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e2e_ocr_variable.py
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e2e_ocr_variable.py
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# pylint: disable=C0111,too-many-arguments,too-many-instance-attributes,too-many-locals,redefined-outer-name,fixme
# pylint: disable=superfluous-parens, no-member, invalid-name
import sys
sys.path.insert(0, "../../python")
import mxnet as mx
import numpy as np
import cv2, random, string,os
from io import BytesIO
from captchaimage import ImageCaptcha
class OCRBatch(object):
def __init__(self, data_names, data, label_names, label):
self.data = data
self.label = label
self.data_names = data_names
self.label_names = label_names
@property
def provide_data(self):
return [(n, x.shape) for n, x in zip(self.data_names, self.data)]
@property
def provide_label(self):
return [(n, x.shape) for n, x in zip(self.label_names, self.label)]
def gen_rand():
buf = ''.join(random.sample(string.digits, random.randint(4,8)))
return buf
def get_label(buf):
a=[]
for x in buf:
if x.isdigit():
a.append(int(x))
elif x.isupper():
a.append(ord(x)-ord('A')+10)
else:
a.append(ord(x)-ord('a')+36)
for i in range(8-len(buf)):
a.append(10)
return np.array(a)
def gen_sample(captcha, width, height, trainlabel):
if trainlabel==0:
num = gen_rand()
img = captcha.generate(num)
img = np.fromstring(img.getvalue(), dtype='uint8')
img = cv2.imdecode(img, cv2.IMREAD_COLOR)
else:
num=trainlabel
img=cv2.imread('temp/current.png')
img = cv2.resize(img, (width, height))
img = np.multiply(img, 1/255.0)
img = img.transpose(2, 0, 1)
return (num, img)
class OCRIter(mx.io.DataIter):
def __init__(self, count, batch_size, num_label, height, width, trainlabel=0):
super(OCRIter, self).__init__()
self.captcha = ImageCaptcha()
self.trainlabel=trainlabel
self.batch_size = batch_size
self.count = count
self.height = height
self.width = width
self.provide_data = [('data', (batch_size, 3, height, width))]
self.provide_label = [('softmax_label', (self.batch_size, num_label))]
def __iter__(self):
for k in range(self.count / self.batch_size):
data = []
label = []
for i in range(self.batch_size):
num, img = gen_sample(self.captcha, self.width, self.height, self.trainlabel)
data.append(img)
label.append(get_label(num))
data_all = [mx.nd.array(data)]
label_all = [mx.nd.array(label)]
data_names = ['data']
label_names = ['softmax_label']
data_batch = OCRBatch(data_names, data_all, label_names, label_all)
yield data_batch
def reset(self):
pass
def get_e2enet_variable(predict=0):
data = mx.symbol.Variable('data')
label = mx.symbol.Variable('softmax_label')
conv1 = mx.symbol.Convolution(name="convolution0",data=data, kernel=(5,5), num_filter=32)
pool1 = mx.symbol.Pooling(data=conv1, pool_type="max", kernel=(2,2), stride=(1, 1))
relu1 = mx.symbol.Activation(data=pool1, act_type="relu")
conv2 = mx.symbol.Convolution(name="convolution1",data=relu1, kernel=(5,5), num_filter=32)
pool2 = mx.symbol.Pooling(data=conv2, pool_type="avg", kernel=(2,2), stride=(1, 1))
relu2 = mx.symbol.Activation(data=pool2, act_type="relu")
conv3 = mx.symbol.Convolution(name="convolution2",data=relu2, kernel=(3,3), num_filter=32)
pool3 = mx.symbol.Pooling(data=conv3, pool_type="avg", kernel=(2,2), stride=(1, 1))
relu3 = mx.symbol.Activation(data=pool3, act_type="relu")
conv4 = mx.symbol.Convolution(name="convolution3",data=relu3, kernel=(3,3), num_filter=32)
pool4 = mx.symbol.Pooling(data=conv4, pool_type="avg", kernel=(2,2), stride=(1, 1))
relu4 = mx.symbol.Activation(data=pool4, act_type="relu")
flatten = mx.symbol.Flatten(data = relu4)
fc1 = mx.symbol.FullyConnected(name="fullyconnected0",data = flatten, num_hidden = 1024)
fc21 = mx.symbol.FullyConnected(name="fullyconnected1",data = fc1, num_hidden = 11)
fc22 = mx.symbol.FullyConnected(name="fullyconnected2",data = fc1, num_hidden = 11)
fc23 = mx.symbol.FullyConnected(name="fullyconnected3",data = fc1, num_hidden = 11)
fc24 = mx.symbol.FullyConnected(name="fullyconnected4",data = fc1, num_hidden = 11)
fc25 = mx.symbol.FullyConnected(name="fullyconnected5",data = fc1, num_hidden = 11)
fc26 = mx.symbol.FullyConnected(name="fullyconnected6",data = fc1, num_hidden = 11)
fc27 = mx.symbol.FullyConnected(name="fullyconnected7",data = fc1, num_hidden = 11)
fc28 = mx.symbol.FullyConnected(name="fullyconnected8",data = fc1, num_hidden = 11)
fc2 = mx.symbol.Concat(*[fc21, fc22, fc23, fc24,fc25,fc26,fc27,fc28], dim = 0)
if predict:
return mx.symbol.SoftmaxOutput(data = fc2, name = "softmax")
label = mx.symbol.transpose(data = label)
label = mx.symbol.Reshape(data = label, target_shape = (0, ))
return mx.symbol.SoftmaxOutput(data = fc2, label = label, name = "softmax")
def Accuracy(label, pred):
label = label.T.reshape((-1, ))
hit = 0
total = 0
for i in range(pred.shape[0] / 8):
l1=[]
l2=[]
for j in range(8):
k = i * 8 + j
if np.argmax(pred[k])<10:
l1.append(np.argmax(pred[k]))
if int(label[k])<10:
l2.append(int(label[k]))
if l1==l2 and len(l1)>0:
hit += 1
total += 1
return 1.0 * hit / total
def train(label):
#_, arg , aux = mx.model.load_checkpoint("e2e-ocr-variable", 1)
model = mx.model.FeedForward(ctx = mx.gpu(),
symbol = get_e2enet_variable(),
num_epoch = 1,
learning_rate = 0.001,
wd = 0.00001,
initializer = mx.init.Xavier(factor_type="in", magnitude=2.34),
momentum = 0.9)
batch_size = 32 if label==0 else 1
data_train = OCRIter(100000 if label==0 else 1, batch_size, 8, 30, 80, label)
data_test = OCRIter(1000 if label==0 else 0, batch_size, 8, 30, 80)
import logging
head = '%(asctime)-15s %(message)s'
logging.basicConfig(level=logging.DEBUG, format=head)
model.fit(X = data_train, eval_data = data_test, eval_metric = Accuracy, batch_end_callback=mx.callback.Speedometer(batch_size, 50),)
model.save("e2e-ocr-variable")
if __name__ == '__main__':
train(0)