PaddleDetection-release-2.6/deploy/python/preprocess.py

# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
#     http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.

import cv2
import numpy as np
from keypoint_preprocess import get_affine_transform
from PIL import Image


def decode_image(im_file, im_info):
    """read rgb image
    Args:
        im_file (str|np.ndarray): input can be image path or np.ndarray
        im_info (dict): info of image
    Returns:
        im (np.ndarray):  processed image (np.ndarray)
        im_info (dict): info of processed image
    """
    if isinstance(im_file, str):
        with open(im_file, 'rb') as f:
            im_read = f.read()
        data = np.frombuffer(im_read, dtype='uint8')
        im = cv2.imdecode(data, 1)  # BGR mode, but need RGB mode
        im = cv2.cvtColor(im, cv2.COLOR_BGR2RGB)
    else:
        im = im_file
    im_info['im_shape'] = np.array(im.shape[:2], dtype=np.float32)
    im_info['scale_factor'] = np.array([1., 1.], dtype=np.float32)
    return im, im_info


class Resize_Mult32(object):
    """resize image by target_size and max_size
    Args:
        target_size (int): the target size of image
        keep_ratio (bool): whether keep_ratio or not, default true
        interp (int): method of resize
    """

    def __init__(self, limit_side_len, limit_type, interp=cv2.INTER_LINEAR):
        self.limit_side_len = limit_side_len
        self.limit_type = limit_type
        self.interp = interp

    def __call__(self, im, im_info):
        """
        Args:
            im (np.ndarray): image (np.ndarray)
            im_info (dict): info of image
        Returns:
            im (np.ndarray):  processed image (np.ndarray)
            im_info (dict): info of processed image
        """
        im_channel = im.shape[2]
        im_scale_y, im_scale_x = self.generate_scale(im)
        im = cv2.resize(
            im,
            None,
            None,
            fx=im_scale_x,
            fy=im_scale_y,
            interpolation=self.interp)
        im_info['im_shape'] = np.array(im.shape[:2]).astype('float32')
        im_info['scale_factor'] = np.array(
            [im_scale_y, im_scale_x]).astype('float32')
        return im, im_info

    def generate_scale(self, img):
        """
        Args:
            img (np.ndarray): image (np.ndarray)
        Returns:
            im_scale_x: the resize ratio of X
            im_scale_y: the resize ratio of Y
        """
        limit_side_len = self.limit_side_len
        h, w, c = img.shape

        # limit the max side
        if self.limit_type == 'max':
            if h > w:
                ratio = float(limit_side_len) / h
            else:
                ratio = float(limit_side_len) / w
        elif self.limit_type == 'min':
            if h < w:
                ratio = float(limit_side_len) / h
            else:
                ratio = float(limit_side_len) / w
        elif self.limit_type == 'resize_long':
            ratio = float(limit_side_len) / max(h, w)
        else:
            raise Exception('not support limit type, image ')
        resize_h = int(h * ratio)
        resize_w = int(w * ratio)

        resize_h = max(int(round(resize_h / 32) * 32), 32)
        resize_w = max(int(round(resize_w / 32) * 32), 32)

        im_scale_y = resize_h / float(h)
        im_scale_x = resize_w / float(w)
        return im_scale_y, im_scale_x


class Resize(object):
    """resize image by target_size and max_size
    Args:
        target_size (int): the target size of image
        keep_ratio (bool): whether keep_ratio or not, default true
        interp (int): method of resize
    """

    def __init__(self, target_size, keep_ratio=True, interp=cv2.INTER_LINEAR):
        if isinstance(target_size, int):
            target_size = [target_size, target_size]
        self.target_size = target_size
        self.keep_ratio = keep_ratio
        self.interp = interp

    def __call__(self, im, im_info):
        """
        Args:
            im (np.ndarray): image (np.ndarray)
            im_info (dict): info of image
        Returns:
            im (np.ndarray):  processed image (np.ndarray)
            im_info (dict): info of processed image
        """
        assert len(self.target_size) == 2
        assert self.target_size[0] > 0 and self.target_size[1] > 0
        im_channel = im.shape[2]
        im_scale_y, im_scale_x = self.generate_scale(im)
        im = cv2.resize(
            im,
            None,
            None,
            fx=im_scale_x,
            fy=im_scale_y,
            interpolation=self.interp)
        im_info['im_shape'] = np.array(im.shape[:2]).astype('float32')
        im_info['scale_factor'] = np.array(
            [im_scale_y, im_scale_x]).astype('float32')
        return im, im_info

    def generate_scale(self, im):
        """
        Args:
            im (np.ndarray): image (np.ndarray)
        Returns:
            im_scale_x: the resize ratio of X
            im_scale_y: the resize ratio of Y
        """
        origin_shape = im.shape[:2]
        im_c = im.shape[2]
        if self.keep_ratio:
            im_size_min = np.min(origin_shape)
            im_size_max = np.max(origin_shape)
            target_size_min = np.min(self.target_size)
            target_size_max = np.max(self.target_size)
            im_scale = float(target_size_min) / float(im_size_min)
            if np.round(im_scale * im_size_max) > target_size_max:
                im_scale = float(target_size_max) / float(im_size_max)
            im_scale_x = im_scale
            im_scale_y = im_scale
        else:
            resize_h, resize_w = self.target_size
            im_scale_y = resize_h / float(origin_shape[0])
            im_scale_x = resize_w / float(origin_shape[1])
        return im_scale_y, im_scale_x


class ShortSizeScale(object):
    """
    Scale images by short size.
    Args:
        short_size(float | int): Short size of an image will be scaled to the short_size.
        fixed_ratio(bool): Set whether to zoom according to a fixed ratio. default: True
        do_round(bool): Whether to round up when calculating the zoom ratio. default: False
        backend(str): Choose pillow or cv2 as the graphics processing backend. default: 'pillow'
    """

    def __init__(self,
                 short_size,
                 fixed_ratio=True,
                 keep_ratio=None,
                 do_round=False,
                 backend='pillow'):
        self.short_size = short_size
        assert (fixed_ratio and not keep_ratio) or (
            not fixed_ratio
        ), "fixed_ratio and keep_ratio cannot be true at the same time"
        self.fixed_ratio = fixed_ratio
        self.keep_ratio = keep_ratio
        self.do_round = do_round

        assert backend in [
            'pillow', 'cv2'
        ], "Scale's backend must be pillow or cv2, but get {backend}"

        self.backend = backend

    def __call__(self, img):
        """
        Performs resize operations.
        Args:
            img (PIL.Image): a PIL.Image.
        return:
            resized_img: a PIL.Image after scaling.
        """

        result_img = None

        if isinstance(img, np.ndarray):
            h, w, _ = img.shape
        elif isinstance(img, Image.Image):
            w, h = img.size
        else:
            raise NotImplementedError

        if w <= h:
            ow = self.short_size
            if self.fixed_ratio:  # default is True
                oh = int(self.short_size * 4.0 / 3.0)
            elif not self.keep_ratio:  # no
                oh = self.short_size
            else:
                scale_factor = self.short_size / w
                oh = int(h * float(scale_factor) +
                         0.5) if self.do_round else int(h * self.short_size / w)
                ow = int(w * float(scale_factor) +
                         0.5) if self.do_round else int(w * self.short_size / h)
        else:
            oh = self.short_size
            if self.fixed_ratio:
                ow = int(self.short_size * 4.0 / 3.0)
            elif not self.keep_ratio:  # no
                ow = self.short_size
            else:
                scale_factor = self.short_size / h
                oh = int(h * float(scale_factor) +
                         0.5) if self.do_round else int(h * self.short_size / w)
                ow = int(w * float(scale_factor) +
                         0.5) if self.do_round else int(w * self.short_size / h)

        if type(img) == np.ndarray:
            img = Image.fromarray(img, mode='RGB')

        if self.backend == 'pillow':
            result_img = img.resize((ow, oh), Image.BILINEAR)
        elif self.backend == 'cv2' and (self.keep_ratio is not None):
            result_img = cv2.resize(
                img, (ow, oh), interpolation=cv2.INTER_LINEAR)
        else:
            result_img = Image.fromarray(
                cv2.resize(
                    np.asarray(img), (ow, oh), interpolation=cv2.INTER_LINEAR))

