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未验证 提交 5050e761 编写于 作者: B Bai Yifan 提交者: GitHub
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Support user-defined activation/weight quantize and preprocess. (#28570) 

* support user-defined quant and preprocess
上级 11e32baf
隐藏空白更改
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Showing with 373 addition and 39 deletion
python/paddle/fluid/contrib/slim/quantization/imperative/qat.py
浏览文件 @ 5050e761
......@@ -59,7 +59,11 @@ class ImperativeQuantAware(object):
weight_quantize_type='abs_max',
activation_quantize_type='moving_average_abs_max',
moving_rate=0.9,
quantizable_layer_type=['Conv2D', 'Linear']):
quantizable_layer_type=['Conv2D', 'Linear'],
weight_preprocess_layer=None,
act_preprocess_layer=None,
weight_quantize_layer=None,
act_quantize_layer=None):
"""
The constructor for ImperativeQuantAware.
......@@ -81,7 +85,28 @@ class ImperativeQuantAware(object):
quantizable_op_type(list[str]): List the type of layers that will be quantized.
Default is ['Conv2D', 'Linear']. The quantizable_op_type in
QuantizationFreezePass and ConvertToInt8Pass must be the same as this.
weight_preprocess_layer(paddle.nn.Layer, optional): A paddle Layer that defines how to preprocess
weight before quantization. Using this can quickly test if user's
preprocess method works or not. The 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_layer(paddle.nn.Layer, optional): A paddle Layer that defines how to preprocess
activation before quantization. Using this can quickly test if user's
preprocess method works or not. The input is non-quantized
activation and function returns processed activation to be quantized.
If None, the activation will be quantized directly. Default is None.
weight_quantize_layer(paddle.nn.Layer, optional): A paddle Layer that defines how to quantize weight.
Using this can quickly test if user's quantization method works or not.
In this layer, user should both define quantization method and
dequantization method, that is, the function's input is non-quantized
weight and returns dequantized weight. If None, will use
quantization op defined by 'weight_quantize_type'. Default is None.
act_quantize_layer(paddle.nn.Layer, optional): A paddle Layer that defines how to quantize activation.
Using this can quickly test if user's quantization method works or not.
In this layer, user should both define quantization method and
dequantization method, that is, the function's input is non-quantized
activation and returns dequantized activation. If None, will use
quantization op defined by 'activation_quantize_type'. Default is None.
Examples:
.. code-block:: python
......@@ -118,6 +143,19 @@ class ImperativeQuantAware(object):
self._activation_bits = activation_bits
self._moving_rate = moving_rate
self._weight_pre_layer = weight_preprocess_layer
self._act_pre_layer = act_preprocess_layer
self._weight_quant_layer = weight_quantize_layer
self._act_quant_layer = act_quantize_layer
t_check = lambda method: method is None or issubclass(method, dygraph.layers.Layer)
assert t_check(
self._weight_pre_layer), "weight_preprocess should be nn.Layer"
assert t_check(self._act_pre_layer), "act_preprocess should be nn.Layer"
assert t_check(
self._weight_quant_layer), "weight_quantize should be nn.Layer"
assert t_check(self._act_quant_layer), "act_quantize should be nn.Layer"
quant_type = {
'abs_max', 'moving_average_abs_max', 'channel_wise_abs_max'
}
......@@ -189,7 +227,9 @@ class ImperativeQuantAware(object):
quantized_layer = quant_nn.__dict__[quantized_counterpart[index]](
layer, self._weight_bits, self._activation_bits, self._moving_rate,
self._weight_quantize_type, self._activation_quantize_type)
self._weight_quantize_type, self._activation_quantize_type,
self._weight_pre_layer, self._act_pre_layer,
self._weight_quant_layer, self._act_quant_layer)
return quantized_layer
......
