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# SPDX-FileCopyrightText: Copyright (c) 2021-2022 NVIDIA CORPORATION & AFFILIATES. All rights reserved.
# SPDX-License-Identifier: LicenseRef-NvidiaProprietary
#
# NVIDIA CORPORATION, its affiliates and licensors retain all intellectual
# property and proprietary rights in and to this material, related
# documentation and any modifications thereto. Any use, reproduction,
# disclosure or distribution of this material and related documentation
# without an express license agreement from NVIDIA CORPORATION or
# its affiliates is strictly prohibited.
"""Custom replacement for `torch.nn.functional.conv2d` that supports
arbitrarily high order gradients with zero performance penalty."""

import contextlib
import torch
from pdb import set_trace as st
import traceback

# pylint: disable=redefined-builtin
# pylint: disable=arguments-differ
# pylint: disable=protected-access

#----------------------------------------------------------------------------

enabled = False  # Enable the custom op by setting this to true.
weight_gradients_disabled = False  # Forcefully disable computation of gradients with respect to the weights.


@contextlib.contextmanager
def no_weight_gradients(disable=True):
    global weight_gradients_disabled
    old = weight_gradients_disabled
    if disable:
        weight_gradients_disabled = True
    yield
    weight_gradients_disabled = old


#----------------------------------------------------------------------------


def conv2d(input,
           weight,
           bias=None,
           stride=1,
           padding=0,
           dilation=1,
           groups=1):
    if _should_use_custom_op(input):
        return _conv2d_gradfix(transpose=False,
                               weight_shape=weight.shape,
                               stride=stride,
                               padding=padding,
                               output_padding=0,
                               dilation=dilation,
                               groups=groups).apply(input, weight, bias)
    return torch.nn.functional.conv2d(input=input,
                                      weight=weight,
                                      bias=bias,
                                      stride=stride,
                                      padding=padding,
                                      dilation=dilation,
                                      groups=groups)


def conv_transpose2d(input,
                     weight,
                     bias=None,
                     stride=1,
                     padding=0,
                     output_padding=0,
                     groups=1,
                     dilation=1):
    if _should_use_custom_op(input):
        return _conv2d_gradfix(transpose=True,
                               weight_shape=weight.shape,
                               stride=stride,
                               padding=padding,
                               output_padding=output_padding,
                               groups=groups,
                               dilation=dilation).apply(input, weight, bias)
    return torch.nn.functional.conv_transpose2d(input=input,
                                                weight=weight,
                                                bias=bias,
                                                stride=stride,
                                                padding=padding,
                                                output_padding=output_padding,
                                                groups=groups,
                                                dilation=dilation)


#----------------------------------------------------------------------------


def _should_use_custom_op(input):
    assert isinstance(input, torch.Tensor)
    if (not enabled) or (not torch.backends.cudnn.enabled):
        return False
    if input.device.type != 'cuda':
        return False
    return True


def _tuple_of_ints(xs, ndim):
    xs = tuple(xs) if isinstance(xs, (tuple, list)) else (xs, ) * ndim
    assert len(xs) == ndim
    assert all(isinstance(x, int) for x in xs)
    return xs


#----------------------------------------------------------------------------

_conv2d_gradfix_cache = dict()
_null_tensor = torch.empty([0])


def _conv2d_gradfix(transpose, weight_shape, stride, padding, output_padding,
                    dilation, groups):
    # Parse arguments.
    ndim = 2
    weight_shape = tuple(weight_shape)
    stride = _tuple_of_ints(stride, ndim)
    padding = _tuple_of_ints(padding, ndim)
    output_padding = _tuple_of_ints(output_padding, ndim)
    dilation = _tuple_of_ints(dilation, ndim)

    # Lookup from cache.
    key = (transpose, weight_shape, stride, padding, output_padding, dilation,
           groups)
    if key in _conv2d_gradfix_cache:
        return _conv2d_gradfix_cache[key]

    # Validate arguments.
    assert groups >= 1
    assert len(weight_shape) == ndim + 2
    assert all(stride[i] >= 1 for i in range(ndim))
    assert all(padding[i] >= 0 for i in range(ndim))
    assert all(dilation[i] >= 0 for i in range(ndim))
    if not transpose:
        assert all(output_padding[i] == 0 for i in range(ndim))
    else:  # transpose
        assert all(0 <= output_padding[i] < max(stride[i], dilation[i])
                   for i in range(ndim))

    # Helpers.
    common_kwargs = dict(stride=stride,
                         padding=padding,
                         dilation=dilation,
                         groups=groups)

    def calc_output_padding(input_shape, output_shape):
        if transpose:
            return [0, 0]
        return [
            input_shape[i + 2] - (output_shape[i + 2] - 1) * stride[i] -
            (1 - 2 * padding[i]) - dilation[i] * (weight_shape[i + 2] - 1)
            for i in range(ndim)
        ]

    # Forward & backward.
    class Conv2d(torch.autograd.Function):
        @staticmethod
        def forward(ctx, input, weight, bias):
            assert weight.shape == weight_shape
            ctx.save_for_backward(
                input if weight.requires_grad else _null_tensor,
                weight if input.requires_grad else _null_tensor,
            )
            ctx.input_shape = input.shape

