rscd/models/decoderheads/pixel_decoder/msdeformattn.py

import numpy as np
import fvcore.nn.weight_init as weight_init
import torch
from torch import nn
from torch.nn import functional as F


from rscd.models.decoderheads.transformer_decoder.position_encoding import PositionEmbeddingSine
from rscd.models.decoderheads.transformer_decoder.transformer import _get_clones, _get_activation_fn
from rscd.models.decoderheads.pixel_decoder.ops.modules import MSDeformAttn

# MSDeformAttn Transformer encoder in deformable detr
class MSDeformAttnTransformerEncoderLayer(nn.Module):
    def __init__(self,
                 d_model=256, d_ffn=1024,
                 dropout=0.1, activation="relu",
                 n_levels=4, n_heads=8, n_points=4):
        super().__init__()

        # self attention
        self.self_attn = MSDeformAttn(d_model, n_levels, n_heads, n_points)
        self.dropout1 = nn.Dropout(dropout)
        self.norm1 = nn.LayerNorm(d_model)

        # ffn
        self.linear1 = nn.Linear(d_model, d_ffn)
        self.activation = _get_activation_fn(activation)
        self.dropout2 = nn.Dropout(dropout)
        self.linear2 = nn.Linear(d_ffn, d_model)
        self.dropout3 = nn.Dropout(dropout)
        self.norm2 = nn.LayerNorm(d_model)

    @staticmethod
    def with_pos_embed(tensor, pos):
        return tensor if pos is None else tensor + pos

    def forward_ffn(self, src):
        src2 = self.linear2(self.dropout2(self.activation(self.linear1(src))))
        src = src + self.dropout3(src2)
        src = self.norm2(src)
        return src

    def forward(self, src, pos, reference_points, spatial_shapes, level_start_index, padding_mask=None):
        # self attention
        src2 = self.self_attn(self.with_pos_embed(src, pos), reference_points, src, spatial_shapes, level_start_index, padding_mask)
        src = src + self.dropout1(src2)
        src = self.norm1(src)

        # ffn
        src = self.forward_ffn(src)

        return src


class MSDeformAttnTransformerEncoder(nn.Module):
    def __init__(self, encoder_layer, num_layers):
        super().__init__()
        self.layers = _get_clones(encoder_layer, num_layers)
        self.num_layers = num_layers

    @staticmethod
    def get_reference_points(spatial_shapes, valid_ratios, device):
        reference_points_list = []
        for lvl, (H_, W_) in enumerate(spatial_shapes):
            ref_y, ref_x = torch.meshgrid(torch.linspace(0.5, H_ - 0.5, H_, dtype=torch.float32, device=device),
                                          torch.linspace(0.5, W_ - 0.5, W_, dtype=torch.float32, device=device))
            ref_y = ref_y.reshape(-1)[None] / (valid_ratios[:, None, lvl, 1] * H_)
            ref_x = ref_x.reshape(-1)[None] / (valid_ratios[:, None, lvl, 0] * W_)
            ref = torch.stack((ref_x, ref_y), -1)  # [1, H_ * W_, 2]
            reference_points_list.append(ref)
        reference_points = torch.cat(reference_points_list, 1)
        reference_points = reference_points[:, :, None] * valid_ratios[:, None]
        return reference_points

    def forward(self, src, spatial_shapes, level_start_index, valid_ratios, pos=None, padding_mask=None):
        output = src
        reference_points = self.get_reference_points(spatial_shapes, valid_ratios, device=src.device)
        for _, layer in enumerate(self.layers):
            output = layer(output, pos, reference_points, spatial_shapes, level_start_index, padding_mask)

        return output


class MSDeformAttnTransformerEncoderOnly(nn.Module):
    def __init__(self, d_model=256, nhead=8,
                 num_encoder_layers=6, dim_feedforward=1024, dropout=0.1,
                 activation="relu",
                 num_feature_levels=4, enc_n_points=4,
        ):
        super().__init__()

        self.d_model = d_model
        self.nhead = nhead

        encoder_layer = MSDeformAttnTransformerEncoderLayer(d_model, dim_feedforward,
                                                            dropout, activation,
                                                            num_feature_levels, nhead, enc_n_points)
        self.encoder = MSDeformAttnTransformerEncoder(encoder_layer, num_encoder_layers)

