• 吴裕雄--天生自然神经网络与深度学习实战Python+Keras+TensorFlow:生成型与条件型生成型对抗网络

    from keras.layers import LeakyReLU
from keras.layers import BatchNormalization
from keras.optimizers import RMSprop
import math

def  build_generator(inputs, image_size):
  '''
  生成者网络与编解码网络中的解码器如出一辙,输入给它的一维随机向量相当于输入解码器网络的编码向量,
  解码器网络将一维向量反向构造成图片所对应的二维向量,这也是生成者要做的工作,所以下面代码与我们做过
  的解码器网络几乎一模一样
  '''
  image_resize = image_size // 4
  kernel_size = 5
  layer_filters = [128, 64, 32, 1]
  
  x = Dense(image_resize * image_resize * layer_filters[0])(inputs)
  x = Reshape((image_resize, image_resize, layer_filters[0]))(x)
  
  #构造三层反卷积网络
  for filters in layer_filters:
    if filters > layer_filters[-2]:
      strides = 2
    else:
      strides = 1
    
    #使用batch normalization将输入反卷积网络的向量做预处理,没有这一步GAN的训练就会失败
    x = BatchNormalization()(x)
    x = Activation('relu')(x)
    x = Conv2DTranspose(filters = filters, kernel_size = kernel_size,
                       strides = strides,
                       padding = 'same')(x)
  
  x = Activation('sigmoid')(x)
  generator = Model(inputs, x, name = 'generator')
  return generator
    def  build_discriminator(inputs):
  '''
  识别者网络与编码器很像,它使用三层卷积网络从图片中抽取信息,最后使用sigmoid函数输出
  图片是否为真的概率
  '''
  kernel_size = 5
  layer_filters = [32, 64, 128, 256]
  x = inputs
  for filters in layer_filters:
    if filters == layer_filters[-1]:
      strides = 1
    else:
      strides = 2
    x = LeakyReLU(alpha = 0.2)(x)
    x = Conv2D(filters=filters, 
               kernel_size=kernel_size ,
              strides = strides,
              padding = 'same')(x)
    
  x = Flatten()(x)
  x = Dense(1)(x)
  x = Activation('sigmoid')(x)
  discriminator = Model(inputs, x, name='discriminator')
  return discriminator
    def  build_and_train_models():
  '''
  将生成者和识别者连城一个网络进行训练
  '''
  (x_train, _), (_, _) = mnist.load_data()
  image_size = x_train.shape[1]
  x_train = np.reshape(x_train, [-1, image_size, image_size, 1])
  x_train = x_train.astype('float32') / 255
  #设置训练相关的参数
  model_name = '/content/gdrive/My Drive/dcgan_mnist'
  latent_size = 100
  batch_size = 64
  train_steps = 40000
  lr = 2e-4
  decay = 6e-8
  input_shape = (image_size, image_size, 1)
  #构建识别者网络
  inputs = Input(shape = input_shape, name = 'discriminator_input')
  discriminator = build_discriminator(inputs)
  optimizer = RMSprop(lr = lr, decay = decay)
  discriminator.compile(loss = 'binary_crossentropy', optimizer = optimizer,
                       metrics = ['accuracy'])
  #构建生成者网络
  input_shape = (latent_size, )
  inputs = Input(shape = input_shape, name = 'z_input')
  generator = build_generator(inputs, image_size)
  optimizer = RMSprop(lr = lr * 0.5, decay = decay * 0.5)
  #将生成者和识别者连接成一个网络时要冻结识别者,因为训练生成者时识别者网络要保持不变
  discriminator.trainable = False
  adversarial = Model(inputs, discriminator(generator(inputs)),
                     name = model_name)
  adversarial.compile(loss = 'binary_crossentropy',
                     optimizer = optimizer,
                     metrics = ['accuracy'])
  
  models = (generator, discriminator, adversarial)
  params = (batch_size, latent_size, train_steps, model_name)
  train(models, x_train, params)
  
    def  train(models, x_train, params):
  '''
  训练时需要遵守的步骤是,先冻结生成者网络,把真实图片输入到识别者网络,训练识别者网络识别真实图片。
  然后冻结识别者网络,让生成者网络构造图片输入给识别者网络识别,根据识别结果来改进生成者网络
  '''
  #先获得生成者,识别者,以及两者的结合体
  generator, discriminator, adversarial = models
  batch_size, latent_size , train_steps, model_name = params
  save_interval = 500
  
