densepose/modeling/roi_heads/roi_head.py

# Copyright (c) Facebook, Inc. and its affiliates.

import numpy as np
from typing import Dict, List, Optional
import fvcore.nn.weight_init as weight_init
import torch
import torch.nn as nn
from torch.nn import functional as F

from detectron2.layers import Conv2d, ShapeSpec, get_norm
from detectron2.modeling import ROI_HEADS_REGISTRY, StandardROIHeads
from detectron2.modeling.poolers import ROIPooler
from detectron2.modeling.roi_heads import select_foreground_proposals
from detectron2.structures import ImageList, Instances

from .. import (
    build_densepose_data_filter,
    build_densepose_embedder,
    build_densepose_head,
    build_densepose_losses,
    build_densepose_predictor,
    densepose_inference,
)


class Decoder(nn.Module):
    """
    A semantic segmentation head described in detail in the Panoptic Feature Pyramid Networks paper
    (https://arxiv.org/abs/1901.02446). It takes FPN features as input and merges information from
    all levels of the FPN into single output.
    """

    def __init__(self, cfg, input_shape: Dict[str, ShapeSpec], in_features):
        super(Decoder, self).__init__()

        # fmt: off
        self.in_features      = in_features
        feature_strides       = {k: v.stride for k, v in input_shape.items()}
        feature_channels      = {k: v.channels for k, v in input_shape.items()}
        num_classes           = cfg.MODEL.ROI_DENSEPOSE_HEAD.DECODER_NUM_CLASSES
        conv_dims             = cfg.MODEL.ROI_DENSEPOSE_HEAD.DECODER_CONV_DIMS
        self.common_stride    = cfg.MODEL.ROI_DENSEPOSE_HEAD.DECODER_COMMON_STRIDE
        norm                  = cfg.MODEL.ROI_DENSEPOSE_HEAD.DECODER_NORM
        # fmt: on

        self.scale_heads = []
        for in_feature in self.in_features:
            head_ops = []
            head_length = max(
                1, int(np.log2(feature_strides[in_feature]) - np.log2(self.common_stride))
            )
            for k in range(head_length):
                conv = Conv2d(
                    feature_channels[in_feature] if k == 0 else conv_dims,
                    conv_dims,
                    kernel_size=3,
                    stride=1,
                    padding=1,
                    bias=not norm,
                    norm=get_norm(norm, conv_dims),
                    activation=F.relu,
                )
                weight_init.c2_msra_fill(conv)
                head_ops.append(conv)
                if feature_strides[in_feature] != self.common_stride:
                    head_ops.append(
                        nn.Upsample(scale_factor=2, mode="bilinear", align_corners=False)
                    )
            self.scale_heads.append(nn.Sequential(*head_ops))
            self.add_module(in_feature, self.scale_heads[-1])
        self.predictor = Conv2d(conv_dims, num_classes, kernel_size=1, stride=1, padding=0)
        weight_init.c2_msra_fill(self.predictor)

    def forward(self, features: List[torch.Tensor]):
        for i, _ in enumerate(self.in_features):
            if i == 0:
                x = self.scale_heads[i](features[i])
            else:
                x = x + self.scale_heads[i](features[i])
        x = self.predictor(x)
        return x


@ROI_HEADS_REGISTRY.register()
class DensePoseROIHeads(StandardROIHeads):
    """
    A Standard ROIHeads which contains an addition of DensePose head.
    """

    def __init__(self, cfg, input_shape):
        super().__init__(cfg, input_shape)
        self._init_densepose_head(cfg, input_shape)

    def _init_densepose_head(self, cfg, input_shape):
        # fmt: off
        self.densepose_on          = cfg.MODEL.DENSEPOSE_ON
        if not self.densepose_on:
            return
        self.densepose_data_filter = build_densepose_data_filter(cfg)
        dp_pooler_resolution       = cfg.MODEL.ROI_DENSEPOSE_HEAD.POOLER_RESOLUTION
        dp_pooler_sampling_ratio   = cfg.MODEL.ROI_DENSEPOSE_HEAD.POOLER_SAMPLING_RATIO
        dp_pooler_type             = cfg.MODEL.ROI_DENSEPOSE_HEAD.POOLER_TYPE
        self.use_decoder           = cfg.MODEL.ROI_DENSEPOSE_HEAD.DECODER_ON
        # fmt: on
        if self.use_decoder:
            dp_pooler_scales = (1.0 / input_shape[self.in_features[0]].stride,)
        else:
            dp_pooler_scales = tuple(1.0 / input_shape[k].stride for k in self.in_features)
        in_channels = [input_shape[f].channels for f in self.in_features][0]

