214 lines
6.6 KiB
Python
214 lines
6.6 KiB
Python
# Copyright (c) 2022 PaddlePaddle Authors. All Rights Reserved.
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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from __future__ import annotations
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import functools
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import math
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from typing import TYPE_CHECKING, Literal, TypeAlias
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import numpy as np
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from ...base.framework import (
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EagerParamBase,
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default_main_program,
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in_dygraph_mode,
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use_pir_api,
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)
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from .lazy_init import lazy_init_helper
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if TYPE_CHECKING:
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import paddle
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_NonLinearity: TypeAlias = Literal[ # noqa: PYI047
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"sigmoid",
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"linear",
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"conv1d",
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"conv2d",
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"conv3d",
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"conv1d_transpose",
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"conv_transpose1d",
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"conv2d_transpose",
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"conv_transpose2d",
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"conv3d_transpose",
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"conv_transpose3d",
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"tanh",
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"relu",
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"leaky_relu",
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"selu",
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]
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__all__ = []
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class Initializer:
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"""Base class for parameter initializers
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Defines the common interface of parameter initializers.
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They add operations to the init program that are used
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to initialize parameter. Users should not use this class
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directly, but need to use one of its implementations.
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"""
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def __init__(self) -> None:
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pass
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def __call__(
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self, param: paddle.Tensor, block: paddle.pir.Block | None = None
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):
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if not lazy_init_helper().state:
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return self.forward(param, block)
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return self._lazy_init(param, block)
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def forward(
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self, param: paddle.Tensor, block: paddle.pir.Block | None = None
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) -> paddle.Tensor | None:
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"""Add corresponding initialization operations to the network."""
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raise NotImplementedError
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def _lazy_init(
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self, param: paddle.Tensor, block: paddle.pir.Block | None = None
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):
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"""
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Apply lazy initialization
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"""
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assert in_dygraph_mode()
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def init_op_creator(
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forward, param: paddle.Tensor, block: paddle.pir.Block | None
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):
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if use_pir_api():
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new_var = param
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else:
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new_var = param._to_static_var(True, block=block)
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# Record initializer operator
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with lazy_init_helper():
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forward(new_var, block)
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# Add hook function for initializing param in dygraph mode
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param.set_init_func(functools.partial(self.forward))
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param._init_op_creator = functools.partial(
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init_op_creator, self.forward
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)
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return param
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def _check_block(self, block: paddle.pir.Block | None) -> paddle.pir.Block:
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if block is None:
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block = default_main_program().global_block()
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return block
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def _compute_fans(self, var: paddle.Tensor) -> tuple[int, int]:
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"""Compute the fan_in and the fan_out for layers
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This method computes the fan_in and the fan_out
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for neural network layers, if not specified. It is
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not possible to perfectly estimate fan_in and fan_out.
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This method will estimate it correctly for matrix multiply and
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convolutions.
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Args:
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var: variable for which fan_in and fan_out have to be computed.
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Returns:
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tuple of two integers (fan_in, fan_out).
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"""
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shape = (
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var._local_shape
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if (isinstance(var, EagerParamBase) and var.is_dist())
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else var.shape
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)
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if not shape or len(shape) == 0:
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fan_in = fan_out = 1
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elif len(shape) == 1:
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fan_in = fan_out = shape[0]
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elif len(shape) == 2:
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# This is the case for simple matrix multiply
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fan_in = shape[0]
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fan_out = shape[1]
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else:
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# Assume this to be a convolutional kernel
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# In PaddlePaddle, the shape of the kernel is like:
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# [num_filters, num_filter_channels, ...] where the remaining
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# dimensions are the filter_size
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receptive_field_size = np.prod(shape[2:])
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fan_in = shape[1] * receptive_field_size
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fan_out = shape[0] * receptive_field_size
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return (fan_in, fan_out)
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def calculate_gain(
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nonlinearity: str, param: bool | float | None = None
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) -> float:
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"""
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Get the recommended ``gain`` value of some nonlinearity function. ``gain`` value can be used in some
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``paddle.nn.initializer`` api to adjust the initialization value.
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Args:
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nonlinearity(str): name of nonlinearity activation function. If it is a linear function, such as:
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`linear/conv1d/conv2d/conv3d/conv1d_transpose/conv2d_transpose/conv3d_transpose` , 1.0 will be returned.
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param(bool|int|float|None, optional): optional parameter for some nonlinearity function. Now, it only applies to
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'leaky_relu'. Default: None, it will be calculated as 0.01 in the formula.
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Returns:
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A float value, which is the recommended gain for this nonlinearity function.
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Examples:
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.. code-block:: pycon
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>>> import paddle
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>>> gain = paddle.nn.initializer.calculate_gain('tanh')
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>>> print(gain)
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1.6666666666666667
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>>> # 5.0 / 3
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>>> gain = paddle.nn.initializer.calculate_gain('leaky_relu', param=1.0)
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>>> print(gain)
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1.0
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>>> # math.sqrt(2.0 / (1+param^2))
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>>> initializer = paddle.nn.initializer.Orthogonal(gain)
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"""
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if param is None:
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param = 0.01
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else:
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assert isinstance(param, (bool, int, float))
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param = float(param)
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recommended_gain = {
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'sigmoid': 1,
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'linear': 1,
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'conv1d': 1,
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'conv2d': 1,
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'conv3d': 1,
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'conv1d_transpose': 1,
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'conv_transpose1d': 1,
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'conv2d_transpose': 1,
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'conv_transpose2d': 1,
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'conv3d_transpose': 1,
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'conv_transpose3d': 1,
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'tanh': 5.0 / 3,
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'relu': math.sqrt(2.0),
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'leaky_relu': math.sqrt(2.0 / (1 + param**2)),
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'selu': 3.0 / 4,
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}
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if nonlinearity in recommended_gain.keys():
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return recommended_gain[nonlinearity]
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else:
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raise ValueError(
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f"nonlinearity function {nonlinearity} is not supported now."
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)
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