413 lines
16 KiB
Python
413 lines
16 KiB
Python
"""YOLO_v3 Model Defined in Keras."""
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from functools import wraps
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import numpy as np
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import tensorflow as tf
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from keras import backend as K
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from keras.layers import Conv2D, Add, ZeroPadding2D, UpSampling2D, Concatenate, MaxPooling2D
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from keras.layers import LeakyReLU
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from keras.layers import BatchNormalization
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from keras.models import Model
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from keras.regularizers import l2
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from image_detector.yolo3.utils import compose
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@wraps(Conv2D)
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def DarknetConv2D(*args, **kwargs):
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"""Wrapper to set Darknet parameters for Convolution2D."""
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darknet_conv_kwargs = {'kernel_regularizer': l2(5e-4)}
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darknet_conv_kwargs['padding'] = 'valid' if kwargs.get('strides')==(2,2) else 'same'
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darknet_conv_kwargs.update(kwargs)
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return Conv2D(*args, **darknet_conv_kwargs)
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def DarknetConv2D_BN_Leaky(*args, **kwargs):
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"""Darknet Convolution2D followed by BatchNormalization and LeakyReLU."""
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no_bias_kwargs = {'use_bias': False}
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no_bias_kwargs.update(kwargs)
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return compose(
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DarknetConv2D(*args, **no_bias_kwargs),
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BatchNormalization(),
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LeakyReLU(alpha=0.1))
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def resblock_body(x, num_filters, num_blocks):
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'''A series of resblocks starting with a downsampling Convolution2D'''
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# Darknet uses left and top padding instead of 'same' mode
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x = ZeroPadding2D(((1,0),(1,0)))(x)
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x = DarknetConv2D_BN_Leaky(num_filters, (3,3), strides=(2,2))(x)
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for i in range(num_blocks):
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y = compose(
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DarknetConv2D_BN_Leaky(num_filters//2, (1,1)),
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DarknetConv2D_BN_Leaky(num_filters, (3,3)))(x)
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x = Add()([x,y])
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return x
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def darknet_body(x):
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'''Darknent body having 52 Convolution2D layers'''
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x = DarknetConv2D_BN_Leaky(32, (3,3))(x)
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x = resblock_body(x, 64, 1)
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x = resblock_body(x, 128, 2)
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x = resblock_body(x, 256, 8)
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x = resblock_body(x, 512, 8)
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x = resblock_body(x, 1024, 4)
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return x
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def make_last_layers(x, num_filters, out_filters):
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'''6 Conv2D_BN_Leaky layers followed by a Conv2D_linear layer'''
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x = compose(
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DarknetConv2D_BN_Leaky(num_filters, (1,1)),
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DarknetConv2D_BN_Leaky(num_filters*2, (3,3)),
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DarknetConv2D_BN_Leaky(num_filters, (1,1)),
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DarknetConv2D_BN_Leaky(num_filters*2, (3,3)),
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DarknetConv2D_BN_Leaky(num_filters, (1,1)))(x)
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y = compose(
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DarknetConv2D_BN_Leaky(num_filters*2, (3,3)),
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DarknetConv2D(out_filters, (1,1)))(x)
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return x, y
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def yolo_body(inputs, num_anchors, num_classes):
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"""Create YOLO_V3 model CNN body in Keras."""
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darknet = Model(inputs, darknet_body(inputs))
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x, y1 = make_last_layers(darknet.output, 512, num_anchors*(num_classes+5))
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x = compose(
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DarknetConv2D_BN_Leaky(256, (1,1)),
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UpSampling2D(2))(x)
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x = Concatenate()([x,darknet.layers[152].output])
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x, y2 = make_last_layers(x, 256, num_anchors*(num_classes+5))
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x = compose(
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DarknetConv2D_BN_Leaky(128, (1,1)),
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UpSampling2D(2))(x)
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x = Concatenate()([x,darknet.layers[92].output])
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x, y3 = make_last_layers(x, 128, num_anchors*(num_classes+5))
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return Model(inputs, [y1,y2,y3])
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def tiny_yolo_body(inputs, num_anchors, num_classes):
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'''Create Tiny YOLO_v3 model CNN body in keras.'''