            # Simple 1x1 convolution => cuBLAS (only on Volta, not on Ampere).
            if weight_shape[2:] == stride == dilation == (
                    1, 1) and padding == (
                        0, 0) and torch.cuda.get_device_capability(
                            input.device) < (8, 0):
                a = weight.reshape(groups, weight_shape[0] // groups,
                                   weight_shape[1])
                b = input.reshape(input.shape[0], groups,
                                  input.shape[1] // groups, -1)
                c = (a.transpose(1, 2) if transpose else a) @ b.permute(
                    1, 2, 0, 3).flatten(2)
                c = c.reshape(-1, input.shape[0],
                              *input.shape[2:]).transpose(0, 1)
                c = c if bias is None else c + bias.unsqueeze(0).unsqueeze(
                    2).unsqueeze(3)
                return c.contiguous(
                    memory_format=(torch.channels_last if input.stride(1) ==
                                   1 else torch.contiguous_format))

            # General case => cuDNN.
            if transpose:
                return torch.nn.functional.conv_transpose2d(
                    input=input,
                    weight=weight,
                    bias=bias,
                    output_padding=output_padding,
                    **common_kwargs)
            return torch.nn.functional.conv2d(input=input,
                                              weight=weight,
                                              bias=bias,
                                              **common_kwargs)

        @staticmethod
        def backward(ctx, grad_output):
            input, weight = ctx.saved_tensors
            input_shape = ctx.input_shape
            grad_input = None
            grad_weight = None
            grad_bias = None

            if ctx.needs_input_grad[0]:
                p = calc_output_padding(input_shape=input_shape,
                                        output_shape=grad_output.shape)
                op = _conv2d_gradfix(transpose=(not transpose),
                                     weight_shape=weight_shape,
                                     output_padding=p,
                                     **common_kwargs)
                grad_input = op.apply(grad_output, weight, None)
                assert grad_input.shape == input_shape

            if ctx.needs_input_grad[1] and not weight_gradients_disabled:
                grad_weight = Conv2dGradWeight.apply(grad_output, input,
                                                     weight)
                assert grad_weight.shape == weight_shape

            if ctx.needs_input_grad[2]:
                grad_bias = grad_output.sum([0, 2, 3])

            return grad_input, grad_weight, grad_bias

    # Gradient with respect to the weights.
    class Conv2dGradWeight(torch.autograd.Function):
        @staticmethod
        def forward(ctx, grad_output, input, weight):
            ctx.save_for_backward(
                grad_output if input.requires_grad else _null_tensor,
                input if grad_output.requires_grad else _null_tensor,
            )
            ctx.grad_output_shape = grad_output.shape
            ctx.input_shape = input.shape

            # Simple 1x1 convolution => cuBLAS (on both Volta and Ampere).
            if weight_shape[2:] == stride == dilation == (
                    1, 1) and padding == (0, 0):
                a = grad_output.reshape(grad_output.shape[0], groups,
                                        grad_output.shape[1] // groups,
                                        -1).permute(1, 2, 0, 3).flatten(2)
                b = input.reshape(input.shape[0], groups,
                                  input.shape[1] // groups,
                                  -1).permute(1, 2, 0, 3).flatten(2)
                c = (b @ a.transpose(1, 2) if transpose else
                     a @ b.transpose(1, 2)).reshape(weight_shape)
                return c.contiguous(
                    memory_format=(torch.channels_last if input.stride(1) ==
                                   1 else torch.contiguous_format))

            # General case => cuDNN.
            # print(input.device, weight.device, flush=True)
            # for line in traceback.format_stack():
            #     print(line.strip(), flush=True)
            return torch.ops.aten.convolution_backward(
                grad_output=grad_output,
                input=input,
                weight=weight,
                bias_sizes=None,
                stride=stride,
                padding=padding,
                dilation=dilation,
                transposed=transpose,
                output_padding=output_padding,
                groups=groups,
                output_mask=[False, True, False])[1]

        @staticmethod
        def backward(ctx, grad2_grad_weight):
            grad_output, input = ctx.saved_tensors
            grad_output_shape = ctx.grad_output_shape
            input_shape = ctx.input_shape
            grad2_grad_output = None
            grad2_input = None

            if ctx.needs_input_grad[0]:
                grad2_grad_output = Conv2d.apply(input, grad2_grad_weight,
                                                 None)
                assert grad2_grad_output.shape == grad_output_shape

            if ctx.needs_input_grad[1]:
                p = calc_output_padding(input_shape=input_shape,
                                        output_shape=grad_output_shape)
                op = _conv2d_gradfix(transpose=(not transpose),
                                     weight_shape=weight_shape,
                                     output_padding=p,
                                     **common_kwargs)
                grad2_input = op.apply(grad_output, grad2_grad_weight, None)
                assert grad2_input.shape == input_shape

            return grad2_grad_output, grad2_input

    _conv2d_gradfix_cache[key] = Conv2d
    return Conv2d


#----------------------------------------------------------------------------