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text_dataflow.py
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text_dataflow.py
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#!/usr/bin/env python
# -*- coding: utf-8 -*-
import os
import config as cfg
from tensorpack.dataflow import (
DataFromList, MapData, MapDataComponent, RNGDataFlow, PrefetchData,
MultiProcessMapData, MultiThreadMapData, TestDataSpeed, imgaug, BatchData
)
import cv2
import math
import numpy as np
import threading
import multiprocessing
from matplotlib import pyplot as plt
from contextlib import contextmanager
from common import (
CustomResize, DataFromListOfDict, box_to_point8,
filter_boxes_inside_shape, np_iou, point8_to_box, polygons_to_mask,
)
from dataset import LSVT, ART, ReCTS #, TotalText, ICDAR2017RCTW, MLT2019
def largest_size_at_most(height, width, largest_side, max_scale):
"""
Compute resized image size with limited max scale.
"""
scale = largest_side/height if height>width else largest_side/width
scale = min(scale, max_scale)
new_height, new_width = height * scale, width * scale
return new_height, new_width
def aspect_preserving_resize(image, largest_side, max_scale=4.):
"""
Resize image with perserved aspect and limited max scale.
"""
height, width = image.shape[:2]
new_height, new_width = largest_size_at_most(height, width, largest_side, max_scale)
new_height = max(new_height, cfg.stride)
new_width = max(new_width, cfg.stride)
resized_image = cv2.resize(image, (int(new_width), int(new_height)))
return resized_image
def padding_image(image, padding_size):
"""
Padding arbitrary-shaped text image to square for tensorflow batch training.
"""
height, width = image.shape[:2]
padding_h = padding_size - height
padding_w = padding_size - width
padding_top = np.random.randint(padding_h)
padding_left = np.random.randint(padding_w)
padding_down = padding_h - padding_top
padding_right = padding_w - padding_left
padding_img = cv2.copyMakeBorder(image, padding_top, padding_down, padding_left, padding_right, borderType=cv2.BORDER_CONSTANT, value=[0,0,0])
return padding_img, (padding_top, padding_left, height, width)
def rotatedPoint(R, point):
"""
Transform polygon with affine transform matrix.
"""
x = R[0,0]*point[0] + R[0,1]*point[1] + R[0,2]
y = R[1,0]*point[0] + R[1,1]*point[1] + R[1,2]
return [int(x), int(y)]
def affine_transform(image, polygon):
"""
Conduct same affine transform for both image and polygon for data augmentation.
"""
height, width, _ = image.shape
center_x, center_y = width/2, height/2
angle = 0 if np.random.uniform()>0.5 else np.random.uniform(-20., 20.)
shear_x, shear_y = (0,0) if np.random.uniform()>0.5 else (np.random.uniform(-0.2, 0.2), np.random.uniform(-0.2, 0.2))
rad = math.radians(angle)
sin, cos = math.sin(rad), math.cos(rad) # x, y
abs_sin, abs_cos = abs(sin), abs(cos)
new_width = ((height * abs_sin) + (width * abs_cos))
new_height = ((height * abs_cos) + (width * abs_sin))
new_width += np.abs(shear_y*new_height)
new_height += np.abs(shear_x*new_width)
new_width = int(new_width)
new_height = int(new_height)
M = np.array([[cos, sin+shear_y, new_width/2 - center_x + (1-cos)*center_x-(sin+shear_y)*center_y],
[-sin+shear_x, cos, new_height/2 - center_y + (sin-shear_x)*center_x+(1-cos)*center_y]])
rotatedImage = cv2.warpAffine(image, M, (new_width, new_height), flags=cv2.INTER_CUBIC, borderMode=cv2.BORDER_CONSTANT, borderValue=(0,0,0))
height, width = rotatedImage.shape[:2]
rotatedPoints = [rotatedPoint(M, point) for point in polygon]
mask = polygons_to_mask([np.array(rotatedPoints, np.float32)], new_height, new_width)
x, y, w, h = cv2.boundingRect(mask)
mask = np.expand_dims(np.float32(mask), axis=-1)
rotatedImage = rotatedImage * mask
cropImage = rotatedImage[y:y+h, x:x+w,:]
return cropImage
class TextDataPreprocessor:
"""
Tensorpack text data preprocess function.