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x1 = compose(
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DarknetConv2D_BN_Leaky(16, (3,3)),
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MaxPooling2D(pool_size=(2,2), strides=(2,2), padding='same'),
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DarknetConv2D_BN_Leaky(32, (3,3)),
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MaxPooling2D(pool_size=(2,2), strides=(2,2), padding='same'),
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DarknetConv2D_BN_Leaky(64, (3,3)),
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MaxPooling2D(pool_size=(2,2), strides=(2,2), padding='same'),
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DarknetConv2D_BN_Leaky(128, (3,3)),
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MaxPooling2D(pool_size=(2,2), strides=(2,2), padding='same'),
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DarknetConv2D_BN_Leaky(256, (3,3)))(inputs)
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x2 = compose(
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MaxPooling2D(pool_size=(2,2), strides=(2,2), padding='same'),
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DarknetConv2D_BN_Leaky(512, (3,3)),
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MaxPooling2D(pool_size=(2,2), strides=(1,1), padding='same'),
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DarknetConv2D_BN_Leaky(1024, (3,3)),
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DarknetConv2D_BN_Leaky(256, (1,1)))(x1)
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y1 = compose(
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DarknetConv2D_BN_Leaky(512, (3,3)),
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DarknetConv2D(num_anchors*(num_classes+5), (1,1)))(x2)
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x2 = compose(
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DarknetConv2D_BN_Leaky(128, (1,1)),
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UpSampling2D(2))(x2)
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y2 = compose(
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Concatenate(),
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DarknetConv2D_BN_Leaky(256, (3,3)),
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DarknetConv2D(num_anchors*(num_classes+5), (1,1)))([x2,x1])
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return Model(inputs, [y1,y2])
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def yolo_head(feats, anchors, num_classes, input_shape, calc_loss=False):
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"""Convert final layer features to bounding box parameters."""
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num_anchors = len(anchors)
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# Reshape to batch, height, width, num_anchors, box_params.
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anchors_tensor = K.reshape(K.constant(anchors), [1, 1, 1, num_anchors, 2])
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grid_shape = K.shape(feats)[1:3] # height, width
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grid_y = K.tile(K.reshape(K.arange(0, stop=grid_shape[0]), [-1, 1, 1, 1]),
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[1, grid_shape[1], 1, 1])
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grid_x = K.tile(K.reshape(K.arange(0, stop=grid_shape[1]), [1, -1, 1, 1]),
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[grid_shape[0], 1, 1, 1])
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grid = K.concatenate([grid_x, grid_y])
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grid = K.cast(grid, K.dtype(feats))
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feats = K.reshape(
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feats, [-1, grid_shape[0], grid_shape[1], num_anchors, num_classes + 5])
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# Adjust preditions to each spatial grid point and anchor size.
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box_xy = (K.sigmoid(feats[..., :2]) + grid) / K.cast(grid_shape[::-1], K.dtype(feats))
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box_wh = K.exp(feats[..., 2:4]) * anchors_tensor / K.cast(input_shape[::-1], K.dtype(feats))
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box_confidence = K.sigmoid(feats[..., 4:5])
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box_class_probs = K.sigmoid(feats[..., 5:])
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if calc_loss == True:
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return grid, feats, box_xy, box_wh
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return box_xy, box_wh, box_confidence, box_class_probs
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def yolo_correct_boxes(box_xy, box_wh, input_shape, image_shape):
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'''Get corrected boxes'''
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box_yx = box_xy[..., ::-1]
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box_hw = box_wh[..., ::-1]
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input_shape = K.cast(input_shape, K.dtype(box_yx))
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image_shape = K.cast(image_shape, K.dtype(box_yx))
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new_shape = K.round(image_shape * K.min(input_shape/image_shape))
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offset = (input_shape-new_shape)/2./input_shape
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scale = input_shape/new_shape
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box_yx = (box_yx - offset) * scale
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box_hw *= scale
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box_mins = box_yx - (box_hw / 2.)