python/paddle/fluid/contrib/slim/quantization/imperative/quant_nn.py
浏览文件 @ 5050e761
......@@ -332,7 +332,11 @@ class QuantizedConv2D(layers.Layer):
activation_bits=8,
moving_rate=0.9,
weight_quantize_type='abs_max',
activation_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')
......@@ -347,26 +351,44 @@ class QuantizedConv2D(layers.Layer):
self.bias = getattr(layer, 'bias')
# For FakeQuant
self._conv2d_quant_axis = 0
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)
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)
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)
quant_weight = self._fake_quant_weight(self.weight)
weight = self.weight
if self._weight_preprocess is not None:
weight = self._weight_preprocess(self.weight)
quant_weight = self._fake_quant_weight(weight)
if in_dygraph_mode() and self._l_type == 'conv2d':
attrs = ('strides', self._stride, 'paddings', self._padding,
......@@ -428,7 +450,11 @@ class QuantizedLinear(layers.Layer):
activation_bits=8,
moving_rate=0.9,
weight_quantize_type='abs_max',
activation_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._act = getattr(layer, '_act')
......@@ -437,26 +463,46 @@ class QuantizedLinear(layers.Layer):
self.bias = getattr(layer, 'bias')
# For FakeQuant
self._linear_quant_axis = 1
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)
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)
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)
quant_weight = self._fake_quant_weight(self.weight)
weight = self.weight
if self._weight_preprocess is not None:
weight = self._weight_preprocess(self.weight)
quant_weight = self._fake_quant_weight(weight)
if in_dygraph_mode():
pre_bias = _varbase_creator(dtype=input.dtype)
core.ops.matmul(quant_input, quant_weight, pre_bias, 'transpose_X',
......
python/paddle/fluid/contrib/slim/tests/test_imperative_qat_user_defined.py 0 → 100644
浏览文件 @ 5050e761
# 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 __future__ import print_function
import os
import numpy as np
import random
import unittest
import logging
import paddle
import paddle.nn as nn
from paddle.optimizer import Adam
from paddle.fluid.contrib.slim.quantization import ImperativeQuantAware
from paddle.fluid.contrib.slim.quantization import QuantizationTransformPass
from paddle.nn import Sequential
from paddle.fluid.dygraph import Conv2D
from paddle.nn import Pool2D
from paddle.fluid.dygraph import Linear
from paddle.fluid.log_helper import get_logger
os.environ["CPU_NUM"] = "1"
_logger = get_logger(
__name__, logging.INFO, fmt='%(asctime)s-%(levelname)s: %(message)s')
class PACT(nn.Layer):
def __init__(self, init_value=20):
super(PACT, self).__init__()
alpha_attr = paddle.ParamAttr(
name=self.full_name() + ".pact",
initializer=paddle.nn.initializer.Constant(value=init_value))
self.alpha = self.create_parameter(
shape=[1], attr=alpha_attr, dtype='float32')
def forward(self, x):
out_left = paddle.nn.functional.relu(x - self.alpha)
out_right = paddle.nn.functional.relu(-self.alpha - x)
x = x - out_left + out_right
return x
class CustomQAT(nn.Layer):
def __init__(self):
super(CustomQAT, self).__init__()
attr = paddle.ParamAttr(
initializer=paddle.nn.initializer.Constant(value=1.0))
self.u_param = self.create_parameter(
shape=[1], attr=attr, dtype='float32')
self.l_param = self.create_parameter(
shape=[1], attr=attr, dtype='float32')
self.alpha_param = self.create_parameter(
shape=[1], attr=attr, dtype='float32')
self.upper = self.create_parameter(
shape=[1], attr=attr, dtype='float32')
self.upper.stop_gradient = True
self.lower = self.create_parameter(
shape=[1], attr=attr, dtype='float32')
self.lower.stop_gradient = True
def forward(self, x):
def clip(x, upper, lower):
x = x + paddle.nn.functional.relu(lower - x)
x = x - paddle.nn.functional.relu(x - upper)
return x
def phi_function(x, mi, alpha, delta):
s = 1 / (1 - alpha)
k = paddle.log(2 / alpha - 1) * (1 / delta)
x = (paddle.tanh((x - mi) * k)) * s
return x
def dequantize(x, lower_bound, delta, interval):
x = ((x + 1) / 2 + interval) * delta + lower_bound
return x
bit = 8
bit_range = 2**bit - 1
paddle.assign(self.upper * 0.9 + self.u_param * 0.1, self.upper)
paddle.assign(self.lower * 0.9 + self.l_param * 0.1, self.lower)
