add abinet_rec_aug and trained model

configs/rec/rec_r45_abinet.yml

@@ -8,7 +8,7 @@ Global:
   # evaluation is run every 2000 iterations
   eval_batch_step: [0, 2000]
   cal_metric_during_train: True
-  pretrained_model:
+  pretrained_model: ./rec_r45_abinet_train/abinet_vl_pretrained
   checkpoints:
   save_inference_dir:
   use_visualdl: False
@@ -67,6 +67,7 @@ Train:
       - DecodeImage: # load image
           img_mode: RGB
           channel_first: False
+      - ABINetRecAug:
       - ABINetLabelEncode: # Class handling label
           ignore_index: *ignore_index
       - ABINetRecResizeImg:

doc/doc_ch/algorithm_rec_abinet.md

@@ -27,7 +27,7 @@
 
 |模型|骨干网络|配置文件|Acc|下载链接|
 | --- | --- | --- | --- | --- |
-|ABINet|ResNet45|[rec_r45_abinet.yml](../../configs/rec/rec_r45_abinet.yml)|90.75%|[训练模型]()/[预训练模型]|
+|ABINet|ResNet45|[rec_r45_abinet.yml](../../configs/rec/rec_r45_abinet.yml)|90.75%|[预训练、训练模型](https://paddleocr.bj.bcebos.com/rec_r45_abinet_train.tar)|
 
 <a name="2"></a>
 ## 2. 环境配置
@@ -80,7 +80,7 @@ python3 tools/infer_rec.py -c configs/rec/rec_r45_abinet.yml -o Global.infer_img
 
 <a name="4-1"></a>
 ### 4.1 Python推理
-首先将训练得到best模型，转换成inference model。这里以训练完成的模型为例（[模型下载地址]() )，可以使用如下命令进行转换：
+首先将训练得到best模型，转换成inference model。这里以训练完成的模型为例（[模型下载地址](https://paddleocr.bj.bcebos.com/rec_r45_abinet_train.tar) )，可以使用如下命令进行转换：
 
 ```shell
 # 注意将pretrained_model的路径设置为本地路径。

doc/doc_en/algorithm_rec_abinet_en.md

@@ -25,7 +25,7 @@ Using MJSynth and SynthText two text recognition datasets for training, and eval
 
 |Model|Backbone|config|Acc|Download link|
 | --- | --- | --- | --- | --- |
-|ABINet|ResNet45|[rec_r45_abinet.yml](../../configs/rec/rec_r45_abinet.yml)|90.75%|[trained model]()/[pretrained model]()|
+|ABINet|ResNet45|[rec_r45_abinet.yml](../../configs/rec/rec_r45_abinet.yml)|90.75%|[pretrained & trained model](https://paddleocr.bj.bcebos.com/rec_r45_abinet_train.tar)|
 
 <a name="2"></a>
 ## 2. Environment
@@ -68,7 +68,7 @@ python3 tools/infer_rec.py -c configs/rec/rec_r45_abinet.yml -o Global.infer_img
 
 <a name="4-1"></a>
 ### 4.1 Python Inference
-First, the model saved during the ABINet text recognition training process is converted into an inference model. ( [Model download link]()) ), you can use the following command to convert:
+First, the model saved during the ABINet text recognition training process is converted into an inference model. ( [Model download link](https://paddleocr.bj.bcebos.com/rec_r45_abinet_train.tar)) ), you can use the following command to convert:
 
 ```
 python3 tools/export_model.py -c configs/rec/rec_r45_abinet.yml -o Global.pretrained_model=./rec_r45_abinet_train/best_accuracy  Global.save_inference_dir=./inference/rec_r45_abinet

ppocr/data/imaug/__init__.py

@@ -25,7 +25,7 @@ from .make_pse_gt import MakePseGt
 
 from .rec_img_aug import RecAug, RecConAug, RecResizeImg, ClsResizeImg, \
     SRNRecResizeImg, GrayRecResizeImg, SARRecResizeImg, PRENResizeImg, \
-    ABINetRecResizeImg, SVTRRecResizeImg
+    ABINetRecResizeImg, SVTRRecResizeImg, ABINetRecAug
 from .ssl_img_aug import SSLRotateResize
 from .randaugment import RandAugment
 from .copy_paste import CopyPaste

