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model.py
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model.py
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"""
CFUN
The main CFUN model implementation.
"""
import time
import math
import os
import re
import numpy as np
import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim
import torch.utils.data
from torch.autograd import Variable
import utils
import backbone
import mask_branch
############################################################
# Logging Utility Functions
############################################################
def log(text, array=None):
"""Prints a text message. And, optionally, if a Numpy array is provided it
prints it's shape, min, and max values.
"""
if array is not None:
text = text.ljust(25)
text += ("shape: {:20} min: {:10.5f} max: {:10.5f}".format(
str(array.shape),
array.min() if array.size else "",
array.max() if array.size else ""))
print(text)
def print_progress_bar(iteration, total, prefix='', suffix='', decimals=1, length=100, fill=''):
"""Call in a loop to create terminal progress bar
@params:
iteration - Required : current iteration (Int)
total - Required : total iterations (Int)
prefix - Optional : prefix string (Str)
suffix - Optional : suffix string (Str)
decimals - Optional : positive number of decimals in percent complete (Int)
length - Optional : character length of bar (Int)
fill - Optional : bar fill character (Str)
"""
percent = ("{0:." + str(decimals) + "f}").format(100 * (iteration / float(total)))
filled_length = int(length * iteration // total)
bar = fill * filled_length + '-' * (length - filled_length)
print('\r%s |%s| %s%% %s' % (prefix, bar, percent, suffix), end='\n')
# Print New Line on Complete
if iteration == total:
print()
############################################################
# Pytorch Utility Functions
############################################################
def unique1d(tensor):
if tensor.size()[0] == 0 or tensor.size()[0] == 1:
return tensor
tensor = tensor.sort()[0]
unique_bool = tensor[1:] != tensor[:-1]
first_element = Variable(torch.ByteTensor([True]), requires_grad=False)
if tensor.is_cuda:
first_element = first_element.cuda()
unique_bool = torch.cat((first_element, unique_bool), dim=0)
return tensor[unique_bool.detach()]
def intersect1d(tensor1, tensor2):
aux = torch.cat((tensor1, tensor2), dim=0)
aux = aux.sort()[0]
return aux[:-1][(aux[1:] == aux[:-1]).detach()]
def log2(x):
"""Implementation of log2. Pytorch doesn't have a native implementation."""
ln2 = torch.log(torch.FloatTensor([2.0]))
if x.is_cuda:
ln2 = ln2.cuda()
return torch.log(x) / ln2
def compute_backbone_shapes(config, image_shape):
"""Computes the depth, width and height of each stage of the backbone network.
Returns:
[N, (depth, height, width)]. Where N is the number of stages
"""
H, W, D = image_shape[:3]
return np.array(
[[int(math.ceil(D / stride)),
int(math.ceil(H / stride)),
int(math.ceil(W / stride))]
for stride in config.BACKBONE_STRIDES])
############################################################
# FPN Graph
############################################################
class TopDownLayer(nn.Module):
"""Generate the Pyramid Feature Maps.
Returns [p2_out, p3_out, c0_out], where p2_out and p3_out is used for RPN
and c0_out is used for mrcnn mask branch.
"""
def __init__(self, in_channels, out_channels):
super(TopDownLayer, self).__init__()
self.conv1 = nn.Conv3d(in_channels, out_channels, kernel_size=1, stride=1)
self.conv2 = nn.Conv3d(out_channels, out_channels, kernel_size=3, stride=1, padding=1)
def forward(self, x, y):
y = F.interpolate(y, scale_factor=2)
x = self.conv1(x)
return self.conv2(x + y)
class FPN(nn.Module):
def __init__(self, C1, C2, C3, out_channels, config):
super(FPN, self).__init__()
self.out_channels = out_channels
self.C1 = C1
self.C2 = C2
self.C3 = C3
self.P3_conv1 = nn.Conv3d(config.BACKBONE_CHANNELS[1] * 4, self.out_channels, kernel_size=1, stride=1)
self.P3_conv2 = nn.Conv3d(self.out_channels, self.out_channels, kernel_size=3, stride=1, padding=1)
self.P2_conv1 = nn.Conv3d(config.BACKBONE_CHANNELS[0] * 4, self.out_channels, kernel_size=1, stride=1)
self.P2_conv2 = nn.Conv3d(self.out_channels, self.out_channels, kernel_size=3, stride=1, padding=1)
def forward(self, x):
x = self.C1(x)
x = self.C2(x)
c2_out = x
x = self.C3(x)
c3_out = x
p3_out = self.P3_conv1(c3_out)
p2_out = self.P2_conv1(c2_out) + F.upsample(p3_out, scale_factor=2)
p3_out = self.P3_conv2(p3_out)
p2_out = self.P2_conv2(p2_out)
return [p2_out, p3_out]
############################################################
# Proposal Layer
############################################################
def apply_box_deltas(boxes, deltas):
"""Applies the given deltas to the given boxes.
boxes: [N, 6] where each row is z1, y1, x1, z2, y2, x2
deltas: [N, 6] where each row is [dz, dy, dx, log(dd), log(dh), log(dw)]
"""
# Convert to z, y, x, d, h, w
depth = boxes[:, 3] - boxes[:, 0]
height = boxes[:, 4] - boxes[:, 1]
width = boxes[:, 5] - boxes[:, 2]
center_z = boxes[:, 0] + 0.5 * depth
center_y = boxes[:, 1] + 0.5 * height
center_x = boxes[:, 2] + 0.5 * width
# Apply deltas
center_z += deltas[:, 0] * depth
center_y += deltas[:, 1] * height
center_x += deltas[:, 2] * width
depth *= torch.exp(deltas[:, 3])
height *= torch.exp(deltas[:, 4])
width *= torch.exp(deltas[:, 5])
# Convert back to z1, y1, x1, z2, y2, x2
z1 = center_z - 0.5 * depth
y1 = center_y - 0.5 * height
x1 = center_x - 0.5 * width
z2 = z1 + depth
y2 = y1 + height
x2 = x1 + width
result = torch.stack([z1, y1, x1, z2, y2, x2], dim=1)
return result
def clip_boxes(boxes, window):
"""boxes: [N, 6] each col is z1, y1, x1, z2, y2, x2
window: [6] in the form z1, y1, x1, z2, y2, x2
"""
boxes = torch.stack(
[boxes[:, 0].clamp(float(window[0]), float(window[3])),
boxes[:, 1].clamp(float(window[1]), float(window[4])),
boxes[:, 2].clamp(float(window[2]), float(window[5])),
boxes[:, 3].clamp(float(window[0]), float(window[3])),
boxes[:, 4].clamp(float(window[1]), float(window[4])),
boxes[:, 5].clamp(float(window[2]), float(window[5]))], 1)
return boxes
def proposal_layer(inputs, proposal_count, nms_threshold, anchors, config=None):
"""Receives anchor scores and selects a subset to pass as proposals
to the second stage. Filtering is done based on anchor scores and
non-max suppression to remove overlaps. It also applies bounding
box refinement deltas to anchors.
Inputs:
rpn_probs: [batch, anchors, (bg prob, fg prob)]
rpn_bbox: [batch, anchors, (dz, dy, dx, log(dd), log(dh), log(dw))]
Returns:
Proposals in normalized coordinates [batch, rois, (z1, y1, x1, z2, y2, x2)]
"""
# Currently only supports batchsize 1
inputs[0] = inputs[0].squeeze(0)
inputs[1] = inputs[1].squeeze(0)
# Box Scores. Use the foreground class confidence. [Batch, num_rois, 1]
scores = inputs[0][:, 1]
# Box deltas [batch, num_rois, 6]
deltas = inputs[1]
std_dev = torch.from_numpy(np.reshape(config.RPN_BBOX_STD_DEV, [1, 6])).float()
if config.GPU_COUNT:
std_dev = std_dev.cuda()
deltas = deltas * std_dev
# Improve performance by trimming to top anchors by score
# and doing the rest on the smaller subset.
pre_nms_limit = min(config.PRE_NMS_LIMIT, anchors.size()[0])
scores, order = scores.sort(descending=True)
order = order[:pre_nms_limit]
scores = scores[:pre_nms_limit]
deltas = deltas[order.detach(), :]
anchors = anchors[order.detach(), :]
# Apply deltas to anchors to get refined anchors.
# [batch, N, (z1, y1, x1, z2, y2, x2)]
boxes = apply_box_deltas(anchors, deltas)
# Clip to image boundaries. [batch, N, (z1, y1, x1, z2, y2, x2)]
height, width, depth = config.IMAGE_SHAPE[:3]
window = np.array([0, 0, 0, depth, height, width]).astype(np.float32)
boxes = clip_boxes(boxes, window)
# Non-max suppression
keep = utils.non_max_suppression(boxes.cpu().detach().numpy(),
scores.cpu().detach().numpy(), nms_threshold, proposal_count)
keep = torch.from_numpy(keep).long()
boxes = boxes[keep, :]
# Normalize dimensions to range of 0 to 1.
norm = torch.from_numpy(np.array([depth, height, width, depth, height, width])).float()
if config.GPU_COUNT:
norm = norm.cuda()
normalized_boxes = boxes / norm
# Add back batch dimension
normalized_boxes = normalized_boxes.unsqueeze(0)
return normalized_boxes
############################################################
# ROIAlign Layer
############################################################
def RoI_Align(feature_map, pool_size, boxes):
"""Implementation of 3D RoI Align (actually it's just pooling rather than align).
feature_map: [channels, depth, height, width]. Generated from FPN.
pool_size: [D, H, W]. The shape of the output.
boxes: [num_boxes, (z1, y1, x1, z2, y2, x2)].
"""
boxes = utils.denorm_boxes_graph(boxes, (feature_map.size()[1], feature_map.size()[2], feature_map.size()[3]))
boxes[:, 0] = boxes[:, 0].floor()
boxes[:, 1] = boxes[:, 1].floor()
boxes[:, 2] = boxes[:, 2].floor()
boxes[:, 3] = boxes[:, 3].ceil()
boxes[:, 4] = boxes[:, 4].ceil()
boxes[:, 5] = boxes[:, 5].ceil()
boxes = boxes.long()
output = torch.zeros((boxes.size()[0], feature_map.size()[0], pool_size[0], pool_size[1], pool_size[2])).cuda()
for i in range(boxes.size()[0]):
try:
output[i] = F.interpolate((feature_map[:, boxes[i][0]:boxes[i][3], boxes[i][1]:boxes[i][4], boxes[i][2]:boxes[i][5]]).unsqueeze(0),
size=pool_size, mode='trilinear', align_corners=True).cuda()
except:
print("RoI_Align error!")
print("box:", boxes[i], "feature_map size:", feature_map.size())
pass
return output.cuda()
def pyramid_roi_align(inputs, pool_size, test_flag=False):
"""Implements ROI Pooling on multiple levels of the feature pyramid.
Params:
- pool_size: [depth, height, width] of the output pooled regions. Usually [7, 7, 7]
- image_shape: [height, width, depth, channels]. Shape of input image in pixels
Inputs:
- boxes: [batch, num_boxes, (z1, y1, x1, z2, y2, x2)] in normalized coordinates.
- Feature maps: List of feature maps from different levels of the pyramid.
Each is [batch, channels, depth, height, width]
Output:
Pooled regions in the shape: [num_boxes, channels, depth, height, width].
The width, height and depth are those specific in the pool_shape in the layer
constructor.
"""
# Currently only supports batchsize 1
if test_flag:
for i in range(0, len(inputs)):
inputs[i] = inputs[i].squeeze(0)
else:
for i in range(1, len(inputs)):
inputs[i] = inputs[i].squeeze(0)
# Crop boxes [batch, num_boxes, (y1, x1, z1, y2, x2, z2)] in normalized coordinates
boxes = inputs[0]
# Feature Maps. List of feature maps from different level of the
# feature pyramid. Each is [batch, channels, depth, height, width]
feature_maps = inputs[1:]
# Assign each ROI to a level in the pyramid based on the ROI volume.
z1, y1, x1, z2, y2, x2 = boxes.chunk(6, dim=1)
d = z2 - z1
h = y2 - y1
w = x2 - x1
# Equation 1 in the Feature Pyramid Networks paper.
# Account for the fact that our coordinates are normalized here.
# TODO: change the equation here
roi_level = 4 + (1. / 3.) * log2(h * w * d)
roi_level = roi_level.round().int()
roi_level = roi_level.clamp(2, 3)
# Loop through levels and apply ROI pooling to P2 or P3.
pooled = []
box_to_level = []
for i, level in enumerate(range(2, 4)):
ix = (roi_level == level)
if not ix.any():
continue
ix = torch.nonzero(ix)[:, 0]
level_boxes = boxes[ix.detach(), :]
# Keep track of which box is mapped to which level
box_to_level.append(ix.detach())
# Stop gradient propagation to ROI proposals
level_boxes = level_boxes.detach()
# Crop and Resize
# From Mask R-CNN paper: "We sample four regular locations, so that we can evaluate
# either max or average pooling. In fact, interpolating only a single value at each bin center
# (without pooling) is nearly as effective."
# Here we use the simplified approach of a single value per bin.
# Result: [batch * num_boxes, channels, pool_depth, pool_height, pool_width]
pooled_features = RoI_Align(feature_maps[i], pool_size, level_boxes)
pooled.append(pooled_features)
# Pack pooled features into one tensor
pooled = torch.cat(pooled, dim=0)
# Pack box_to_level mapping into one array and add another
# column representing the order of pooled boxes
box_to_level = torch.cat(box_to_level, dim=0)
# Rearrange pooled features to match the order of the original boxes
_, box_to_level = torch.sort(box_to_level)
pooled = pooled[box_to_level, :, :, :]
return pooled
############################################################
# Detection Target Layer
############################################################
def bbox_overlaps(boxes1, boxes2):
"""Computes IoU overlaps between two sets of boxes.
boxes1, boxes2: [N, (z1, y1, x1, z2, y2, x2)].
"""
# 1. Tile boxes2 and repeat boxes1. This allows us to compare
# every boxes1 against every boxes2 without loops.
boxes1_repeat = boxes2.size()[0]
boxes2_repeat = boxes1.size()[0]
boxes1 = boxes1.repeat(1, boxes1_repeat).view(-1, 6)
boxes2 = boxes2.repeat(boxes2_repeat, 1)
# 2. Compute intersections
b1_z1, b1_y1, b1_x1, b1_z2, b1_y2, b1_x2 = boxes1.chunk(6, dim=1)
b2_z1, b2_y1, b2_x1, b2_z2, b2_y2, b2_x2 = boxes2.chunk(6, dim=1)
z1 = torch.max(b1_z1, b2_z1)[:, 0]
y1 = torch.max(b1_y1, b2_y1)[:, 0]
x1 = torch.max(b1_x1, b2_x1)[:, 0]
z2 = torch.min(b1_z2, b2_z2)[:, 0]
y2 = torch.min(b1_y2, b2_y2)[:, 0]
x2 = torch.min(b1_x2, b2_x2)[:, 0]
zeros = Variable(torch.zeros(z1.size()[0]), requires_grad=False)
if z1.is_cuda:
zeros = zeros.cuda()
intersection = torch.max(x2 - x1, zeros) * torch.max(y2 - y1, zeros) * torch.max(z2 - z1, zeros)
# 3. Compute unions
b1_volume = (b1_z2 - b1_z1) * (b1_y2 - b1_y1) * (b1_x2 - b1_x1)
b2_volume = (b2_z2 - b2_z1) * (b2_y2 - b2_y1) * (b2_x2 - b2_x1)
union = b1_volume[:, 0] + b2_volume[:, 0] - intersection
# 4. Compute IoU and reshape to [boxes1, boxes2]
iou = intersection / union
overlaps = iou.view(boxes2_repeat, boxes1_repeat)
return overlaps
def detection_target_layer(proposals, gt_class_ids, gt_boxes, gt_masks, config):
"""Subsamples proposals and generates target box refinement, class_ids,
and masks for each.
Inputs:
proposals: [batch, N, (z1, y1, x1, z2, y2, x2)] in normalized coordinates. Might
be zero padded if there are not enough proposals.
gt_class_ids: [batch, MAX_GT_INSTANCES] Integer class IDs.
gt_boxes: [batch, MAX_GT_INSTANCES, (z1, y1, x1, z2, y2, x2)] in normalized
coordinates.
gt_masks: [batch, MAX_GT_INSTANCES, depth, height, width] of np.int32 type
Returns: Target ROIs and corresponding class IDs, bounding box shifts,
and masks.
rois: [batch, TRAIN_ROIS_PER_IMAGE, (z1, y1, x1, z2, y2, x2)] in normalized coordinates
target_class_ids: [batch, TRAIN_ROIS_PER_IMAGE]. Integer class IDs.
target_deltas: [batch, TRAIN_ROIS_PER_IMAGE, NUM_CLASSES,
(dz, dy, dx, log(dd), log(dh), log(dw), class_id)]
Class-specific bbox refinements.
target_mask: [batch, TRAIN_ROIS_PER_IMAGE, depth, height, width)
Masks cropped to bbox boundaries and resized to neural
network output size.
"""
# Currently only supports batchsize 1
proposals = proposals.squeeze(0)
gt_class_ids = gt_class_ids.squeeze(0)
gt_boxes = gt_boxes.squeeze(0)
gt_masks = gt_masks.squeeze(0)
# Compute overlaps matrix [proposals, gt_boxes]
overlaps = bbox_overlaps(proposals, gt_boxes)
# Determine positive and negative ROIs
roi_iou_max = torch.max(overlaps, dim=1)[0]
print("rpn_roi_iou_max:", roi_iou_max.max())
# 1. Positive ROIs are those with >= 0.5 IoU with a GT box
positive_roi_bool = roi_iou_max >= config.DETECTION_TARGET_IOU_THRESHOLD
# Subsample ROIs. Aim for 33% positive
# Positive ROIs
if torch.nonzero(positive_roi_bool).size()[0] != 0:
positive_indices = torch.nonzero(positive_roi_bool)[:, 0]
positive_count = int(config.TRAIN_ROIS_PER_IMAGE *
config.ROI_POSITIVE_RATIO)
rand_idx = torch.randperm(positive_indices.size()[0])
rand_idx = rand_idx[:positive_count]
if config.GPU_COUNT:
rand_idx = rand_idx.cuda()
positive_indices = positive_indices[rand_idx]
positive_count = positive_indices.size()[0]
positive_rois = proposals[positive_indices.detach(), :]
# Assign positive ROIs to GT boxes.
positive_overlaps = overlaps[positive_indices.detach(), :]
roi_gt_box_assignment = torch.max(positive_overlaps, dim=1)[1]
roi_gt_boxes = gt_boxes[roi_gt_box_assignment.detach(), :]
roi_gt_class_ids = gt_class_ids[roi_gt_box_assignment.detach()]
# Compute bbox refinement for positive ROIs
deltas = Variable(utils.box_refinement(positive_rois.detach(), roi_gt_boxes.detach()), requires_grad=False)
std_dev = torch.from_numpy(config.BBOX_STD_DEV).float()
if config.GPU_COUNT:
std_dev = std_dev.cuda()
deltas /= std_dev
# Assign positive ROIs to GT masks
# Permute masks to [N, depth, height, width]
# Pick the right mask for each ROI
roi_gt_masks = np.zeros((positive_rois.shape[0], 8,) + config.MASK_SHAPE)
for i in range(0, positive_rois.shape[0]):
z1 = int(gt_masks.shape[1]*positive_rois[i, 0])
z2 = int(gt_masks.shape[1]*positive_rois[i, 3])
y1 = int(gt_masks.shape[2]*positive_rois[i, 1])
y2 = int(gt_masks.shape[2]*positive_rois[i, 4])
x1 = int(gt_masks.shape[3]*positive_rois[i, 2])
x2 = int(gt_masks.shape[3]*positive_rois[i, 5])
crop_mask = gt_masks[:, z1:z2, y1:y2, x1:x2].cpu().numpy()
crop_mask = utils.resize(crop_mask, (8,) + config.MASK_SHAPE, order=0, preserve_range=True)
roi_gt_masks[i, :, :, :, :] = crop_mask
roi_gt_masks = torch.from_numpy(roi_gt_masks).cuda()
roi_gt_masks = roi_gt_masks.type(torch.DoubleTensor)
else:
positive_count = 0
# 2. Negative ROIs are those with < 0.5 with every GT box.
negative_roi_bool = roi_iou_max < config.DETECTION_TARGET_IOU_THRESHOLD
negative_roi_bool = negative_roi_bool
# Negative ROIs. Add enough to maintain positive:negative ratio.
if torch.nonzero(negative_roi_bool).size()[0] != 0 and positive_count > 0:
negative_indices = torch.nonzero(negative_roi_bool)[:, 0]
r = 1.0 / config.ROI_POSITIVE_RATIO
negative_count = int(r * positive_count - positive_count)
rand_idx = torch.randperm(negative_indices.size()[0])
rand_idx = rand_idx[:negative_count]
if config.GPU_COUNT:
rand_idx = rand_idx.cuda()
negative_indices = negative_indices[rand_idx]
negative_count = negative_indices.size()[0]
negative_rois = proposals[negative_indices.detach(), :]
else:
negative_count = 0
# Append negative ROIs and pad bbox deltas and masks that
# are not used for negative ROIs with zeros.
if positive_count > 0 and negative_count > 0:
rois = torch.cat((positive_rois, negative_rois), dim=0)
zeros = Variable(torch.zeros(negative_count), requires_grad=False).long()
if config.GPU_COUNT:
zeros = zeros.cuda()
roi_gt_class_ids = torch.cat([roi_gt_class_ids.long(), zeros], dim=0)
zeros = Variable(torch.zeros(negative_count, 6), requires_grad=False)
if config.GPU_COUNT:
zeros = zeros.cuda()
deltas = torch.cat([deltas, zeros], dim=0)
zeros = Variable(torch.zeros(negative_count, config.MASK_SHAPE[0], config.MASK_SHAPE[1], config.MASK_SHAPE[2]),
requires_grad=False)
if config.GPU_COUNT:
zeros = zeros.cuda()
masks = roi_gt_masks
elif positive_count > 0:
rois = positive_rois
elif negative_count > 0:
positive_rois = Variable(torch.FloatTensor(), requires_grad=False)
rois = negative_rois
zeros = Variable(torch.zeros(negative_count), requires_grad=False)
if config.GPU_COUNT:
zeros = zeros.cuda()
positive_rois = positive_rois.cuda()
roi_gt_class_ids = zeros
zeros = Variable(torch.zeros(negative_count, 6), requires_grad=False).int()
if config.GPU_COUNT:
zeros = zeros.cuda()
deltas = zeros
zeros = Variable(torch.zeros(negative_count, config.MASK_SHAPE[0], config.MASK_SHAPE[1], config.MASK_SHAPE[2]),
requires_grad=False)
if config.GPU_COUNT:
zeros = zeros.cuda()
masks = zeros
else:
positive_rois = Variable(torch.FloatTensor(), requires_grad=False)
rois = Variable(torch.FloatTensor(), requires_grad=False)
roi_gt_class_ids = Variable(torch.IntTensor(), requires_grad=False)
deltas = Variable(torch.FloatTensor(), requires_grad=False)
masks = Variable(torch.FloatTensor(), requires_grad=False)
if config.GPU_COUNT:
positive_rois = positive_rois.cuda()
rois = rois.cuda()
roi_gt_class_ids = roi_gt_class_ids.cuda()
deltas = deltas.cuda()
masks = masks.cuda()
return positive_rois, rois, roi_gt_class_ids, deltas, masks
############################################################
# Detection Layer
############################################################
def clip_to_window(window, boxes):
"""window: (z1, y1, x1, z2, y2, x2). The window in the image we want to clip to.
boxes: [N, (z1, y1, x1, z2, y2, x2)]
"""
boxes[:, 0] = boxes[:, 0].clamp(float(window[0]), float(window[3]))
boxes[:, 1] = boxes[:, 1].clamp(float(window[1]), float(window[4]))
boxes[:, 2] = boxes[:, 2].clamp(float(window[2]), float(window[5]))
boxes[:, 3] = boxes[:, 3].clamp(float(window[0]), float(window[3]))
boxes[:, 4] = boxes[:, 4].clamp(float(window[1]), float(window[4]))
boxes[:, 5] = boxes[:, 5].clamp(float(window[2]), float(window[5]))
return boxes
def refine_detections(rois, probs, deltas, window, config):
"""Refine classified proposals and filter overlaps and return final
detections.
Inputs:
rois: [N, (z1, y1, x1, z2, y2, x2)] in normalized coordinates
probs: [N, num_classes]. Class probabilities.
deltas: [N, num_classes, (dz, dy, dx, log(dd), log(dh), log(dw))]. Class-specific
bounding box deltas.
window: (z1, y1, x1, z2, y2, x2) in image coordinates. The part of the image
that contains the image excluding the padding.
Returns detections shaped: [N, (z1, y1, x1, z2, y2, x2, class_id, score)]
"""
# Class IDs per ROI
_, class_ids = torch.max(probs, dim=1)
# Class probability of the top class of each ROI
# Class-specific bounding box deltas
idx = torch.arange(class_ids.size()[0]).long()
if config.GPU_COUNT:
idx = idx.cuda()
class_scores = probs[idx, class_ids.detach()]
deltas_specific = deltas[idx, class_ids.detach()]
# Apply bounding box deltas
# Shape: [boxes, (z1, y1, x1, z2, y2, x2)] in normalized coordinates
std_dev = torch.from_numpy(np.reshape(config.RPN_BBOX_STD_DEV, [1, 6])).float()
if config.GPU_COUNT:
std_dev = std_dev.cuda()
refined_rois = apply_box_deltas(rois, deltas_specific * std_dev)
# Convert coordinates to image domain
height, width, depth = config.IMAGE_SHAPE[:3]
scale = torch.from_numpy(np.array([depth, height, width, depth, height, width])).float()
if config.GPU_COUNT:
scale = scale.cuda()
refined_rois *= scale
# Clip boxes to image window
refined_rois = clip_to_window(window, refined_rois)
# Round and cast to int since we're dealing with pixels now
refined_rois = torch.round(refined_rois)
# Filter out background boxes
keep_bool = class_ids > 0
# Filter out low confidence boxes
if config.DETECTION_MIN_CONFIDENCE:
keep_bool = keep_bool & (class_scores >= config.DETECTION_MIN_CONFIDENCE)
keep = torch.nonzero(keep_bool)[:, 0]
# Apply per-class NMS
pre_nms_class_ids = class_ids[keep.detach()]
pre_nms_scores = class_scores[keep.detach()]
pre_nms_rois = refined_rois[keep.detach()]
for i, class_id in enumerate(unique1d(pre_nms_class_ids)):
# Pick detections of this class
ixs = torch.nonzero(pre_nms_class_ids == class_id)[:, 0]
# Sort
ix_rois = pre_nms_rois[ixs.detach()]
ix_scores = pre_nms_scores[ixs]
ix_scores, order = ix_scores.sort(descending=True)
ix_rois = ix_rois[order.detach(), :]
class_keep = utils.non_max_suppression(ix_rois.cpu().detach().numpy(), ix_scores.cpu().detach().numpy(),
config.DETECTION_NMS_THRESHOLD, config.DETECTION_MAX_INSTANCES)
class_keep = torch.from_numpy(class_keep).long()
# Map indices
class_keep = keep[ixs[order[class_keep].detach()].detach()]
if i == 0:
nms_keep = class_keep
else:
nms_keep = unique1d(torch.cat((nms_keep, class_keep)))
keep = intersect1d(keep, nms_keep)
# Keep top detections
roi_count = config.DETECTION_MAX_INSTANCES
roi_count = min(roi_count, keep.size()[0])
top_ids = class_scores[keep.detach()].sort(descending=True)[1][:roi_count]
keep = keep[top_ids.detach()]
# Arrange output as [N, (z1, y1, x1, z2, y2, x2, class_id, score)]
# Coordinates are in image domain.
result = torch.cat((refined_rois[keep.detach()],
class_ids[keep.detach()].unsqueeze(1).float(),
class_scores[keep.detach()].unsqueeze(1)), dim=1)
return result
def detection_layer(config, rois, mrcnn_class, mrcnn_bbox, image_meta):
"""Takes classified proposal boxes and their bounding box deltas and
returns the final detection boxes.
Returns:
[batch, num_detections, (z1, y1, x1, z2, y2, x2, class_score)] in pixels
"""
# Currently only supports batchsize 1
rois = rois.squeeze(0)
_, _, window, _ = parse_image_meta(image_meta)
window = window[0]
detections = refine_detections(rois, mrcnn_class, mrcnn_bbox, window, config)
return detections
############################################################
# Region Proposal Network
############################################################
class RPN(nn.Module):
"""Builds the model of Region Proposal Network.
anchors_per_location: number of anchors per pixel in the feature map
anchor_stride: Controls the density of anchors. Typically 1 (anchors for
every pixel in the feature map), or 2 (every other pixel).
Returns:
rpn_logits: [batch, D, H, W, 2] Anchor classifier logits (before softmax)
rpn_probs: [batch, D, H, W, 2] Anchor classifier probabilities.
rpn_bbox: [batch, D, H, W, (dz, dy, dx, log(dd), log(dh), log(dw))] Deltas to be applied to anchors.
"""
def __init__(self, anchors_per_location, anchor_stride, channel, conv_channel):
super(RPN, self).__init__()
self.conv_shared = nn.Conv3d(channel, conv_channel, kernel_size=3, stride=anchor_stride, padding=1)
self.relu = nn.ReLU(inplace=True)
self.conv_class = nn.Conv3d(conv_channel, 2 * anchors_per_location, kernel_size=1, stride=1)
self.softmax = nn.Softmax(dim=2)
self.conv_bbox = nn.Conv3d(conv_channel, 6 * anchors_per_location, kernel_size=1, stride=1)
def forward(self, x):
# Shared convolutional base of the RPN
x = self.relu(self.conv_shared(x))
# Anchor Score. [batch, anchors per location * 2, depth, height, width].
rpn_class_logits = self.conv_class(x)
# Reshape to [batch, anchors, 2]
rpn_class_logits = rpn_class_logits.permute(0, 2, 3, 4, 1)
rpn_class_logits = rpn_class_logits.contiguous()
rpn_class_logits = rpn_class_logits.view(x.size()[0], -1, 2)
# Softmax on last dimension of BG/FG.
rpn_probs = self.softmax(rpn_class_logits)
# Bounding box refinement. [batch, anchors per location * 6, D, H, W]
# where 6 == delta [z, y, x, log(d), log(h), log(w)]
rpn_bbox = self.conv_bbox(x)
# Reshape to [batch, anchors, 6]
rpn_bbox = rpn_bbox.permute(0, 2, 3, 4, 1)
rpn_bbox = rpn_bbox.contiguous()
rpn_bbox = rpn_bbox.view(x.size()[0], -1, 6)
return [rpn_class_logits, rpn_probs, rpn_bbox]
############################################################
# Feature Pyramid Network Heads
############################################################
class Classifier(nn.Module):
def __init__(self, channel, pool_size, image_shape, num_classes, fc_size, test_flag=False):
super(Classifier, self).__init__()
self.pool_size = pool_size
self.image_shape = image_shape
self.fc_size = fc_size
self.test_flag = test_flag
self.conv1 = nn.Conv3d(channel, fc_size, kernel_size=self.pool_size, stride=1)
self.bn1 = nn.BatchNorm3d(fc_size, eps=0.001, momentum=0.01)
self.conv2 = nn.Conv3d(fc_size, fc_size, kernel_size=1, stride=1)
self.bn2 = nn.BatchNorm3d(fc_size, eps=0.001, momentum=0.01)
self.relu = nn.ReLU(inplace=True)
self.linear_class = nn.Linear(fc_size, num_classes)
self.softmax = nn.Softmax(dim=1)
self.linear_bbox = nn.Linear(fc_size, num_classes * 6)
def forward(self, x, rois):
x = pyramid_roi_align([rois] + x, self.pool_size, self.test_flag)
x = self.conv1(x)
x = self.bn1(x)
x = self.relu(x)
x = self.conv2(x)
x = self.bn2(x)
x = self.relu(x)
x = x.view(-1, self.fc_size)
mrcnn_class_logits = self.linear_class(x)
mrcnn_probs = self.softmax(mrcnn_class_logits)
mrcnn_bbox = self.linear_bbox(x)
mrcnn_bbox = mrcnn_bbox.view(mrcnn_bbox.size()[0], -1, 6)
return [mrcnn_class_logits, mrcnn_probs, mrcnn_bbox]
class Mask(nn.Module):
def __init__(self, channel, pool_size, num_classes, conv_channel, stage, test_flag=False):
super(Mask, self).__init__()
self.pool_size = pool_size
self.test_flag = test_flag
self.modified_u_net = mask_branch.Modified3DUNet(channel, num_classes, stage, conv_channel)
self.softmax = nn.Softmax(dim=1)
def forward(self, x, rois):
x = pyramid_roi_align([rois] + x, self.pool_size, self.test_flag)
x = self.modified_u_net(x)
output = self.softmax(x)
return x, output
############################################################
# Loss Functions
############################################################
def compute_rpn_class_loss(rpn_match, rpn_class_logits):
"""RPN anchor classifier loss.
rpn_match: [batch, anchors, 1]. Anchor match type. 1=positive,
-1=negative, 0=neutral anchor.
rpn_class_logits: [batch, anchors, 2]. RPN classifier logits for FG/BG.
"""
# Squeeze last dim to simplify
rpn_match = rpn_match.squeeze(2)
# Get anchor classes. Convert the -1/+1 match to 0/1 values.
anchor_class = (rpn_match == 1).long()
# Positive and Negative anchors contribute to the loss,
# but neutral anchors (match value = 0) don't.
indices = torch.nonzero(rpn_match != 0)
# Pick rows that contribute to the loss and filter out the rest.
rpn_class_logits = rpn_class_logits[indices.detach()[:, 0], indices.detach()[:, 1], :]
anchor_class = anchor_class[indices.detach()[:, 0], indices.detach()[:, 1]]
# Cross-entropy loss
loss = F.cross_entropy(rpn_class_logits, anchor_class)
return loss
def compute_rpn_bbox_loss(target_bbox, rpn_match, rpn_bbox):
"""Return the RPN bounding box loss graph.
target_bbox: [batch, max positive anchors, (dz, dy, dx, log(dd), log(dh), log(dw))].
Uses 0 padding to fill in unused bbox deltas.
rpn_match: [batch, anchors, 1]. Anchor match type. 1=positive,
-1=negative, 0=neutral anchor.
rpn_bbox: [batch, anchors, (dz, dy, dx, log(dd), log(dh), log(dw))]
"""
# Squeeze last dim to simplify
rpn_match = rpn_match.squeeze(2)
# Positive anchors contribute to the loss, but negative and
# neutral anchors (match value of 0 or -1) don't.
indices = torch.nonzero(rpn_match == 1)
# Pick bbox deltas that contribute to the loss
rpn_bbox = rpn_bbox[indices.detach()[:, 0], indices.detach()[:, 1]]
# Trim target bounding box deltas to the same length as rpn_bbox.
target_bbox = target_bbox[0, :rpn_bbox.size()[0], :]
# Smooth L1 loss
loss = F.smooth_l1_loss(rpn_bbox, target_bbox)
return loss
def compute_mrcnn_class_loss(target_class_ids, pred_class_logits):
"""Loss for the classifier head of Mask RCNN.
target_class_ids: [batch, num_rois]. Integer class IDs. Uses zero
padding to fill in the array.
pred_class_logits: [batch, num_rois, num_classes]
"""
# Loss
if target_class_ids.size()[0] != 0:
loss = F.cross_entropy(pred_class_logits, target_class_ids.long())
else:
loss = Variable(torch.FloatTensor([0]), requires_grad=False)
if target_class_ids.is_cuda:
loss = loss.cuda()
return loss
def compute_mrcnn_bbox_loss(target_bbox, target_class_ids, pred_bbox):
"""Loss for Mask R-CNN bounding box refinement.
target_bbox: [batch, num_rois, (dz, dy, dx, log(dd), log(dh), log(dw))]
target_class_ids: [batch, num_rois]. Integer class IDs.
pred_bbox: [batch, num_rois, num_classes, (dz, dy, dx, log(dd), log(dh), log(dw))]
"""
if target_class_ids.size()[0] != 0:
# Only positive ROIs contribute to the loss. And only
# the right class_id of each ROI. Get their indices.
positive_roi_ix = torch.nonzero(target_class_ids > 0)[:, 0]
positive_roi_class_ids = target_class_ids[positive_roi_ix.detach()].long()
indices = torch.stack((positive_roi_ix, positive_roi_class_ids), dim=1)
# Gather the deltas (predicted and true) that contribute to loss
target_bbox = target_bbox[indices[:, 0].detach(), :]
pred_bbox = pred_bbox[indices[:, 0].detach(), indices[:, 1].detach(), :]
# Smooth L1 loss
loss = F.smooth_l1_loss(pred_bbox, target_bbox)
else:
loss = Variable(torch.FloatTensor([0]), requires_grad=False)
if target_class_ids.is_cuda:
loss = loss.cuda()
return loss
def compute_mrcnn_mask_loss(target_masks, target_class_ids, pred_masks):
"""Mask binary cross-entropy loss for the masks head.
target_masks: [batch, num_rois, depth, height, width].