"""
def __init__(self, cfg):
self.cfg = cfg
def __call__(self, roidb):
filename, label, mask, bbox, polygon = roidb['filename'], roidb['label'], roidb['mask'], roidb['bbox'], roidb['polygon'],
img = cv2.imread(filename)
img = cv2.cvtColor(img, cv2.COLOR_BGR2RGB)
image = affine_transform(img, polygon)
# img = img[bbox[0]:bbox[2], bbox[1]:bbox[3], :] if image.shape[0]<cfg.stride/2 or image.shape[1]<cfg.stride/2 else image
img = img if image.shape[0]<cfg.stride/2 or image.shape[1]<cfg.stride/2 else image
largest_side = np.random.randint(cfg.crop_min_size, cfg.image_size)
img = aspect_preserving_resize(img, largest_side)
img, crop_bbox = padding_image(img, cfg.image_size)
normalized_bbox = [coord/cfg.image_size for coord in crop_bbox]
img = img.astype("float32")/255.
ret = {"image": img, "label": label, "mask": mask, "normalized_bbox": normalized_bbox, "is_training":True, "dropout_keep_prob":0.5}
return ret
def get_train_dataflow(roidb):
"""
Tensorpack text dataflow.
"""
ds = DataFromList(roidb, shuffle=True)
preprocess = TextDataPreprocessor(cfg)
buffer_size = cfg.num_threads * 10
ds = MultiThreadMapData(ds, cfg.num_threads, preprocess, buffer_size=buffer_size)
# ds = MultiProcessMapData(ds, cfg.num_workers, preprocess, buffer_size=buffer_size)
ds = PrefetchData(ds, 100, multiprocessing.cpu_count() // 4)
#ds = BatchData(ds, cfg.batch_size, remainder=True)
return ds
def get_roidb(dataset_name):
"""
Load generated numpy dataset for tensorpack dataflow.
"""
dataset = np.load(dataset_name)[()]
filenames, labels, masks, bboxes, points = dataset["filenames"], dataset["labels"], dataset["masks"], dataset["bboxes"], dataset["points"]
roidb = []
for filename, label, mask, bbox, polygon in zip(filenames, labels, masks, bboxes, points):
item = {"filename":filename, "label":label, "mask":mask, "bbox":bbox, "polygon":polygon}
roidb.append(item)
return roidb
def get_batch_train_dataflow(roidbs, batch_size):
"""
Tensorpack batch text dataflow.
"""
batched_roidbs = []
batch = []
for i, d in enumerate(roidbs):
if i % batch_size == 0:
if len(batch) == batch_size:
batched_roidbs.append(batch)
batch = []
batch.append(d)
def preprocess(roidb_batch):
"""
Tensorpack batch text data preprocess function.
"""
datapoint_list = []
for roidb in roidb_batch:
filename, label, mask, bbox, polygon = roidb['filename'], roidb['label'], roidb['mask'], roidb['bbox'], roidb['polygon']
img = cv2.imread(filename)
img = cv2.cvtColor(img, cv2.COLOR_BGR2RGB)
image = affine_transform(img, polygon)
# img = img[bbox[0]:bbox[2], bbox[1]:bbox[3], :] if image.shape[0]<cfg.stride/2 or image.shape[1]<cfg.stride/2 else image
img = img if image.shape[0]<cfg.stride/2 or image.shape[1]<cfg.stride/2 else image
largest_side = np.random.randint(cfg.crop_min_size, cfg.image_size)
img = aspect_preserving_resize(img, largest_side)
img, crop_bbox = padding_image(img, cfg.image_size)
normalized_bbox = [coord/cfg.image_size for coord in crop_bbox]
img = img.astype("float32")/255.
ret = {"image": img, "label": label, "mask": mask, "normalized_bbox": normalized_bbox}
datapoint_list.append(ret)
batched_datapoint = {"is_training":True, "dropout_keep_prob":0.5}
for stackable_field in ["image", "label", "mask", "normalized_bbox"]:
batched_datapoint[stackable_field] = np.stack([d[stackable_field] for d in datapoint_list])
return batched_datapoint
ds = DataFromList(batched_roidbs, shuffle=True)
ds = MultiThreadMapData(ds, cfg.num_threads, preprocess)
# ds = PrefetchData(ds, 100, multiprocessing.cpu_count() // 4)
return ds
if __name__ == "__main__":
lsvt = LSVT()
lsvt.load_data()
print(len(lsvt.filenames))
filenames = lsvt.filenames
labels = lsvt.labels
masks = lsvt.masks
bboxes = lsvt.bboxes
points = lsvt.points
roidb = []
for filename, label, mask, bbox, polygon in zip(filenames, labels, masks, bboxes, points):
item = {"filename":filename, "label":label, "mask":mask, "bbox":bbox, "polygon":polygon}
roidb.append(item)
ds = get_train_dataflow(roidb)
from tensorpack.dataflow import PrintData
ds = PrintData(ds, 10)
# TestDataSpeed(ds, 50000).start()
for k in ds:
print(k['label'], k['mask'], k['normalized_bbox'])
plt.imshow(k['image'])
plt.show()