ppocr/data/imaug/abinet_aug.py

+# copyright (c) 2020 PaddlePaddle Authors. All Rights Reserve.
+#
+# 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.
+"""
+This code is refer from:
+https://github.com/FangShancheng/ABINet/blob/main/transforms.py
+"""
+import math
+import numbers
+import random
+
+import cv2
+import numpy as np
+from paddle.vision.transforms import Compose, ColorJitter
+
+
+def sample_asym(magnitude, size=None):
+    return np.random.beta(1, 4, size) * magnitude
+
+
+def sample_sym(magnitude, size=None):
+    return (np.random.beta(4, 4, size=size) - 0.5) * 2 * magnitude
+
+
+def sample_uniform(low, high, size=None):
+    return np.random.uniform(low, high, size=size)
+
+
+def get_interpolation(type='random'):
+    if type == 'random':
+        choice = [
+            cv2.INTER_NEAREST, cv2.INTER_LINEAR, cv2.INTER_CUBIC, cv2.INTER_AREA
+        ]
+        interpolation = choice[random.randint(0, len(choice) - 1)]
+    elif type == 'nearest':
+        interpolation = cv2.INTER_NEAREST
+    elif type == 'linear':
+        interpolation = cv2.INTER_LINEAR
+    elif type == 'cubic':
+        interpolation = cv2.INTER_CUBIC
+    elif type == 'area':
+        interpolation = cv2.INTER_AREA
+    else:
+        raise TypeError(
+            'Interpolation types only nearest, linear, cubic, area are supported!'
+        )
+    return interpolation
+
+
+class CVRandomRotation(object):
+    def __init__(self, degrees=15):
+        assert isinstance(degrees,
+                          numbers.Number), "degree should be a single number."
+        assert degrees >= 0, "degree must be positive."
+        self.degrees = degrees
+
+    @staticmethod
+    def get_params(degrees):
+        return sample_sym(degrees)
+
+    def __call__(self, img):
+        angle = self.get_params(self.degrees)
+        src_h, src_w = img.shape[:2]
+        M = cv2.getRotationMatrix2D(
+            center=(src_w / 2, src_h / 2), angle=angle, scale=1.0)
+        abs_cos, abs_sin = abs(M[0, 0]), abs(M[0, 1])
+        dst_w = int(src_h * abs_sin + src_w * abs_cos)
+        dst_h = int(src_h * abs_cos + src_w * abs_sin)
+        M[0, 2] += (dst_w - src_w) / 2
+        M[1, 2] += (dst_h - src_h) / 2
+
+        flags = get_interpolation()
+        return cv2.warpAffine(
+            img,
+            M, (dst_w, dst_h),
+            flags=flags,
+            borderMode=cv2.BORDER_REPLICATE)
+
+
+class CVRandomAffine(object):
+    def __init__(self, degrees, translate=None, scale=None, shear=None):
+        assert isinstance(degrees,
+                          numbers.Number), "degree should be a single number."
+        assert degrees >= 0, "degree must be positive."
+        self.degrees = degrees
+
+        if translate is not None:
+            assert isinstance(translate, (tuple, list)) and len(translate) == 2, \
+                "translate should be a list or tuple and it must be of length 2."
+            for t in translate:
+                if not (0.0 <= t <= 1.0):
+                    raise ValueError(
+                        "translation values should be between 0 and 1")
+        self.translate = translate
+
+        if scale is not None:
+            assert isinstance(scale, (tuple, list)) and len(scale) == 2, \
+                "scale should be a list or tuple and it must be of length 2."
+            for s in scale:
+                if s <= 0:
+                    raise ValueError("scale values should be positive")
+        self.scale = scale
+
+        if shear is not None:
+            if isinstance(shear, numbers.Number):
+                if shear < 0:
+                    raise ValueError(
+                        "If shear is a single number, it must be positive.")
+                self.shear = [shear]
+            else:
+                assert isinstance(shear, (tuple, list)) and (len(shear) == 2), \
+                    "shear should be a list or tuple and it must be of length 2."
+                self.shear = shear
+        else:
+            self.shear = shear
+
+    def _get_inverse_affine_matrix(self, center, angle, translate, scale,
+                                   shear):
+        # https://github.com/pytorch/vision/blob/v0.4.0/torchvision/transforms/functional.py#L717
+        from numpy import sin, cos, tan
+
+        if isinstance(shear, numbers.Number):
+            shear = [shear, 0]
+
+        if not isinstance(shear, (tuple, list)) and len(shear) == 2:
+            raise ValueError(
+                "Shear should be a single value or a tuple/list containing " +
+                "two values. Got {}".format(shear))
+
+        rot = math.radians(angle)
+        sx, sy = [math.radians(s) for s in shear]
+
+        cx, cy = center
+        tx, ty = translate
+
+        # RSS without scaling
+        a = cos(rot - sy) / cos(sy)
