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update yolo deps

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	# YOLOv5 🚀 by Ultralytics, GPL-3.0 license
	"""
	Model validation metrics
	"""

	import math
	import warnings
	from pathlib import Path

	import numpy as np
	import torch


	def fitness(x):
	# Model fitness as a weighted combination of metrics
	w = [0.0, 0.0, 0.1, 0.9] # weights for [P, R, [email protected], [email protected]:0.95]
	return (x[:, :4] * w).sum(1)


	def ap_per_class(tp, conf, pred_cls, target_cls, plot=False, save_dir='.', names=(), eps=1e-16):
	""" Compute the average precision, given the recall and precision curves.
	Source: https://github.com/rafaelpadilla/Object-Detection-Metrics.
	# Arguments
	tp: True positives (nparray, nx1 or nx10).
	conf: Objectness value from 0-1 (nparray).
	pred_cls: Predicted object classes (nparray).
	target_cls: True object classes (nparray).
	plot: Plot precision-recall curve at [email protected]
	save_dir: Plot save directory
	# Returns
	The average precision as computed in py-faster-rcnn.
	"""

	# Sort by objectness
	i = np.argsort(-conf)
	tp, conf, pred_cls = tp[i], conf[i], pred_cls[i]

	# Find unique classes
	unique_classes, nt = np.unique(target_cls, return_counts=True)
	nc = unique_classes.shape[0] # number of classes, number of detections

	# Create Precision-Recall curve and compute AP for each class
	px, py = np.linspace(0, 1, 1000), [] # for plotting
	ap, p, r = np.zeros((nc, tp.shape[1])), np.zeros((nc, 1000)), np.zeros((nc, 1000))
	for ci, c in enumerate(unique_classes):
	i = pred_cls == c
	n_l = nt[ci] # number of labels
	n_p = i.sum() # number of predictions

	if n_p == 0 or n_l == 0:
	continue
	else:
	# Accumulate FPs and TPs
	fpc = (1 - tp[i]).cumsum(0)
	tpc = tp[i].cumsum(0)

	# Recall
	recall = tpc / (n_l + eps) # recall curve
	r[ci] = np.interp(-px, -conf[i], recall[:, 0], left=0) # negative x, xp because xp decreases

	# Precision
	precision = tpc / (tpc + fpc) # precision curve
	p[ci] = np.interp(-px, -conf[i], precision[:, 0], left=1) # p at pr_score

	# AP from recall-precision curve
	for j in range(tp.shape[1]):
	ap[ci, j], mpre, mrec = compute_ap(recall[:, j], precision[:, j])
	if plot and j == 0:
	py.append(np.interp(px, mrec, mpre)) # precision at [email protected]

	# Compute F1 (harmonic mean of precision and recall)
	f1 = 2 * p * r / (p + r + eps)
	names = [v for k, v in names.items() if k in unique_classes] # list: only classes that have data
	names = {i: v for i, v in enumerate(names)} # to dict
	if plot:
	plot_pr_curve(px, py, ap, Path(save_dir) / 'PR_curve.png', names)
	plot_mc_curve(px, f1, Path(save_dir) / 'F1_curve.png', names, ylabel='F1')
	plot_mc_curve(px, p, Path(save_dir) / 'P_curve.png', names, ylabel='Precision')
	plot_mc_curve(px, r, Path(save_dir) / 'R_curve.png', names, ylabel='Recall')

	i = f1.mean(0).argmax() # max F1 index
	p, r, f1 = p[:, i], r[:, i], f1[:, i]
	tp = (r * nt).round() # true positives
	fp = (tp / (p + eps) - tp).round() # false positives
	return tp, fp, p, r, f1, ap, unique_classes.astype('int32')


	def compute_ap(recall, precision):
	""" Compute the average precision, given the recall and precision curves
	# Arguments
	recall: The recall curve (list)
	precision: The precision curve (list)
	# Returns
	Average precision, precision curve, recall curve
	"""

	# Append sentinel values to beginning and end
	mrec = np.concatenate(([0.0], recall, [1.0]))
	mpre = np.concatenate(([1.0], precision, [0.0]))

	# Compute the precision envelope
	mpre = np.flip(np.maximum.accumulate(np.flip(mpre)))

	# Integrate area under curve
	method = 'interp' # methods: 'continuous', 'interp'
	if method == 'interp':
	x = np.linspace(0, 1, 101) # 101-point interp (COCO)
	ap = np.trapz(np.interp(x, mrec, mpre), x) # integrate
	else: # 'continuous'
	i = np.where(mrec[1:] != mrec[:-1])[0] # points where x axis (recall) changes
	ap = np.sum((mrec[i + 1] - mrec[i]) * mpre[i + 1]) # area under curve

	return ap, mpre, mrec


	class ConfusionMatrix:
	# Updated version of https://github.com/kaanakan/object_detection_confusion_matrix
	def __init__(self, nc, conf=0.25, iou_thres=0.45):
	self.matrix = np.zeros((nc + 1, nc + 1))
	self.nc = nc # number of classes
	self.conf = conf
	self.iou_thres = iou_thres

	def process_batch(self, detections, labels):
	"""
	Return intersection-over-union (Jaccard index) of boxes.
	Both sets of boxes are expected to be in (x1, y1, x2, y2) format.
	Arguments:
	detections (Array[N, 6]), x1, y1, x2, y2, conf, class
	labels (Array[M, 5]), class, x1, y1, x2, y2
	Returns:
	None, updates confusion matrix accordingly
	"""
	detections = detections[detections[:, 4] > self.conf]
	gt_classes = labels[:, 0].int()
	detection_classes = detections[:, 5].int()
	iou = box_iou(labels[:, 1:], detections[:, :4])

	x = torch.where(iou > self.iou_thres)
	if x[0].shape[0]:
	matches = torch.cat((torch.stack(x, 1), iou[x[0], x[1]][:, None]), 1).cpu().numpy()
	if x[0].shape[0] > 1:
	matches = matches[matches[:, 2].argsort()[::-1]]
	matches = matches[np.unique(matches[:, 1], return_index=True)[1]]
	matches = matches[matches[:, 2].argsort()[::-1]]
	matches = matches[np.unique(matches[:, 0], return_index=True)[1]]
	else:
	matches = np.zeros((0, 3))

	n = matches.shape[0] > 0
	m0, m1, _ = matches.transpose().astype(np.int16)
	for i, gc in enumerate(gt_classes):
	j = m0 == i
	if n and sum(j) == 1:
	self.matrix[detection_classes[m1[j]], gc] += 1 # correct
	else:
	self.matrix[self.nc, gc] += 1 # background FP

	if n:
	for i, dc in enumerate(detection_classes):
	if not any(m1 == i):
	self.matrix[dc, self.nc] += 1 # background FN

	def matrix(self):
	return self.matrix

	def tp_fp(self):
	tp = self.matrix.diagonal() # true positives
	fp = self.matrix.sum(1) - tp # false positives
	# fn = self.matrix.sum(0) - tp # false negatives (missed detections)
	return tp[:-1], fp[:-1] # remove background class

	def plot(self, normalize=True, save_dir='', names=()):
	pass

	def print(self):
	for i in range(self.nc + 1):
	print(' '.join(map(str, self.matrix[i])))


	def bbox_iou(box1, box2, x1y1x2y2=True, GIoU=False, DIoU=False, CIoU=False, eps=1e-7):
	# Returns the IoU of box1 to box2. box1 is 4, box2 is nx4
	box2 = box2.T

	# Get the coordinates of bounding boxes
	if x1y1x2y2: # x1, y1, x2, y2 = box1
	b1_x1, b1_y1, b1_x2, b1_y2 = box1[0], box1[1], box1[2], box1[3]
	b2_x1, b2_y1, b2_x2, b2_y2 = box2[0], box2[1], box2[2], box2[3]
	else: # transform from xywh to xyxy
	b1_x1, b1_x2 = box1[0] - box1[2] / 2, box1[0] + box1[2] / 2
	b1_y1, b1_y2 = box1[1] - box1[3] / 2, box1[1] + box1[3] / 2
	b2_x1, b2_x2 = box2[0] - box2[2] / 2, box2[0] + box2[2] / 2
	b2_y1, b2_y2 = box2[1] - box2[3] / 2, box2[1] + box2[3] / 2

	# Intersection area
	inter = (torch.min(b1_x2, b2_x2) - torch.max(b1_x1, b2_x1)).clamp(0) * \
	(torch.min(b1_y2, b2_y2) - torch.max(b1_y1, b2_y1)).clamp(0)