        self.level_embed = nn.Parameter(torch.Tensor(num_feature_levels, d_model))

        self._reset_parameters()

    def _reset_parameters(self):
        for p in self.parameters():
            if p.dim() > 1:
                nn.init.xavier_uniform_(p)
        for m in self.modules():
            if isinstance(m, MSDeformAttn):
                m._reset_parameters()
        nn.init.normal_(self.level_embed)

    def get_valid_ratio(self, mask):
        _, H, W = mask.shape
        valid_H = torch.sum(~mask[:, :, 0], 1)
        valid_W = torch.sum(~mask[:, 0, :], 1)
        valid_ratio_h = valid_H.float() / H
        valid_ratio_w = valid_W.float() / W
        valid_ratio = torch.stack([valid_ratio_w, valid_ratio_h], -1)
        return valid_ratio

    def forward(self, srcs, pos_embeds):
        masks = [torch.zeros((x.size(0), x.size(2), x.size(3)), device=x.device, dtype=torch.bool) for x in srcs]
        # prepare input for encoder
        src_flatten = []
        mask_flatten = []
        lvl_pos_embed_flatten = []
        spatial_shapes = []
        for lvl, (src, mask, pos_embed) in enumerate(zip(srcs, masks, pos_embeds)):
            bs, c, h, w = src.shape
            spatial_shape = (h, w)
            spatial_shapes.append(spatial_shape)
            src = src.flatten(2).transpose(1, 2)
            mask = mask.flatten(1)
            pos_embed = pos_embed.flatten(2).transpose(1, 2)
            lvl_pos_embed = pos_embed + self.level_embed[lvl].view(1, 1, -1)
            lvl_pos_embed_flatten.append(lvl_pos_embed)
            src_flatten.append(src)
            mask_flatten.append(mask)
        src_flatten = torch.cat(src_flatten, 1)
        mask_flatten = torch.cat(mask_flatten, 1)
        lvl_pos_embed_flatten = torch.cat(lvl_pos_embed_flatten, 1)
        spatial_shapes = torch.as_tensor(spatial_shapes, dtype=torch.long, device=src_flatten.device)
        level_start_index = torch.cat((spatial_shapes.new_zeros((1, )), spatial_shapes.prod(1).cumsum(0)[:-1]))
        valid_ratios = torch.stack([self.get_valid_ratio(m) for m in masks], 1)

        # encoder
        memory = self.encoder(src_flatten, spatial_shapes, level_start_index, valid_ratios, lvl_pos_embed_flatten, mask_flatten)

        return memory, spatial_shapes, level_start_index

class MSDeformAttnPixelDecoder(nn.Module):
    def __init__(
        self,
        input_shape,
        transformer_dropout=0.1,
        transformer_nheads=8,
        transformer_dim_feedforward=2048,
        transformer_enc_layers=6,
        conv_dim=256,
        mask_dim=256,

        # deformable transformer encoder args
        transformer_in_features= ["res3", "res4", "res5"],
        common_stride=4,
    ):
        super().__init__()
        # backbone中["res3", "res4", "res5"]特征层的(channel, stride), eg. [(32,4), (64, 8),(128, 16),(256, 32)]
        transformer_input_shape = {k: v for k, v in input_shape.items() if k in transformer_in_features} 
        
        # this is the input shape of pixel decoder        
        self.in_features = [k for k, v in input_shape.items()]  # starting from "res3" to "res5"        
        self.feature_channels = [v.channel for k, v in input_shape.items()] # eg. [16, 64, 128, 256]
        