+        b = -cos(rot - sy) * tan(sx) / cos(sy) - sin(rot)
+        c = sin(rot - sy) / cos(sy)
+        d = -sin(rot - sy) * tan(sx) / cos(sy) + cos(rot)
+
+        # Inverted rotation matrix with scale and shear
+        # det([[a, b], [c, d]]) == 1, since det(rotation) = 1 and det(shear) = 1
+        M = [d, -b, 0, -c, a, 0]
+        M = [x / scale for x in M]
+
+        # Apply inverse of translation and of center translation: RSS^-1 * C^-1 * T^-1
+        M[2] += M[0] * (-cx - tx) + M[1] * (-cy - ty)
+        M[5] += M[3] * (-cx - tx) + M[4] * (-cy - ty)
+
+        # Apply center translation: C * RSS^-1 * C^-1 * T^-1
+        M[2] += cx
+        M[5] += cy
+        return M
+
+    @staticmethod
+    def get_params(degrees, translate, scale_ranges, shears, height):
+        angle = sample_sym(degrees)
+        if translate is not None:
+            max_dx = translate[0] * height
+            max_dy = translate[1] * height
+            translations = (np.round(sample_sym(max_dx)),
+                            np.round(sample_sym(max_dy)))
+        else:
+            translations = (0, 0)
+
+        if scale_ranges is not None:
+            scale = sample_uniform(scale_ranges[0], scale_ranges[1])
+        else:
+            scale = 1.0
+
+        if shears is not None:
+            if len(shears) == 1:
+                shear = [sample_sym(shears[0]), 0.]
+            elif len(shears) == 2:
+                shear = [sample_sym(shears[0]), sample_sym(shears[1])]
+        else:
+            shear = 0.0
+
+        return angle, translations, scale, shear
+
+    def __call__(self, img):
+        src_h, src_w = img.shape[:2]
+        angle, translate, scale, shear = self.get_params(
+            self.degrees, self.translate, self.scale, self.shear, src_h)
+
+        M = self._get_inverse_affine_matrix((src_w / 2, src_h / 2), angle,
+                                            (0, 0), scale, shear)
+        M = np.array(M).reshape(2, 3)
+
+        startpoints = [(0, 0), (src_w - 1, 0), (src_w - 1, src_h - 1),
+                       (0, src_h - 1)]
+        project = lambda x, y, a, b, c: int(a * x + b * y + c)
+        endpoints = [(project(x, y, *M[0]), project(x, y, *M[1]))
+                     for x, y in startpoints]
+
+        rect = cv2.minAreaRect(np.array(endpoints))
+        bbox = cv2.boxPoints(rect).astype(dtype=np.int)
+        max_x, max_y = bbox[:, 0].max(), bbox[:, 1].max()
+        min_x, min_y = bbox[:, 0].min(), bbox[:, 1].min()
+
+        dst_w = int(max_x - min_x)
+        dst_h = int(max_y - min_y)
+        M[0, 2] += (dst_w - src_w) / 2
+        M[1, 2] += (dst_h - src_h) / 2
+
+        # add translate
+        dst_w += int(abs(translate[0]))
+        dst_h += int(abs(translate[1]))
+        if translate[0] < 0: M[0, 2] += abs(translate[0])
+        if translate[1] < 0: M[1, 2] += abs(translate[1])
+
+        flags = get_interpolation()
+        return cv2.warpAffine(
+            img,
+            M, (dst_w, dst_h),
+            flags=flags,
+            borderMode=cv2.BORDER_REPLICATE)
+
+
+class CVRandomPerspective(object):
+    def __init__(self, distortion=0.5):
+        self.distortion = distortion
+
+    def get_params(self, width, height, distortion):
+        offset_h = sample_asym(
+            distortion * height / 2, size=4).astype(dtype=np.int)
+        offset_w = sample_asym(
+            distortion * width / 2, size=4).astype(dtype=np.int)
+        topleft = (offset_w[0], offset_h[0])
+        topright = (width - 1 - offset_w[1], offset_h[1])
+        botright = (width - 1 - offset_w[2], height - 1 - offset_h[2])
+        botleft = (offset_w[3], height - 1 - offset_h[3])
+
+        startpoints = [(0, 0), (width - 1, 0), (width - 1, height - 1),
+                       (0, height - 1)]
+        endpoints = [topleft, topright, botright, botleft]
+        return np.array(
+            startpoints, dtype=np.float32), np.array(
+                endpoints, dtype=np.float32)
+
+    def __call__(self, img):
+        height, width = img.shape[:2]
+        startpoints, endpoints = self.get_params(width, height, self.distortion)
+        M = cv2.getPerspectiveTransform(startpoints, endpoints)
+
+        # TODO: more robust way to crop image
+        rect = cv2.minAreaRect(endpoints)
+        bbox = cv2.boxPoints(rect).astype(dtype=np.int)
+        max_x, max_y = bbox[:, 0].max(), bbox[:, 1].max()
+        min_x, min_y = bbox[:, 0].min(), bbox[:, 1].min()
+        min_x, min_y = max(min_x, 0), max(min_y, 0)
+
+        flags = get_interpolation()
+        img = cv2.warpPerspective(
+            img,
+            M, (max_x, max_y),
+            flags=flags,
+            borderMode=cv2.BORDER_REPLICATE)
+        img = img[min_y:, min_x:]
+        return img
+
+
+class CVRescale(object):
+    def __init__(self, factor=4, base_size=(128, 512)):
