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# Copyright (c) Facebook, Inc. and its affiliates.
from typing import Any, List
import torch
from torch.nn import functional as F
from detectron2.config import CfgNode
from detectron2.structures import Instances
from .mask_or_segm import MaskOrSegmentationLoss
from .registry import DENSEPOSE_LOSS_REGISTRY
from .utils import (
BilinearInterpolationHelper,
ChartBasedAnnotationsAccumulator,
LossDict,
extract_packed_annotations_from_matches,
)
@DENSEPOSE_LOSS_REGISTRY.register()
class DensePoseChartLoss:
"""
DensePose loss for chart-based training. A mesh is split into charts,
each chart is given a label (I) and parametrized by 2 coordinates referred to
as U and V. Ground truth consists of a number of points annotated with
I, U and V values and coarse segmentation S defined for all pixels of the
object bounding box. In some cases (see `COARSE_SEGM_TRAINED_BY_MASKS`),
semantic segmentation annotations can be used as ground truth inputs as well.
Estimated values are tensors:
* U coordinates, tensor of shape [N, C, S, S]
* V coordinates, tensor of shape [N, C, S, S]
* fine segmentation estimates, tensor of shape [N, C, S, S] with raw unnormalized
scores for each fine segmentation label at each location
* coarse segmentation estimates, tensor of shape [N, D, S, S] with raw unnormalized
scores for each coarse segmentation label at each location
where N is the number of detections, C is the number of fine segmentation
labels, S is the estimate size ( = width = height) and D is the number of
coarse segmentation channels.
The losses are:
* regression (smooth L1) loss for U and V coordinates
* cross entropy loss for fine (I) and coarse (S) segmentations
Each loss has an associated weight
"""
def __init__(self, cfg: CfgNode):
"""
Initialize chart-based loss from configuration options
Args:
cfg (CfgNode): configuration options
"""
# fmt: off
self.heatmap_size = cfg.MODEL.ROI_DENSEPOSE_HEAD.HEATMAP_SIZE
self.w_points = cfg.MODEL.ROI_DENSEPOSE_HEAD.POINT_REGRESSION_WEIGHTS
self.w_part = cfg.MODEL.ROI_DENSEPOSE_HEAD.PART_WEIGHTS
self.w_segm = cfg.MODEL.ROI_DENSEPOSE_HEAD.INDEX_WEIGHTS
self.n_segm_chan = cfg.MODEL.ROI_DENSEPOSE_HEAD.NUM_COARSE_SEGM_CHANNELS
# fmt: on
self.segm_trained_by_masks = cfg.MODEL.ROI_DENSEPOSE_HEAD.COARSE_SEGM_TRAINED_BY_MASKS
self.segm_loss = MaskOrSegmentationLoss(cfg)
def __call__(
self, proposals_with_gt: List[Instances], densepose_predictor_outputs: Any, **kwargs
) -> LossDict:
"""
Produce chart-based DensePose losses
Args:
proposals_with_gt (list of Instances): detections with associated ground truth data
densepose_predictor_outputs: an object of a dataclass that contains predictor outputs
with estimated values; assumed to have the following attributes:
* coarse_segm - coarse segmentation estimates, tensor of shape [N, D, S, S]
* fine_segm - fine segmentation estimates, tensor of shape [N, C, S, S]
* u - U coordinate estimates per fine labels, tensor of shape [N, C, S, S]
* v - V coordinate estimates per fine labels, tensor of shape [N, C, S, S]
where N is the number of detections, C is the number of fine segmentation
labels, S is the estimate size ( = width = height) and D is the number of
coarse segmentation channels.
Return:
dict: str -> tensor: dict of losses with the following entries:
* `loss_densepose_U`: smooth L1 loss for U coordinate estimates
* `loss_densepose_V`: smooth L1 loss for V coordinate estimates
* `loss_densepose_I`: cross entropy for raw unnormalized scores for fine
segmentation estimates given ground truth labels;
* `loss_densepose_S`: cross entropy for raw unnormalized scores for coarse
segmentation estimates given ground truth labels;
"""
# densepose outputs are computed for all images and all bounding boxes;
# i.e. if a batch has 4 images with (3, 1, 2, 1) proposals respectively,
# the outputs will have size(0) == 3+1+2+1 == 7
if not len(proposals_with_gt):
return self.produce_fake_densepose_losses(densepose_predictor_outputs)
accumulator = ChartBasedAnnotationsAccumulator()
packed_annotations = extract_packed_annotations_from_matches(proposals_with_gt, accumulator)
