Bernstein_Poster_2024/avg_pooling_nnmf_sp1.01/make_network.py

import torch
from append_block import append_block
from L1NormLayer import L1NormLayer
from NNMF2d import NNMF2d
from append_parameter import append_parameter


def make_network(
    input_dim_x: int,
    input_dim_y: int,
    input_number_of_channel: int,
    iterations: int,
    torch_device: torch.device,
    epsilon: bool | None = None,
    positive_function_type: int = 0,
    beta: float | None = None,
    # Conv:
    number_of_output_channels: list[int] = [32*1, 64*1, 96*1, 10],
    kernel_size_conv: list[tuple[int, int]] = [
        (5, 5),
        (5, 5),
        (-1, -1),  # Take the whole input image x and y size
        (1, 1),
    ],
    stride_conv: list[tuple[int, int]] = [
        (1, 1),
        (1, 1),
        (1, 1),
        (1, 1),
    ],
    padding_conv: list[tuple[int, int]] = [
        (0, 0),
        (0, 0),
        (0, 0),
        (0, 0),
    ],
    dilation_conv: list[tuple[int, int]] = [
        (1, 1),
        (1, 1),
        (1, 1),
        (1, 1),
    ],
    # Pool:
    kernel_size_pool: list[tuple[int, int]] = [
        (2, 2),
        (2, 2),
        (-1, -1),  # No pooling layer
        (-1, -1),  # No pooling layer
    ],
    stride_pool: list[tuple[int, int]] = [
        (2, 2),
        (2, 2),
        (-1, -1),
        (-1, -1),
    ],
    padding_pool: list[tuple[int, int]] = [
        (0, 0),
        (0, 0),
        (0, 0),
        (0, 0),
    ],
    dilation_pool: list[tuple[int, int]] = [
        (1, 1),
        (1, 1),
        (1, 1),
        (1, 1),
    ],
    enable_onoff: bool = False,
) -> tuple[
    torch.nn.Sequential,
    list[list[torch.nn.parameter.Parameter]],
    list[str],
]:

    assert len(number_of_output_channels) == len(kernel_size_conv)
    assert len(number_of_output_channels) == len(stride_conv)
    assert len(number_of_output_channels) == len(padding_conv)
    assert len(number_of_output_channels) == len(dilation_conv)
    assert len(number_of_output_channels) == len(kernel_size_pool)
    assert len(number_of_output_channels) == len(stride_pool)
    assert len(number_of_output_channels) == len(padding_pool)
    assert len(number_of_output_channels) == len(dilation_pool)

    if enable_onoff:
        input_number_of_channel *= 2

    parameter_cnn_top: list[torch.nn.parameter.Parameter] = []
    parameter_nnmf: list[torch.nn.parameter.Parameter] = []
    parameter_norm: list[torch.nn.parameter.Parameter] = []

    test_image = torch.ones(
        (1, input_number_of_channel, input_dim_x, input_dim_y), device=torch_device
    )

    network = torch.nn.Sequential()
    network = network.to(torch_device)

    for block_id in range(0, len(number_of_output_channels)):

        test_image = append_block(
            network=network,
            out_channels=number_of_output_channels[block_id],
            test_image=test_image,
            dilation=dilation_conv[block_id],
            padding=padding_conv[block_id],
            stride=stride_conv[block_id],
            kernel_size=kernel_size_conv[block_id],
            epsilon=epsilon,
            positive_function_type=positive_function_type,
            beta=beta,
            iterations=iterations,
            torch_device=torch_device,
            parameter_cnn_top=parameter_cnn_top,
            parameter_nnmf=parameter_nnmf,
            parameter_norm=parameter_norm,
        )

        if (kernel_size_pool[block_id][0] > 0) and (kernel_size_pool[block_id][1] > 0):
            network.append(torch.nn.AvgPool2d(kernel_size=(2, 2), stride=(2, 2)))
            test_image = network[-1](test_image)

            # network.append(torch.nn.ReLU())
            # test_image = network[-1](test_image)

            # mock_output = (
            #     torch.nn.functional.conv2d(
            #         torch.zeros(
            #             1,
            #             1,
            #             test_image.shape[2],
            #             test_image.shape[3],
            #         ),
            #         torch.zeros((1, 1, 2, 2)),
            #         stride=(2, 2),
            #         padding=(0, 0),
            #         dilation=(1, 1),
            #     )
            #     .squeeze(0)
            #     .squeeze(0)
            # )

            # network.append(
            #     torch.nn.Unfold(
            #         kernel_size=(2, 2),
            #         stride=(2, 2),
            #         padding=(0, 0),
            #         dilation=(1, 1),
            #     )
            # )
            # test_image = network[-1](test_image)

            # network.append(
            #     torch.nn.Fold(
            #         output_size=mock_output.shape,
            #         kernel_size=(1, 1),
            #         dilation=1,
            #         padding=0,
            #         stride=1,
            #     )
            # )
            # test_image = network[-1](test_image)

            # network.append(L1NormLayer())
            # test_image = network[-1](test_image)

            # network.append(
            #     NNMF2d(
            #         in_channels=test_image.shape[1],
            #         out_channels=test_image.shape[1] // 4,
            #         epsilon=epsilon,
            #         positive_function_type=positive_function_type,
            #         beta=beta,
            #         iterations=iterations,
            #         local_learning=False,
            #         local_learning_kl=False,
            #     ).to(torch_device)
            # )

            # test_image = network[-1](test_image)
            # append_parameter(module=network[-1], parameter_list=parameter_nnmf)

            # network.append(
            #     torch.nn.BatchNorm2d(
            #         num_features=test_image.shape[1],
            #         device=torch_device,
            #         momentum=0.1,
            #         track_running_stats=False,
            #     )
            # )
            # test_image = network[-1](test_image)
            # append_parameter(module=network[-1], parameter_list=parameter_norm)

    network.append(torch.nn.Softmax(dim=1))
    test_image = network[-1](test_image)

    network.append(torch.nn.Flatten())
    test_image = network[-1](test_image)

    parameters: list[list[torch.nn.parameter.Parameter]] = [
        parameter_cnn_top,
        parameter_nnmf,
        parameter_norm,
    ]

    name_list: list[str] = [
        "cnn_top",
        "nnmf",
        "batchnorm2d",
    ]

    return (
        network,
        parameters,
        name_list,
    )