import io import cv2 import numpy as np from PIL import Image from .db_resize_for_test import DetResizeForTest class NormalizeImage(object): """normalize image such as substract mean, divide std""" def __init__(self, scale=None, mean=None, std=None, order='chw', **kwargs): if isinstance(scale, str): scale = eval(scale) self.scale = np.float32(scale if scale is not None else 1.0 / 255.0) mean = mean if mean is not None else [0.485, 0.456, 0.406] std = std if std is not None else [0.229, 0.224, 0.225] shape = (3, 1, 1) if order == 'chw' else (1, 1, 3) self.mean = np.array(mean).reshape(shape).astype('float32') self.std = np.array(std).reshape(shape).astype('float32') def __call__(self, data): img = data['image'] from PIL import Image if isinstance(img, Image.Image): img = np.array(img) assert isinstance(img, np.ndarray), "invalid input 'img' in NormalizeImage" data['image'] = (img.astype('float32') * self.scale - self.mean) / self.std return data class ToCHWImage(object): """convert hwc image to chw image""" def __init__(self, **kwargs): pass def __call__(self, data): img = data['image'] from PIL import Image if isinstance(img, Image.Image): img = np.array(img) data['image'] = img.transpose((2, 0, 1)) return data class KeepKeys(object): def __init__(self, keep_keys, **kwargs): self.keep_keys = keep_keys def __call__(self, data): data_list = [] for key in self.keep_keys: data_list.append(data[key]) return data_list def transform(data, ops=None): """transform.""" if ops is None: ops = [] for op in ops: data = op(data) if data is None: return None return data class DecodeImage(object): """decode image.""" def __init__(self, img_mode='RGB', channel_first=False, ignore_orientation=False, **kwargs): self.img_mode = img_mode self.channel_first = channel_first self.ignore_orientation = ignore_orientation def __call__(self, data): img = data['image'] assert type(img) is bytes and len( img) > 0, "invalid input 'img' in DecodeImage" img = np.frombuffer(img, dtype='uint8') if self.ignore_orientation: img = cv2.imdecode( img, cv2.IMREAD_IGNORE_ORIENTATION | cv2.IMREAD_COLOR) else: img = cv2.imdecode(img, 1) if img is None: return None if self.img_mode == 'GRAY': img = cv2.cvtColor(img, cv2.COLOR_GRAY2BGR) elif self.img_mode == 'RGB': assert img.shape[2] == 3, 'invalid shape of image[%s]' % ( img.shape) img = img[:, :, ::-1] if self.channel_first: img = img.transpose((2, 0, 1)) data['image'] = img return data class DecodeImagePIL(object): """decode image.""" def __init__(self, img_mode='RGB', **kwargs): self.img_mode = img_mode def __call__(self, data): img = data['image'] assert type(img) is bytes and len( img) > 0, "invalid input 'img' in DecodeImage" img = data['image'] buf = io.BytesIO(img) img = Image.open(buf).convert('RGB') if self.img_mode == 'Gray': img = img.convert('L') elif self.img_mode == 'BGR': img = np.array(img)[:, :, ::-1] # 将图片转为numpy格式,并将最后一维通道倒序 img = Image.fromarray(np.uint8(img)) data['image'] = img return data def create_operators(op_param_list, global_config=None): """create operators based on the config. Args: params(list): a dict list, used to create some operators """ assert isinstance(op_param_list, list), 'operator config should be a list' ops = [] for operator in op_param_list: assert isinstance(operator, dict) and len(operator) == 1, 'yaml format error' op_name = list(operator)[0] param = {} if operator[op_name] is None else operator[op_name] if global_config is not None: param.update(global_config) op = eval(op_name)(**param) ops.append(op) return ops