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import os
import random
from collections import Counter
import matplotlib.patches as patches
import matplotlib.pyplot as plt
import numpy as np
import torch
from tqdm import tqdm
from . import config
def iou_width_height(boxes1, boxes2):
"""
Parameters:
boxes1 (tensor): width and height of the first bounding boxes
boxes2 (tensor): width and height of the second bounding boxes
Returns:
tensor: Intersection over union of the corresponding boxes
"""
intersection = torch.min(boxes1[..., 0], boxes2[..., 0]) * torch.min(
boxes1[..., 1], boxes2[..., 1]
)
union = (
boxes1[..., 0] * boxes1[..., 1] + boxes2[..., 0] * boxes2[..., 1] - intersection
)
return intersection / union
def intersection_over_union(boxes_preds, boxes_labels, box_format="midpoint"):
"""
Video explanation of this function:
https://youtu.be/XXYG5ZWtjj0
This function calculates intersection over union (iou) given pred boxes
and target boxes.
Parameters:
boxes_preds (tensor): Predictions of Bounding Boxes (BATCH_SIZE, 4)
boxes_labels (tensor): Correct labels of Bounding Boxes (BATCH_SIZE, 4)
box_format (str): midpoint/corners, if boxes (x,y,w,h) or (x1,y1,x2,y2)
Returns:
tensor: Intersection over union for all examples
"""
if box_format == "midpoint":
box1_x1 = boxes_preds[..., 0:1] - boxes_preds[..., 2:3] / 2
box1_y1 = boxes_preds[..., 1:2] - boxes_preds[..., 3:4] / 2
box1_x2 = boxes_preds[..., 0:1] + boxes_preds[..., 2:3] / 2
box1_y2 = boxes_preds[..., 1:2] + boxes_preds[..., 3:4] / 2
box2_x1 = boxes_labels[..., 0:1] - boxes_labels[..., 2:3] / 2
box2_y1 = boxes_labels[..., 1:2] - boxes_labels[..., 3:4] / 2
box2_x2 = boxes_labels[..., 0:1] + boxes_labels[..., 2:3] / 2
box2_y2 = boxes_labels[..., 1:2] + boxes_labels[..., 3:4] / 2
if box_format == "corners":
box1_x1 = boxes_preds[..., 0:1]
box1_y1 = boxes_preds[..., 1:2]
box1_x2 = boxes_preds[..., 2:3]
box1_y2 = boxes_preds[..., 3:4]
box2_x1 = boxes_labels[..., 0:1]
box2_y1 = boxes_labels[..., 1:2]
box2_x2 = boxes_labels[..., 2:3]
box2_y2 = boxes_labels[..., 3:4]
x1 = torch.max(box1_x1, box2_x1)
y1 = torch.max(box1_y1, box2_y1)
x2 = torch.min(box1_x2, box2_x2)
y2 = torch.min(box1_y2, box2_y2)
intersection = (x2 - x1).clamp(0) * (y2 - y1).clamp(0)
box1_area = abs((box1_x2 - box1_x1) * (box1_y2 - box1_y1))
box2_area = abs((box2_x2 - box2_x1) * (box2_y2 - box2_y1))
return intersection / (box1_area + box2_area - intersection + 1e-6)
def non_max_suppression(bboxes, iou_threshold, threshold, box_format="corners"):
"""
Video explanation of this function:
https://youtu.be/YDkjWEN8jNA
Does Non Max Suppression given bboxes
Parameters:
bboxes (list): list of lists containing all bboxes with each bboxes
specified as [class_pred, prob_score, x1, y1, x2, y2]
iou_threshold (float): threshold where predicted bboxes is correct
threshold (float): threshold to remove predicted bboxes (independent of IoU)
box_format (str): "midpoint" or "corners" used to specify bboxes
Returns:
list: bboxes after performing NMS given a specific IoU threshold
"""
assert type(bboxes) == list