+        """ Define image scales using gaussian pyramid and rescale image to target scale.
+        
+        Args:
+            factor: the decayed factor from base size, factor=4 keeps target scale by default.
+            base_size: base size the build the bottom layer of pyramid
+        """
+        if isinstance(factor, numbers.Number):
+            self.factor = round(sample_uniform(0, factor))
+        elif isinstance(factor, (tuple, list)) and len(factor) == 2:
+            self.factor = round(sample_uniform(factor[0], factor[1]))
+        else:
+            raise Exception('factor must be number or list with length 2')
+        # assert factor is valid
+        self.base_h, self.base_w = base_size[:2]
+
+    def __call__(self, img):
+        if self.factor == 0: return img
+        src_h, src_w = img.shape[:2]
+        cur_w, cur_h = self.base_w, self.base_h
+        scale_img = cv2.resize(
+            img, (cur_w, cur_h), interpolation=get_interpolation())
+        for _ in range(self.factor):
+            scale_img = cv2.pyrDown(scale_img)
+        scale_img = cv2.resize(
+            scale_img, (src_w, src_h), interpolation=get_interpolation())
+        return scale_img
+
+
+class CVGaussianNoise(object):
+    def __init__(self, mean=0, var=20):
+        self.mean = mean
+        if isinstance(var, numbers.Number):
+            self.var = max(int(sample_asym(var)), 1)
+        elif isinstance(var, (tuple, list)) and len(var) == 2:
+            self.var = int(sample_uniform(var[0], var[1]))
+        else:
+            raise Exception('degree must be number or list with length 2')
+
+    def __call__(self, img):
+        noise = np.random.normal(self.mean, self.var**0.5, img.shape)
+        img = np.clip(img + noise, 0, 255).astype(np.uint8)
+        return img
+
+
+class CVMotionBlur(object):
+    def __init__(self, degrees=12, angle=90):
+        if isinstance(degrees, numbers.Number):
+            self.degree = max(int(sample_asym(degrees)), 1)
+        elif isinstance(degrees, (tuple, list)) and len(degrees) == 2:
+            self.degree = int(sample_uniform(degrees[0], degrees[1]))
+        else:
+            raise Exception('degree must be number or list with length 2')
+        self.angle = sample_uniform(-angle, angle)
+
+    def __call__(self, img):
+        M = cv2.getRotationMatrix2D((self.degree // 2, self.degree // 2),
+                                    self.angle, 1)
+        motion_blur_kernel = np.zeros((self.degree, self.degree))
+        motion_blur_kernel[self.degree // 2, :] = 1
+        motion_blur_kernel = cv2.warpAffine(motion_blur_kernel, M,
+                                            (self.degree, self.degree))
+        motion_blur_kernel = motion_blur_kernel / self.degree
+        img = cv2.filter2D(img, -1, motion_blur_kernel)
+        img = np.clip(img, 0, 255).astype(np.uint8)
+        return img
+
+
+class CVGeometry(object):
+    def __init__(self,
+                 degrees=15,
+                 translate=(0.3, 0.3),
+                 scale=(0.5, 2.),
+                 shear=(45, 15),
+                 distortion=0.5,
+                 p=0.5):
+        self.p = p
+        type_p = random.random()
+        if type_p < 0.33:
+            self.transforms = CVRandomRotation(degrees=degrees)
+        elif type_p < 0.66:
+            self.transforms = CVRandomAffine(
+                degrees=degrees, translate=translate, scale=scale, shear=shear)
+        else:
+            self.transforms = CVRandomPerspective(distortion=distortion)
+
+    def __call__(self, img):
+        if random.random() < self.p:
+            return self.transforms(img)
+        else:
+            return img
+
+
+class CVDeterioration(object):
+    def __init__(self, var, degrees, factor, p=0.5):
+        self.p = p
+        transforms = []
+        if var is not None:
+            transforms.append(CVGaussianNoise(var=var))
+        if degrees is not None:
+            transforms.append(CVMotionBlur(degrees=degrees))
+        if factor is not None:
+            transforms.append(CVRescale(factor=factor))
+
+        random.shuffle(transforms)
+        transforms = Compose(transforms)
+        self.transforms = transforms
+
+    def __call__(self, img):
+        if random.random() < self.p:
+
+            return self.transforms(img)
+        else:
+            return img
+
+
+class CVColorJitter(object):
+    def __init__(self,
+                 brightness=0.5,
+                 contrast=0.5,
+                 saturation=0.5,
+                 hue=0.1,
+                 p=0.5):
+        self.p = p
+        self.transforms = ColorJitter(
+            brightness=brightness,
+            contrast=contrast,
+            saturation=saturation,
+            hue=hue)
+
+    def __call__(self, img):
+        if random.random() < self.p: return self.transforms(img)
+        else: return img