        if self.use_decoder:
            self.decoder = Decoder(cfg, input_shape, self.in_features)

        self.densepose_pooler = ROIPooler(
            output_size=dp_pooler_resolution,
            scales=dp_pooler_scales,
            sampling_ratio=dp_pooler_sampling_ratio,
            pooler_type=dp_pooler_type,
        )
        self.densepose_head = build_densepose_head(cfg, in_channels)
        self.densepose_predictor = build_densepose_predictor(
            cfg, self.densepose_head.n_out_channels
        )
        self.densepose_losses = build_densepose_losses(cfg)
        self.embedder = build_densepose_embedder(cfg)

    def _forward_densepose(self, features: Dict[str, torch.Tensor], instances: List[Instances]):
        """
        Forward logic of the densepose prediction branch.

        Args:
            features (dict[str, Tensor]): input data as a mapping from feature
                map name to tensor. Axis 0 represents the number of images `N` in
                the input data; axes 1-3 are channels, height, and width, which may
                vary between feature maps (e.g., if a feature pyramid is used).
            instances (list[Instances]): length `N` list of `Instances`. The i-th
                `Instances` contains instances for the i-th input image,
                In training, they can be the proposals.
                In inference, they can be the predicted boxes.

        Returns:
            In training, a dict of losses.
            In inference, update `instances` with new fields "densepose" and return it.
        """
        if not self.densepose_on:
            return {} if self.training else instances

        features_list = [features[f] for f in self.in_features]
        if self.training:
            proposals, _ = select_foreground_proposals(instances, self.num_classes)
            features_list, proposals = self.densepose_data_filter(features_list, proposals)
            if len(proposals) > 0:
                proposal_boxes = [x.proposal_boxes for x in proposals]

                if self.use_decoder:
                    features_list = [self.decoder(features_list)]

                features_dp = self.densepose_pooler(features_list, proposal_boxes)
                densepose_head_outputs = self.densepose_head(features_dp)
                densepose_predictor_outputs = self.densepose_predictor(densepose_head_outputs)
                densepose_loss_dict = self.densepose_losses(
                    proposals, densepose_predictor_outputs, embedder=self.embedder
                )
                return densepose_loss_dict
        else:
            pred_boxes = [x.pred_boxes for x in instances]

            if self.use_decoder:
                features_list = [self.decoder(features_list)]

            features_dp = self.densepose_pooler(features_list, pred_boxes)
            if len(features_dp) > 0:
                densepose_head_outputs = self.densepose_head(features_dp)
                densepose_predictor_outputs = self.densepose_predictor(densepose_head_outputs)
            else:
                densepose_predictor_outputs = None

            densepose_inference(densepose_predictor_outputs, instances)
            return instances

    def forward(
        self,
        images: ImageList,
        features: Dict[str, torch.Tensor],
        proposals: List[Instances],
        targets: Optional[List[Instances]] = None,
    ):
        instances, losses = super().forward(images, features, proposals, targets)
        del targets, images

        if self.training:
            losses.update(self._forward_densepose(features, instances))
        return instances, losses

    def forward_with_given_boxes(
        self, features: Dict[str, torch.Tensor], instances: List[Instances]
    ):
        """
        Use the given boxes in `instances` to produce other (non-box) per-ROI outputs.

        This is useful for downstream tasks where a box is known, but need to obtain
        other attributes (outputs of other heads).
        Test-time augmentation also uses this.

        Args:
            features: same as in `forward()`
            instances (list[Instances]): instances to predict other outputs. Expect the keys
                "pred_boxes" and "pred_classes" to exist.

        Returns:
            instances (list[Instances]):
                the same `Instances` objects, with extra
                fields such as `pred_masks` or `pred_keypoints`.
        """

        instances = super().forward_with_given_boxes(features, instances)
        instances = self._forward_densepose(features, instances)
        return instances