bboxes = [box for box in bboxes if box[1] > threshold]
bboxes = sorted(bboxes, key=lambda x: x[1], reverse=True)
bboxes_after_nms = []
while bboxes:
chosen_box = bboxes.pop(0)
bboxes = [
box
for box in bboxes
if box[0] != chosen_box[0]
or intersection_over_union(
torch.tensor(chosen_box[2:]),
torch.tensor(box[2:]),
box_format=box_format,
)
< iou_threshold
]
bboxes_after_nms.append(chosen_box)
return bboxes_after_nms
def mean_average_precision(
pred_boxes, true_boxes, iou_threshold=0.5, box_format="midpoint", num_classes=20
):
"""
Video explanation of this function:
https://youtu.be/FppOzcDvaDI
This function calculates mean average precision (mAP)
Parameters:
pred_boxes (list): list of lists containing all bboxes with each bboxes
specified as [train_idx, class_prediction, prob_score, x1, y1, x2, y2]
true_boxes (list): Similar as pred_boxes except all the correct ones
iou_threshold (float): threshold where predicted bboxes is correct
box_format (str): "midpoint" or "corners" used to specify bboxes
num_classes (int): number of classes
Returns:
float: mAP value across all classes given a specific IoU threshold
"""
# list storing all AP for respective classes
average_precisions = []
# used for numerical stability later on
epsilon = 1e-6
for c in range(num_classes):
detections = []
ground_truths = []
# Go through all predictions and targets,
# and only add the ones that belong to the
# current class c
for detection in pred_boxes:
if detection[1] == c:
detections.append(detection)
for true_box in true_boxes:
if true_box[1] == c:
ground_truths.append(true_box)
# find the amount of bboxes for each training example
# Counter here finds how many ground truth bboxes we get
# for each training example, so let's say img 0 has 3,
# img 1 has 5 then we will obtain a dictionary with:
# amount_bboxes = {0:3, 1:5}
amount_bboxes = Counter([gt[0] for gt in ground_truths])
# We then go through each key, val in this dictionary
# and convert to the following (w.r.t same example):
# ammount_bboxes = {0:torch.tensor[0,0,0], 1:torch.tensor[0,0,0,0,0]}
for key, val in amount_bboxes.items():
amount_bboxes[key] = torch.zeros(val)
# sort by box probabilities which is index 2
detections.sort(key=lambda x: x[2], reverse=True)
TP = torch.zeros((len(detections)))
FP = torch.zeros((len(detections)))
total_true_bboxes = len(ground_truths)
# If none exists for this class then we can safely skip
if total_true_bboxes == 0:
continue
for detection_idx, detection in enumerate(detections):
# Only take out the ground_truths that have the same
# training idx as detection
ground_truth_img = [
bbox for bbox in ground_truths if bbox[0] == detection[0]
]
num_gts = len(ground_truth_img)
best_iou = 0
for idx, gt in enumerate(ground_truth_img):
iou = intersection_over_union(
torch.tensor(detection[3:]),
torch.tensor(gt[3:]),
box_format=box_format,
)
if iou > best_iou:
best_iou = iou
best_gt_idx = idx
if best_iou > iou_threshold:
# only detect ground truth detection once
if amount_bboxes[detection[0]][best_gt_idx] == 0:
# true positive and add this bounding box to seen
TP[detection_idx] = 1
amount_bboxes[detection[0]][best_gt_idx] = 1