  #构造给生成者网络的一维随机向量
  noise_input = np.random.uniform(-1.0, 1.0, size = [16, latent_size])
  train_size = x_train.shape[0]
  for i in range(train_steps):
    #先训练识别者网络,将真实图片和伪造图片同时输入识别者,让识别者学会区分真假图片
    rand_indexes = np.random.randint(0, train_size, size = batch_size)
    real_images = x_train[rand_indexes]
    noise = np.random.uniform(-1.0, 1.0, size = [batch_size, latent_size])
    #让生成者构造虚假图片
    fake_images = generator.predict(noise)
    x = np.concatenate((real_images, fake_images))
    y = np.ones([2 * batch_size, 1])
    #真实图片对应标签1,虚假图片对应标签0
    y[batch_size : , :] = 0.0
    loss, acc = discriminator.train_on_batch(x, y)
    log = "%d: [discriminator loss: %f, acc: %f]" % (i, loss, acc)
    
    #冻结识别者,让生成者构造一系列图片输入识别者,根据识别者识别结果改进生成者网络
    noise = np.random.uniform(-1.0, 1.0, size = [batch_size, latent_size])
    y = np.ones([batch_size, 1])
    #训练生成者时需要使用到识别者返回的结果,因此我们从两者连接后的网络进行训练
    loss, acc = adversarial.train_on_batch(noise, y)
    log = "%s [adversarial loss: %f, acc: %f]" % (log, loss, acc)
    print(log)
    if (i + 1) % save_interval == 0:
      if (i + 1) == train_steps:
        show = True
      else:
        show = False
      #将生成者构造的图片绘制出来
      plot_images(generator, noise_input = noise_input,
                 show = show, step = (i + 1),
                 model_name = model_name)
      #将生成者当前的网络参数存储成文件
    generator.save(model_name + ".h5")
  
    def  plot_images(generator, noise_input, show = False,
                step = 0,
                model_name = ''):
  os.makedirs(model_name, exist_ok = True)
  filename = os.path.join(model_name, "%05d.png" % step)
  images = generator.predict(noise_input)
  plt.figure(figsize = (2.2, 2.2))
  num_images = images.shape[0]
  image_size = images.shape[1]
  rows = int(math.sqrt(noise_input.shape[0]))
  for i in range(num_images):
    plt.subplot(rows, rows, i + 1)
    image = np.reshape(images[i], [image_size, image_size])
    plt.imshow(image, cmap= 'gray')
    plt.axis('off')
    
  plt.savefig(filename)
  if show:
    plt.show()
  else:
    plt.close('all')
    from google.colab import drive
drive.mount('/content/gdrive')

    from keras.datasets import mnist
from keras.layers import LeakyReLU
from keras.layers import Activation
from keras.optimizers import RMSprop
import os
 
build_and_train_models()

    from keras.models import load_model
import os

generator = load_model('/content/gdrive/My Drive/dcgan_mnist.h5')
#构造一批随机初始化的一维向量让生成者网络创造图片
noise = np.random.randint(-1.0, 1.0, size=[16, 100])
plot_images(generator, noise_input = noise,
           show = True, model_name="test_image")

    from keras.layers.merge import concatenate
from keras.utils import to_categorical

