pytorch-image-models/timm/models/pnasnet.py

"""
 pnasnet5large implementation grabbed from Cadene's pretrained models
 Additional credit to https://github.com/creafz

 https://github.com/Cadene/pretrained-models.pytorch/blob/master/pretrainedmodels/models/pnasnet.py

"""
from __future__ import print_function, division, absolute_import
from collections import OrderedDict

import torch
import torch.nn as nn
import torch.nn.functional as F

from .registry import register_model
from .helpers import load_pretrained
from .layers import SelectAdaptivePool2d

__all__ = ['PNASNet5Large']

default_cfgs = {
    'pnasnet5large': {
        'url': 'https://github.com/rwightman/pytorch-image-models/releases/download/v0.1-cadene/pnasnet5large-bf079911.pth',
        'input_size': (3, 331, 331),
        'pool_size': (11, 11),
        'crop_pct': 0.875,
        'interpolation': 'bicubic',
        'mean': (0.5, 0.5, 0.5),
        'std': (0.5, 0.5, 0.5),
        'num_classes': 1001,
        'first_conv': 'conv_0.conv',
        'classifier': 'last_linear',
    },
}


class MaxPool(nn.Module):

    def __init__(self, kernel_size, stride=1, padding=1, zero_pad=False):
        super(MaxPool, self).__init__()
        self.zero_pad = nn.ZeroPad2d((1, 0, 1, 0)) if zero_pad else None
        self.pool = nn.MaxPool2d(kernel_size, stride=stride, padding=padding)

    def forward(self, x):
        if self.zero_pad:
            x = self.zero_pad(x)
        x = self.pool(x)
        if self.zero_pad:
            x = x[:, :, 1:, 1:]
        return x


class SeparableConv2d(nn.Module):

    def __init__(self, in_channels, out_channels, dw_kernel_size, dw_stride,
                 dw_padding):
        super(SeparableConv2d, self).__init__()
        self.depthwise_conv2d = nn.Conv2d(in_channels, in_channels,
                                          kernel_size=dw_kernel_size,
                                          stride=dw_stride, padding=dw_padding,
                                          groups=in_channels, bias=False)
        self.pointwise_conv2d = nn.Conv2d(in_channels, out_channels,
                                          kernel_size=1, bias=False)

    def forward(self, x):
        x = self.depthwise_conv2d(x)
        x = self.pointwise_conv2d(x)
        return x


class BranchSeparables(nn.Module):

    def __init__(self, in_channels, out_channels, kernel_size, stride=1,
                 stem_cell=False, zero_pad=False):
        super(BranchSeparables, self).__init__()
        padding = kernel_size // 2
        middle_channels = out_channels if stem_cell else in_channels
        self.zero_pad = nn.ZeroPad2d((1, 0, 1, 0)) if zero_pad else None
        self.relu_1 = nn.ReLU()
        self.separable_1 = SeparableConv2d(in_channels, middle_channels,
                                           kernel_size, dw_stride=stride,
                                           dw_padding=padding)
        self.bn_sep_1 = nn.BatchNorm2d(middle_channels, eps=0.001)
        self.relu_2 = nn.ReLU()
        self.separable_2 = SeparableConv2d(middle_channels, out_channels,
                                           kernel_size, dw_stride=1,
                                           dw_padding=padding)
        self.bn_sep_2 = nn.BatchNorm2d(out_channels, eps=0.001)

    def forward(self, x):
        x = self.relu_1(x)
        if self.zero_pad:
            x = self.zero_pad(x)
        x = self.separable_1(x)
        if self.zero_pad:
            x = x[:, :, 1:, 1:].contiguous()
        x = self.bn_sep_1(x)
        x = self.relu_2(x)
        x = self.separable_2(x)
        x = self.bn_sep_2(x)
        return x


class ReluConvBn(nn.Module):

    def __init__(self, in_channels, out_channels, kernel_size, stride=1):
        super(ReluConvBn, self).__init__()
        self.relu = nn.ReLU()
        self.conv = nn.Conv2d(in_channels, out_channels,
                              kernel_size=kernel_size, stride=stride,
                              bias=False)
        self.bn = nn.BatchNorm2d(out_channels, eps=0.001)

    def forward(self, x):
        x = self.relu(x)
        x = self.conv(x)
        x = self.bn(x)
        return x


class FactorizedReduction(nn.Module):

