pytorchのoutputについて

Question

以下のプログラムは手書き数字データセットMNISTを10クラスに識別するものです。
正解数と識別率をevaluate関数で求めているのですが、どのデータがどのクラスに分類されたかを調べるために混同行列を用いてみました。しかし、このプログラムを実行すると、ncorrectの値と混同行列の体格成分の和が一致しません。どうすれば一致するでしょうか。

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学習用プログラム

import os
import sys
import numpy as np
import datetime

import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim

import getdata

PATH_MNIST = './mnist'
PATH_RESULT = 'result_mnist'

### definition of the network
#
class NN(nn.Module):

    def __init__(self):
        super(NN, self).__init__()
        Hin1, Win1 = 28, 28
        self.conv1 = nn.Conv2d(1, 32, kernel_size = 5)
        Hout1, Wout1 = _output_shape(Hin1, Win1, self.conv1) # 24 x 24
        self.conv2 = nn.Conv2d(self.conv1.out_channels, 64, kernel_size = 5) 
        Hout2, Wout2 = _output_shape(Hout1//2, Wout1//2, self.conv2) # 8 x 8
        self.fc1 = nn.Linear(64 * (Hout2//2) * (Wout2//2), 1024) # 64 x 4 x 4
        self.fc2 = nn.Linear(self.fc1.out_features, 10)

    def forward(self, X):
        X = F.relu(F.max_pool2d(self.conv1(X), 2))
        X = F.relu(F.max_pool2d(self.conv2(X), 2))
        X = X.view(-1, self.fc1.in_features)
        X = F.relu(self.fc1(X))
        X = self.fc2(X)
        return F.log_softmax(X, dim = 1)

def _output_shape(Hin, Win, conv2d):
        Hout = int(np.floor((Hin + 2 * conv2d.padding[0] - conv2d.dilation[0] * (conv2d.kernel_size[0] - 1) - 1) / conv2d.stride[0] + 1))
        Wout = int(np.floor((Win + 2 * conv2d.padding[1] - conv2d.dilation[1] * (conv2d.kernel_size[1] - 1) - 1) / conv2d.stride[1] + 1))
        return Hout, Wout

def evaluate(model, X, Y, bindex):
    A = np.zeros((10,10))
    nbatch = bindex.shape[0]
    loss = 0
    ncorrect = 0
    with torch.no_grad():
        for ib in range(nbatch):
            ii = np.where(bindex[ib, :])[0]
            output = model(X[ii, ::])
            
            #loss += F.nll_loss(output, Y[ii], size_average=False).item()
            loss += F.nll_loss(output, Y[ii], reduction='sum').item()
            pred = output.max(1, keepdim=True)[1] # argmax of the output #ここで分類結果を求める
            for i in range(100):
                A[Y[i]][pred[i]] += 1
            ncorrect += pred.eq(Y[ii].view_as(pred)).sum().item()
            

    loss /= X.shape[0]
    acc = ncorrect / X.shape[0]
    print(A)
    print(np.trace(A),np.sum(A))
    return loss, acc, ncorrect

    

if __name__ == '__main__':

    ### device
    #
    use_gpu_if_available = True
    if use_gpu_if_available and torch.cuda.is_available():
        device = torch.device('cuda')
    else:
        device = torch.device('cpu')
    print('# using', device)
    
    ### reading and preparing the training data
    #
    data = getdata.Data(PATH_MNIST, nV = 10000)

    D = data.nrow * data.ncol
    K = data.nclass
    datLraw, labL = data.getData('L')
    datL = datLraw.reshape((-1, 1, data.nrow, data.ncol))
    datVraw, labV = data.getData('V')
    datV = datVraw.reshape((-1, 1, data.nrow, data.ncol))
    NV = datV.shape[0]
    NL = datL.shape[0]

    ### to torch.Tensor
    #
    XL = torch.from_numpy(datL.astype(np.float32)).to(device)
    YL = torch.from_numpy(labL).to(device)
    XV = torch.from_numpy(datV.astype(np.float32)).to(device)
    YV = torch.from_numpy(labV).to(device)
    