        # this is the input shape of transformer encoder (could use less features than pixel decoder        
        self.transformer_in_features = [k for k, v in transformer_input_shape.items()]  # starting from "res3" to "res5"
        transformer_in_channels = [v.channel for k, v in transformer_input_shape.items()] # eg. [64, 128, 256]
        self.transformer_feature_strides = [v.stride for k, v in transformer_input_shape.items()]  # to decide extra FPN layers

        self.transformer_num_feature_levels = len(self.transformer_in_features)
        if self.transformer_num_feature_levels > 1:
            input_proj_list = []
            # from low resolution to high resolution (res5 -> res3)
            for in_channels in transformer_in_channels[::-1]:
                input_proj_list.append(nn.Sequential(
                    nn.Conv2d(in_channels, conv_dim, kernel_size=1),
                    nn.GroupNorm(32, conv_dim),
                ))
            self.input_proj = nn.ModuleList(input_proj_list)
        else:
            self.input_proj = nn.ModuleList([
                nn.Sequential(
                    nn.Conv2d(transformer_in_channels[-1], conv_dim, kernel_size=1),
                    nn.GroupNorm(32, conv_dim),
                )])

        for proj in self.input_proj:
            nn.init.xavier_uniform_(proj[0].weight, gain=1)
            nn.init.constant_(proj[0].bias, 0)

        self.transformer = MSDeformAttnTransformerEncoderOnly(
            d_model=conv_dim,
            dropout=transformer_dropout,
            nhead=transformer_nheads,
            dim_feedforward=transformer_dim_feedforward,
            num_encoder_layers=transformer_enc_layers,
            num_feature_levels=self.transformer_num_feature_levels,
        )
        N_steps = conv_dim // 2
        self.pe_layer = PositionEmbeddingSine(N_steps, normalize=True)

        self.mask_dim = mask_dim
        # use 1x1 conv instead
        self.mask_features = nn.Conv2d(
            conv_dim,
            mask_dim,
            kernel_size=1,
            stride=1,
            padding=0,
        )
        weight_init.c2_xavier_fill(self.mask_features)
        
        self.maskformer_num_feature_levels = 3  # always use 3 scales
        self.common_stride = common_stride

        # extra fpn levels
        stride = min(self.transformer_feature_strides)
        self.num_fpn_levels = int(np.log2(stride) - np.log2(self.common_stride))

        lateral_convs = []
        output_convs = []

        for idx, in_channels in enumerate(self.feature_channels[:self.num_fpn_levels]): # res2 -> fpn
            lateral_conv = nn.Sequential(nn.Conv2d(in_channels, conv_dim, kernel_size=1),
                                         nn.GroupNorm(32, conv_dim),
                                         nn.ReLU(inplace=True))

            output_conv = nn.Sequential(nn.Conv2d(conv_dim, conv_dim, kernel_size=3,  stride=1,  padding=1),
                                        nn.GroupNorm(32, conv_dim),
                                        nn.ReLU(inplace=True))
            
            weight_init.c2_xavier_fill(lateral_conv[0])
            weight_init.c2_xavier_fill(output_conv[0])
            self.add_module("adapter_{}".format(idx + 1), lateral_conv)
            self.add_module("layer_{}".format(idx + 1), output_conv)

            lateral_convs.append(lateral_conv)
            output_convs.append(output_conv)
        # Place convs into top-down order (from low to high resolution)
        # to make the top-down computation in forward clearer.
        self.lateral_convs = lateral_convs[::-1]
        self.output_convs = output_convs[::-1]

    def forward_features(self, features):
        srcs = []
        pos = []
        # Reverse feature maps into top-down order (from low to high resolution), 'res5' -> 'res3'
        for idx, f in enumerate(self.transformer_in_features[::-1]):
            x = features[f].float()  # deformable detr does not support half precision
            srcs.append(self.input_proj[idx](x))
            pos.append(self.pe_layer(x))

        y, spatial_shapes, level_start_index = self.transformer(srcs, pos)
        bs = y.shape[0]

        split_size_or_sections = [None] * self.transformer_num_feature_levels
        for i in range(self.transformer_num_feature_levels):
            if i < self.transformer_num_feature_levels - 1:
                split_size_or_sections[i] = level_start_index[i + 1] - level_start_index[i]
            else:
                split_size_or_sections[i] = y.shape[1] - level_start_index[i]
        y = torch.split(y, split_size_or_sections, dim=1)

        out = []
        multi_scale_features = []
        num_cur_levels = 0
        for i, z in enumerate(y):
            out.append(z.transpose(1, 2).view(bs, -1, spatial_shapes[i][0], spatial_shapes[i][1]))

        # append `out` with extra FPN levels
        # Reverse feature maps into top-down order (from low to high resolution)
        for idx, f in enumerate(self.in_features[:self.num_fpn_levels][::-1]):
            x = features[f].float()
            lateral_conv = self.lateral_convs[idx]
            output_conv = self.output_convs[idx]
            cur_fpn = lateral_conv(x)
            # Following FPN implementation, we use nearest upsampling here
            y = cur_fpn + F.interpolate(out[-1], size=cur_fpn.shape[-2:], mode="bilinear", align_corners=False)
            y = output_conv(y)
            out.append(y)

        for o in out:
            if num_cur_levels < self.maskformer_num_feature_levels:
                multi_scale_features.append(o)
                num_cur_levels += 1

        return self.mask_features(out[-1]), out[0], multi_scale_features

class MSDeformAttnPixelDecoder4ScalesFASeg(nn.Module):
    def __init__(
            self,
            input_shape,
            transformer_dropout= 0.1,
            transformer_nheads= 8,
            transformer_dim_feedforward= 2048,
            transformer_enc_layers= 6,
            conv_dim= 256,
            mask_dim= 256,

            # deformable transformer encoder args
            transformer_in_features= ["res3", "res4", "res5"],
            common_stride= 4,
    ):
        """
        NOTE: this interface is experimental.
        Args:
            input_shape: shapes (channels and stride) of the input features
            transformer_dropout: dropout probability in transformer
            transformer_nheads: number of heads in transformer
            transformer_dim_feedforward: dimension of feedforward network
            transformer_enc_layers: number of transformer encoder layers
            conv_dims: number of output channels for the intermediate conv layers.
            mask_dim: number of output channels for the final conv layer.
            norm (str or callable): normalization for all conv layers
        """
        super().__init__()
        transformer_input_shape = {
            k: v for k, v in input_shape.items() if k in transformer_in_features
        }

        # this is the input shape of pixel decoder        
        self.in_features = [k for k, v in input_shape.items()]  # starting from "res3" to "res5"        
        self.feature_channels = [v.channel for k, v in input_shape.items()] # eg. [16, 64, 128, 256]
        
        # this is the input shape of transformer encoder (could use less features than pixel decoder        
        self.transformer_in_features = [k for k, v in transformer_input_shape.items()]  # starting from "res3" to "res5"
        transformer_in_channels = [v.channel for k, v in transformer_input_shape.items()] # eg. [64, 128, 256]
        self.transformer_feature_strides = [v.stride for k, v in transformer_input_shape.items()]  # to decide extra FPN layers

        self.transformer_num_feature_levels = len(self.transformer_in_features)
        # self.pos_linear = len(self.transformer_in_features)

        pos_linear_list = []
        if self.transformer_num_feature_levels > 1:
            input_proj_list = []
            # from low resolution to high resolution (res5 -> res2)
            for in_channels in transformer_in_channels[::-1]:
                input_proj_list.append(nn.Sequential(
                    nn.Conv2d(in_channels, conv_dim, kernel_size=1),
                    nn.GroupNorm(32, conv_dim),
                ))

                # positional encoding generator
                pos_linear_list.append(nn.Conv2d(256, 256, kernel_size=3, stride=1,
                                            padding=1, bias=True, groups=256))

            # For "res2"
            input_proj_list.append(nn.Sequential(
                nn.Conv2d(in_channels // 2, conv_dim, kernel_size=1),
                nn.GroupNorm(32, conv_dim),
            ))
            self.input_proj = nn.ModuleList(input_proj_list)

        else:
            self.input_proj = nn.ModuleList([
                nn.Sequential(
                    nn.Conv2d(transformer_in_channels[-1], conv_dim, kernel_size=1),
                    nn.GroupNorm(32, conv_dim),
                )])

        # For "res2", positional encoding generator
        pos_linear_list.append(nn.Conv2d(256, 256, kernel_size=3, stride=1,
                                         padding=1, bias=True, groups=256))

        self.pos_linear = nn.ModuleList(pos_linear_list)

        for proj in self.input_proj:
            nn.init.xavier_uniform_(proj[0].weight, gain=1)
            nn.init.constant_(proj[0].bias, 0)

        self.transformer = MSDeformAttnTransformerEncoderOnly(
            d_model=conv_dim,
            dropout=transformer_dropout,
            nhead=transformer_nheads,
            dim_feedforward=transformer_dim_feedforward,
            num_encoder_layers=transformer_enc_layers,
            num_feature_levels=self.transformer_num_feature_levels,
        )
        N_steps = conv_dim // 2

        self.mask_dim = mask_dim
        # use 1x1 conv instead
        self.mask_features = nn.Conv2d(
            conv_dim,
            mask_dim,
            kernel_size=1,
            stride=1,
            padding=0,
        )
        weight_init.c2_xavier_fill(self.mask_features)

        self.maskformer_num_feature_levels = 4  # Here we use 4 scales
        self.common_stride = common_stride

        # extra fpn levels
        stride = min(self.transformer_feature_strides)
        self.num_fpn_levels = int(np.log2(stride) - np.log2(self.common_stride))

        lateral_convs = []
        output_convs = []

        for idx, in_channels in enumerate(self.feature_channels[:self.num_fpn_levels]):
            lateral_conv = nn.Sequential(nn.Conv2d(in_channels, conv_dim, kernel_size=1),
                                         nn.GroupNorm(32, conv_dim),
                                         nn.ReLU(inplace=True))

            output_conv = nn.Sequential(nn.Conv2d(conv_dim, conv_dim, kernel_size=3,  stride=1,  padding=1),
                                        nn.GroupNorm(32, conv_dim),
                                        nn.ReLU(inplace=True))
            
            weight_init.c2_xavier_fill(lateral_conv[0])
            weight_init.c2_xavier_fill(output_conv[0])
            self.add_module("adapter_{}".format(idx + 1), lateral_conv)
            self.add_module("layer_{}".format(idx + 1), output_conv)

            lateral_convs.append(lateral_conv)
            output_convs.append(output_conv)
        # Place convs into top-down order (from low to high resolution)
        # to make the top-down computation in forward clearer.
        self.lateral_convs = lateral_convs[::-1]
        self.output_convs = output_convs[::-1]

    def forward_features(self, features):
        srcs = []
        pos = []

        # Reverse feature maps into top-down order (from low to high resolution)
        for idx, f in enumerate(self.transformer_in_features[::-1]):
            x = features[f].float()
            x = self.input_proj[idx](x)
            # deformable detr does not support half precision
            srcs.append(x)
            pos.append(self.pos_linear[idx](x))

        x_res2 = self.input_proj[-1](features['res2'])
        pos.append(self.pos_linear[-1](x_res2))
        srcs.append(x_res2)

        y, spatial_shapes, level_start_index = self.transformer(srcs[:3], pos[:3])
        bs = y.shape[0]

        split_size_or_sections = [None] * self.transformer_num_feature_levels
        for i in range(self.transformer_num_feature_levels):
            if i < self.transformer_num_feature_levels - 1:
                split_size_or_sections[i] = level_start_index[i + 1] - level_start_index[i]
            else:
                split_size_or_sections[i] = y.shape[1] - level_start_index[i]
        y = torch.split(y, split_size_or_sections, dim=1)

        out = []
        multi_scale_features = []
        num_cur_levels = 0
        for i, z in enumerate(y):
            out.append(z.transpose(1, 2).view(bs, -1, spatial_shapes[i][0], spatial_shapes[i][1]))

        # append `out` with extra FPN levels
        # Reverse feature maps into top-down order (from low to high resolution)
        for idx, f in enumerate(self.in_features[:self.num_fpn_levels][::-1]):
            x = features[f].float()
            lateral_conv = self.lateral_convs[idx]
            output_conv = self.output_convs[idx]
            cur_fpn = lateral_conv(x)
            # Following FPN implementation, we use nearest upsampling here
            y = cur_fpn + F.interpolate(out[-1], size=cur_fpn.shape[-2:], mode="bilinear", align_corners=False)
            y = output_conv(y)
            out.append(y)

        for o in out:
            if num_cur_levels < self.maskformer_num_feature_levels:
                multi_scale_features.append(o)
                num_cur_levels += 1

        return self.mask_features(out[-1]), out[0], multi_scale_features, pos