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box_maxes = box_yx + (box_hw / 2.)
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boxes = K.concatenate([
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box_mins[..., 0:1], # y_min
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box_mins[..., 1:2], # x_min
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box_maxes[..., 0:1], # y_max
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box_maxes[..., 1:2] # x_max
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])
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# Scale boxes back to original image shape.
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boxes *= K.concatenate([image_shape, image_shape])
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return boxes
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def yolo_boxes_and_scores(feats, anchors, num_classes, input_shape, image_shape):
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'''Process Conv layer output'''
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box_xy, box_wh, box_confidence, box_class_probs = yolo_head(feats,
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anchors, num_classes, input_shape)
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boxes = yolo_correct_boxes(box_xy, box_wh, input_shape, image_shape)
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boxes = K.reshape(boxes, [-1, 4])
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box_scores = box_confidence * box_class_probs
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box_scores = K.reshape(box_scores, [-1, num_classes])
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return boxes, box_scores
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def yolo_eval(yolo_outputs,
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anchors,
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num_classes,
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image_shape,
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max_boxes=20,
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score_threshold=.6,
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iou_threshold=.5):
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"""Evaluate YOLO model on given input and return filtered boxes."""
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num_layers = len(yolo_outputs)
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anchor_mask = [[6,7,8], [3,4,5], [0,1,2]] if num_layers==3 else [[3,4,5], [1,2,3]] # default setting
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input_shape = K.shape(yolo_outputs[0])[1:3] * 32
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boxes = []
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box_scores = []
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for l in range(num_layers):
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_boxes, _box_scores = yolo_boxes_and_scores(yolo_outputs[l],
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anchors[anchor_mask[l]], num_classes, input_shape, image_shape)
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boxes.append(_boxes)
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box_scores.append(_box_scores)
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boxes = K.concatenate(boxes, axis=0)
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box_scores = K.concatenate(box_scores, axis=0)
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mask = box_scores >= score_threshold
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max_boxes_tensor = K.constant(max_boxes, dtype='int32')
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boxes_ = []
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scores_ = []
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classes_ = []
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for c in range(num_classes):
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# TODO: use keras backend instead of tf.
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class_boxes = tf.boolean_mask(boxes, mask[:, c])
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class_box_scores = tf.boolean_mask(box_scores[:, c], mask[:, c])
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nms_index = tf.image.non_max_suppression(
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class_boxes, class_box_scores, max_boxes_tensor, iou_threshold=iou_threshold)
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class_boxes = K.gather(class_boxes, nms_index)
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class_box_scores = K.gather(class_box_scores, nms_index)
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classes = K.ones_like(class_box_scores, 'int32') * c
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boxes_.append(class_boxes)
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scores_.append(class_box_scores)
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classes_.append(classes)
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boxes_ = K.concatenate(boxes_, axis=0)
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scores_ = K.concatenate(scores_, axis=0)
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classes_ = K.concatenate(classes_, axis=0)
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return boxes_, scores_, classes_
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def preprocess_true_boxes(true_boxes, input_shape, anchors, num_classes):
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'''Preprocess true boxes to training input format
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Parameters
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----------
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true_boxes: array, shape=(m, T, 5)
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Absolute x_min, y_min, x_max, y_max, class_id relative to input_shape.
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input_shape: array-like, hw, multiples of 32
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anchors: array, shape=(N, 2), wh
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num_classes: integer
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Returns
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-------
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y_true: list of array, shape like yolo_outputs, xywh are reletive value
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'''
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assert (true_boxes[..., 4]<num_classes).all(), 'class id must be less than num_classes'
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num_layers = len(anchors)//3 # default setting
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anchor_mask = [[6,7,8], [3,4,5], [0,1,2]] if num_layers==3 else [[3,4,5], [1,2,3]]
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true_boxes = np.array(true_boxes, dtype='float32')
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input_shape = np.array(input_shape, dtype='int32')
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boxes_xy = (true_boxes[..., 0:2] + true_boxes[..., 2:4]) // 2
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boxes_wh = true_boxes[..., 2:4] - true_boxes[..., 0:2]
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true_boxes[..., 0:2] = boxes_xy/input_shape[::-1]
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true_boxes[..., 2:4] = boxes_wh/input_shape[::-1]
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m = true_boxes.shape[0]
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grid_shapes = [input_shape//{0:32, 1:16, 2:8}[l] for l in range(num_layers)]
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y_true = [np.zeros((m,grid_shapes[l][0],grid_shapes[l][1],len(anchor_mask[l]),5+num_classes),
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dtype='float32') for l in range(num_layers)]
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# Expand dim to apply broadcasting.
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anchors = np.expand_dims(anchors, 0)
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anchor_maxes = anchors / 2.
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anchor_mins = -anchor_maxes
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valid_mask = boxes_wh[..., 0]>0
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for b in range(m):
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# Discard zero rows.
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wh = boxes_wh[b, valid_mask[b]]
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if len(wh)==0: continue
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# Expand dim to apply broadcasting.
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wh = np.expand_dims(wh, -2)
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box_maxes = wh / 2.
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box_mins = -box_maxes
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intersect_mins = np.maximum(box_mins, anchor_mins)
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intersect_maxes = np.minimum(box_maxes, anchor_maxes)
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intersect_wh = np.maximum(intersect_maxes - intersect_mins, 0.)
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intersect_area = intersect_wh[..., 0] * intersect_wh[..., 1]
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box_area = wh[..., 0] * wh[..., 1]
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anchor_area = anchors[..., 0] * anchors[..., 1]
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iou = intersect_area / (box_area + anchor_area - intersect_area)
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# Find best anchor for each true box
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best_anchor = np.argmax(iou, axis=-1)
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for t, n in enumerate(best_anchor):
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for l in range(num_layers):
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if n in anchor_mask[l]:
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i = np.floor(true_boxes[b,t,0]*grid_shapes[l][1]).astype('int32')
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j = np.floor(true_boxes[b,t,1]*grid_shapes[l][0]).astype('int32')
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k = anchor_mask[l].index(n)
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c = true_boxes[b,t, 4].astype('int32')
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y_true[l][b, j, i, k, 0:4] = true_boxes[b,t, 0:4]
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y_true[l][b, j, i, k, 4] = 1
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y_true[l][b, j, i, k, 5+c] = 1
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return y_true
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def box_iou(b1, b2):
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'''Return iou tensor
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Parameters
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----------
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b1: tensor, shape=(i1,...,iN, 4), xywh
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b2: tensor, shape=(j, 4), xywh
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Returns
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-------
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iou: tensor, shape=(i1,...,iN, j)
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'''
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# Expand dim to apply broadcasting.
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b1 = K.expand_dims(b1, -2)
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b1_xy = b1[..., :2]
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b1_wh = b1[..., 2:4]
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b1_wh_half = b1_wh/2.
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b1_mins = b1_xy - b1_wh_half
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b1_maxes = b1_xy + b1_wh_half
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# Expand dim to apply broadcasting.
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b2 = K.expand_dims(b2, 0)
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b2_xy = b2[..., :2]
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b2_wh = b2[..., 2:4]
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b2_wh_half = b2_wh/2.
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b2_mins = b2_xy - b2_wh_half
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b2_maxes = b2_xy + b2_wh_half
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intersect_mins = K.maximum(b1_mins, b2_mins)
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intersect_maxes = K.minimum(b1_maxes, b2_maxes)
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intersect_wh = K.maximum(intersect_maxes - intersect_mins, 0.)
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intersect_area = intersect_wh[..., 0] * intersect_wh[..., 1]
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b1_area = b1_wh[..., 0] * b1_wh[..., 1]
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b2_area = b2_wh[..., 0] * b2_wh[..., 1]
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iou = intersect_area / (b1_area + b2_area - intersect_area)
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return iou
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def yolo_loss(args, anchors, num_classes, ignore_thresh=.5, print_loss=False):
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'''Return yolo_loss tensor
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Parameters
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----------
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yolo_outputs: list of tensor, the output of yolo_body or tiny_yolo_body
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y_true: list of array, the output of preprocess_true_boxes
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anchors: array, shape=(N, 2), wh
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num_classes: integer
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ignore_thresh: float, the iou threshold whether to ignore object confidence loss
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Returns
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-------
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loss: tensor, shape=(1,)
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'''
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num_layers = len(anchors)//3 # default setting
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yolo_outputs = args[:num_layers]
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y_true = args[num_layers:]
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anchor_mask = [[6,7,8], [3,4,5], [0,1,2]] if num_layers==3 else [[3,4,5], [1,2,3]]
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input_shape = K.cast(K.shape(yolo_outputs[0])[1:3] * 32, K.dtype(y_true[0]))
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grid_shapes = [K.cast(K.shape(yolo_outputs[l])[1:3], K.dtype(y_true[0])) for l in range(num_layers)]
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loss = 0
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m = K.shape(yolo_outputs[0])[0] # batch size, tensor
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mf = K.cast(m, K.dtype(yolo_outputs[0]))
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for l in range(num_layers):
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object_mask = y_true[l][..., 4:5]
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true_class_probs = y_true[l][..., 5:]
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grid, raw_pred, pred_xy, pred_wh = yolo_head(yolo_outputs[l],
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anchors[anchor_mask[l]], num_classes, input_shape, calc_loss=True)
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pred_box = K.concatenate([pred_xy, pred_wh])
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# Darknet raw box to calculate loss.
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raw_true_xy = y_true[l][..., :2]*grid_shapes[l][::-1] - grid
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raw_true_wh = K.log(y_true[l][..., 2:4] / anchors[anchor_mask[l]] * input_shape[::-1])
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raw_true_wh = K.switch(object_mask, raw_true_wh, K.zeros_like(raw_true_wh)) # avoid log(0)=-inf
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box_loss_scale = 2 - y_true[l][...,2:3]*y_true[l][...,3:4]
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# Find ignore mask, iterate over each of batch.
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ignore_mask = tf.TensorArray(K.dtype(y_true[0]), size=1, dynamic_size=True)
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object_mask_bool = K.cast(object_mask, 'bool')
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def loop_body(b, ignore_mask):
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true_box = tf.boolean_mask(y_true[l][b,...,0:4], object_mask_bool[b,...,0])
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iou = box_iou(pred_box[b], true_box)
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best_iou = K.max(iou, axis=-1)
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ignore_mask = ignore_mask.write(b, K.cast(best_iou<ignore_thresh, K.dtype(true_box)))
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return b+1, ignore_mask
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_, ignore_mask = tf.while_loop(lambda b,*args: b<m, loop_body, [0, ignore_mask])
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ignore_mask = ignore_mask.stack()
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ignore_mask = K.expand_dims(ignore_mask, -1)
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# K.binary_crossentropy is helpful to avoid exp overflow.
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xy_loss = object_mask * box_loss_scale * K.binary_crossentropy(raw_true_xy, raw_pred[...,0:2], from_logits=True)
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wh_loss = object_mask * box_loss_scale * 0.5 * K.square(raw_true_wh-raw_pred[...,2:4])
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confidence_loss = object_mask * K.binary_crossentropy(object_mask, raw_pred[...,4:5], from_logits=True)+ \
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(1-object_mask) * K.binary_crossentropy(object_mask, raw_pred[...,4:5], from_logits=True) * ignore_mask
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class_loss = object_mask * K.binary_crossentropy(true_class_probs, raw_pred[...,5:], from_logits=True)
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xy_loss = K.sum(xy_loss) / mf
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wh_loss = K.sum(wh_loss) / mf
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confidence_loss = K.sum(confidence_loss) / mf
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class_loss = K.sum(class_loss) / mf
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loss += xy_loss + wh_loss + confidence_loss + class_loss
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if print_loss:
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loss = tf.Print(loss, [loss, xy_loss, wh_loss, confidence_loss, class_loss, K.sum(ignore_mask)], message='loss: ')
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return loss
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