    def __init__(self, in_channels, out_channels):
        super(FactorizedReduction, self).__init__()
        self.relu = nn.ReLU()
        self.path_1 = nn.Sequential(OrderedDict([
            ('avgpool', nn.AvgPool2d(1, stride=2, count_include_pad=False)),
            ('conv', nn.Conv2d(in_channels, out_channels // 2,
                               kernel_size=1, bias=False)),
        ]))
        self.path_2 = nn.Sequential(OrderedDict([
            ('pad', nn.ZeroPad2d((0, 1, 0, 1))),
            ('avgpool', nn.AvgPool2d(1, stride=2, count_include_pad=False)),
            ('conv', nn.Conv2d(in_channels, out_channels // 2,
                               kernel_size=1, bias=False)),
        ]))
        self.final_path_bn = nn.BatchNorm2d(out_channels, eps=0.001)

    def forward(self, x):
        x = self.relu(x)

        x_path1 = self.path_1(x)

        x_path2 = self.path_2.pad(x)
        x_path2 = x_path2[:, :, 1:, 1:]
        x_path2 = self.path_2.avgpool(x_path2)
        x_path2 = self.path_2.conv(x_path2)

        out = self.final_path_bn(torch.cat([x_path1, x_path2], 1))
        return out


class CellBase(nn.Module):

    def cell_forward(self, x_left, x_right):
        x_comb_iter_0_left = self.comb_iter_0_left(x_left)
        x_comb_iter_0_right = self.comb_iter_0_right(x_left)
        x_comb_iter_0 = x_comb_iter_0_left + x_comb_iter_0_right

        x_comb_iter_1_left = self.comb_iter_1_left(x_right)
        x_comb_iter_1_right = self.comb_iter_1_right(x_right)
        x_comb_iter_1 = x_comb_iter_1_left + x_comb_iter_1_right

        x_comb_iter_2_left = self.comb_iter_2_left(x_right)
        x_comb_iter_2_right = self.comb_iter_2_right(x_right)
        x_comb_iter_2 = x_comb_iter_2_left + x_comb_iter_2_right

        x_comb_iter_3_left = self.comb_iter_3_left(x_comb_iter_2)
        x_comb_iter_3_right = self.comb_iter_3_right(x_right)
        x_comb_iter_3 = x_comb_iter_3_left + x_comb_iter_3_right

        x_comb_iter_4_left = self.comb_iter_4_left(x_left)
        if self.comb_iter_4_right:
            x_comb_iter_4_right = self.comb_iter_4_right(x_right)
        else:
            x_comb_iter_4_right = x_right
        x_comb_iter_4 = x_comb_iter_4_left + x_comb_iter_4_right

        x_out = torch.cat(
            [x_comb_iter_0, x_comb_iter_1, x_comb_iter_2, x_comb_iter_3,
             x_comb_iter_4], 1)
        return x_out


class CellStem0(CellBase):

    def __init__(self, in_channels_left, out_channels_left, in_channels_right,
                 out_channels_right):
        super(CellStem0, self).__init__()
        self.conv_1x1 = ReluConvBn(in_channels_right, out_channels_right,
                                   kernel_size=1)
        self.comb_iter_0_left = BranchSeparables(in_channels_left,
                                                 out_channels_left,
                                                 kernel_size=5, stride=2,
                                                 stem_cell=True)
        self.comb_iter_0_right = nn.Sequential(OrderedDict([
            ('max_pool', MaxPool(3, stride=2)),
            ('conv', nn.Conv2d(in_channels_left, out_channels_left,
                               kernel_size=1, bias=False)),
            ('bn', nn.BatchNorm2d(out_channels_left, eps=0.001)),
        ]))
        self.comb_iter_1_left = BranchSeparables(out_channels_right,
                                                 out_channels_right,
                                                 kernel_size=7, stride=2)
        self.comb_iter_1_right = MaxPool(3, stride=2)
        self.comb_iter_2_left = BranchSeparables(out_channels_right,
                                                 out_channels_right,
                                                 kernel_size=5, stride=2)
        self.comb_iter_2_right = BranchSeparables(out_channels_right,
                                                  out_channels_right,
                                                  kernel_size=3, stride=2)
        self.comb_iter_3_left = BranchSeparables(out_channels_right,
                                                 out_channels_right,
                                                 kernel_size=3)
        self.comb_iter_3_right = MaxPool(3, stride=2)
        self.comb_iter_4_left = BranchSeparables(in_channels_right,
                                                 out_channels_right,
                                                 kernel_size=3, stride=2,
                                                 stem_cell=True)
        self.comb_iter_4_right = ReluConvBn(out_channels_right,
                                            out_channels_right,
                                            kernel_size=1, stride=2)