else:
FP[detection_idx] = 1
# if IOU is lower then the detection is a false positive
else:
FP[detection_idx] = 1
TP_cumsum = torch.cumsum(TP, dim=0)
FP_cumsum = torch.cumsum(FP, dim=0)
recalls = TP_cumsum / (total_true_bboxes + epsilon)
precisions = TP_cumsum / (TP_cumsum + FP_cumsum + epsilon)
precisions = torch.cat((torch.tensor([1]), precisions))
recalls = torch.cat((torch.tensor([0]), recalls))
# torch.trapz for numerical integration
average_precisions.append(torch.trapz(precisions, recalls))
return sum(average_precisions) / len(average_precisions)
def plot_image(image, boxes):
"""Plots predicted bounding boxes on the image"""
cmap = plt.get_cmap("tab20b")
class_labels = (
config.COCO_LABELS if config.DATASET == "COCO" else config.PASCAL_CLASSES
)
colors = [cmap(i) for i in np.linspace(0, 1, len(class_labels))]
im = np.array(image)
height, width, _ = im.shape
# Create figure and axes
fig, ax = plt.subplots(1)
# Display the image
ax.imshow(im)
# box[0] is x midpoint, box[2] is width
# box[1] is y midpoint, box[3] is height
# Create a Rectangle patch
for box in boxes:
assert (
len(box) == 6
), "box should contain class pred, confidence, x, y, width, height"
class_pred = box[0]
box = box[2:]
upper_left_x = box[0] - box[2] / 2
upper_left_y = box[1] - box[3] / 2
rect = patches.Rectangle(
(upper_left_x * width, upper_left_y * height),
box[2] * width,
box[3] * height,
linewidth=2,
edgecolor=colors[int(class_pred)],
facecolor="none",
)
# Add the patch to the Axes
ax.add_patch(rect)
plt.text(
upper_left_x * width,
upper_left_y * height,
s=class_labels[int(class_pred)],
color="white",
verticalalignment="top",
bbox={"color": colors[int(class_pred)], "pad": 0},
)
return fig
# plt.show()
def get_evaluation_bboxes(
loader,
model,
iou_threshold,
anchors,
threshold,
box_format="midpoint",
device="cuda",
):
# make sure model is in eval before get bboxes
model.eval()
train_idx = 0
all_pred_boxes = []
all_true_boxes = []
for batch_idx, (x, labels) in enumerate(tqdm(loader)):
x = x.to(device)
with torch.no_grad():
predictions = model(x)
batch_size = x.shape[0]
bboxes = [[] for _ in range(batch_size)]
for i in range(3):
S = predictions[i].shape[2]
anchor = torch.tensor([*anchors[i]]).to(device) * S
boxes_scale_i = cells_to_bboxes(predictions[i], anchor, S=S, is_preds=True)
for idx, (box) in enumerate(boxes_scale_i):
bboxes[idx] += box
# we just want one bbox for each label, not one for each scale
true_bboxes = cells_to_bboxes(labels[2], anchor, S=S, is_preds=False)
for idx in range(batch_size):
nms_boxes = non_max_suppression(
bboxes[idx],
iou_threshold=iou_threshold,
threshold=threshold,
box_format=box_format,
)
for nms_box in nms_boxes:
all_pred_boxes.append([train_idx] + nms_box)
for box in true_bboxes[idx]:
if box[1] > threshold:
all_true_boxes.append([train_idx] + box)
train_idx += 1
model.train()
return all_pred_boxes, all_true_boxes
def cells_to_bboxes(predictions, anchors, S, is_preds=True):
"""
Scales the predictions coming from the model to
be relative to the entire image such that they for example later
can be plotted or.