    ### initializing the network
    #
    Seed = 20
    torch.manual_seed(Seed)
    nn = NN()
    model = nn.to(device)
    print(nn)
    optimizer = optim.SGD(model.parameters(), lr = 0.01, momentum = 0.9)
    print(optimizer)

    ### training
    #
    batchsize = 100
    bindexL = getdata.makeBatchIndex(NL, batchsize)
    nbatchL = bindexL.shape[0]
    bindexV = getdata.makeBatchIndex(NV, batchsize)
    nbatchV = bindexV.shape[0]

    nitr = 10001
    nd = 0
    start = datetime.datetime.now()

    for i in range(nitr):

        if (i != 0) and (i % 500 == 0):
            model.eval()  # setting the module in evaluation mode
            lossL, accL, ncorrectL = evaluate(model, XL, YL, bindexL)
            #lossV, accV = evaluate(model, XV, YV, bindexV)
            print('#epoch{}'.format(nd/NL), end = ' 　　')
            print('{:.4f} {:.2f} {}'.format(lossL, accL*100, ncorrectL))
            fnModel = os.path.join(PATH_RESULT, os.path.splitext(sys.argv[0])[0] + 'seed{}-{}'.format(str(Seed),str(int(nd/NL))) + '-params.pickle')
            with open(fnModel, mode = 'wb') as f:
                torch.save(model.state_dict(), f)
        model.train()  # setting the module in training mode
        ib = np.random.randint(0, nbatchL)
        ii = np.where(bindexL[ib, :])[0]
        optimizer.zero_grad()
        output = model(XL[ii, :])
        loss = F.nll_loss(output, YL[ii])
        loss.backward()
        optimizer.step()

        nd += ii.shape[0]

    print('# elapsed time: ', datetime.datetime.now() - start)
    
    ### saving the model
    #
    fnModel = os.path.join(PATH_RESULT, os.path.splitext(sys.argv[0])[0] + 'seed{}-params.pickle'.format(Seed))
    with open(fnModel, mode = 'wb') as f:
        torch.save(model.state_dict(), f)
        print('# The model is saved to ', fnModel)

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テスト用プログラム

import os
import sys
import pickle
import numpy as np
import datetime

import torch
import torch.nn as nn
import torch.nn.functional as F

import getdata
import cnnL


if __name__ == '__main__':

    ### device
    #
    use_gpu_if_available = True
    if use_gpu_if_available and torch.cuda.is_available():
        device = torch.device('cuda')
    else:
        device = torch.device('cpu')
    print('# using', device)

    ### initializing the network
    #
    fnModel = os.path.join(cnnL.PATH_RESULT,'cnnL-params.pickle')
    torch.manual_seed(0)
    nn = cnnL.NN()
    with open(fnModel, mode = 'rb') as f:
        nn.load_state_dict(torch.load(f))
    model = nn.to(device)

    ### reading and preparing the training data
    #
    data = getdata.Data(cnnL.PATH_MNIST, nV = 10000)

    D = data.nrow * data.ncol
    K = data.nclass
    datTraw, labT = data.getData('T')
    datT = datTraw.reshape((-1, 1, data.nrow, data.ncol))
    NT = datT.shape[0]

    ### to torch.Tensor
    #
    XT = torch.from_numpy(datT.astype(np.float32)).to(device)
    YT = torch.from_numpy(labT).to(device)
    
    ### evaluation
    #
    batchsize = 100
    bindexT = getdata.makeBatchIndex(NT, batchsize)
    model.eval()  # setting the module in evaluation mode
    start = datetime.datetime.now()
    lossT, accT = cnnL.evaluate(model, XT, YT, bindexT)
    print('# elapsed time: ', datetime.datetime.now() - start)
    print('{:.4f} {:.2f}'.format(lossT, accT*100))

Answer 1

コードにキャッチアップできず申し訳ないのですが、問題を切り分けるための提案をさせてください。

まず、原因はevaluateの実装にある可能性が高いので、nnの実装からこれを切り離して考えます。

関数evaluateの引数X, Y, bindex、および関数の中のoutput = model(X[ii, ::])を手で作った簡単な配列に置き換え、混合行列とncorrectの出力を見てみます。どちらが期待される値と異なっていますか？

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よりよい回答を得るために、こちらも参考にしてみてください。

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