    def forward(self, x_left):
        x_right = self.conv_1x1(x_left)
        x_out = self.cell_forward(x_left, x_right)
        return x_out


class Cell(CellBase):

    def __init__(self, in_channels_left, out_channels_left, in_channels_right,
                 out_channels_right, is_reduction=False, zero_pad=False,
                 match_prev_layer_dimensions=False):
        super(Cell, self).__init__()

        # If `is_reduction` is set to `True` stride 2 is used for
        # convolutional and pooling layers to reduce the spatial size of
        # the output of a cell approximately by a factor of 2.
        stride = 2 if is_reduction else 1

        # If `match_prev_layer_dimensions` is set to `True`
        # `FactorizedReduction` is used to reduce the spatial size
        # of the left input of a cell approximately by a factor of 2.
        self.match_prev_layer_dimensions = match_prev_layer_dimensions
        if match_prev_layer_dimensions:
            self.conv_prev_1x1 = FactorizedReduction(in_channels_left,
                                                     out_channels_left)
        else:
            self.conv_prev_1x1 = ReluConvBn(in_channels_left,
                                            out_channels_left, kernel_size=1)

        self.conv_1x1 = ReluConvBn(in_channels_right, out_channels_right,
                                   kernel_size=1)
        self.comb_iter_0_left = BranchSeparables(out_channels_left,
                                                 out_channels_left,
                                                 kernel_size=5, stride=stride,
                                                 zero_pad=zero_pad)
        self.comb_iter_0_right = MaxPool(3, stride=stride, zero_pad=zero_pad)
        self.comb_iter_1_left = BranchSeparables(out_channels_right,
                                                 out_channels_right,
                                                 kernel_size=7, stride=stride,
                                                 zero_pad=zero_pad)
        self.comb_iter_1_right = MaxPool(3, stride=stride, zero_pad=zero_pad)
        self.comb_iter_2_left = BranchSeparables(out_channels_right,
                                                 out_channels_right,
                                                 kernel_size=5, stride=stride,
                                                 zero_pad=zero_pad)
        self.comb_iter_2_right = BranchSeparables(out_channels_right,
                                                  out_channels_right,
                                                  kernel_size=3, stride=stride,
                                                  zero_pad=zero_pad)
        self.comb_iter_3_left = BranchSeparables(out_channels_right,
                                                 out_channels_right,
                                                 kernel_size=3)
        self.comb_iter_3_right = MaxPool(3, stride=stride, zero_pad=zero_pad)
        self.comb_iter_4_left = BranchSeparables(out_channels_left,
                                                 out_channels_left,
                                                 kernel_size=3, stride=stride,
                                                 zero_pad=zero_pad)
        if is_reduction:
            self.comb_iter_4_right = ReluConvBn(out_channels_right,
                                                out_channels_right,
                                                kernel_size=1, stride=stride)
        else:
            self.comb_iter_4_right = None

    def forward(self, x_left, x_right):
        x_left = self.conv_prev_1x1(x_left)
        x_right = self.conv_1x1(x_right)
        x_out = self.cell_forward(x_left, x_right)
        return x_out


class PNASNet5Large(nn.Module):
    def __init__(self, num_classes=1001, in_chans=3, drop_rate=0.5, global_pool='avg'):
        super(PNASNet5Large, self).__init__()
        self.num_classes = num_classes
        self.num_features = 4320
        self.drop_rate = drop_rate