        return result_img


class NormalizeImage(object):
    """normalize image
    Args:
        mean (list): im - mean
        std (list): im / std
        is_scale (bool): whether need im / 255
        norm_type (str): type in ['mean_std', 'none']
    """

    def __init__(self, mean, std, is_scale=True, norm_type='mean_std'):
        self.mean = mean
        self.std = std
        self.is_scale = is_scale
        self.norm_type = norm_type

    def __call__(self, im, im_info):
        """
        Args:
            im (np.ndarray): image (np.ndarray)
            im_info (dict): info of image
        Returns:
            im (np.ndarray):  processed image (np.ndarray)
            im_info (dict): info of processed image
        """
        im = im.astype(np.float32, copy=False)
        if self.is_scale:
            scale = 1.0 / 255.0
            im *= scale

        if self.norm_type == 'mean_std':
            mean = np.array(self.mean)[np.newaxis, np.newaxis, :]
            std = np.array(self.std)[np.newaxis, np.newaxis, :]
            im -= mean
            im /= std
        return im, im_info


class Permute(object):
    """permute image
    Args:
        to_bgr (bool): whether convert RGB to BGR 
        channel_first (bool): whether convert HWC to CHW
    """

    def __init__(self, ):
        super(Permute, self).__init__()

    def __call__(self, im, im_info):
        """
        Args:
            im (np.ndarray): image (np.ndarray)
            im_info (dict): info of image
        Returns:
            im (np.ndarray):  processed image (np.ndarray)
            im_info (dict): info of processed image
        """
        im = im.transpose((2, 0, 1)).copy()
        return im, im_info


class PadStride(object):
    """ padding image for model with FPN, instead PadBatch(pad_to_stride) in original config
    Args:
        stride (bool): model with FPN need image shape % stride == 0
    """

    def __init__(self, stride=0):
        self.coarsest_stride = stride

    def __call__(self, im, im_info):
        """
        Args:
            im (np.ndarray): image (np.ndarray)
            im_info (dict): info of image
        Returns:
            im (np.ndarray):  processed image (np.ndarray)
            im_info (dict): info of processed image
        """
        coarsest_stride = self.coarsest_stride
        if coarsest_stride <= 0:
            return im, im_info
        im_c, im_h, im_w = im.shape
        pad_h = int(np.ceil(float(im_h) / coarsest_stride) * coarsest_stride)
        pad_w = int(np.ceil(float(im_w) / coarsest_stride) * coarsest_stride)
        padding_im = np.zeros((im_c, pad_h, pad_w), dtype=np.float32)
        padding_im[:, :im_h, :im_w] = im
        return padding_im, im_info


class LetterBoxResize(object):
    def __init__(self, target_size):
        """
        Resize image to target size, convert normalized xywh to pixel xyxy
        format ([x_center, y_center, width, height] -> [x0, y0, x1, y1]).
        Args:
            target_size (int|list): image target size.
        """
        super(LetterBoxResize, self).__init__()
        if isinstance(target_size, int):
            target_size = [target_size, target_size]
        self.target_size = target_size

    def letterbox(self, img, height, width, color=(127.5, 127.5, 127.5)):
        # letterbox: resize a rectangular image to a padded rectangular
        shape = img.shape[:2]  # [height, width]
        ratio_h = float(height) / shape[0]
        ratio_w = float(width) / shape[1]
        ratio = min(ratio_h, ratio_w)
        new_shape = (round(shape[1] * ratio),
                     round(shape[0] * ratio))  # [width, height]
        padw = (width - new_shape[0]) / 2
        padh = (height - new_shape[1]) / 2
        top, bottom = round(padh - 0.1), round(padh + 0.1)
        left, right = round(padw - 0.1), round(padw + 0.1)

        img = cv2.resize(
            img, new_shape, interpolation=cv2.INTER_AREA)  # resized, no border
        img = cv2.copyMakeBorder(
            img, top, bottom, left, right, cv2.BORDER_CONSTANT,
            value=color)  # padded rectangular
        return img, ratio, padw, padh