	# Union Area
	w1, h1 = b1_x2 - b1_x1, b1_y2 - b1_y1 + eps
	w2, h2 = b2_x2 - b2_x1, b2_y2 - b2_y1 + eps
	union = w1 * h1 + w2 * h2 - inter + eps

	iou = inter / union
	if CIoU or DIoU or GIoU:
	cw = torch.max(b1_x2, b2_x2) - torch.min(b1_x1, b2_x1) # convex (smallest enclosing box) width
	ch = torch.max(b1_y2, b2_y2) - torch.min(b1_y1, b2_y1) # convex height
	if CIoU or DIoU: # Distance or Complete IoU https://arxiv.org/abs/1911.08287v1
	c2 = cw 2 + ch 2 + eps # convex diagonal squared
	rho2 = ((b2_x1 + b2_x2 - b1_x1 - b1_x2) ** 2 +
	(b2_y1 + b2_y2 - b1_y1 - b1_y2) ** 2) / 4 # center distance squared
	if CIoU: # https://github.com/Zzh-tju/DIoU-SSD-pytorch/blob/master/utils/box/box_utils.py#L47
	v = (4 / math.pi ** 2) * torch.pow(torch.atan(w2 / h2) - torch.atan(w1 / h1), 2)
	with torch.no_grad():
	alpha = v / (v - iou + (1 + eps))
	return iou - (rho2 / c2 + v * alpha) # CIoU
	return iou - rho2 / c2 # DIoU
	c_area = cw * ch + eps # convex area
	return iou - (c_area - union) / c_area # GIoU https://arxiv.org/pdf/1902.09630.pdf
	return iou # IoU

	def box_iou(box1, box2):
	# https://github.com/pytorch/vision/blob/master/torchvision/ops/boxes.py
	"""
	Return intersection-over-union (Jaccard index) of boxes.
	Both sets of boxes are expected to be in (x1, y1, x2, y2) format.
	Arguments:
	box1 (Tensor[N, 4])
	box2 (Tensor[M, 4])
	Returns:
	iou (Tensor[N, M]): the NxM matrix containing the pairwise
	IoU values for every element in boxes1 and boxes2
	"""

	def box_area(box):
	# box = 4xn
	return (box[2] - box[0]) * (box[3] - box[1])

	area1 = box_area(box1.T)
	area2 = box_area(box2.T)

	# inter(N,M) = (rb(N,M,2) - lt(N,M,2)).clamp(0).prod(2)
	inter = (torch.min(box1[:, None, 2:], box2[:, 2:]) - torch.max(box1[:, None, :2], box2[:, :2])).clamp(0).prod(2)
	return inter / (area1[:, None] + area2 - inter) # iou = inter / (area1 + area2 - inter)


	def bbox_ioa(box1, box2, eps=1E-7):
	""" Returns the intersection over box2 area given box1, box2. Boxes are x1y1x2y2
	box1: np.array of shape(4)
	box2: np.array of shape(nx4)
	returns: np.array of shape(n)
	"""

	box2 = box2.transpose()

	# Get the coordinates of bounding boxes
	b1_x1, b1_y1, b1_x2, b1_y2 = box1[0], box1[1], box1[2], box1[3]
	b2_x1, b2_y1, b2_x2, b2_y2 = box2[0], box2[1], box2[2], box2[3]

	# Intersection area
	inter_area = (np.minimum(b1_x2, b2_x2) - np.maximum(b1_x1, b2_x1)).clip(0) * \
	(np.minimum(b1_y2, b2_y2) - np.maximum(b1_y1, b2_y1)).clip(0)

	# box2 area
	box2_area = (b2_x2 - b2_x1) * (b2_y2 - b2_y1) + eps

	# Intersection over box2 area
	return inter_area / box2_area


	def wh_iou(wh1, wh2):
	# Returns the nxm IoU matrix. wh1 is nx2, wh2 is mx2
	wh1 = wh1[:, None] # [N,1,2]
	wh2 = wh2[None] # [1,M,2]
	inter = torch.min(wh1, wh2).prod(2) # [N,M]
	return inter / (wh1.prod(2) + wh2.prod(2) - inter) # iou = inter / (area1 + area2 - inter)


	# Plots ----------------------------------------------------------------------------------------------------------------

	def plot_pr_curve(px, py, ap, save_dir='pr_curve.png', names=()):
	pass

	def plot_mc_curve(px, py, save_dir='mc_curve.png', names=(), xlabel='Confidence', ylabel='Metric'):
	pass