A float32 tensor of values 0 or 1. Uses zero padding to fill array.
target_class_ids: [batch, num_rois]. Integer class IDs. Zero padded.
pred_masks: [batch, proposals, num_classes, depth, height, width] float32 tensor
with values from 0 to 1.
"""
if target_class_ids.size()[0] != 0:
# Only positive ROIs contribute to the loss. And only the class specific mask of each ROI.
positive_ix = torch.nonzero(target_class_ids > 0)[:, 0]
positive_class_ids = target_class_ids[positive_ix.detach()].long()
indices = torch.stack((positive_ix, positive_class_ids), dim=1)
# Gather the masks (predicted and true) that contribute to loss
y_true_ = target_masks[indices[:,0], :, :, :]
y_true = y_true_.long().cuda()
y_true = torch.argmax(y_true,dim=1)
y_pred = pred_masks[indices[:, 0].detach(), :, :, :, :]
# Binary cross entropy
los = nn.CrossEntropyLoss().cuda()
loss = los(y_pred, y_true)
else:
loss = Variable(torch.FloatTensor([0]), requires_grad=False)
if target_class_ids.is_cuda:
loss = loss.cuda()
return loss
def compute_mrcnn_mask_edge_loss(target_masks, target_class_ids, pred_masks):
"""Mask edge mean square error loss for the Edge Agreement Head.
Here I use the Sobel kernel without smoothing the ground_truth masks.
target_masks: [batch, num_rois, depth, height, width].
target_class_ids: [batch, num_rois]. Integer class IDs. Zero padded.
pred_masks: [batch, proposals, num_classes, depth, height, width] float32 tensor with values from 0 to 1.
"""
if target_class_ids.size()[0] != 0:
# Generate the xyz dimension Sobel kernels
kernel_x = np.array([[[1, 2, 1], [0, 0, 0], [-1, -2, -1]],
[[2, 4, 2], [0, 0, 0], [-2, -4, -2]],
[[1, 2, 1], [0, 0, 0], [-1, -2, -1]]])
kernel_y = kernel_x.transpose((1, 0, 2))
kernel_z = kernel_x.transpose((0, 2, 1))
kernel = torch.from_numpy(np.array([kernel_x, kernel_y, kernel_z]).reshape((3, 1, 3, 3, 3))).float().cuda()
# Only positive ROIs contribute to the loss. And only the class specific mask of each ROI.
positive_ix = torch.nonzero(target_class_ids > 0)[:, 0]
positive_class_ids = target_class_ids[positive_ix.detach()].long()
indices = torch.stack((positive_ix, positive_class_ids), dim=1)
# Gather the masks (predicted and true) that contribute to loss
y_true = target_masks[:indices.size()[0], 1:, :, :]
y_pred = pred_masks[indices[:, 0].detach(), 1:, :, :, :]
# Implement the edge detection convolution
loss_fn = nn.MSELoss()
loss = torch.FloatTensor([0]).cuda()
for i in range(indices.size()[0]):
y_true_ = y_true[i]
y_pred_ = y_pred[i].unsqueeze(0) # [N, 7, 64, 64, 64]
for j in range(7):
y_true_final = F.conv3d(y_true_[j, :, :, :].unsqueeze(0).unsqueeze(0).cuda().float(), kernel)
y_pred_final = F.conv3d(y_pred_[:, j, :, :, :].unsqueeze(1), kernel)
y_true_final = torch.sqrt(torch.pow(y_true_final[:, 0], 2) + torch.pow(y_true_final[:, 1], 2) +
torch.pow(y_true_final[:, 0], 2))
y_pred_final = torch.sqrt(torch.pow(y_pred_final [:, 0], 2) + torch.pow(y_pred_final [:, 1], 2) +
torch.pow(y_pred_final [:, 0], 2))
# Mean Square Error
loss += loss_fn(y_pred_final, y_true_final)
loss /= indices.size()[0]
else:
loss = Variable(torch.FloatTensor([0]), requires_grad=False)
if target_class_ids.is_cuda:
loss = loss.cuda()
return loss
def compute_losses(rpn_match, rpn_bbox, rpn_class_logits, rpn_pred_bbox, target_class_ids, mrcnn_class_logits,
target_deltas, mrcnn_bbox, target_mask, mrcnn_mask, mrcnn_mask_logits, stage):
rpn_class_loss = compute_rpn_class_loss(rpn_match, rpn_class_logits)
rpn_bbox_loss = compute_rpn_bbox_loss(rpn_bbox, rpn_match, rpn_pred_bbox)
mrcnn_class_loss = compute_mrcnn_class_loss(torch.from_numpy(np.where(target_class_ids > 0, 1, 0)).cuda(),
mrcnn_class_logits)
mrcnn_bbox_loss = compute_mrcnn_bbox_loss(target_deltas,
torch.from_numpy(np.where(target_class_ids > 0, 1, 0)).cuda(), mrcnn_bbox)
mrcnn_mask_loss = compute_mrcnn_mask_loss(target_mask, target_class_ids, mrcnn_mask_logits)
if stage == 'finetune':
mrcnn_mask_edge_loss = compute_mrcnn_mask_edge_loss(target_mask, target_class_ids, mrcnn_mask)
else:
mrcnn_mask_edge_loss = Variable(torch.FloatTensor([0]), requires_grad=False).cuda()
return [rpn_class_loss, rpn_bbox_loss, mrcnn_class_loss, mrcnn_bbox_loss, mrcnn_mask_loss, mrcnn_mask_edge_loss]