INPUT:
predictions: tensor of size (N, 3, S, S, num_classes+5)
anchors: the anchors used for the predictions
S: the number of cells the image is divided in on the width (and height)
is_preds: whether the input is predictions or the true bounding boxes
OUTPUT:
converted_bboxes: the converted boxes of sizes (N, num_anchors, S, S, 1+5) with class index,
object score, bounding box coordinates
"""
BATCH_SIZE = predictions.shape[0]
num_anchors = len(anchors)
box_predictions = predictions[..., 1:5]
if is_preds:
anchors = anchors.reshape(1, len(anchors), 1, 1, 2)
box_predictions[..., 0:2] = torch.sigmoid(box_predictions[..., 0:2])
box_predictions[..., 2:] = torch.exp(box_predictions[..., 2:]) * anchors
scores = torch.sigmoid(predictions[..., 0:1])
best_class = torch.argmax(predictions[..., 5:], dim=-1).unsqueeze(-1)
else:
scores = predictions[..., 0:1]
best_class = predictions[..., 5:6]
cell_indices = (
torch.arange(S)
.repeat(predictions.shape[0], 3, S, 1)
.unsqueeze(-1)
.to(predictions.device)
)
x = 1 / S * (box_predictions[..., 0:1] + cell_indices)
y = 1 / S * (box_predictions[..., 1:2] + cell_indices.permute(0, 1, 3, 2, 4))
w_h = 1 / S * box_predictions[..., 2:4]
converted_bboxes = torch.cat((best_class, scores, x, y, w_h), dim=-1).reshape(
BATCH_SIZE, num_anchors * S * S, 6
)
return converted_bboxes.tolist()
def check_class_accuracy(model, loader, threshold):
model.eval()
tot_class_preds, correct_class = 0, 0
tot_noobj, correct_noobj = 0, 0
tot_obj, correct_obj = 0, 0
for idx, (x, y) in enumerate(tqdm(loader)):
x = x.to(config.DEVICE)
with torch.no_grad():
out = model(x)
for i in range(3):
y[i] = y[i].to(config.DEVICE)
obj = y[i][..., 0] == 1 # in paper this is Iobj_i
noobj = y[i][..., 0] == 0 # in paper this is Iobj_i
correct_class += torch.sum(
torch.argmax(out[i][..., 5:][obj], dim=-1) == y[i][..., 5][obj]
)
tot_class_preds += torch.sum(obj)
obj_preds = torch.sigmoid(out[i][..., 0]) > threshold
correct_obj += torch.sum(obj_preds[obj] == y[i][..., 0][obj])
tot_obj += torch.sum(obj)
correct_noobj += torch.sum(obj_preds[noobj] == y[i][..., 0][noobj])
tot_noobj += torch.sum(noobj)
class_acc = (correct_class / (tot_class_preds + 1e-16)) * 100
no_obj_acc = (correct_noobj / (tot_noobj + 1e-16)) * 100
obj_acc = (correct_obj / (tot_obj + 1e-16)) * 100
print(f"Class accuracy is: {class_acc:2f}%")
print(f"No obj accuracy is: {no_obj_acc:2f}%")
print(f"Obj accuracy is: {obj_acc:2f}%")
model.train()
return class_acc, no_obj_acc, obj_acc
def get_mean_std(loader):
# var[X] = E[X**2] - E[X]**2
channels_sum, channels_sqrd_sum, num_batches = 0, 0, 0
for data, _ in tqdm(loader):
channels_sum += torch.mean(data, dim=[0, 2, 3])
channels_sqrd_sum += torch.mean(data**2, dim=[0, 2, 3])
num_batches += 1
mean = channels_sum / num_batches
std = (channels_sqrd_sum / num_batches - mean**2) ** 0.5
return mean, std
def save_checkpoint(model, optimizer, filename="my_checkpoint.pth.tar"):
print("=> Saving checkpoint")
checkpoint = {
"state_dict": model.state_dict(),
"optimizer": optimizer.state_dict(),
}
torch.save(checkpoint, filename)
def load_checkpoint(checkpoint_file, model, optimizer, lr):
print("=> Loading checkpoint")
checkpoint = torch.load(checkpoint_file, map_location=config.DEVICE)
model.load_state_dict(checkpoint["state_dict"])
optimizer.load_state_dict(checkpoint["optimizer"])
# If we don't do this then it will just have learning rate of old checkpoint
# and it will lead to many hours of debugging \:
for param_group in optimizer.param_groups:
param_group["lr"] = lr
def plot_couple_examples(model, loader, thresh, iou_thresh, anchors):
model.eval()
x, y = next(iter(loader))
x = x.to(config.DEVICE)
with torch.no_grad():
out = model(x)
bboxes = [[] for _ in range(x.shape[0])]
for i in range(3): # should not be hard coded
batch_size, A, S, _, _ = out[i].shape
anchor = anchors[i]
boxes_scale_i = cells_to_bboxes(out[i], anchor, S=S, is_preds=True)
for idx, (box) in enumerate(boxes_scale_i):
bboxes[idx] += box
model.train() #correct indetation?
