out, out_scale, *attrs) return out check_variable_and_dtype(input, 'input', ['float32'], "FakeChannelWiseQuantDequantAbsMax") attrs = {'bit_length': self._quant_bits, 'quant_axis': self._quant_axis} inputs = {"X": [input]} quant_out = self._helper.create_variable( name="{}.quantized.dequantized".format(input.name), dtype=input.dtype, type=core.VarDesc.VarType.LOD_TENSOR, persistable=False, stop_gradient=False) out_scale = self._scale if not out_scale: out_scale = self._helper.create_variable( name=self._scale_name, dtype=self._dtype, type=core.VarDesc.VarType.LOD_TENSOR, persistable=False, stop_gradient=True) outputs = {"Out": [quant_out], "OutScale": [out_scale]} self._helper.append_op( type="fake_channel_wise_quantize_dequantize_abs_max", inputs=inputs, outputs=outputs, attrs=attrs) return quant_out def _get_fake_quant_type(quant_type, **kwargs): call_args = { "name": kwargs.get("name", None), "quant_bits": kwargs.get("quant_bits", 8), "dtype": kwargs.get("dtype", "float32") } if quant_type == 'abs_max': call_args["quant_on_weight"] = kwargs.get("quant_on_weight", False) elif quant_type == 'moving_average_abs_max': call_args["moving_rate"] = kwargs.get("moving_rate", 0.9) elif quant_type == 'channel_wise_abs_max': call_args["quant_on_weight"] = kwargs.get("quant_on_weight", False) call_args["channel_num"] = kwargs.get("channel_num", None) call_args["quant_axis"] = kwargs.get("quant_axis", 0) assert call_args["channel_num"] is not None, ( "You need to input channel_num" "when you use channel_wise_abs_max strategy.") fake_quant_map = { 'abs_max': FakeQuantAbsMax, 'moving_average_abs_max': FakeQuantMovingAverage, 'channel_wise_abs_max': FakeChannelWiseQuantDequantAbsMax } return fake_quant_map[quant_type](**call_args) class QuantizedConv2D(layers.Layer): """ The computational logic of QuantizedConv2D is the same with Conv2D. The only difference is that its inputs are all fake quantized. """ def __init__(self, layer, weight_bits=8, activation_bits=8, moving_rate=0.9, weight_quantize_type='abs_max', activation_quantize_type='abs_max', weight_pre_layer=None, act_pre_layer=None, weight_quant_layer=None, act_quant_layer=None): super(QuantizedConv2D, self).__init__() # For Conv2D self._groups = getattr(layer, '_groups') self._stride = getattr(layer, '_stride') self._padding = getattr(layer, '_padding') self._padding_mode = getattr(layer, '_padding_mode') if self._padding_mode != 'zeros': self._reversed_padding_repeated_twice = getattr( layer, '_reversed_padding_repeated_twice') self._dilation = getattr(layer, '_dilation') self._data_format = getattr(layer, '_data_format') self.weight = getattr(layer, 'weight') self.bias = getattr(layer, 'bias') # For FakeQuant self._conv2d_quant_axis = 0 if weight_quant_layer is not None: self._fake_quant_weight = weight_quant_layer() else: self._fake_quant_weight = _get_fake_quant_type( weight_quantize_type, name=self.weight.name, moving_rate=moving_rate, quant_bits=weight_bits, dtype=self._dtype, quant_on_weight=True, channel_num=self.weight.shape[self._conv2d_quant_axis], quant_axis=self._conv2d_quant_axis) if act_quant_layer is not None: self._fake_quant_input = act_quant_layer() else: self._fake_quant_input = _get_fake_quant_type( activation_quantize_type, name=layer.full_name(), moving_rate=moving_rate, quant_bits=activation_bits, dtype=self._dtype, quant_on_weight=False) self._act_preprocess = act_pre_layer( ) if act_pre_layer is not None else None self._weight_preprocess = weight_pre_layer( ) if weight_pre_layer is not None else None def forward(self, input): if self._act_preprocess is not None: input = self._act_preprocess(input) quant_input = self._fake_quant_input(input) weight = self.weight if self._weight_preprocess is not None: weight = self._weight_preprocess(self.weight) quant_weight = self._fake_quant_weight(weight) if self._padding_mode != 'zeros': quant_input = F.pad(quant_input, self._reversed_padding_repeated_twice, mode=self._padding_mode, data_format=self._data_format) self._padding = 0 return F.conv2d( quant_input, quant_weight, bias=self.bias, padding=self._padding, stride=self._stride, dilation=self._dilation, groups=self._groups, data_format=self._data_format) class QuantizedLinear(layers.Layer): """ The computational logic of QuantizedLinear is the same with Linear. The only difference is that its inputs are all fake quantized. """ def __init__(self, layer, weight_bits=8, activation_bits=8, moving_rate=0.9, weight_quantize_type='abs_max', activation_quantize_type='abs_max', weight_pre_layer=None, act_pre_layer=None, weight_quant_layer=None, act_quant_layer=None): super(QuantizedLinear, self).__init__() # For Linear self.weight = getattr(layer, 'weight') self.bias = getattr(layer, 'bias') self.name = getattr(layer, 'name') # For FakeQuant self._linear_quant_axis = 1 if weight_quant_layer is not None: self._fake_quant_weight = weight_quant_layer() else: self._fake_quant_weight = _get_fake_quant_type( weight_quantize_type, name=self.weight.name, moving_rate=moving_rate, quant_bits=weight_bits, dtype=self._dtype, quant_on_weight=True, channel_num=self.weight.shape[self._linear_quant_axis], quant_axis=self._linear_quant_axis) if act_quant_layer is not None: self._fake_quant_input = act_quant_layer() else: self._fake_quant_input = _get_fake_quant_type( activation_quantize_type, name=layer.full_name(), moving_rate=moving_rate, quant_bits=activation_bits, dtype=self._dtype, quant_on_weight=False) self._act_preprocess = act_pre_layer( ) if act_pre_layer is not None else None self._weight_preprocess = weight_pre_layer( ) if weight_pre_layer is not None else None def forward(self, input): if self._act_preprocess is not None: input = self._act_preprocess(input) quant_input = self._fake_quant_input(input) weight = self.weight if self._weight_preprocess is not None: weight = self._weight_preprocess(self.weight) quant_weight = self._fake_quant_weight(weight) out = F.linear( x=quant_input, weight=quant_weight, bias=self.bias, name=self.name) return out class QuantizedNoweightLayer(layers.Layer): def __init__(self, layer, weight_bits=8, activation_bits=8, moving_rate=0.9, *args, **kwargs): super(QuantizedNoweightLayer, self).__init__() self._layer = layer self._fake_quant_input = _get_fake_quant_type( 'moving_average_abs_max', name=layer.full_name(), moving_rate=moving_rate, quant_bits=activation_bits, dtype=self._dtype, quant_on_weight=False) def forward(self, input): quant_input = self._fake_quant_input(input) return self._layer.forward(quant_input) class MovingAverageAbsMaxScale(layers.Layer): def __init__(self, name=None, moving_rate=0.9, dtype='float32'): r""" MovingAverageMaxScale layer is used to calculating the output quantization scale of Layer. Its computational formula is described as below: :math:`scale = (moving\_rate*accum+max(abs(x)))/(moving\_rate*state+1)` :math:`Out = X` """ super(MovingAverageAbsMaxScale, self).__init__() self._moving_rate = moving_rate self._dtype = dtype scale_prefix = '{}.scale'.format(name) if name else 'outscale.scale' name = unique_name.generate(scale_prefix) scale_attr = ParamAttr( name=name, initializer=Constant(1), trainable=False) self._scale = self.create_parameter( shape=[1], attr=scale_attr, dtype=self._dtype) self._scale.stop_gradient = True state_prefix = "{}.state".format(name) if name else 'outscale.state' state_attr = ParamAttr( name=unique_name.generate(state_prefix), initializer=Constant(1), trainable=False) self._state = self.create_parameter( shape=[1], attr=state_attr, dtype=self._dtype) self._state.stop_gradient = True accum_prefix = "{}.accum".format(name) if name else 'outscale.accum' accum_attr = ParamAttr( name=unique_name.generate(accum_prefix), initializer=Constant(1), trainable=False) self._accum = self.create_parameter( shape=[1], attr=accum_attr, dtype=self._dtype) self._accum.stop_gradient = True MovingAverageAbsMaxScale._has_create = True def forward(self, input): if in_dygraph_mode(): attrs = ('moving_rate', self._moving_rate, 'is_test', not self.training) state = self._state if self.training else None accum = self._accum if self.training else None out_scale, _, _ = core.ops.moving_average_abs_max_scale( input, accum, state, self._scale, state, accum, *attrs) return out_scale check_variable_and_dtype(input, 'input', ['float32', 'float64'], 'MovingAverageAbsMaxScale') scale_out = self._scale attrs = {'moving_rate': self._moving_rate, 'is_test': not self.training} inputs = {"X": [input]} outputs = {"OutScale": [scale_out]} if self.training: inputs['InState'] = [self._state] inputs['InAccum'] = [self._accum] outputs['OutState'] = [self._state] outputs['OutAccum'] = [self._accum] self._helper.append_op( type="moving_average_abs_max_scale", inputs=inputs, outputs=outputs, attrs=attrs) return scale_out