# 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. import collections import numpy as np from ..... import compat as cpt from .... import core from ....framework import IrGraph from ....framework import IrNode from ....framework import Operator from .... import unique_name from ....framework import Program, program_guard, default_startup_program from ....data import data from ....layers import mean from ....executor import scope_guard from ....framework import _get_paddle_place __all__ = [ 'QuantizationTransformPass', 'QuantizationFreezePass', 'ConvertToInt8Pass', 'TransformForMobilePass', 'OutScaleForTrainingPass', 'OutScaleForInferencePass', 'AddQuantDequantPass' ] _fake_quant_op_list = [ 'fake_quantize_abs_max', 'fake_quantize_range_abs_max', 'fake_quantize_moving_average_abs_max', 'fake_channel_wise_quantize_abs_max' ] _fake_dequant_op_list = [ 'fake_dequantize_max_abs', 'fake_channel_wise_dequantize_max_abs' ] _fake_quant_dequant_op_list = [ 'fake_quantize_dequantize_moving_average_abs_max' ] _out_scale_op_list = [ "conv2d", "depthwise_conv2d", "mul", "matmul", "matmul_v2", "relu", "leaky_relu", "relu6", "sigmoid", "tanh", "prelu", "swish", "softmax", "batch_norm", "layer_norm", "elementwise_add", "pool2d", "reshape2", "transpose2", "concat", "elementwise_mul", "scale", "slice", "hard_swish", "hard_sigmoid", "conv2d_transpose", "gru", "bilinear_interp", "nearest_interp", "trilinear_interp", "flatten", "flatten2", "transpose", "pad2d", "reshape", "layer_norm", ] # list op real input and output names, to avoid processing input such as AxisTensor. _op_real_in_out_name = { "conv2d": [["Input", "Filter"], ["Output"]], "depthwise_conv2d": [["Input", "Filter"], ["Output"]], "conv2d_transpose": [["Input", "Filter"], ["Output"]], "mul": [["X", "Y"], ["Out"]], "matmul": [["X", "Y"], ["Out"]], "matmul_v2": [["X", "Y"], ["Out"]], "pool2d": [["X"], ["Out"]], "elementwise_add": [["X", "Y"], ["Out"]], "concat": [["X"], ["Out"]], "softmax": [["X"], ["Out"]], "argmax": [["X"], ["Out"]], "transpose": [["X"], ["Out"]], "equal": [["X", "Y"], ["Out"]], "gather": [["X"], ["Out"]], "greater_equal": [["X", "Y"], ["Out"]], "greater_than": [["X", "Y"], ["Out"]], "less_equal": [["X", "Y"], ["Out"]], "less_than": [["X", "Y"], ["Out"]], "mean": [["X"], ["Out"]], "not_equal": [["X", "Y"], ["Out"]], "reshape": [["X"], ["Out"]], "reshape2": [["X"], ["Out"]], "transpose2": [["X"], ["Out"]], "bilinear_interp": [["X"], ["Out"]], "nearest_interp": [["X"], ["Out"]], "trilinear_interp": [["X"], ["Out"]], "slice": [["Input"], ["Out"]], "squeeze": [["X"], ["Out"]], "elementwise_sub": [["X", "Y"], ["Out"]], "relu": [["X"], ["Out"]], "relu6": [["X"], ["Out"]], "leaky_relu": [["X"], ["Out"]], "prelu": [["X"], ["Out"]], "tanh": [["X"], ["Out"]], "swish": [["X"], ["Out"]], "dropout": [["X"], ["Out"]], "batch_norm": [["X"], ["Y"]], "layer_norm": [["X"], ["Y"]], "sigmoid": [["X"], ["Out"]], "elementwise_mul": [["X", "Y"], ["Out"]], "scale": [["X"], ["Out"]], "hard_swish": [["X"], ["Out"]], "hard_sigmoid": [["X"], ["Out"]], "gru": [["Input", "Weight"], ["Hidden"]], "lstm": [["Input", "Weight"], ["Hidden"]], "pad2d": [["X"], ["Out"]], "flatten": [["X"], ["Out"]], "flatten2": [["X"], ["Out"]], "unsqueeze2": [["X"], ["Out"]], "flatten_contiguous_range": [['X'], ["Out", "XShape"]], } _conv_ops = ['conv2d', 'depthwise_conv2d', 'conv2d_transpose'] _channelwise_quant_axis1_ops = [ 'conv2d_transpose', 'mul', 'matmul', 'matmul_v2' ] def _get_op_input_var_names(op): """ Get the input var names of the op. Args: op(IrNode, Operator): the input op. Returns: input_var_names or None. """ assert isinstance(op, (IrNode, Operator)), \ "The input op should be IrNode or Operator." var_names = [] op_name = op.name() if isinstance(op, IrNode) \ else op.type if op_name not in _op_real_in_out_name: return [] name_list = _op_real_in_out_name[op_name][0] for name in name_list: var_name = op.input(name) if isinstance(var_name, list): var_names.extend(var_name) else: var_names.append(var_name) return var_names def _get_input_name_index(op, input_var_name): """Get the input name and index of the var_name in the op""" assert isinstance(op, (IrNode, Operator)), \ "The input op should be IrNode or Operator." op_name = op.name() if isinstance(op, IrNode) \ else op.type if op_name not in _op_real_in_out_name: return None res = None for argname in _op_real_in_out_name[op_name][0]: var_names = op.input(argname) for index, name in enumerate(var_names): if name == input_var_name: res = (argname, index) return res def _get_op_output_var_names(op): """ """ assert isinstance(op, (IrNode, Operator)), \ "The input op should be IrNode or Operator." var_names = [] op_name = op.name() if isinstance(op, IrNode) \ else op.type if op_name not in _op_real_in_out_name: return [] name_list = _op_real_in_out_name[op_name][1] for name in name_list: var_name = op.output(name) if isinstance(var_name, list): var_names.extend(var_name) else: var_names.append(var_name) return var_names def _get_output_name_index(op, output_var_name): """Get the output name and index of the var_name in the op""" assert isinstance(op, (IrNode, Operator)), \ "The input op should be IrNode or Operator." op_name = op.name() if isinstance(op, IrNode) \ else op.type if op_name not in _op_real_in_out_name: return None name_list = _op_real_in_out_name[op_name][1] res = None for name in name_list: var_name = op.output(name) for index, val in enumerate(var_name): if val == output_var_name: res = (name, index) return res def _init_var_node(var_node, value, scope, place): assert isinstance(value, np.ndarray), 'The type of value should be numpy array.' assert scope is not None, \ 'The scope cannot be set None.' assert place is not None, \ 'The place cannot be set None.' tensor = scope.var(var_node.name()).get_tensor() tensor.set(value, place) def _is_input_all_not_persistable(graph, op_node): ''' Analyse the real inputs of the op node are all not persistable. ''' is_input_all_not_persistable = True for var_name in _get_op_input_var_names(op_node): in_node = graph._find_node_by_name(op_node.inputs, var_name) is_input_all_not_persistable = (is_input_all_not_persistable and \ (not in_node.persistable())) return is_input_all_not_persistable def _check_grandchild_op_node(op_node, grandchild_op_name): ''' Check whether the fake_quant node has a grandchild op node named grandchild_op_name. ''' for out1_var_node in op_node.outputs: for out1_op_node in out1_var_node.outputs: for out2_var_node in out1_op_node.outputs: for out2_op_node in out2_var_node.outputs: if out2_op_node.name() == grandchild_op_name: return True return False class QuantizationTransformPass(object): """ Quantize the ops that have weights. Add quant and dequant ops for the quantized ops's inputs. """ _supported_quantizable_op_type = [ 'conv2d', 'depthwise_conv2d', 'conv2d_transpose', 'mul', 'matmul', 'matmul_v2' ] def __init__(self, scope=None, place=None, weight_bits=8, activation_bits=8, activation_quantize_type='abs_max', weight_quantize_type='abs_max', window_size=10000, moving_rate=0.9, skip_pattern=['skip_quant'], quantizable_op_type=['conv2d', 'depthwise_conv2d', 'mul'], weight_quantize_func=None, act_quantize_func=None, weight_preprocess_func=None, act_preprocess_func=None, optimizer_func=None, executor=None): r""" Constructor. Args: scope(fluid.Scope): When activation use 'range_abs_max' as the quantize type, this pass will create some new parameters. The scope is used to initialize these new parameters. place(fluid.CPUPlace|fluid.CUDAPlace|str): place is used to initialize new parameters described above. If it's string, It can be ``cpu``, and ``gpu:x``, where ``x`` is the index of the GPUs. weight_bits(int): quantization bit number for weights, the bias is not quantized. activation_bits(int): quantization bit number for activation. activation_quantize_type(str): quantization type for