        self.conv_0 = nn.Sequential(OrderedDict([
            ('conv', nn.Conv2d(in_chans, 96, kernel_size=3, stride=2, bias=False)),
            ('bn', nn.BatchNorm2d(96, eps=0.001))
        ]))
        self.cell_stem_0 = CellStem0(in_channels_left=96, out_channels_left=54,
                                     in_channels_right=96,
                                     out_channels_right=54)
        self.cell_stem_1 = Cell(in_channels_left=96, out_channels_left=108,
                                in_channels_right=270, out_channels_right=108,
                                match_prev_layer_dimensions=True,
                                is_reduction=True)
        self.cell_0 = Cell(in_channels_left=270, out_channels_left=216,
                           in_channels_right=540, out_channels_right=216,
                           match_prev_layer_dimensions=True)
        self.cell_1 = Cell(in_channels_left=540, out_channels_left=216,
                           in_channels_right=1080, out_channels_right=216)
        self.cell_2 = Cell(in_channels_left=1080, out_channels_left=216,
                           in_channels_right=1080, out_channels_right=216)
        self.cell_3 = Cell(in_channels_left=1080, out_channels_left=216,
                           in_channels_right=1080, out_channels_right=216)
        self.cell_4 = Cell(in_channels_left=1080, out_channels_left=432,
                           in_channels_right=1080, out_channels_right=432,
                           is_reduction=True, zero_pad=True)
        self.cell_5 = Cell(in_channels_left=1080, out_channels_left=432,
                           in_channels_right=2160, out_channels_right=432,
                           match_prev_layer_dimensions=True)
        self.cell_6 = Cell(in_channels_left=2160, out_channels_left=432,
                           in_channels_right=2160, out_channels_right=432)
        self.cell_7 = Cell(in_channels_left=2160, out_channels_left=432,
                           in_channels_right=2160, out_channels_right=432)
        self.cell_8 = Cell(in_channels_left=2160, out_channels_left=864,
                           in_channels_right=2160, out_channels_right=864,
                           is_reduction=True)
        self.cell_9 = Cell(in_channels_left=2160, out_channels_left=864,
                           in_channels_right=4320, out_channels_right=864,
                           match_prev_layer_dimensions=True)
        self.cell_10 = Cell(in_channels_left=4320, out_channels_left=864,
                            in_channels_right=4320, out_channels_right=864)
        self.cell_11 = Cell(in_channels_left=4320, out_channels_left=864,
                            in_channels_right=4320, out_channels_right=864)
        self.relu = nn.ReLU()
        self.global_pool = SelectAdaptivePool2d(pool_type=global_pool)
        self.last_linear = nn.Linear(self.num_features * self.global_pool.feat_mult(), num_classes)

    def get_classifier(self):
        return self.last_linear

    def reset_classifier(self, num_classes, global_pool='avg'):
        self.num_classes = num_classes
        self.global_pool = SelectAdaptivePool2d(pool_type=global_pool)
        del self.last_linear
        if num_classes:
            self.last_linear = nn.Linear(self.num_features * self.global_pool.feat_mult(), num_classes)
        else:
            self.last_linear = None

    def forward_features(self, x):
        x_conv_0 = self.conv_0(x)
        x_stem_0 = self.cell_stem_0(x_conv_0)
        x_stem_1 = self.cell_stem_1(x_conv_0, x_stem_0)
        x_cell_0 = self.cell_0(x_stem_0, x_stem_1)
        x_cell_1 = self.cell_1(x_stem_1, x_cell_0)
        x_cell_2 = self.cell_2(x_cell_0, x_cell_1)
        x_cell_3 = self.cell_3(x_cell_1, x_cell_2)
        x_cell_4 = self.cell_4(x_cell_2, x_cell_3)
        x_cell_5 = self.cell_5(x_cell_3, x_cell_4)
        x_cell_6 = self.cell_6(x_cell_4, x_cell_5)
        x_cell_7 = self.cell_7(x_cell_5, x_cell_6)
        x_cell_8 = self.cell_8(x_cell_6, x_cell_7)
        x_cell_9 = self.cell_9(x_cell_7, x_cell_8)
        x_cell_10 = self.cell_10(x_cell_8, x_cell_9)
        x_cell_11 = self.cell_11(x_cell_9, x_cell_10)
        x = self.relu(x_cell_11)
        return x

    def forward(self, x):
        x = self.forward_features(x)
        x = self.global_pool(x).flatten(1)
        if self.drop_rate > 0:
            x = F.dropout(x, self.drop_rate, training=self.training)
        x = self.last_linear(x)
        return x


@register_model
def pnasnet5large(pretrained=False, num_classes=1000, in_chans=3, **kwargs):
    r"""PNASNet-5 model architecture from the
    `"Progressive Neural Architecture Search"
    <https://arxiv.org/abs/1712.00559>`_ paper.
    """
    default_cfg = default_cfgs['pnasnet5large']
    model = PNASNet5Large(num_classes=1000, in_chans=in_chans, **kwargs)
    model.default_cfg = default_cfg
    if pretrained:
        load_pretrained(model, default_cfg, num_classes, in_chans)

    return model