ppocr/data/imaug/rec_img_aug.py

@@ -19,6 +19,8 @@ import random
 import copy
 from PIL import Image
 from .text_image_aug import tia_perspective, tia_stretch, tia_distort
+from .abinet_aug import CVGeometry, CVDeterioration, CVColorJitter
+from paddle.vision.transforms import Compose
 
 
 class RecAug(object):
@@ -94,6 +96,31 @@ class BaseDataAugmentation(object):
         return data
 
 
+class ABINetRecAug(object):
+    def __init__(self, **kwargs):
+        self.transforms = Compose([
+            CVGeometry(
+                degrees=45,
+                translate=(0.0, 0.0),
+                scale=(0.5, 2.),
+                shear=(45, 15),
+                distortion=0.5,
+                p=0.5), CVDeterioration(
+                    var=20, degrees=6, factor=4, p=0.25), CVColorJitter(
+                        brightness=0.5,
+                        contrast=0.5,
+                        saturation=0.5,
+                        hue=0.1,
+                        p=0.25)
+        ])
+
+    def __call__(self, data):
+        img = data['image']
+        img = self.transforms(img)
+        data['image'] = img
+        return data
+
+
 class RecConAug(object):
     def __init__(self,
                  prob=0.5,

test_tipc/configs/rec_r45_abinet/rec_r45_abinet.yml

@@ -68,6 +68,7 @@ Train:
       - DecodeImage: # load image
           img_mode: RGB
           channel_first: False
+      - ABINetRecAug:
       - ABINetLabelEncode: # Class handling label
           ignore_index: *ignore_index
       - ABINetRecResizeImg: