Exemple #1
0
class ToTensor(object):
    def __init__(self):
        self.timer = Timer()

    def call_single_view(self, image, target):
        return F.to_tensor(image), target

    def call_double_view(self, image, target):
        self.timer.tic()
        left_image, right_image = image['left'], image['right']
        left_target, right_target = target['left'], target['right']
        left_image = F.to_tensor(left_image)
        right_image = F.to_tensor(right_image)
        image = {'left': left_image, 'right': right_image}
        target = {'left': left_target, 'right': right_target}
        self.timer.toc()
        if PRINT_TIME:
            print('totensor', self.timer.average_time)
        return image, target

    def __call__(self, image, target):
        if isinstance(image, dict) and isinstance(target, dict):
            return self.call_double_view(image, target)
        else:
            return self.call_single_view(image, target)
Exemple #2
0
class Normalize(object):
    def __init__(self, mean, std, to_bgr255=True):
        self.mean = mean
        self.std = std
        self.to_bgr255 = to_bgr255
        self.timer = Timer()

    def call_single_view(self, image, target):
        # if self.to_bgr255:
        #     image = image[[2, 1, 0]] * 255
        image = F.normalize(image, mean=self.mean, std=self.std)
        return image, target

    def call_double_view(self, image, target):
        self.timer.tic()
        left_image, right_image = image['left'], image['right']
        left_target, right_target = target['left'], target['right']
        if self.to_bgr255:
            left_image = left_image[[2, 1, 0]] * 255
            right_image = right_image[[2, 1, 0]] * 255
        # left_image -= self.mean
        # right_image -= self.mean
        left_image = F.normalize(left_image, mean=self.mean, std=self.std)
        right_image = F.normalize(right_image, mean=self.mean, std=self.std)
        image = {'left': left_image, 'right': right_image}
        target = {'left': left_target, 'right': right_target}
        self.timer.toc()
        if PRINT_TIME:
            print('normalize', self.timer.average_time)
        return image, target

    def __call__(self, image, target):
        if isinstance(image, dict) and isinstance(target, dict):
            return self.call_double_view(image, target)
        else:
            return self.call_single_view(image, target)
Exemple #3
0
class Resize(object):
    def __init__(self, min_size, max_size):
        if not isinstance(min_size, (list, tuple)):
            min_size = (min_size, )
        self.min_size = min_size
        self.max_size = max_size
        self.getsizetimer = Timer()
        self.imgtimer = Timer()
        self.tgttimer = Timer()
        # self.timer = Timer()

    # modified from torchvision to add support for max size
    def get_size(self, image_size):
        w, h = image_size
        size = random.choice(self.min_size)
        max_size = self.max_size
        if max_size is not None:
            min_original_size = float(min((w, h)))
            max_original_size = float(max((w, h)))
            if max_original_size / min_original_size * size > max_size:
                size = int(
                    round(max_size * min_original_size / max_original_size))

        if (w <= h and w == size) or (h <= w and h == size):
            return (h, w)

        if w < h:
            ow = size
            oh = int(size * h / w)
        else:
            oh = size
            ow = int(size * w / h)

        return (oh, ow)

    def call_single_view(self, image, target):
        # h, w = self.get_size(image.shape[:-1][::-1])
        # image = cv2.resize(image, None, None, fx=h / image.shape[0],
        #                    fy=h / image.shape[0], interpolation=cv2.INTER_LINEAR)
        self.getsizetimer.tic()
        h, w = self.get_size(image.size)
        self.getsizetimer.toc()
        if PRINT_TIME:
            print('getsize', self.getsizetimer.average_time)
        self.imgtimer.tic()
        image = image.resize((w, h))
        self.imgtimer.toc()
        if PRINT_TIME:
            print('img resize', self.imgtimer.average_time)
        self.tgttimer.tic()
        target = target.resize(image.size)
        self.tgttimer.toc()
        if PRINT_TIME:
            print('tgt resize', self.tgttimer.average_time)
        return image, target

    def call_double_view(self, image, target):
        # self.timer.tic()
        left_image, right_image = image['left'], image['right']
        left_target, right_target = target['left'], target['right']
        left_image, left_target = self.call_single_view(
            left_image, left_target)
        right_image, right_target = self.call_single_view(
            right_image, right_target)
        image = {'left': left_image, 'right': right_image}
        target = {'left': left_target, 'right': right_target}
        # self.timer.toc()
        # print('resize', self.timer.average_time)
        return image, target

    def __call__(self, image, target):
        if isinstance(image, dict) and isinstance(target, dict):
            return self.call_double_view(image, target)
        else:
            return self.call_single_view(image, target)