for i in range(batch_size // 4):
nms_boxes = non_max_suppression(
bboxes[i],
iou_threshold=iou_thresh,
threshold=thresh,
box_format="midpoint",
)
plot_image(x[i].permute(1, 2, 0).detach().cpu(), nms_boxes)
def seed_everything(seed=42):
os.environ["PYTHONHASHSEED"] = str(seed)
random.seed(seed)
np.random.seed(seed)
torch.manual_seed(seed)
torch.cuda.manual_seed(seed)
torch.cuda.manual_seed_all(seed)
torch.backends.cudnn.deterministic = True
torch.backends.cudnn.benchmark = False
def clip_coords(boxes, img_shape):
# Clip bounding xyxy bounding boxes to image shape (height, width)
boxes[:, 0].clamp_(0, img_shape[1]) # x1
boxes[:, 1].clamp_(0, img_shape[0]) # y1
boxes[:, 2].clamp_(0, img_shape[1]) # x2
boxes[:, 3].clamp_(0, img_shape[0]) # y2
def xywhn2xyxy(x, w=640, h=640, padw=0, padh=0):
# Convert nx4 boxes from [x, y, w, h] normalized to [x1, y1, x2, y2] where xy1=top-left, xy2=bottom-right
y = x.clone() if isinstance(x, torch.Tensor) else np.copy(x)
y[..., 0] = w * (x[..., 0] - x[..., 2] / 2) + padw # top left x
y[..., 1] = h * (x[..., 1] - x[..., 3] / 2) + padh # top left y
y[..., 2] = w * (x[..., 0] + x[..., 2] / 2) + padw # bottom right x
y[..., 3] = h * (x[..., 1] + x[..., 3] / 2) + padh # bottom right y
return y
def xyn2xy(x, w=640, h=640, padw=0, padh=0):
# Convert normalized segments into pixel segments, shape (n,2)
y = x.clone() if isinstance(x, torch.Tensor) else np.copy(x)
y[..., 0] = w * x[..., 0] + padw # top left x
y[..., 1] = h * x[..., 1] + padh # top left y
return y
def xyxy2xywhn(x, w=640, h=640, clip=False, eps=0.0):
# Convert nx4 boxes from [x1, y1, x2, y2] to [x, y, w, h] normalized where xy1=top-left, xy2=bottom-right
if clip:
clip_boxes(x, (h - eps, w - eps)) # warning: inplace clip
y = x.clone() if isinstance(x, torch.Tensor) else np.copy(x)
y[..., 0] = ((x[..., 0] + x[..., 2]) / 2) / w # x center
y[..., 1] = ((x[..., 1] + x[..., 3]) / 2) / h # y center
y[..., 2] = (x[..., 2] - x[..., 0]) / w # width
y[..., 3] = (x[..., 3] - x[..., 1]) / h # height
return y
def clip_boxes(boxes, shape):
# Clip boxes (xyxy) to image shape (height, width)
if isinstance(boxes, torch.Tensor): # faster individually
boxes[..., 0].clamp_(0, shape[1]) # x1
boxes[..., 1].clamp_(0, shape[0]) # y1
boxes[..., 2].clamp_(0, shape[1]) # x2
boxes[..., 3].clamp_(0, shape[0]) # y2
else: # np.array (faster grouped)
boxes[..., [0, 2]] = boxes[..., [0, 2]].clip(0, shape[1]) # x1, x2
boxes[..., [1, 3]] = boxes[..., [1, 3]].clip(0, shape[0]) # y1, y2 |