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这篇文章主要讲解了keras如何打印loss对权重的导数,内容清晰明了,对此有兴趣的小伙伴可以学习一下,相信大家阅读完之后会有帮助。
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怀疑模型梯度爆炸,想打印模型 loss 对各权重的导数看看。如果如果fit来训练的话,可以用keras.callbacks.TensorBoard实现。
但此次使用train_on_batch来训练的,用K.gradients和K.function实现。
Codes
以一份 VAE 代码为例
# -*- coding: utf8 -*- import keras from keras.models import Model from keras.layers import Input, Lambda, Conv2D, MaxPooling2D, Flatten, Dense, Reshape from keras.losses import binary_crossentropy from keras.datasets import mnist, fashion_mnist import keras.backend as K from scipy.stats import norm import numpy as np import matplotlib.pyplot as plt BATCH = 128 N_CLASS = 10 EPOCH = 5 IN_DIM = 28 * 28 H_DIM = 128 Z_DIM = 2 (x_train, y_train), (x_test, y_test) = fashion_mnist.load_data() x_train = x_train.reshape(len(x_train), -1).astype('float32') / 255. x_test = x_test.reshape(len(x_test), -1).astype('float32') / 255. def sampleing(args): """reparameterize""" mu, logvar = args eps = K.random_normal([K.shape(mu)[0], Z_DIM], mean=0.0, stddev=1.0) return mu + eps * K.exp(logvar / 2.) # encode x_in = Input([IN_DIM]) h = Dense(H_DIM, activation='relu')(x_in) z_mu = Dense(Z_DIM)(h) # mean,不用激活 z_logvar = Dense(Z_DIM)(h) # log variance,不用激活 z = Lambda(sampleing, output_shape=[Z_DIM])([z_mu, z_logvar]) # 只能有一个参数 encoder = Model(x_in, [z_mu, z_logvar, z], name='encoder') # decode z_in = Input([Z_DIM]) h_hat = Dense(H_DIM, activation='relu')(z_in) x_hat = Dense(IN_DIM, activation='sigmoid')(h_hat) decoder = Model(z_in, x_hat, name='decoder') # VAE x_in = Input([IN_DIM]) x = x_in z_mu, z_logvar, z = encoder(x) x = decoder(z) out = x vae = Model(x_in, [out, out], name='vae') # loss_kl = 0.5 * K.sum(K.square(z_mu) + K.exp(z_logvar) - 1. - z_logvar, axis=1) # loss_recon = binary_crossentropy(K.reshape(vae_in, [-1, IN_DIM]), vae_out) * IN_DIM # loss_vae = K.mean(loss_kl + loss_recon) def loss_kl(y_true, y_pred): return 0.5 * K.sum(K.square(z_mu) + K.exp(z_logvar) - 1. - z_logvar, axis=1) # vae.add_loss(loss_vae) vae.compile(optimizer='rmsprop', loss=[loss_kl, 'binary_crossentropy'], loss_weights=[1, IN_DIM]) vae.summary() # 获取模型权重 variable w = vae.trainable_weights print(w) # 打印 KL 对权重的导数 # KL 要是 Tensor,不能是上面的函数 `loss_kl` grad = K.gradients(0.5 * K.sum(K.square(z_mu) + K.exp(z_logvar) - 1. - z_logvar, axis=1), w) print(grad) # 有些是 None 的 grad = grad[grad is not None] # 去掉 None,不然报错 # 打印梯度的函数 # K.function 的输入和输出必要是 list!就算只有一个 show_grad = K.function([vae.input], [grad]) # vae.fit(x_train, # y_train, # 不能传 y_train # batch_size=BATCH, # epochs=EPOCH, # verbose=1, # validation_data=(x_test, None)) ''' 以 train_on_batch 方式训练 ''' for epoch in range(EPOCH): for b in range(x_train.shape[0] // BATCH): idx = np.random.choice(x_train.shape[0], BATCH) x = x_train[idx] l = vae.train_on_batch([x], [x, x]) # 计算梯度 gd = show_grad([x]) # 打印梯度 print(gd) # show manifold PIXEL = 28 N_PICT = 30 grid_x = norm.ppf(np.linspace(0.05, 0.95, N_PICT)) grid_y = grid_x figure = np.zeros([N_PICT * PIXEL, N_PICT * PIXEL]) for i, xi in enumerate(grid_x): for j, yj in enumerate(grid_y): noise = np.array([[xi, yj]]) # 必须秩为 2,两层中括号 x_gen = decoder.predict(noise) # print('x_gen shape:', x_gen.shape) x_gen = x_gen[0].reshape([PIXEL, PIXEL]) figure[i * PIXEL: (i+1) * PIXEL, j * PIXEL: (j+1) * PIXEL] = x_gen fig = plt.figure(figsize=(10, 10)) plt.imshow(figure, cmap='Greys_r') fig.savefig('./variational_autoencoder.png') plt.show()
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