# NOTE: we need to keep the same computation graph on all the GPUs to
# perform reduction properly. Hence even if we have no data on one
# of the GPUs, we still need to generate the computation graph.
# Add fake (zero) loss in the form Tensor.sum() * 0
if packed_annotations is None:
return self.produce_fake_densepose_losses(densepose_predictor_outputs)
h, w = densepose_predictor_outputs.u.shape[2:]
interpolator = BilinearInterpolationHelper.from_matches(
packed_annotations,
(h, w),
)
j_valid_fg = interpolator.j_valid * ( # pyre-ignore[16]
packed_annotations.fine_segm_labels_gt > 0
)
# pyre-fixme[6]: For 1st param expected `Tensor` but got `int`.
if not torch.any(j_valid_fg):
return self.produce_fake_densepose_losses(densepose_predictor_outputs)
losses_uv = self.produce_densepose_losses_uv(
proposals_with_gt,
densepose_predictor_outputs,
packed_annotations,
interpolator,
j_valid_fg, # pyre-ignore[6]
)
losses_segm = self.produce_densepose_losses_segm(
proposals_with_gt,
densepose_predictor_outputs,
packed_annotations,
interpolator,
j_valid_fg, # pyre-ignore[6]
)
return {**losses_uv, **losses_segm}
def produce_fake_densepose_losses(self, densepose_predictor_outputs: Any) -> LossDict:
"""
Fake losses for fine segmentation and U/V coordinates. These are used when
no suitable ground truth data was found in a batch. The loss has a value 0
and is primarily used to construct the computation graph, so that
`DistributedDataParallel` has similar graphs on all GPUs and can perform
reduction properly.
Args:
densepose_predictor_outputs: DensePose predictor outputs, an object
of a dataclass that is assumed to have the following attributes:
* fine_segm - fine segmentation estimates, tensor of shape [N, C, S, S]
* u - U coordinate estimates per fine labels, tensor of shape [N, C, S, S]
* v - V coordinate estimates per fine labels, tensor of shape [N, C, S, S]
Return:
dict: str -> tensor: dict of losses with the following entries:
* `loss_densepose_U`: has value 0
* `loss_densepose_V`: has value 0
* `loss_densepose_I`: has value 0
* `loss_densepose_S`: has value 0
"""
losses_uv = self.produce_fake_densepose_losses_uv(densepose_predictor_outputs)
losses_segm = self.produce_fake_densepose_losses_segm(densepose_predictor_outputs)
return {**losses_uv, **losses_segm}
def produce_fake_densepose_losses_uv(self, densepose_predictor_outputs: Any) -> LossDict:
"""
Fake losses for U/V coordinates. These are used when no suitable ground
truth data was found in a batch. The loss has a value 0
and is primarily used to construct the computation graph, so that
`DistributedDataParallel` has similar graphs on all GPUs and can perform
reduction properly.
Args:
densepose_predictor_outputs: DensePose predictor outputs, an object
of a dataclass that is assumed to have the following attributes:
* u - U coordinate estimates per fine labels, tensor of shape [N, C, S, S]
* v - V coordinate estimates per fine labels, tensor of shape [N, C, S, S]
Return:
dict: str -> tensor: dict of losses with the following entries:
* `loss_densepose_U`: has value 0
* `loss_densepose_V`: has value 0
"""
return {
"loss_densepose_U": densepose_predictor_outputs.u.sum() * 0,
"loss_densepose_V": densepose_predictor_outputs.v.sum() * 0,
}
def produce_fake_densepose_losses_segm(self, densepose_predictor_outputs: Any) -> LossDict:
"""
Fake losses for fine / coarse segmentation. These are used when
no suitable ground truth data was found in a batch. The loss has a value 0
and is primarily used to construct the computation graph, so that
`DistributedDataParallel` has similar graphs on all GPUs and can perform
reduction properly.