def build_cgan_discriminator(inputs, y_labels, image_size):
  '''
  识别图片,并将图片与输入的one-hot-vector关联起来
  '''
  kernel_size = 5
  layer_filters = [32, 64, 128, 256]
  x = inputs
  y = Dense(image_size * image_size)(y_labels)
  y = Reshape((image_size, image_size, 1))(y)
  #把图片数据与one-hot-vector拼接起来,这里是唯一与前面代码不同之处
  x = concatenate([x, y])
 
  for filters in layer_filters:
    if filters == layer_filters[-1]:
      strides = 1
    else:
      strides = 2
    x = LeakyReLU(alpha=0.2)(x)
    x = Conv2D(filters = filters,
              kernel_size = kernel_size,
              strides = strides,
              padding = 'same')(x)
    
  x = Flatten()(x)
  x = Dense(1)(x)
  x = Activation('sigmoid')(x)
  discriminator = Model([inputs, y_labels], x ,
                       name = 'discriminator')
  return discriminator
    def  build_cgan_generator(inputs, y_labels, image_size):
  '''
  生成者网络在构造图片时,需要将输入向量与对应的one-hot-vector结合在一起考虑
  '''
  image_resize = image_size // 4
  kernel_size = 5
  layer_filters = [128, 64, 32, 1]
  #将输入向量与One-hot-vector结合在一起
  x = concatenate([inputs, y_labels], axis = 1)
  x = Dense(image_resize * image_resize * layer_filters[0])(x)
  x = Reshape((image_resize, image_resize, layer_filters[0]))(x)
  for filters in layer_filters:
    if filters > layer_filters[-2]:
      strides = 2
    else:
      strides = 1
    
    x = BatchNormalization()(x)
    x = Activation('relu')(x)
    x = Conv2DTranspose(filters = filters,
                       kernel_size = kernel_size,
                       strides = strides,
                       padding = 'same')(x)
  x = Activation('sigmoid')(x)
  generator = Model([inputs, y_labels], x, name='generator')
  return generator
    def  train_cgan(models, data, params):
  generator, discriminator, adversarial = models
  #获取图片数据以及图片对应数字的one-hot-vector
  x_train, y_train = data
  batch_size, latent_size, train_steps, num_labels, model_name = params
  save_interval = 500
  noise_input = np.random.uniform(-1.0, 1.0, size=[16, latent_size])
  '''
  np.eye产生对角矩阵,例如np.eye(3) = [[1,0,0], [0,1,0], [0,0,1]],
  于是np.eye(3)[2, 3, 1] = [[0,1,0], [0,0,1], [1,0,0]]
  '''
  noise_class = np.eye(num_labels)[np.arange(0, 16) % num_labels]
  train_size = x_train.shape[0]
  print(model_name, "Labels for generated images: ", np.argmax(noise_class, 1))
  for i in range(train_steps):
    rand_indexes = np.random.randint(0, train_size, size = batch_size)
    real_images = x_train[rand_indexes]
    #增加图片对应的one-hot-vector
    real_labels = y_train[rand_indexes]
    
    noise = np.random.uniform(-1.0, 1.0, size = [batch_size, latent_size])
    #增加构造图片对应的one-hot-vector
    fake_labels = np.eye(num_labels)[np.random.choice(num_labels, batch_size)]
    fake_images = generator.predict([noise, fake_labels])
    #把真实图片和虚假图片连接起来
    x = np.concatenate((real_images, fake_images))
    #将真实图片对应的one-hot-vecotr和虚假图片对应的One-hot-vector连接起来
    y_labels = np.concatenate((real_labels, fake_labels))
    