activation, now support 'abs_max', 'range_abs_max' and 'moving_average_abs_max'. If use 'abs_max' mode, the quantization scale will be calculated dynamically each step in both training and testing period. If use 'range_abs_max', a static quantization scale will be calculated during training and used in inference. weight_quantize_type(str): quantization type for weights, support 'abs_max' and 'channel_wise_abs_max'. The 'range_abs_max' usually is not used for weight, since weights are fixed once the model is well trained. window_size(int): the window size for 'range_abs_max' quantization. moving_rate(float): the param for 'moving_average_abs_max' quantization. skip_pattern(str or str list): The user-defined quantization skip pattern, which will be presented in the name scope of an op. When the skip pattern is detected in an op's name scope, the corresponding op will not be quantized. quantizable_op_type(list[str]): List the type of ops that will be quantized. Default is ["conv2d", "depthwise_conv2d", "mul"]. The quantizable_op_type in QuantizationFreezePass and ConvertToInt8Pass must be the same as this. weight_quantize_func(function): Function that defines how to quantize weight. Using this can quickly test if user's quantization method works or not. In this function, user should both define quantization function and dequantization function, that is, the function's input is non-quantized weight and function returns dequantized weight. If None, will use quantization op defined by 'weight_quantize_type'. Default is None. act_quantize_func(function): Function that defines how to quantize activation. Using this can quickly test if user's quantization method works or not. In this function, user should both define quantization and dequantization process, that is, the function's input is non-quantized activation and function returns dequantized activation. If None, will use quantization op defined by 'activation_quantize_type'. Default is None. weight_preprocess_func(function): Function that defines how to preprocess weight before quantization. Using this can quickly test if user's preprocess method works or not. The function's input is non-quantized weight and function returns processed weight to be quantized. If None, the weight will be quantized directly. Default is None. act_preprocess_func(function): Function that defines how to preprocess activation before quantization. Using this can quickly test if user's preprocess method works or not. The function's input is non-quantized activation and function returns processed activation to be quantized. If None, the activation will be quantized directly. Default is None. optimizer_func(function): Fuction return a optimizer. When 'is_test' is False and user want to use self-defined quantization function and preprocess function, this function must be set. Default is None. executor(Fluid.Executor): If user want to use self-defined quantization function and preprocess function, executor must be set for initialization. Default is None. Examples: .. code-block:: python # The original graph will be rewrite. import paddle.fluid as fluid from paddle.fluid.contrib.slim.quantization \ import QuantizationTransformPass from paddle.fluid.contrib.slim.graph import IrGraph from paddle.fluid import core graph = IrGraph(core.Graph(program.desc), for_test=False) place = fluid.CPUPlace() transform_pass = QuantizationTransformPass(fluid.global_scope(), place) transform_pass.apply(graph) """ self._scope = scope self._place = _get_paddle_place(place) self._weight_bits = weight_bits self._activation_bits = activation_bits self._skip_pattern = skip_pattern self._weight_quantize_func = weight_quantize_func self._act_quantize_func = act_quantize_func self._weight_preprocess_func = weight_preprocess_func self._act_preprocess_func = act_preprocess_func self._optimizer = optimizer_func self._exe = executor quant_type = [ 'abs_max', 'channel_wise_abs_max', 'range_abs_max', 'moving_average_abs_max' ] assert activation_quantize_type != 'channel_wise_abs_max', \ "The activation quantization type does not support 'channel_wise_abs_max'." if activation_quantize_type not in quant_type: raise ValueError( "Unknown activation_quantize_type : '%s'. It can only be " "'abs_max' or 'range_abs_max' or 'moving_average_abs_max'." % (str(activation_quantize_type))) if weight_quantize_type not in quant_type: raise ValueError( "Unknown weight_quantize_type: '%s'. It can only be " "'abs_max' or 'channel_wise_abs_max' or 'range_abs_max' " "or 'moving_average_abs_max'." % (str(weight_quantize_type))) self._activation_quantize_type = activation_quantize_type self._weight_quantize_type = weight_quantize_type self._window_size = window_size self._moving_rate = moving_rate self._quantizable_ops = quantizable_op_type for op in self._quantizable_ops: assert op in QuantizationTransformPass._supported_quantizable_op_type, \ op + " is not supported for quantization." self._quantizable_grad_ops = [ '%s_grad' % (op) for op in self._quantizable_ops ] self._is_test = None self._global_step = None self.create_var_map = {} self.create_op_map = {} def apply(self, graph): """ Quantize the graph for training process. According to weight and activation quantization type, the graph will be added some fake quantize operators and fake dequantize operators. Args: graph(IrGraph): the applied graph. Returns: None """ assert isinstance(graph, IrGraph), 'graph must be the instance of IrGraph.' self._is_test = graph.is_test() # marked the variable which has been dequantized. dequantized_vars = collections.OrderedDict() persistable_vars = [p.name() for p in graph.all_persistable_nodes()] processed_vars = [] def _quant_preprocess(op_node): user_skipped = False if isinstance(self._skip_pattern, list): user_skipped = op_node.op().has_attr("op_namescope") and \ any(pattern in op_node.op().attr("op_namescope") \ for pattern in self._skip_pattern) elif isinstance(self._skip_pattern, str): user_skipped = op_node.op().has_attr("op_namescope") and \ op_node.op().attr("op_namescope").find( self._skip_pattern) != -1 if user_skipped: op_node.op()._set_attr("skip_quant", True) op_node.op()._set_attr("with_quant_attr", True) def _transform_forward(graph, op): op.op()._set_attr("quantization_type", "qat_with_weight") op.op()._set_attr("with_quant_attr", True) inputs = op.inputs for var_node in inputs: if var_node.name() not in op.input_arg_names(): continue if var_node.name() in dequantized_vars: dequant_var_node = dequantized_vars[var_node.name()] else: name = var_node.name() if name in processed_vars: continue is_weight = True if var_node.name() in persistable_vars \ else False # if var node is weight and weight_preprocess_func is not None, # will insert weight preprocess func # to preorocess weight before quantization # if var node is activation and act_preprocess_func is not None, # will insert activation preprocess func # to preorocess activation before quantization if is_weight and self._weight_preprocess_func is not None: var_node = self._insert_func( graph, self._weight_preprocess_func, var_node, op) elif not is_weight and self._act_preprocess_func is not None: var_node = self._insert_func( graph, self._act_preprocess_func, var_node, op) # if var node is weight and weight_quantize_func is not None, # will insert weight quantize func to quantize and dequantize weight # if var node is activation and act_quantize_func is not None, # will insert act quantize func to quantize and dequantize activation if is_weight and self._weight_quantize_func is not None: target_out_node = self._insert_func( graph, self._weight_quantize_func, var_node, op) processed_vars.append(name) continue elif not is_weight and self._act_quantize_func is not None: target_out_node = self._insert_func( graph, self._act_quantize_func, var_node, op) processed_vars.append(name) continue quant_bits = self._weight_bits if var_node.name() in persistable_vars \ else self._activation_bits quant_type = self._weight_quantize_type if is_weight \ else self._activation_quantize_type if quant_type == 'channel_wise_abs_max': # Weight quantization quant_axis = 1 if op.name() in \ _channelwise_quant_axis1_ops else 0 quant_var_node, scale_var_node = self._insert_channel_quant_op( graph, var_node, name, quant_bits, quant_axis) dequant_var_node = self._insert_channel_dequant_op( graph, quant_var_node, [scale_var_node], [quant_bits], quant_axis) else: quant_var_node, scale_var_node = self._insert_quant_op( graph, var_node, name, quant_bits, quant_type) dequant_var_node = self._insert_dequant_op( graph, quant_var_node, scale_var_node, quant_bits) dequantized_vars[name] = dequant_var_node graph.update_input_link(var_node, dequant_var_node, op) def _transform_backward(graph, op): for var_node in op.inputs: if var_node.name() not in op.input_arg_names(): continue if var_node.name() in dequantized_vars: dequant_var_node = dequantized_vars[var_node.name()] graph.update_input_link(var_node, dequant_var_node, op) def _has_weight(op): has_weight = False for var_node in op.inputs: if var_node.name() not in op.input_arg_names(): continue name = var_node.name() if var_node.name() in persistable_vars: has_weight = True return has_weight if not self._is_test: self._create_global_step(graph) ops = graph.all_op_nodes() # Do the preproccess of quantization, such as skipping some ops # for not being quantized. for op in ops: if op.name() in self._quantizable_ops or \ op.name() in self._quantizable_grad_ops: _quant_preprocess(op) # Insert mapping table to solve the problem in saving inference model. graph.out_node_mapping_table = dict() # The process of _transform_forward and _transform_backward is needed in two for loops. # The loop for transforming the forward graph: for op in ops: if op.name() in self._quantizable_ops: if not self._is_skip_quant(graph, op) and _has_weight(op): _transform_forward(graph, op) # The loop for renaming the inputs of backward op. for op in ops: if op.name() in self._quantizable_grad_ops and _has_weight(op): _transform_backward(graph, op) graph.resolve_hazard() return graph def _create_global_step(self, graph): if self._weight_quantize_type == 'range_abs_max' or \ self._activation_quantize_type == 'range_abs_max': counter_name = cpt.to_text('@STEP_COUNTER@') for node in graph.all_var_nodes(): if node.name() == counter_name: self._global_step = node if self._global_step is None: global_step_in = graph.create_persistable_node( name=counter_name, var_type=core.VarDesc.VarType.LOD_TENSOR, shape=[1], var_dtype=core.VarDesc.VarType.INT64) _init_var_node( global_step_in, np.zeros( [1], dtype='int64'), self._scope, self._place) global_step_out = graph.create_var_node_from_desc( global_step_in.var()) # The attribute of `op_role` is needed by ParallelExecutor. increment_op = graph.create_op_node( op_type='increment', attrs={ 'step': 1.0, 'op_role': core.op_proto_and_checker_maker.OpRole.Forward }, inputs={'X': global_step_in}, outputs={'Out': global_step_out}) graph.link_to(global_step_in, increment_op) graph.link_to(increment_op, global_step_out) self._global_step = global_step_out def _insert_quant_op(self, graph, var_node, name, quant_bits, quant_type): """ Insert fake_quantize_op in the graph. """ if quant_type == 'abs_max': return self._insert_quant_abs_max_op(graph, var_node, name, quant_bits) elif quant_type == 'range_abs_max': return self._insert_quant_range_abs_max_op(graph, var_node, name, quant_bits) elif quant_type == 'moving_average_abs_max': return self._insert_quant_moving_average_abs_max_op( graph, var_node, name, quant_bits) def _insert_quant_abs_max_op(self, graph, var_node, name, quant_bits): """ Insert fake_quantize_abs_max op in the graph. """ assert var_node.is_var(), '{} is not a var'.format(var_node.name()) quant_var_node = graph.create_var_node( name=self._quantized_var_name(name), var_type=var_node.type(), shape=var_node.shape(), var_dtype=var_node.dtype()) scale_var_node = graph.create_persistable_node( name=self._quantized_scale_name(name), var_type=var_node.type(), shape=[1], var_dtype=var_node.dtype()) data_type = 'float64' if var_node.dtype( ) == core.VarDesc.VarType.FP64 else 'float32' _init_var_node( scale_var_node, np.zeros( scale_var_node.shape(), dtype=data_type), self._scope, self._place) quant_op_node = graph.create_op_node( op_type='fake_quantize_abs_max', attrs={ 'bit_length': quant_bits, 'op_role': core.op_proto_and_checker_maker.OpRole.Forward }, inputs={'X': var_node}, outputs={'Out': quant_var_node, 'OutScale': scale_var_node}) graph.link_to(var_node, quant_op_node) graph.link_to(quant_op_node, quant_var_node) graph.link_to(quant_op_node, scale_var_node) return quant_var_node, scale_var_node def _insert_quant_range_abs_max_op(self, graph, var_node, name, quant_bits): """ Insert fake_quantize_range_abs_max on the graph. """ assert var_node.is_var(), '{} is not a var'.format(var_node.name()) quant_var_node = graph.create_var_node( name=self._quantized_var_name(name), var_type=var_node.type(), shape=var_node.shape(), var_dtype=var_node.dtype()) scale_in_node = graph.create_persistable_node( name=self._quantized_scale_name(name), var_type=core.VarDesc.VarType.LOD_TENSOR, shape=[1], var_dtype=var_node.dtype()) data_type = 'float64' if var_node.dtype( ) == core.VarDesc.VarType.FP64 else 'float32' _init_var_node( scale_in_node, np.array( [0.001], dtype=data_type), self._scope, self._place) scale_out_node = graph.create_var_node_from_desc(scale_in_node.var()) inputs = {'X': var_node, 'InScale': scale_in_node} outputs = {'Out': quant_var_node, 'OutScale': scale_out_node} if not self._is_test: # The name of scales_var_node maybe 'scales_0', 'scales_1', etc. scales_node = graph.create_persistable_node( name=unique_name.generate('scales'), var_type=core.VarDesc.VarType.LOD_TENSOR, shape=[self._window_size], var_dtype=var_node.dtype()) data_type = 'float64' if var_node.dtype( ) == core.VarDesc.VarType.FP64 else 'float32' _init_var_node( scales_node, np.zeros( [self._window_size], dtype=data_type), self._scope, self._place) inputs['Iter'] = self._global_step outputs['OutScales'] = scales_node attrs = { 'window_size': self._window_size, 'bit_length': quant_bits, 'is_test': self._is_test, 'op_role': core.op_proto_and_checker_maker.OpRole.Forward } quant_op_node = graph.create_op_node( op_type='fake_quantize_range_abs_max', attrs=attrs, inputs=inputs, outputs=outputs) graph.link_to(var_node, quant_op_node) graph.link_to(scale_in_node, quant_op_node) graph.link_to(quant_op_node, quant_var_node) graph.link_to(quant_op_node, scale_out_node) if not self._is_test: graph.link_to(self._global_step, quant_op_node) graph.link_to(quant_op_node, scales_node) return quant_var_node, scale_out_node def _insert_quant_moving_average_abs_max_op(self, graph, var_node, name, quant_bits): """Insert fake_quantize_moving_average_abs_max """ quant_var_node = graph.create_var_node( name=self._quantized_var_name(name), var_type=var_node.type(), shape=var_node.shape(), var_dtype=var_node.dtype()) scale_in_node = graph.create_persistable_node( name=self._quantized_scale_name(name), var_type=core.VarDesc.VarType.LOD_TENSOR, shape=[1], var_dtype=var_node.dtype()) data_type = 'float64' if var_node.dtype( ) == core.VarDesc.VarType.FP64 else 'float32' _init_var_node( scale_in_node, np.array( [0.001], dtype=data_type), self._scope, self._place) scale_out_node = graph.create_var_node_from_desc(scale_in_node.var()) ins = {'X': var_node, 'InScale': scale_in_node} outs = {'Out': quant_var_node, 'OutScale': scale_out_node} if not self._is_test: state_in_node = graph.create_persistable_node( name=unique_name.generate('state'), var_type=core.VarDesc.VarType.LOD_TENSOR, var_dtype=var_node.dtype(), shape=[1]) data_type = 'float64' if var_node.dtype( ) == core.VarDesc.VarType.FP64 else 'float32' _init_var_node( state_in_node, np.ones( [1], dtype=data_type), self._scope, self._place) accum_in_node = graph.create_persistable_node( name=unique_name.generate('accum'), var_type=core.VarDesc.VarType.LOD_TENSOR, var_dtype=var_node.dtype(), shape=[1]) _init_var_node( accum_in_node, np.ones( [1], dtype=data_type), self._scope, self._place) state_out_node = graph.create_var_node_from_desc(state_in_node.var( )) accum_out_node = graph.create_var_node_from_desc(accum_in_node.var( )) ins['InState'] = state_in_node ins['InAccum'] = accum_in_node outs['OutState'] = state_out_node outs['OutAccum'] = accum_out_node attrs = { 'bit_length': quant_bits, 'moving_rate': self._moving_rate, 'is_test': self._is_test, 'op_role': core.op_proto_and_checker_maker.OpRole.Forward } quant_op_node = graph.create_op_node( op_type='fake_quantize_moving_average_abs_max', attrs=attrs, inputs=ins, outputs=outs) graph.link_to(var_node, quant_op_node) graph.link_to(scale_in_node, quant_op_node) graph.link_to(quant_op_node, quant_var_node) graph.link_to(quant_op_node, scale_out_node) if not self._is_test: graph.link_to(state_in_node, quant_op_node) graph.link_to(accum_in_node, quant_op_node) graph.link_to(quant_op_node, state_out_node) graph.link_to(quant_op_node, accum_out_node) return quant_var_node, scale_out_node def _insert_channel_quant_op(self, graph, var_node, name, quant_bits, quant_axis): """ Insert fake_channel_wise_quantize_abs_max op in the graph. """ assert var_node.is_var(), '{} is not a var'.format(var_node.name()) quant_var_node = graph.create_var_node( name=self._quantized_var_name(name), var_type=var_node.type(), shape=var_node.shape(), var_dtype=var_node.dtype()) scale_var_node = graph.create_persistable_node( name=self._quantized_scale_name(name), var_type=var_node.type(), shape=[var_node.shape()[quant_axis]], var_dtype=var_node.dtype()) data_type = 'float64' if var_node.dtype( ) == core.VarDesc.VarType.FP64 else 'float32' _init_var_node( scale_var_node, np.zeros( scale_var_node.shape(), dtype=data_type), self._scope, self._place) quant_op_node = graph.create_op_node( op_type='fake_channel_wise_quantize_abs_max', attrs={ 'bit_length': quant_bits, 'quant_axis': quant_axis, 'is_test': self._is_test, 'op_role': core.op_proto_and_checker_maker.OpRole.Forward }, inputs={'X': var_node}, outputs={'Out': quant_var_node, 'OutScale': scale_var_node}) graph.link_to(var_node, quant_op_node) graph.link_to(quant_op_node, quant_var_node) graph.link_to(quant_op_node, scale_var_node) return quant_var_node, scale_var_node def _insert_dequant_op(self, graph, var_node, scale_var_node, quant_bits): """ Insert fake_dequantize_op in the graph. """ assert var_node.is_var(), '{} is not a var'.format(var_node.name()) dequant_var_node = graph.create_var_node( name=self._dequantized_var_name(var_node.name()), var_type=var_node.type(), shape=var_node.shape(), var_dtype=var_node.dtype()) max_range = (1 << (quant_bits - 1)) - 1 dequant_op_node = graph.create_op_node( op_type='fake_dequantize_max_abs', attrs={ 'max_range': float(max_range), 'op_role': core.op_proto_and_checker_maker.OpRole.Forward }, inputs={'X': var_node, 'Scale': scale_var_node}, outputs={'Out': dequant_var_node}) graph.link_to(var_node, dequant_op_node) graph.link_to(scale_var_node, dequant_op_node) graph.link_to(dequant_op_node, dequant_var_node) return dequant_var_node def _insert_channel_dequant_op(self, graph, var_node, scale_var_nodes, quant_bits, quant_axis): """ Insert fake_channel_wise_dequantize_max_abs in the graph. """ assert var_node.is_var(), '{} is not a var'.format(var_node.name()) dequant_var_node = graph.create_var_node( name=self._dequantized_var_name(var_node.name()), var_type=var_node.type(), shape=var_node.shape(), var_dtype=var_node.dtype()) dequant_op_node = graph.create_op_node( op_type='fake_channel_wise_dequantize_max_abs', attrs={ 'quant_bits': quant_bits, 'quant_axis': quant_axis, 'op_role': core.op_proto_and_checker_maker.OpRole.Forward }, inputs={'X': var_node, 'Scales': scale_var_nodes}, outputs={'Out': dequant_var_node}) graph.link_to(var_node, dequant_op_node) for scale_n in scale_var_nodes: graph.link_to(scale_n, dequant_op_node) graph.link_to(dequant_op_node, dequant_var_node) return dequant_var_node def _create_new_node(self, graph, in_node): """ create a node that same with in_node in graph Args: graph(IrGraph): create node in graph. in_node(IrVarNode): create node that same with in_node. Returns: created new node """ key = '' for inp in in_node.inputs: key = key + inp.name() key = key + in_node.name() for inp in in_node.outputs: key = key + inp.name() if key in self.create_var_map.keys(): new_node = self.create_var_map[key] elif in_node.is_ctrl_var(): new_node = graph.create_control_dep_var() self.create_var_map[key] = new_node else: new_node = graph.create_var_node_from_desc(in_node.node.var()) self.create_var_map[key] = new_node return new_node def _copy_graph(self, graph, source_graph, op_node): """ copy op_node in source_graph to graph. And will run recursively for next ops that link to op_node's outputs. Args: graph(IrGraph): target graph to copy. source_graph(IrGraph): source graph to copy. op_node(IrOpNode): op node in source_graph. Returns: None """ key = '' for inp in op_node.inputs: key = key + inp.name() key = key + op_node.name() for inp in op_node.outputs: key = key + inp.name() has_created = False if key in self.create_op_map.keys(): new_op_node = self.create_op_map[key] has_created = True else: new_op_node = graph.create_op_node_from_desc(op_node.node.op()) self.create_op_map[key] = new_op_node if has_created: return for in_node in op_node.inputs: new_node = self._create_new_node(graph, in_node) graph.link_to(new_node, new_op_node) for in_node in op_node.outputs: new_node = self._create_new_node(graph, in_node) graph.link_to(new_op_node, new_node) for var_node in op_node.outputs: for next_op_node in var_node.outputs: self._copy_graph(graph, source_graph, next_op_node) return def _insert_func(self, graph, func, var_node, op): """ Insert a tmp program that returned by func between var_node and op. Args: graph(IrGraph): target graph to insert tmp program. func(Function): function to define a tmp program var_node(IrVarNode): node in target graph. op(IrOpNode): op in target graph. Returns: op's new input that replaces var_node """ tmp_program = Program() startup_program = Program() with program_guard(tmp_program, startup_program): with unique_name.guard(var_node.name() + "_"): in_node = data( var_node.name() + '_tmp_input', shape=var_node.shape(), dtype='float32') out_node = func(in_node) graph.out_node_mapping_table[out_node.name] = var_node.name() # loss shape must be 1 when minimize loss = mean(out_node) if not graph._for_test: assert self._optimizer, "optimizer_func must be set when graph is test graph" in_node.stop_gradient = False optimizer = self._optimizer() optimizer.minimize(loss) with scope_guard(self._scope): self._exe.run(startup_program) tmp_graph = IrGraph( core.Graph(tmp_program.desc), for_test=graph._for_test) in_node = tmp_graph._find_node_by_name(tmp_graph.all_var_nodes(), in_node.name) out_node = tmp_graph._find_node_by_name(tmp_graph.all_var_nodes(), out_node.name) in_node_params = [] in_op_node = [] # copy tmp graph to graph, after that, we can insert tmp graph's copy to graph. for node in tmp_graph.all_var_nodes(): if node.inputs == [] and node.persistable(): in_node_params.append(node) for node in tmp_graph.all_op_nodes(): if node.inputs == []: in_op_node.append(node) for node in in_node.outputs: self._copy_graph(graph, tmp_graph, node) for node in in_node_params: for op_node in node.outputs: self._copy_graph(graph, tmp_graph, op_node) for node in in_op_node: self._copy_graph(graph, tmp_graph, node) target_in_node = graph._find_node_by_name(graph.all_var_nodes(), in_node.name()) target_out_node = graph._find_node_by_name(graph.all_var_nodes(), out_node.name()) loss_node = graph._find_node_by_name(graph.all_var_nodes(), loss.name) outputs = target_in_node.outputs for node in outputs: graph.update_input_link(target_in_node, var_node, node) graph.update_input_link(var_node, target_out_node, op) # update grad if not graph._for_test: op_out = op.outputs[0] op_out_grad = graph._find_node_by_name(graph.all_var_nodes(), op_out.name() + "@GRAD") # find op's gradient op, such as conv2d_grad op_grad = op_out_grad.outputs[0] target_out_grad_node = graph._find_node_by_name( graph.all_var_nodes(), target_out_node.name() + "@GRAD") in_node_grad = graph._find_node_by_name( graph.all_var_nodes(), target_in_node.name() + "@GRAD") in_node_grad_op = in_node_grad.inputs # update op_grad's input graph.update_input_link(var_node, target_out_node, op_grad) op_grad_out = None # find var_node's corresponding grad node for node in op_grad.outputs: if var_node.name() + "@GRAD" in node.name(): op_grad_out = node # update op_grad's output if op_grad_out is not None: graph.update_output_link(op_grad_out, target_out_grad_node, op_grad) else: graph.link_to(op_grad, target_out_grad_node) for node in in_node_grad_op: graph.update_input_link(target_in_node, var_node, node) if op_grad_out: graph.update_output_link(in_node_grad, op_grad_out, node) # remove useless nodes mean_grad = target_out_grad_node.inputs[0] mean_out_grad = mean_grad.inputs[0] fill_constant_node = mean_out_grad.inputs[0] graph.safe_remove_nodes(mean_grad) graph.safe_remove_nodes(mean_out_grad) graph.safe_remove_nodes(fill_constant_node) graph.safe_remove_nodes(in_node_grad) graph.safe_remove_nodes(loss_node.inputs[0]) graph.safe_remove_nodes(loss_node) graph.safe_remove_nodes(target_in_node) return target_out_node def _quantized_var_name(self, var_name): """ Return quantized variable name for the input `var_name`. """ return "%s.quantized" % (var_name) def _dequantized_var_name(self, var_name): """ Return dequantized variable name for the input `var_name`. """ return "%s.dequantized" % (var_name) def _quantized_scale_name(self, var_name): """ Return the scale name of quantized variable for the input `var_name`. """ return "%s.scale" % (var_name) def _is_skip_quant(self, graph, op_node): """ Analyse whether the op node skips quantization. """ is_skip = False if op_node.op().has_attr("skip_quant") and \ op_node.op().attr("skip_quant"): is_skip = True # if the inputs of mul and matmul are not all persistable, use # AddQuantDequantPass to quantize them. if op_node.name() in ["mul", "matmul"] and \ _is_input_all_not_persistable(graph, op_node): is_skip = True if op_node.op().has_attr("quantization_type") and \ op_node.op().attr("quantization_type") == "qat_without_weight": is_skip = True return is_skip class QuantizationFreezePass(object): def __init__(self, scope, place, bias_correction=False, weight_bits=8, activation_bits=8, weight_quantize_type='abs_max', quantizable_op_type=None): """ The freeze pass is used to adjust the quantize operator order, for example: 1) `activation -> quant -> dequant -> conv2d` will be frozen into `activation -> quant -> conv2d -> dequant` 2) `weight -> quant -> dequant -> conv2d` will be frozen into `weight -> conv2d`, and weight will be scaled offline. Args: scope(fluid.Scope): scope is used to get the weight tensor values. place(fluid.CPUPlace|fluid.CUDAPlace|str): place is used to restore the weight tensors. If it's string, It can be ``cpu``, and ``gpu:x``, where ``x`` is the index of the GPUs. bias_correction(bool): whether use bias correction for post-training quantization. https://arxiv.org/abs/1810.05723. weight_bits(int): quantization bit number for weights. activation_bits(int): quantization bit number for activation. weight_quantize_type(str): quantization type for weights, support 'abs_max' and 'channel_wise_abs_max'. The 'range_abs_max' usually is not used for weight, since weights are fixed once the model is well trained. quantizable_op_type(list[str]): This input param will be removed latter. The pass will process all quantized op, so it is not necessary to set the input param. """ assert scope is not None, \ 'The scope cannot be set None.' assert place is not None, \ 'The place cannot be set None.' self._scope = scope self._bias_correction = bias_correction self._place = _get_paddle_place(place) self._weight_bits = weight_bits self._activation_bits = activation_bits self._weight_quantize_type = weight_quantize_type self._fake_quant_op_names = _fake_quant_op_list self._fake_dequant_op_names = _fake_dequant_op_list self._op_input_rename_map = collections.OrderedDict() self._op_output_rename_map = collections.OrderedDict() self._quant_var_scale_map = collections.OrderedDict() def apply(self, graph): """ Adjust quantize/dequantize operators order for the inference process. Args: graph(IrGraph): the applied graph. Returns: None """ # Get input scales in fake quant op and process weights persistable_vars = [p.name() for p in graph.all_persistable_nodes()] ops = graph.all_op_nodes() for op_node in ops: op_name = op_node.name() if op_name in self._fake_quant_op_names: input_arg_name = op_node.input('X')[0] if hasattr(graph, 'out_node_mapping_table'): if input_arg_name in graph.out_node_mapping_table.keys(): input_arg_name = graph.out_node_mapping_table[ input_arg_name] if input_arg_name not in persistable_vars: scale_v = graph._find_node_by_name( op_node.outputs, op_node.output('OutScale')[0]) self._quant_var_scale_map[input_arg_name] = scale_v else: # Obtain scale from OutScale var node scale_v = self._load_var(op_node.output('OutScale')[0]) assert scale_v.ndim in [ 1, 2 ], "the dim of scale_v should be 1 or 2" if scale_v.ndim == 2: scale_v = scale_v[0] if scale_v.size == 1 and self._weight_quantize_type == 'abs_max': scale_v = scale_v[0] else: scale_v = scale_v.tolist() self._quant_var_scale_map[input_arg_name] = scale_v # Quantize weight and restore param_v = self._load_var(input_arg_name) if isinstance(scale_v, list) and \ any(_check_grandchild_op_node(op_node, op) for op in _channelwise_quant_axis1_ops): quant_axis = 1 else: quant_axis = 0 quantized_param_v = self._quant( param_v.copy(), scale_v, self._weight_bits, quant_axis) if self._bias_correction == True: quantized_param_v = self._bias_correction_w( param_v, quantized_param_v, scale_v, quant_axis) self._restore_var(input_arg_name, quantized_param_v) self._remove_fake_quant_and_dequant_op(graph, op_node) # Remove all fake dequant op ops = graph.all_op_nodes() for op_node in ops: op_name = op_node.name() if op_name in self._fake_dequant_op_names: self._remove_fake_quant_and_dequant_op(graph, op_node) # Insert post dequant op ops = graph.all_op_nodes() for op_node in ops: op_node_desc = op_node.op() if op_node_desc.has_attr("quantization_type") and \ op_node_desc.attr("quantization_type") == "qat_with_weight": if self._weight_quantize_type == 'channel_wise_abs_max': self._insert_post_channel_dequant_op(graph, op_node, quant_axis) else: self._insert_post_dequant_op(graph, op_node) # Rename inputs of the followed ops after inserting dequant_op after fc/conv for op_node in ops: for var_node in op_node.inputs: if var_node.node in self._op_output_rename_map: old_in = var_node new_in = self._op_output_rename_map[var_node.node] graph.update_input_link(old_in, new_in, op_node) # remove the unused var node in the graph self._remove_unused_var_nodes(graph) graph.resolve_hazard() return graph def _remove_fake_quant_and_dequant_op(self, graph, op_node): k = graph._find_node_by_name(op_node.outputs, op_node.output('Out')[0]) v = graph._find_node_by_name(op_node.inputs, op_node.input('X')[0]) if v.node not in self._op_input_rename_map: self._op_input_rename_map[k.node] = v else: self._op_input_rename_map[k.node] = self._op_input_rename_map[ v.node] graph.safe_remove_nodes(op_node) def _insert_post_channel_dequant_op(self, graph, op_node, quant_axis): persistable_vars = [p.name() for p in graph.all_persistable_nodes()] for var_node in op_node.inputs: name = var_node.name() if name not in op_node.input_arg_names(): continue if var_node.node in self._op_input_rename_map: old_in = var_node new_in = self._op_input_rename_map[var_node.node] new_in.clear_outputs() graph.update_input_link(old_in, new_in, op_node) original_var_name = self._original_var_name(name) scale_v = self._quant_var_scale_map[original_var_name] if original_var_name in persistable_vars: assert isinstance( scale_v, list), 'The scale of parameter %s is not a list.' % ( original_var_name) channel_scale = np.array(scale_v) else: assert isinstance(scale_v, IrNode) scale_var_node = self._quant_var_scale_map[original_var_name] if len(op_node.output_arg_names()) != 1: raise ValueError("Only support one output, but op %s has" " more than one output." % (op_node.name())) output_var_node = graph._find_node_by_name( op_node.outputs, op_node.output_arg_names()[0]) weight_scale_node = graph.create_persistable_node( name=unique_name.generate('channel_scale'), var_type=core.VarDesc.VarType.LOD_TENSOR, shape=[channel_scale.shape[0]], var_dtype=output_var_node.dtype()) data_type = 'float64' if output_var_node.dtype( ) == core.VarDesc.VarType.FP64 else 'float32' _init_var_node(weight_scale_node, channel_scale.astype(data_type), self._scope, self._place) dequant_var_node = graph.create_var_node( name=self._dequantized_var_name(output_var_node.name()), var_type=output_var_node.type(), shape=output_var_node.shape(), var_dtype=output_var_node.dtype()) if op_node.op().has_attr("x_num_col_dims"): x_num_col_dims = op_node.op().attr("x_num_col_dims") else: x_num_col_dims = 1 dequant_op_node = graph.create_op_node( op_type='fake_channel_wise_dequantize_max_abs', attrs={ 'quant_bits': [self._weight_bits, self._activation_bits], 'quant_axis': quant_axis, 'op_role': core.op_proto_and_checker_maker.OpRole.Forward, 'x_num_col_dims': x_num_col_dims }, inputs={ 'X': output_var_node, 'Scales': [weight_scale_node, scale_var_node] }, outputs={'Out': dequant_var_node}) graph.link_to(output_var_node, dequant_op_node) graph.link_to(scale_var_node, dequant_op_node) graph.link_to(weight_scale_node, dequant_op_node) graph.link_to(dequant_op_node, dequant_var_node) self._op_output_rename_map[output_var_node.node] = dequant_var_node return dequant_var_node def _insert_post_dequant_op(self, graph, op_node): persistable_vars = [p.name() for p in graph.all_persistable_nodes()] max_range = 1 param_range = (1 << (self._weight_bits - 1)) - 1 act_range = (1 << (self._activation_bits - 1)) - 1 for var_node in op_node.inputs: name = var_node.name() if name not in op_node.input_arg_names(): continue if var_node.node in self._op_input_rename_map: old_in = var_node new_in = self._op_input_rename_map[var_node.node] new_in.clear_outputs() graph.update_input_link(old_in, new_in, op_node) original_var_name = self._original_var_name(name) scale_v = self._quant_var_scale_map[original_var_name] if original_var_name in persistable_vars: assert self._is_float( scale_v), 'The scale of parameter %s is not a float.' % ( original_var_name) scale_v = 1e-8 if scale_v == 0.0 else scale_v max_range *= param_range / scale_v else: max_range *= act_range assert isinstance(scale_v, IrNode) scale_var_node = self._quant_var_scale_map[original_var_name] if len(op_node.output_arg_names()) != 1: raise ValueError("Only support one output, but op %s has" " more than one output." % (op_node.name())) output_var_node = graph._find_node_by_name( op_node.outputs, op_node.output_arg_names()[0]) dequant_var_node = graph.create_var_node( name=self._dequantized_var_name(output_var_node.name()), var_type=output_var_node.type(), shape=output_var_node.shape(), var_dtype=output_var_node.dtype()) dequant_op_node = graph.create_op_node( op_type='fake_dequantize_max_abs', attrs={ 'max_range': float(max_range), 'op_role': core.op_proto_and_checker_maker.OpRole.Forward }, inputs={'X': output_var_node, 'Scale': scale_var_node}, outputs={'Out': dequant_var_node}) graph.link_to(output_var_node, dequant_op_node) graph.link_to(scale_var_node, dequant_op_node) graph.link_to(dequant_op_node, dequant_var_node) self._op_output_rename_map[output_var_node.node] = dequant_var_node return dequant_var_node def _load_var(self, name): return np.array(self._scope.find_var(name).get_tensor()) def _restore_var(self, name, array): tensor = self._scope.find_var(name).get_tensor() tensor.set(array, self._place) def _remove_unused_var_nodes(self, graph): all_used_vars = set() ops = graph.all_op_nodes() for op_node in ops: for input_node in op_node.inputs: all_used_vars.add(input_node) for output_node in op_node.outputs: all_used_vars.add(output_node) all_used_vars = {n.node for n in all_used_vars} all_unused_vars = { n for n in filter(lambda node: node.node not in all_used_vars, graph.all_var_nodes()) } graph.safe_remove_nodes(all_unused_vars) def _original_var_name(self, var_name): """ Return the original variable name. """ if var_name.endswith('.quantized.dequantized'): return var_name[:-len('.quantized.dequantized')] if var_name.endswith('.quantized'): return var_name[:-len('.quantized')] if var_name.endswith('.dequantized'): return var_name[:-len('.dequantized')] if var_name.endswith('.scale'): return var_name[:-len('.scale')] else: return var_name def _dequantized_var_name(self, var_name): """ Return dequantized variable name for the input `var_name`. """ return "%s.dequantized" % (var_name) def _is_float(self, v): return isinstance(v, float) or isinstance(v, np.float32) \ or isinstance(v, np.float64) def _quant(self, x, scale, num_bits, quant_axis): assert quant_axis in [0, 1], 'quant_axis should be 0 or 1 for now.' bnt = (1 << (num_bits - 1)) - 1 def _clip(x, scale): x[x > scale] = scale x[x < -scale] = -scale return x if isinstance(scale, list): for i, s in enumerate(scale): if s == 0.0: s = 1e-8 if quant_axis == 0: x[i] = _clip(x[i], s) x[i] = np.round(x[i] / s * bnt) else: x[:, i] = _clip(x[:, i], s) x[:, i] = np.round(x[:, i] / s * bnt) else: scale = 1e-8 if scale == 0.0 else scale x = _clip(x, scale) x = np.round(x / scale * bnt) return x def _bias_correction_w(self, x, x_quant, scale_v, quant_axis): ''' Bias correction for weight ''' eps = 1e-8 bnt = (1 << (self._weight_bits - 1)) - 1 x_dequant = x_quant.copy() if isinstance(scale_v, list): if quant_axis == 0: for i, s in enumerate(scale_v): x_dequant[i] = x_dequant[i] * s / bnt quant_bias = x - x_dequant mean_bias = quant_bias.reshape(quant_bias.shape[0], -1).mean(-1) std_orig = x.reshape(x.shape[0], -1).std(-1) std_quant = x_dequant.reshape(x_dequant.shape[0], -1).std(-1) std_bias = std_orig / (std_quant + eps) else: for i, s in enumerate(scale_v): x_dequant[:, i] = x_quant[:, i] * s / bnt quant_bias = x - x_dequant mean_bias = np.array([ quant_bias[:, i].mean() for i in range(quant_bias.shape[1]) ]) std_orig = np.array([x[:, i].std() for i in range(x.shape[1])]) std_quant = np.array( [x_dequant[:, i].std() for i in range(x_dequant.shape[1])]) std_bias = std_orig / (std_quant + eps) else: x_dequant = x_quant * scale_v / bnt mean_bias = (x - x_dequant).mean() std_bias = x.std() / (x_dequant.std() + eps) if mean_bias.ndim == 1: std_bias = np.resize(std_bias, x.shape) mean_bias = np.resize(mean_bias, x.shape) x_dequant = (mean_bias + x_dequant) * std_bias quantized_param_v = self._quant(x_dequant, scale_v, self._weight_bits, quant_axis) return quantized_param_v class ConvertToInt8Pass(object): def __init__(self, scope, place, quantizable_op_type=None): """ Convert the weights into int8_t type. Args: scope(fluid.Scope): scope is used to get the weight tensor values. place(fluid.CPUPlace|fluid.CUDAPlace|str): place is used to restore the 8bits weight tensors. If it's string, It can be ``cpu``, and ``gpu:x``, where ``x`` is the index of the GPUs. quantizable_op_type(list[str]): This input param will be removed latter. The pass will process all quantized op, so it is not necessary to set the input param. """ assert scope is not None, \ 'The scope cannot be set None.' assert place is not None, \ 'The place cannot be set None.' self._scope = scope self._place = _get_paddle_place(place) def apply(self, graph): """ Convert weights' type of the graph. After that, the data type of the graph weights is int8_t. Args: graph(IrGraph): the applied graph. Returns: None """ persistable_vars = [p.name() for p in graph.all_persistable_nodes()] ops = graph.all_op_nodes() input_map = {} for op_node in ops: if op_node.op().has_attr("quantization_type") and \ op_node.op().attr("quantization_type") == "qat_with_weight": for var_node in op_node.inputs: name = var_node.name() if name in persistable_vars: if name not in input_map: int8_var_node = self._convert_to_int8(graph, var_node) input_map[name] = int8_var_node graph.update_input_link(var_node, input_map[name], op_node) # remove the unused var node in the graph self._remove_unused_var_nodes(graph) graph.resolve_hazard() return graph def _convert_to_int8(self, graph, var_node): int8_var_node_name = var_node.name() + ".int8" int8_var_node = graph.create_persistable_node( name=cpt.to_text(int8_var_node_name), var_type=var_node.type(), shape=var_node.shape(), var_dtype=core.VarDesc.VarType.INT8) array = self._load_var(var_node.name()) self._scope.var(int8_var_node_name) self._store_var(int8_var_node_name, array, np.int8) return int8_var_node def _load_var(self, name): return np.array(self._scope.find_var(name).get_tensor()) def _store_var(self, name, array, dtype): tensor = self._scope.find_var(name).get_tensor() tensor.set(array.astype(dtype), self._place) def _remove_unused_var_nodes(self, graph): all_used_vars = set() ops = graph.all_op_nodes() for op_node in ops: for input_node in op_node.inputs: all_used_vars.add(input_node) for output_node in op_node.outputs: all_used_vars.add(output_node) all_used_vars = {n.node for n in all_used_vars} all_unused_vars = { n for n in filter(lambda node: node.node not in all_used_vars, graph.all_var_nodes()) } graph.safe_remove_nodes(all_unused_vars) class TransformForMobilePass(object): def __init__(self): """ This pass is used to convert the frozen graph for paddle-mobile execution. """ self._fake_quant_op_names = _fake_quant_op_list self._fake_dequant_op_names = _fake_dequant_op_list def apply(self, graph): """ Because paddle-mobile use `quantize` an `dequantize` as the names of quantize operator and dequantize operator, the `apply` function just realize this logic. Args: graph(IrGraph): the graph will be transformed. Returns: None """ ops = graph.all_op_nodes() for op_node in ops: name = op_node.name() if name in self._fake_quant_op_names: op_node.set_type('quantize') quant_node = graph.create_op_node_from_desc(op_node.op()) for input_node in op_node.inputs: graph.link_to(input_node, quant_node) for output_node in op_node.outputs: graph.link_to(quant_node, output_node) graph.safe_remove_nodes(op_node) if name in self._fake_dequant_op_names: op_node.set_type('dequantize') dequant_node = graph.create_op_node_from_desc(op_node.op()) for input_node in op_node.inputs: graph.link_to(input_node, dequant_node) for output_node in op_node.outputs: graph.link_to(dequant_node, output_node) graph.safe_remove_nodes(op_node) graph.resolve_hazard() return graph class OutScaleForTrainingPass(object): def __init__(self, scope=None, place=None, moving_rate=0.9): """ This pass is used for calculating output scales of some operators. These output scales may be used by tensorRT or some other inference engines. Args: scope(fluid.Scope): The scope is used to initialize these new parameters. place(fluid.CPUPlace|fluid.CUDAPlace|str): The place is used to initialize new parameters. If it's string, It can be ``cpu``, and ``gpu:x``, where ``x`` is the index of the GPUs. moving_rate(float): The decay coefficient of moving average. The default value is 0.9. """ self._scope = scope self._place = _get_paddle_place(place) self._moving_rate = moving_rate self._is_test = None self._teller_set = _out_scale_op_list def apply(self, graph): """ Insert the `moving_average_abs_max_scale` op in order to calculate output scales of operators in the teller_set. Args: graph(IrGraph): the target graph. """ assert isinstance(graph, IrGraph), 'graph must be the instance of IrGraph.' self._is_test = graph.is_test() target_ops = [] for op in graph.all_op_nodes(): if op.name() in self._teller_set: target_ops.append(op) for op in target_ops: for output_var_name in _get_op_output_var_names(op): in_node = graph._find_node_by_name(op.outputs, output_var_name) if in_node.dtype() not in \ [core.VarDesc.VarType.FP64, core.VarDesc.VarType.FP32]: continue scale_node = graph.create_persistable_node( name=self._scale_name(in_node.name()), var_type=core.VarDesc.VarType.LOD_TENSOR, shape=[1], var_dtype=in_node.dtype()) data_type = 'float64' if in_node.dtype() \ == core.VarDesc.VarType.FP64 else 'float32' _init_var_node( scale_node, np.ones( [1], dtype=data_type), self._scope, self._place) ins = {'X': in_node} outs = {'OutScale': scale_node} if not self._is_test: state_in_node = graph.create_persistable_node( name=unique_name.generate('scale_state@'), var_type=core.VarDesc.VarType.LOD_TENSOR, var_dtype=in_node.dtype(), shape=[1]) _init_var_node( state_in_node, np.ones( [1], dtype=data_type), self._scope, self._place) accum_in_node = graph.create_persistable_node( name=unique_name.generate('scale_accum@'), var_type=core.VarDesc.VarType.LOD_TENSOR, var_dtype=in_node.dtype(), shape=[1]) _init_var_node( accum_in_node, np.ones( [1], dtype=data_type), self._scope, self._place) state_out_node = graph.create_var_node_from_desc( state_in_node.var()) accum_out_node = graph.create_var_node_from_desc( accum_in_node.var()) ins['InState'] = state_in_node ins['InAccum'] = accum_in_node outs['OutState'] = state_out_node outs['OutAccum'] = accum_out_node attrs = { 'moving_rate': self._moving_rate, 'is_test': self._is_test, 'op_role': core.op_proto_and_checker_maker.OpRole.Forward } scale_op_node = graph.create_op_node( op_type='moving_average_abs_max_scale', attrs=attrs, inputs=ins, outputs=outs) graph.link_to(in_node, scale_op_node) graph.link_to(scale_op_node, scale_node) if not self._is_test: graph.link_to(state_in_node, scale_op_node) graph.link_to(accum_in_node, scale_op_node) graph.link_to(scale_op_node, state_out_node) graph.link_to(scale_op_node, accum_out_node) graph.resolve_hazard() return graph def _scale_name(self, var_name): """ Return the scale name for the var named `var_name`. """ return "%s@scale" % (var_name) class OutScaleForInferencePass(object): def __init__(self, scope=None): """ This pass is used for setting output scales of some operators. These output scales may be used by tensorRT or some other inference engines. Args: scope(fluid.Scope): The scope is used to initialize these new parameters. """ self._scope = scope self._teller_set = _out_scale_op_list def apply(self, graph): """ Get output scales from the scope and set these scales in op_descs of operators in the teller_set. Args: graph(IrGraph): the target graph. """ assert isinstance(graph, IrGraph), 'graph must be the instance of IrGraph.' op_nodes = graph.all_op_nodes() for op_node in op_nodes: if op_node.name() in self._teller_set: var_names = _get_op_output_var_names(op_node) for var_name in var_names: in_node = graph._find_node_by_name(op_node.outputs, var_name) if in_node.dtype() not in \ [core.VarDesc.VarType.FP64, core.VarDesc.VarType.FP32]: continue scale_name = self._scale_name(var_name) scale_var = self._scope.find_var(scale_name) assert scale_var is not None, \ "Can not find {} variable in the scope".format(scale_name) scale_value = np.array(scale_var.get_tensor())[0] # For compatibility, we save output threshold by two methods. op_node.op()._set_attr("out_threshold", float(scale_value)) argname_index = _get_output_name_index(op_node, var_name) assert argname_index is not None, \ var_name + " is not the output of the op" op_node.op()._set_attr(argname_index[0] + str(argname_index[1]) \ + "_threshold", float(scale_value)) op_node.op()._set_attr("with_quant_attr", True) graph.resolve_hazard() return graph def _scale_name(self, var_name): """ Return the scale name for the var named `var_name`. """ return "%s@scale" % (var_name) class AddQuantDequantPass(object): """ Quantize the ops that do not have weights, and add quant_dequant op for the quantized ops's inputs. """ _supported_quantizable_op_type = [ "pool2d", "elementwise_add", "concat", "softmax", "argmax", "transpose", "equal", "gather", "greater_equal", "greater_than", "less_equal", "less_than", "mean", "not_equal", "reshape", "reshape2", "bilinear_interp", "nearest_interp", "trilinear_interp", "slice", "squeeze", "elementwise_sub", "mul", "matmul", "relu", "relu6", "leaky_relu", "tanh", "swish", "scale", "transpose", "transpose2", "sigmoid", "pad2d", "flatten", "flatten2", "batch_norm", "layer_norm", "matmul_v2" ] # To be compatible with PaddleSlim, not remove _activation_type for now _activation_type = ["relu", "relu6", "leaky_relu", "tanh", "swish"] def __init__(self, scope=None, place=None, moving_rate=0.9, quant_bits=8, skip_pattern=["skip_quant"], quantizable_op_type=["elementwise_add", "pool2d"], is_full_quantized=False): """ Constructor. Args: scope(fluid.Scope): The scope is used to initialize these new parameters. place(fluid.CPUPlace|fluid.CUDAPlace|str): place is used to initialize new parameters described above. If ``place`` is string, it can be It can be ``cpu`` or ``gpu:x``, where ``x`` is the index of the GPUs. moving_rate(float, optional): the param for 'quant_dequant_moving_average_abs_max' quantization. Default is 0.9. quant_bits(int, optional): quantization bit number for activation. Default is 8. skip_pattern(str, optional): The user-defined quantization skip pattern, which will be presented in the name scope of an op. When the skip pattern is detected in an op's name scope, the corresponding op will not be quantized. Default is 'skip_quant'. quantizable_op_type(list[str], optional): List the type of ops that will be quantized. Default is ["elementwise_add", "pool2d"]. is_full_quantized(bool, optional): If set is_full_quantized as True, apply quantization to all supported quantizable op type. If set is_full_quantized as False, only apply quantization to the op type according to the input quantizable_op_type. """ self._scope = scope self._place = _get_paddle_place(place) self._moving_rate = moving_rate self._quant_bits = quant_bits self._is_test = None self._skip_pattern = skip_pattern if is_full_quantized: self._quantizable_op_type = \ AddQuantDequantPass._supported_quantizable_op_type else: self._quantizable_op_type = quantizable_op_type for op_type in quantizable_op_type: assert op_type in AddQuantDequantPass._supported_quantizable_op_type, \ op_type + " is not supported for quantization." self._quantizable_grad_op_type = [ '%s_grad' % (op) for op in self._quantizable_op_type ] assert self._scope != None, "scope must not be None." assert self._place != None, "place must not be None." def apply(self, graph): """ Add quant_dequant before some ops, such as the 'elementwise_add' and 'pool2d' op. Args: graph(IrGraph): the target graph. Returns: None """ assert isinstance(graph, IrGraph), 'graph must be the instance of IrGraph.' self._is_test = graph.is_test() dequantized_vars_map = collections.OrderedDict() # Forward stage, insert quant_dequant op all_op_nodes = graph.all_op_nodes() for op_node in all_op_nodes: if op_node.name() in self._quantizable_op_type: is_skip = False if isinstance(self._skip_pattern, list): is_skip = op_node.op().has_attr("op_namescope") and \ any(pattern in op_node.op().attr("op_namescope") for pattern in self._skip_pattern) elif isinstance(self._skip_pattern, str): is_skip = op_node.op().has_attr("op_namescope") and \ op_node.op().attr("op_namescope").find(self._skip_pattern) != -1 is_quantized = op_node.op().has_attr("quantization_type") and \ op_node.op().attr("quantization_type") == "qat_with_weight" if is_skip or is_quantized or \ (not _is_input_all_not_persistable(graph, op_node)): continue op_node.op()._set_attr("quantization_type", "qat_without_weight") op_node.op()._set_attr("activation_bits", self._quant_bits) op_node.op()._set_attr("with_quant_attr", True) arg_names = _get_op_input_var_names(op_node) for arg_name in arg_names: in_node = graph._find_node_by_name(op_node.inputs, arg_name) if arg_name in dequantized_vars_map: quant_var_node = dequantized_vars_map[arg_name] else: quant_var_node, _ = \ self._inser_quant_dequant_moving_average_abs_max_op( graph, in_node, self._quant_bits) dequantized_vars_map[arg_name] = quant_var_node graph.update_input_link(in_node, quant_var_node, op_node) # Backward stage, update input link for op_node in all_op_nodes: if op_node.name() in self._quantizable_grad_op_type: for input_name in op_node.input_arg_names(): if input_name in dequantized_vars_map: in_node = graph._find_node_by_name(op_node.inputs, input_name) dequant_var_node = dequantized_vars_map[input_name] graph.update_input_link(in_node, dequant_var_node, op_node) graph.resolve_hazard() return graph def _inser_quant_dequant_moving_average_abs_max_op(self, graph, var_node, quant_bits): """Insert fake_quantize_dequantize_moving_average_abs_max op. """ quant_var_node = graph.create_var_node( name="{}.quant_dequant".format(var_node.name()), var_type=var_node.type(), shape=var_node.shape(), var_dtype=var_node.dtype()) scale_in_node = graph.create_persistable_node( name="{}.quant_dequant.scale".format(var_node.name()), var_type=core.VarDesc.VarType.LOD_TENSOR, shape=[1], var_dtype=var_node.dtype()) data_type = 'float64' if var_node.dtype( ) == core.VarDesc.VarType.FP64 else 'float32' _init_var_node( scale_in_node, np.array( [0.001], dtype=data_type), self._scope, self._place) scale_out_node = graph.create_var_node_from_desc(scale_in_node.var()) ins = {'X': var_node, 'InScale': scale_in_node} outs = {'Out': quant_var_node, 'OutScale': scale_out_node} if not self._is_test: state_in_node = graph.create_persistable_node( name=unique_name.generate('quant_dequant.state'), var_type=core.VarDesc.VarType.LOD_TENSOR, var_dtype=var_node.dtype(), shape=[1]) data_type = 'float64' if var_node.dtype( ) == core.VarDesc.VarType.FP64 else 'float32' _init_var_node( state_in_node, np.ones( [1], dtype=data_type), self._scope, self._place) accum_in_node = graph.create_persistable_node( name=unique_name.generate('quant_dequant.accum'), var_type=core.VarDesc.VarType.LOD_TENSOR, var_dtype=var_node.dtype(), shape=[1]) _init_var_node( accum_in_node, np.ones( [1], dtype=data_type), self._scope, self._place) state_out_node = graph.create_var_node_from_desc(state_in_node.var( )) accum_out_node = graph.create_var_node_from_desc(accum_in_node.var( )) ins['InState'] = state_in_node ins['InAccum'] = accum_in_node outs['OutState'] = state_out_node outs['OutAccum'] = accum_out_node attrs = { 'bit_length': quant_bits, 'moving_rate': self._moving_rate, 'is_test': self._is_test, 'op_role': core.op_proto_and_checker_maker.OpRole.Forward } quant_op_node = graph.create_op_node( op_type='fake_quantize_dequantize_moving_average_abs_max', attrs=attrs, inputs=ins, outputs=outs) graph.link_to(var_node, quant_op_node) graph.link_to(scale_in_node, quant_op_node) graph.link_to(quant_op_node, quant_var_node) graph.link_to(quant_op_node, scale_out_node) if not self._is_test: graph.link_to(state_in_node, quant_op_node) graph.link_to(accum_in_node, quant_op_node) graph.link_to(quant_op_node, state_out_node) graph.link_to(quant_op_node, accum_out_node) return quant_var_node, scale_out_node