x = clip(x, self.upper, self.lower)
delta = (self.upper - self.lower) / bit_range
interval = (x - self.lower) / delta
mi = (interval + 0.5) * delta + self.l_param
x = phi_function(x, mi, self.alpha_param, delta)
x = dequantize(x, self.l_param, delta, interval)
return x
class ImperativeLenet(paddle.nn.Layer):
def __init__(self, num_classes=10, classifier_activation='softmax'):
super(ImperativeLenet, self).__init__()
self.features = Sequential(
Conv2D(
num_channels=1,
num_filters=6,
filter_size=3,
stride=1,
padding=1),
Pool2D(
pool_size=2, pool_type='max', pool_stride=2),
Conv2D(
num_channels=6,
num_filters=16,
filter_size=5,
stride=1,
padding=0),
Pool2D(
pool_size=2, pool_type='max', pool_stride=2))
self.fc = Sequential(
Linear(
input_dim=400, output_dim=120),
Linear(
input_dim=120, output_dim=84),
Linear(
input_dim=84, output_dim=num_classes,
act=classifier_activation))
def forward(self, inputs):
x = self.features(inputs)
x = paddle.flatten(x, 1)
x = self.fc(x)
return x
class TestUserDefinedActPreprocess(unittest.TestCase):
def setUp(self):
_logger.info("test act_preprocess")
self.imperative_qat = ImperativeQuantAware(act_preprocess_layer=PACT)
def test_quant_aware_training(self):
imperative_qat = self.imperative_qat
seed = 1
np.random.seed(seed)
paddle.static.default_main_program().random_seed = seed
paddle.static.default_startup_program().random_seed = seed
lenet = ImperativeLenet()
fixed_state = {}
param_init_map = {}
for name, param in lenet.named_parameters():
p_shape = param.numpy().shape
p_value = param.numpy()
if name.endswith("bias"):
value = np.zeros_like(p_value).astype('float32')
else:
value = np.random.normal(
loc=0.0, scale=0.01,
size=np.product(p_shape)).reshape(p_shape).astype('float32')
fixed_state[name] = value
param_init_map[param.name] = value
lenet.set_dict(fixed_state)
imperative_qat.quantize(lenet)
adam = Adam(learning_rate=0.001, parameters=lenet.parameters())
dynamic_loss_rec = []
def train(model):
adam = Adam(learning_rate=0.001, parameters=model.parameters())
epoch_num = 1
for epoch in range(epoch_num):
model.train()
for batch_id, data in enumerate(train_reader()):
x_data = np.array([x[0].reshape(1, 28, 28)
for x in data]).astype('float32')
y_data = np.array(
[x[1] for x in data]).astype('int64').reshape(-1, 1)
img = paddle.to_tensor(x_data)
label = paddle.to_tensor(y_data)
out = model(img)
acc = paddle.metric.accuracy(out, label, k=1)
loss = nn.functional.loss.cross_entropy(out, label)
avg_loss = paddle.mean(loss)
avg_loss.backward()
adam.minimize(avg_loss)
model.clear_gradients()
if batch_id % 50 == 0:
_logger.info(
"Train | At epoch {} step {}: loss = {:}, acc= {:}".
format(epoch, batch_id,
avg_loss.numpy(), acc.numpy()))
break
def test(model):
model.eval()
avg_acc = [[], []]
for batch_id, data in enumerate(test_reader()):
x_data = np.array([x[0].reshape(1, 28, 28)
for x in data]).astype('float32')
y_data = np.array(
[x[1] for x in data]).astype('int64').reshape(-1, 1)
img = paddle.to_tensor(x_data)
label = paddle.to_tensor(y_data)
out = model(img)
acc_top1 = paddle.metric.accuracy(input=out, label=label, k=1)
acc_top5 = paddle.metric.accuracy(input=out, label=label, k=5)
avg_acc[0].append(acc_top1.numpy())
avg_acc[1].append(acc_top5.numpy())
if batch_id % 100 == 0:
_logger.info(
"Test | step {}: acc1 = {:}, acc5 = {:}".format(
batch_id, acc_top1.numpy(), acc_top5.numpy()))
train_reader = paddle.batch(
paddle.dataset.mnist.train(), batch_size=512, drop_last=True)
test_reader = paddle.batch(paddle.dataset.mnist.test(), batch_size=512)
train(lenet)
test(lenet)
class TestUserDefinedWeightPreprocess(TestUserDefinedActPreprocess):
def setUp(self):
_logger.info("test weight_preprocess")
self.imperative_qat = ImperativeQuantAware(weight_preprocess_layer=PACT)
class TestUserDefinedActQuantize(TestUserDefinedActPreprocess):
def setUp(self):
_logger.info("test act_quantize")
self.imperative_qat = ImperativeQuantAware(act_quantize_layer=CustomQAT)
class TestUserDefinedWeightQuantize(TestUserDefinedActPreprocess):
def setUp(self):
_logger.info("test weight_quantize")
self.imperative_qat = ImperativeQuantAware(
weight_quantize_layer=CustomQAT)
if __name__ == '__main__':
unittest.main()
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