    y = np.ones([2 * batch_size, 1])
    #上半部分图片为真,下半部分图片为假
    y[batch_size:, :] = 0.0
    #先训练识别者网络,这里需要将图片及对应的one-hot-vector输入
    loss, acc = discriminator.train_on_batch([x, y_labels], y)
    log = "%d: [discriminator loss : %f, acc: %f]" % (i, loss, acc)
    '''
    冻结识别者网络,构造随机一维向量以及指定数字的one-hot-vector输入生成者
    网络进行训练
    '''
    noise = np.random.uniform(-1.0, 1.0, size=[batch_size, latent_size])
    fake_labels = np.eye(num_labels)[np.random.choice(num_labels, batch_size)]
    y = np.ones([batch_size, 1])
    loss, acc = adversarial.train_on_batch([noise, fake_labels], y)
    log = "%s [adversarial loss :%f, acc: %f]" % (log, loss, acc)
    if (i + 1) % save_interval == 0:
      print(log)
      if (i+1) == train_steps:
        show = True
      else:
        show = False
      plot_images_cgan(generator, 
                 noise_input = noise_input,
                 noise_class = noise_class,
                 show = show,
                 step = (i+1),
                 model_name = model_name)
      generator.save(model_name + ".h5")
    def  build_and_train_models_cgan():
  (x_train, y_train), (_,_) = mnist.load_data()
  image_size = x_train.shape[1]
  x_train = np.reshape(x_train, [-1, image_size, image_size, 1])
  x_train = x_train.astype('float32') / 255
  #获得要生成数字的最大值
  num_labels = np.amax(y_train) + 1
  #转换为one-hot-vector
  y_train = to_categorical(y_train)
  
  model_name = "/content/gdrive/My Drive/cgan_mnist"
  latent_size = 100
  batch_size = 64
  train_steps = 40000
  lr = 2e-4
  decay = 6e-8
  input_shape = (image_size, image_size, 1)
  label_shape = (num_labels, )
  inputs = Input(shape=input_shape, name='discriminator_input')
  labels = Input(shape=label_shape, name = 'class_labels')
  #构建识别者网络时要传入图片对应的One-hot-vector
  discriminator = build_cgan_discriminator(inputs, labels, image_size)
  optimizer = RMSprop(lr=lr, decay = decay)
  discriminator.compile(loss='binary_crossentropy', 
                         optimizer=optimizer,
                         metrics = ['accuracy'])
  
  input_shape = (latent_size,)
  inputs = Input(shape=input_shape, name='z_input')
  #构造生成者时也要传入one-hot-vector
  generator = build_cgan_generator(inputs, labels, image_size)
  optimizer = RMSprop(lr = lr*0.5, decay = decay * 0.5)
  #将生成者和识别者连接起来时要冻结识别者
  discriminator.trainable = False
  outputs = discriminator([generator([inputs, labels]), labels])
  adversarial = Model([inputs, labels], outputs, name = model_name)
  adversarial.compile(loss ='binary_crossentropy',
                      optimizer = optimizer,
                      metrics = ['accuracy'])
  models = (generator, discriminator, adversarial)
  data = (x_train, y_train)
  params = (batch_size, latent_size, train_steps, num_labels, model_name)
  train_cgan(models, data, params)
    def  plot_images_cgan(generator, 
                 noise_input, 
                 noise_class,
                 show = False,
                step = 0,
                model_name = ''):
  os.makedirs(model_name, exist_ok = True)
  filename = os.path.join(model_name, "%05d.png" % step)
  images = generator.predict([noise_input, noise_class])
  print(model_name, "labels for generated images: ", np.argmax(noise_class, 
                                                               axis =1))
  plt.figure(figsize = (2.2, 2.2))
  num_images = images.shape[0]
  image_size = images.shape[1]
  rows = int(math.sqrt(noise_input.shape[0]))
  for i in range(num_images):
    plt.subplot(rows, rows, i + 1)
    image = np.reshape(images[i], [image_size, image_size])
    plt.imshow(image, cmap= 'gray')
    plt.axis('off')
    
  plt.savefig(filename)
  if show:
    plt.show()
  else:
    plt.close('all')
    from keras.layers import LeakyReLU
from keras.layers import BatchNormalization
from keras.optimizers import RMSprop
import math
from keras.layers import Activation, Dense, Input

build_and_train_models_cgan()
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  • 原文地址:https://www.cnblogs.com/tszr/p/12269774.html
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