# Chainerで、Trainer使用時と、学習ループを直接書いた場合とで、精度が異なる現象について

Chainerで、Mnistのサンプルをtrainerを使って学習させた場合と、

ubuntu 16.04 64bit
python 2.7
chainer 3.3

## コードは以下になります。

``````#!/usr/bin/python
# -*- coding: utf-8 -*-

import numpy as np
import chainer
from chainer import cuda, Function, gradient_check, report, training,
utils, Variable
from chainer import datasets, iterators, optimizers, serializers
from chainer import Link, Chain, ChainList
from chainer.dataset import convert
import chainer.functions as F
import chainer.links as L
from chainer.datasets import tuple_dataset
from chainer import training
from chainer.training import extensions
import time

##use GPU
xp = cuda.cupy

train, test = datasets.get_mnist(withlabel=True, ndim=3)
train_count = len(train)
test_count = len(test)
class MyModel(Chain):
def __init__(self):
super(MyModel, self).__init__(
cn1=L.Convolution2D(1, 20, 5),
cn2=L.Convolution2D(20, 50, 5),
fc1=L.Linear(800, 500),
fc2=L.Linear(500, 10),
)

def __call__(self, x, t):
##convert data
converted_x, converted_t = Variable(cuda.to_gpu(x)),
Variable(cuda.to_gpu(t))
#return F.softmax_cross_entropy(self.fwd(x), t)
return F.softmax_cross_entropy(self.fwd(converted_x), converted_t)

def fwd(self, x):
h1 = F.max_pooling_2d(F.relu(self.cn1(x)), 2)
h2 = F.max_pooling_2d(F.relu(self.cn2(h1)), 2)
h3 = F.dropout(F.relu(self.fc1(h2)))
return self.fc2(h3)

###setting--------------------
model = MyModel()

#gpu mode
gpu_device = 0
model.to_gpu(gpu_device)
optimizer.setup(model)

##set parameter
batchsize=1000
epochsize=60
N=len(train) #training data

train_iter = iterators.SerialIterator(train, batchsize)#1000 is batch size
test_iter = chainer.iterators.SerialIterator(test,batchsize,repeat=False, shuffle=False)

###----training1-----------------------------------------------------------------------
for epoch in range(0, epochsize):
print "epoch: %d" % epoch
sum_loss = 0
x_batch = np.array([train[epoch*batchsize][0]])
y_batch = np.array(train[epoch*batchsize][1])

#create batch
for i in range(1, batchsize):
trainingdata=np.array([train[(epoch*batchsize) + i][0]])
x_batch = np.append(x_batch,trainingdata,axis=0)
labeldata=np.array([train[(epoch*batchsize) + i][1]])
y_batch = np.append(y_batch,labeldata)

#learning
loss=model(x_batch,y_batch)
loss.backward()
optimizer.update(model, x_batch, y_batch)
sum_loss += float(loss.data) * len(y_batch)

###----training2-----------------------------------------------------------------------
iterator = iterators.SerialIterator(train, batchsize)#1000 is batch size
updater = training.StandardUpdater(iterator, optimizer)
trainer = training.Trainer(updater, (epochsize, 'epoch')) #10 is epoch
trainer.extend(extensions.ProgressBar())
trainer.run()

###----test-----------------
ok = 0
for i in range(len(test)):

x = Variable(cuda.to_gpu(np.array([test[i][0]])))

t = test[i][1]
out = model.fwd(x)
ans = np.argmax(cuda.to_cpu(out.data))

####labe and predicted label
print("label is ",t)
print("predicted label is ", ans)

if (ans == t):
ok += 1
print (ok * 1.0) / len(test)
``````