Files
paddlepaddle--paddle/python/paddle/quantization/imperative/ptq.py
T
2026-07-13 12:40:42 +08:00

486 lines
18 KiB
Python

# 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 logging
import os
import numpy as np
import paddle
from paddle.nn.quant import quant_layers
from ...static.log_helper import get_logger
from ...static.quantization.utils import (
_get_input_name_index,
_get_op_input_var_names,
_get_op_output_var_names,
_get_output_name_index,
)
from . import fuse_utils, ptq_config, ptq_hooks, ptq_quantizer, utils
from .ptq_registry import PTQRegistry
INFER_MODEL_SUFFIX = ".pdmodel"
INFER_PARAMS_SUFFIX = ".pdiparams"
_logger = get_logger(
__name__, logging.INFO, fmt='%(asctime)s-%(levelname)s: %(message)s'
)
class ImperativePTQ:
"""
Static post training quantization.
"""
def __init__(self, quant_config=ptq_config.default_ptq_config):
"""
Constructor.
Args:
quant_config(PTQConfig): the config of post training quantization.
The config has weight_quantizer and activation_quantizer.
In default, the weight_quantizer is PerChannelAbsmaxQuantizer
and the activation_quantizer is KLQuantizer.
"""
super().__init__()
assert isinstance(quant_config, ptq_config.PTQConfig)
self._quant_config = quant_config
def quantize(self, model, inplace=False, fuse=False, fuse_list=None):
"""
Add quant config and hook to the target layer.
Args:
model(paddle.nn.Layer): The model to be quantized.
inplace(bool): Whether apply quantization to the input model.
Default: False.
fuse(bool): Whether to fuse layers.
Default: False.
fuse_list(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.
Return
quantized_model(paddle.nn.Layer): The quantized model.
"""
assert isinstance(model, paddle.nn.Layer), (
"The model must be the instance of paddle.nn.Layer."
)
if not inplace:
model = copy.deepcopy(model)
if fuse:
model.eval()
model = fuse_utils.fuse_layers(model, fuse_list)
for name, layer in model.named_sublayers():
if (
PTQRegistry.is_supported_layer(layer)
and utils.is_leaf_layer(layer)
and not self._is_skip_layer(layer)
):
# Add quant config
quant_config = copy.deepcopy(self._quant_config)
if PTQRegistry.is_simulated_quant_layer(layer):
quant_config.enable_in_act_quantizer = True
layer._quant_config = quant_config
# register hook
hook = ptq_hooks.quant_forward_post_hook
quant_hook_handle = layer.register_forward_post_hook(hook)
quant_config.quant_hook_handle = quant_hook_handle
layer._forward_post_hooks.move_to_end(
quant_hook_handle._hook_id, last=False
)
return model
def save_quantized_model(self, model, path, input_spec=None, **config):
"""
1. Convert the quantized model
2. Call jit.save to save the inference model
3. Post process the inference model.
Args:
model (Layer): The model to be saved.
path (str): The path prefix to save model. The format is
``dirname/file_prefix`` or ``file_prefix``.
input_spec (list[InputSpec|Tensor], optional): Describes the input
of the saved model's forward method, which can be described by
InputSpec or example Tensor. If None, all input variables of
the original Layer's forward method would be the inputs of
the saved model. Default None.
**config (dict, optional): Other save configuration options for
compatibility. We do not recommend using these configurations,
they may be removed in the future. If not necessary, DO NOT use
them. Default None.
The following options are currently supported:
(1) output_spec (list[Tensor]): Selects the output targets of
the saved model. By default, all return variables of original
Layer's forward method are kept as the output of the saved model.
If the provided ``output_spec`` list is not all output variables,
the saved model will be pruned according to the given
``output_spec`` list.
Returns:
None
"""
assert isinstance(model, paddle.nn.Layer), (
"The model must be the instance of paddle.nn.Layer."
)
# Convert and save dygraph quantized model
self._convert(model)
paddle.jit.save(layer=model, path=path, input_spec=input_spec, **config)
# Load inference program
is_dynamic_mode = False
if paddle.in_dynamic_mode():
is_dynamic_mode = True
paddle.enable_static()
place = paddle.CPUPlace()
scope = paddle.static.global_scope()
exe = paddle.static.Executor(place)
dirname = os.path.dirname(path)
basename = os.path.basename(path)
model_filename = basename + INFER_MODEL_SUFFIX
params_filename = basename + INFER_PARAMS_SUFFIX
[
infer_program,
feed_target_names,
fetch_targets,
] = paddle.static.load_inference_model(
path_prefix=dirname,
executor=exe,
model_filename=model_filename,
params_filename=params_filename,
)
# Process inference program
self._clean_up(infer_program)
self._gather_input_thresholds(infer_program, scope)
self._remove_scale_op(infer_program)
# Save final program
model_name = None
if model_filename is None:
model_name = "model"
elif model_filename.endswith(".pdmodel"):
model_name = model_filename.rsplit(".", 1)[0]
else:
model_name = model_filename
path_prefix = os.path.join(dirname, model_name)
feed_vars = [
infer_program.global_block().var(name) for name in feed_target_names
]
paddle.static.save_inference_model(
path_prefix,
feed_vars,
fetch_targets,
executor=exe,
program=infer_program.clone(),
)
if is_dynamic_mode:
paddle.disable_static()
def _convert(self, model):
"""
Convert the quantized model.
Args:
model(paddle.nn.Layer): The quantized model.
inplace(bool): Whether apply conversion to the input model.
Default: False.
Returns:
None
"""
for name, sub_layer in model.named_sublayers():
if self._is_quant_layer(sub_layer):
sub_layer._quant_config.quant_hook_handle.remove()
self._cal_thresholds(model)
for name, sub_layer in model.named_sublayers():
if self._is_quant_layer(sub_layer):
self._save_output_thresholds(sub_layer, sub_layer._quant_config)
self._wrap_simulated_layers(model)
def _cal_thresholds(self, model):
"""
Calculate the thresholds of inputs and outputs.
Args:
model(paddle.nn.Layer): The quantized model.
Returns:
None
"""
assert isinstance(model, paddle.nn.Layer), (
"The input model must be the instance of paddle.nn.Layer."
)
total_num = 0
cur_num = 0
for name, sub_layer in model.named_sublayers():
if self._is_quant_layer(sub_layer):
total_num += 1
for name, sub_layer in model.named_sublayers():
if self._is_quant_layer(sub_layer):
cur_num += 1
if cur_num % 5 == 0:
_logger.info(f"Process the {cur_num} / {total_num} layer")
quant_config = sub_layer._quant_config
if quant_config.enable_in_act_quantizer:
quant_config.in_act_quantizer.cal_thresholds()
quant_config.out_act_quantizer.cal_thresholds()
if PTQRegistry.is_simulated_quant_layer(sub_layer):
weights = (sub_layer.weight,)
quant_config.wt_quantizer.sample_data(sub_layer, weights)
quant_config.wt_quantizer.cal_thresholds()
def _save_output_thresholds(self, sub_layer, quant_config):
"""
Save the output thresholds to the layer.
Args:
sub_layer(paddle.nn.Layer): The quantized layer.
quant_config(PTQConfig): the quant config for the layer.
Returns:
None
"""
assert isinstance(sub_layer, paddle.nn.Layer), (
"The input model must be the instance of paddle.nn.Layer."
)
layer_info = PTQRegistry.layer_info(sub_layer)
output_names = layer_info.output_names
output_thresholds = quant_config.out_act_quantizer.thresholds
assert len(output_names) == 1
if len(output_thresholds) == 1:
save_name = output_names[0] + str(0) + "_threshold"
sub_layer._set_op_attrs({save_name: output_thresholds[0]})
sub_layer._set_op_attrs({"out_threshold": output_thresholds[0]})
else:
_logger.warning(
f"output_thresholds shape of {output_names[0]} need to be 1, but received {len(output_thresholds)}"
)
def _wrap_simulated_layers(self, model):
"""
Replace conv2d and linear with the quantized layers, and save
thresholds into the fake layers.
Args:
model(paddle.nn.Layer): The model to be quantized.
Returns:
None
"""
assert isinstance(model, paddle.nn.Layer), (
"The input model must be the instance of paddle.nn.Layer."
)
for name, sub_layer in model.named_sublayers():
if self._is_quant_layer(
sub_layer
) and PTQRegistry.is_simulated_quant_layer(sub_layer):
quant_config = sub_layer._quant_config
assert quant_config.enable_in_act_quantizer is True
wt_quantizer = quant_config.wt_quantizer
in_act_quantizer = quant_config.in_act_quantizer
# create layer
quant_layer_name = None
for key, value in utils.layer_name_map.items():
if isinstance(sub_layer, value):
quant_layer_name = 'Quantized' + key
break
assert quant_layer_name is not None
if isinstance(wt_quantizer, ptq_quantizer.AbsmaxQuantizer):
weight_quantize_type = "abs_max"
else:
weight_quantize_type = "channel_wise_abs_max"
kwargs = {
"weight_quantize_type": weight_quantize_type,
"activation_quantize_type": "moving_average_abs_max",
"weight_bits": wt_quantizer.quant_bits,
"activation_bits": in_act_quantizer.quant_bits,
}
quant_layer = quant_layers.__dict__[quant_layer_name](
sub_layer, **kwargs
)
# save the input thresholds
assert hasattr(quant_layer, "_fake_quant_input")
assert hasattr(quant_layer._fake_quant_input, "_scale")
if len(in_act_quantizer.thresholds) == 1:
input_threshold = np.array(
[in_act_quantizer.thresholds[0]], dtype=np.float32
)
quant_layer._fake_quant_input._scale.set_value(
input_threshold
)
assert hasattr(quant_layer, "_fake_quant_weight")
assert hasattr(quant_layer._fake_quant_weight, "_scale")
assert len(wt_quantizer.thresholds) == 1
weight_threshold = wt_quantizer.thresholds[0]
if isinstance(weight_threshold, list):
weight_threshold = np.array(
weight_threshold, dtype=np.float32
)
else:
weight_threshold = np.array(
[weight_threshold], dtype=np.float32
)
quant_layer._fake_quant_weight._scale.set_value(
weight_threshold
)
# save the output thresholds
self._save_output_thresholds(quant_layer, quant_config)
# replace the layer
parent_layer, sub_name = utils.find_parent_layer_and_sub_name(
model, name
)
setattr(parent_layer, sub_name, quant_layer)
def _gather_input_thresholds(self, program, scope):
"""
Get and save input thresholds from the front ops.
Args:
program(Program): the input infer program.
scope(Scope): the corresponding scope for the program.
Returns:
None
"""
for op in utils.program_all_ops(program):
for in_var_name in _get_op_input_var_names(op):
previous_op = utils.find_previous_op(op.block, in_var_name)
if previous_op is None:
continue
if (
"quantize_dequantize" in previous_op.type
or previous_op.type == "moving_average_abs_max_scale"
):
attr_name = previous_op.output('OutScale')[0]
in_threshold = utils.load_variable_data(scope, attr_name)
in_threshold = utils.fp_numpy_to_naive(in_threshold)
argname, index = _get_input_name_index(op, in_var_name)
op._set_attr(
argname + str(index) + "_threshold", in_threshold
)
op._set_attr("with_quant_attr", True)
else:
for out_var_name in _get_op_output_var_names(previous_op):
if out_var_name != in_var_name:
continue
argname, index = _get_output_name_index(
previous_op, out_var_name
)
attr_name = argname + str(index) + "_threshold"
if not previous_op.has_attr(attr_name):
continue
threshold = previous_op.attr(attr_name)
argname, index = _get_input_name_index(op, in_var_name)
attr_name = argname + str(index) + "_threshold"
op._set_attr(attr_name, threshold)
op._set_attr("with_quant_attr", True)
def _clean_up(self, program):
"""
Remove useless thresholds which are added in jit.save.
Args:
program(Program): the input infer program.
Returns:
None
"""
def _helper(op, next_op, old_attr_name, new_attr_name):
if (
op.has_attr(old_attr_name)
and next_op.has_attr(old_attr_name)
and op.attr(old_attr_name) == next_op.attr(old_attr_name)
):
threshold = op.attr(old_attr_name)
op._remove_attr(old_attr_name)
next_op._remove_attr(old_attr_name)
next_op._set_attr(new_attr_name, threshold)
next_op._set_attr("with_quant_attr", True)
for op in utils.program_all_ops(program):
if "quantize_dequantize" in op.type:
# remove the thresholds in fake ops
for attr_name in op.attr_names:
if "_threshold" in attr_name:
op._remove_attr(attr_name)
elif op.type in ["conv2d", "matmul"]:
# change the thresholds in conv2d/matmul + eleadd
arg_name = "Output" if op.type == "conv2d" else "Out"
out_var_name = op.output(arg_name)[0]
next_ops = utils.find_next_ops(op.block, out_var_name)
if len(next_ops) > 1 or next_ops[0].type != "elementwise_add":
continue
next_op = next_ops[0]
argname, index = _get_output_name_index(op, out_var_name)
old_attr_name = argname + str(index) + "_threshold"
argname, index = _get_output_name_index(
next_op, next_op.output("Out")[0]
)
new_attr_name = argname + str(index) + "_threshold"
_helper(op, next_op, old_attr_name, new_attr_name)
_helper(op, next_op, "out_threshold", "out_threshold")
def _remove_scale_op(self, program):
"""
Remove the moving_average_abs_max_scale op.
"""
for op in utils.program_all_ops(program):
if op.type == "moving_average_abs_max_scale":
in_var_name = op.input("X")[0]
out_var_name = op.output("Out")[0]
next_ops = utils.find_next_ops(op.block, out_var_name)
for next_op in next_ops:
next_op._rename_input(out_var_name, in_var_name)
@staticmethod
def _is_skip_layer(layer):
return hasattr(layer, "skip_quant") and layer.skip_quant is True
@staticmethod
def _is_quant_layer(layer):
return hasattr(layer, "_quant_config")