    def __call__(self, im, im_info):
        """
        Args:
            im (np.ndarray): image (np.ndarray)
            im_info (dict): info of image
        Returns:
            im (np.ndarray):  processed image (np.ndarray)
            im_info (dict): info of processed image
        """
        assert len(self.target_size) == 2
        assert self.target_size[0] > 0 and self.target_size[1] > 0
        height, width = self.target_size
        h, w = im.shape[:2]
        im, ratio, padw, padh = self.letterbox(im, height=height, width=width)

        new_shape = [round(h * ratio), round(w * ratio)]
        im_info['im_shape'] = np.array(new_shape, dtype=np.float32)
        im_info['scale_factor'] = np.array([ratio, ratio], dtype=np.float32)
        return im, im_info


class Pad(object):
    def __init__(self, size, fill_value=[114.0, 114.0, 114.0]):
        """
        Pad image to a specified size.
        Args:
            size (list[int]): image target size
            fill_value (list[float]): rgb value of pad area, default (114.0, 114.0, 114.0)
        """
        super(Pad, self).__init__()
        if isinstance(size, int):
            size = [size, size]
        self.size = size
        self.fill_value = fill_value

    def __call__(self, im, im_info):
        im_h, im_w = im.shape[:2]
        h, w = self.size
        if h == im_h and w == im_w:
            im = im.astype(np.float32)
            return im, im_info

        canvas = np.ones((h, w, 3), dtype=np.float32)
        canvas *= np.array(self.fill_value, dtype=np.float32)
        canvas[0:im_h, 0:im_w, :] = im.astype(np.float32)
        im = canvas
        return im, im_info


class WarpAffine(object):
    """Warp affine the image
    """

    def __init__(self,
                 keep_res=False,
                 pad=31,
                 input_h=512,
                 input_w=512,
                 scale=0.4,
                 shift=0.1,
                 down_ratio=4):
        self.keep_res = keep_res
        self.pad = pad
        self.input_h = input_h
        self.input_w = input_w
        self.scale = scale
        self.shift = shift
        self.down_ratio = down_ratio

    def __call__(self, im, im_info):
        """
        Args:
            im (np.ndarray): image (np.ndarray)
            im_info (dict): info of image
        Returns:
            im (np.ndarray):  processed image (np.ndarray)
            im_info (dict): info of processed image
        """
        img = cv2.cvtColor(im, cv2.COLOR_RGB2BGR)

        h, w = img.shape[:2]

        if self.keep_res:
            # True in detection eval/infer
            input_h = (h | self.pad) + 1
            input_w = (w | self.pad) + 1
            s = np.array([input_w, input_h], dtype=np.float32)
            c = np.array([w // 2, h // 2], dtype=np.float32)

        else:
            # False in centertrack eval_mot/eval_mot
            s = max(h, w) * 1.0
            input_h, input_w = self.input_h, self.input_w
            c = np.array([w / 2., h / 2.], dtype=np.float32)

        trans_input = get_affine_transform(c, s, 0, [input_w, input_h])
        img = cv2.resize(img, (w, h))
        inp = cv2.warpAffine(
            img, trans_input, (input_w, input_h), flags=cv2.INTER_LINEAR)

        if not self.keep_res:
            out_h = input_h // self.down_ratio
            out_w = input_w // self.down_ratio
            trans_output = get_affine_transform(c, s, 0, [out_w, out_h])

            im_info.update({
                'center': c,
                'scale': s,
                'out_height': out_h,
                'out_width': out_w,
                'inp_height': input_h,
                'inp_width': input_w,
                'trans_input': trans_input,
                'trans_output': trans_output,
            })
        return inp, im_info


def preprocess(im, preprocess_ops):
    # process image by preprocess_ops
    im_info = {
        'scale_factor': np.array(
            [1., 1.], dtype=np.float32),
        'im_shape': None,
    }
    im, im_info = decode_image(im, im_info)
    for operator in preprocess_ops:
        im, im_info = operator(im, im_info)
    return im, im_info