Args:
densepose_predictor_outputs: DensePose predictor outputs, an object
of a dataclass that is assumed to have the following attributes:
* fine_segm - fine segmentation estimates, tensor of shape [N, C, S, S]
* coarse_segm - coarse segmentation estimates, tensor of shape [N, D, S, S]
Return:
dict: str -> tensor: dict of losses with the following entries:
* `loss_densepose_I`: has value 0
* `loss_densepose_S`: has value 0, added only if `segm_trained_by_masks` is False
"""
losses = {
"loss_densepose_I": densepose_predictor_outputs.fine_segm.sum() * 0,
"loss_densepose_S": self.segm_loss.fake_value(densepose_predictor_outputs),
}
return losses
def produce_densepose_losses_uv(
self,
proposals_with_gt: List[Instances],
densepose_predictor_outputs: Any,
packed_annotations: Any,
interpolator: BilinearInterpolationHelper,
j_valid_fg: torch.Tensor,
) -> LossDict:
"""
Compute losses for U/V coordinates: smooth L1 loss between
estimated coordinates and the ground truth.
Args:
proposals_with_gt (list of Instances): detections with associated ground truth data
densepose_predictor_outputs: DensePose predictor outputs, an object
of a dataclass that is assumed to have the following attributes:
* u - U coordinate estimates per fine labels, tensor of shape [N, C, S, S]
* v - V coordinate estimates per fine labels, tensor of shape [N, C, S, S]
Return:
dict: str -> tensor: dict of losses with the following entries:
* `loss_densepose_U`: smooth L1 loss for U coordinate estimates
* `loss_densepose_V`: smooth L1 loss for V coordinate estimates
"""
u_gt = packed_annotations.u_gt[j_valid_fg]
u_est = interpolator.extract_at_points(densepose_predictor_outputs.u)[j_valid_fg]
v_gt = packed_annotations.v_gt[j_valid_fg]
v_est = interpolator.extract_at_points(densepose_predictor_outputs.v)[j_valid_fg]
return {
"loss_densepose_U": F.smooth_l1_loss(u_est, u_gt, reduction="sum") * self.w_points,
"loss_densepose_V": F.smooth_l1_loss(v_est, v_gt, reduction="sum") * self.w_points,
}
def produce_densepose_losses_segm(
self,
proposals_with_gt: List[Instances],
densepose_predictor_outputs: Any,
packed_annotations: Any,
interpolator: BilinearInterpolationHelper,
j_valid_fg: torch.Tensor,
) -> LossDict:
"""
Losses for fine / coarse segmentation: cross-entropy
for segmentation unnormalized scores given ground truth labels at
annotated points for fine segmentation and dense mask annotations
for coarse segmentation.
Args:
proposals_with_gt (list of Instances): detections with associated ground truth data
densepose_predictor_outputs: DensePose predictor outputs, an object
of a dataclass that is assumed to have the following attributes:
* fine_segm - fine segmentation estimates, tensor of shape [N, C, S, S]
* coarse_segm - coarse segmentation estimates, tensor of shape [N, D, S, S]
Return:
dict: str -> tensor: dict of losses with the following entries:
* `loss_densepose_I`: cross entropy for raw unnormalized scores for fine
segmentation estimates given ground truth labels
* `loss_densepose_S`: cross entropy for raw unnormalized scores for coarse
segmentation estimates given ground truth labels;
may be included if coarse segmentation is only trained
using DensePose ground truth; if additional supervision through
instance segmentation data is performed (`segm_trained_by_masks` is True),
this loss is handled by `produce_mask_losses` instead
"""
fine_segm_gt = packed_annotations.fine_segm_labels_gt[
interpolator.j_valid # pyre-ignore[16]
]
fine_segm_est = interpolator.extract_at_points(
densepose_predictor_outputs.fine_segm,
slice_fine_segm=slice(None),
w_ylo_xlo=interpolator.w_ylo_xlo[:, None], # pyre-ignore[16]
w_ylo_xhi=interpolator.w_ylo_xhi[:, None], # pyre-ignore[16]
w_yhi_xlo=interpolator.w_yhi_xlo[:, None], # pyre-ignore[16]
w_yhi_xhi=interpolator.w_yhi_xhi[:, None], # pyre-ignore[16]
)[interpolator.j_valid, :]
return {
"loss_densepose_I": F.cross_entropy(fine_segm_est, fine_segm_gt.long()) * self.w_part,
"loss_densepose_S": self.segm_loss(
proposals_with_gt, densepose_predictor_outputs, packed_annotations
)
* self.w_segm,
}