一小时学会TensorFlow2之自定义层
目录
- 概述
- Sequential
- Model & Layer
- 案例
- 数据集介绍
- 完整代码
概述
通过自定义网络, 我们可以自己创建网络并和现有的网络串联起来, 从而实现各种各样的网络结构http://www.cppcns.com.
Sequential
Sequential 是 Keras 的一个网络容器. 可以帮助我们将多层网络封装在一起.
通过 Sequential 我们可以把现有的层已经我们自己的层实现结合, 一次前向传播就可以实现数据从第一层到最后一层的计算.
格式:
tf.keras.Sequential( layers=None, name=None )
例子:
# 5层网络模型 model = tf.keras.Sequential([ tf.keras.layers.Dense(256, activation=tf.nn.relu), tf.keras.layers.Dense(128, activation=tf.nn.relu), tf.keras.layers.Dense(64, activation=tf.nn.relu), tf.keras.layers.Dense(32, activation=tf.nn.relu), tf.keras.layers.Dense(10) ])
Model & Layer
通过 Model 和 Layer 的__init__
和call()
我们可以自定义层和模型.
Model:
class My_Model(tf.keras.Model): # 继承Model def __init__(self): """ 初始化 """ super(My_Model, self).__init__() self.fc1 = My_Dense(784, 256) # 第一层 self.fc2 = My_Dense(256, 128) # 第二层 self.fc3 = My_Dense(128, 64) # 第三层 self.fc4 = My_Dense(64, 32) # 第四层 self.fc5 = My_Dense(32, 10) # 第五层 def call(self, inputs, training=None): """ 在Model被调用的时候执行 :param inputs: 输入 :paaOqhEPURchram training: 默认为None :return: 返回输出 """ x = self.fc1(inputs) x = tf.nn.relu(x) x = self.fc2(x) x = tf.nn.relu(x) x = self.fc3(x) x = tf.nn.relu(x) x = self.fc4(x) x = tf.nn.relu(x) x = self.fc5(x) return x
Layer:
class My_Dense(tf.keras.layers.Layer): # 继承Layer def __init__(self, input_dim, output_dim): """ 初始化 :param input_dim: :param output_dim: """ super(My_Dense, self).__init__() # 添加变量 self.kernel = self.add_variable("w", [input_dim, output_dim]) # 权重 self.bias = self.add_variable("b", [output_dim]) # 偏置 def call(self, inputs, training=None): """ 在Layer被调用的时候执行, 计算结果 :param inputs: 输入 :param training: 默认为None :return: 返回计算结果 """ # y = w * x + b out = inputs @ self.kernel + self.bias return out
案例
数据集介绍
CIFAR-10 是由 10 类不同的物品组成的 6 万张彩色图片的数据集. 其中 5 万张为训练集, 1 万张为测试集.
完整代码
import tensorflow as tf def pre_process(x, y): # 转换x x = 2 * tf.cast(x, dtype=tf.float32) / 255 - 1 # 转换为-1~1的形式 x = tf.reshape(x, [-1, 32 * 32 * 3]) # 把x铺平 # 转换y y = tf.convert_to_tensor(y) # 转换为0~1的形式 y = tf.one_hot(y, depth=10) # 转成one_hot编码 # 返回x, y return x, y def get_data(): """ 获取数据 :return: """ # 获取数据 (X_train, y_train), (X_test, y_test) = tf.keras.datasets.cifar10.load_data() # 调试输出维度 print(X_train.shape) # (50000, 32, 32, 3) print(y_train.shape) # (50000, 1) # squeeze y_train = tf.squeeze(y_train) # (50000, 1) => (50000,) y_test = tf.squeeze(y_test) # (10000, 1) => (10000,) # 分割训练集 train_db = tf.data.Dataset.from_tensor_slices((X_train, y_train)).shuffle(10000, seed=0) train_db = train_db.batch(batch_size).map(pre_process).repeat(iteration_num) # 迭代20次 # 分割测试集 test_db = tf.data.Dataset.from_tensor_slices((X_test, y_test)).shuffle(10000, seed=0) test_db = test_db.batch(batch_size).map(pre_process) return train_db, test_db class My_Dense(tf.keras.layers.Layer): # 继承Layer def __init__(self, input_dim, output_dim): """ 初始化 :param input_dim: :param output_dim: """ super(My_Dense, self).__init__() 编程客栈 # 添加变量 self.kernel = self.add_weight("w", [input_dim, output_dim]) # 权重 self.bias = self.add_weight("b", [output_dim]) # 偏置 def call(self, inputs, training=None): """ 在Lahttp://www.cppcns.comyer被调用的时候执行, 计算结果 :param inputs: 输入 :param training: 默认为None :return: 返回计算结果 """ # y = w * x + b out = inputs @ self.kernel + self.bias return out class My_Model(tf.keras.Model): # 继承Model def __init__(self): """ 初始化 """ super(My_Model, self).__init__() self.fc1 = My_Dense(32 * 32 * 3, 256) # 第一层 self.fc2 = My_Dense(256, 128) # 第二层 self.fc3 = My_Dense(128, 64) # 第三层 aOqhEPURch self.fc4 = My_Dense(64, 32) # 第四层 self.fc5 = My_Dense(32, 10) # 第五层 def call(self, inputs, training=None): """ 在Model被调用的时候执行 :param inputs: 输入 :param training: 默认为None :return: 返回输出 """ x = self.fc1(inputs) x = tf.nn.relu(x) x = self.fc2(x) x = tf.nn.relu(x) x = self.fc3(x) x = tf.nn.relu(x) x = self.fc4(x) x = tf.nn.relu(x) x = self.fc5(x) return x # 定义超参数 batch_size = 256 # 一次训练的样本数目 learning_rate = 0.001 # 学习率 iteration_num = 20 # 迭代次数 optimizer = tf.keras.optimizers.Adam(learning_rate=learning_rate) # 优化器 loss = tf.losses.CategoricalCrossentropy(from_logits=True) # 损失 network = My_Model() # 实例化网络 # 调试输出summary network.build(input_shape=[None, 32 * 32 * 3]) print(network.summary()) # 组合 network.compile(optimizer=optimizer, loss=loss, metrics=["accuracy"]) if __name__ == "__main__": # 获取分割的数据集 train_db, test_db = get_data() # 拟合 network.fit(train_db, epochs=5, validation_data=test_db, validation_freq=1)
输出结果:
Model: "my__model"
_________________________________________________________________ Layer (type) Output Shape Param # ================================================================= my__dense (My_Dense) multiple 786688 _________________________________________________________________ my__dense_1 (My_Dense) multiple 32896 _________________________________________________________________ my__dense_2 (My_Dense) multiple 8256 _________________________________________________________________ my__dense_3 (My_Dense) multiple 2080 _________________________________________________________________ my__dense_4 (My_Dense) multiple 330 ================================================================= Total params: 830,250 Trainable params: 830,250 Non-trainable params: 0 _________________________________________________________________ None (50000, 32, 32, 3) (50000, 1) 2021-06-15 14:35:26.600766: I tensorflow/compiler/mlir/mlir_graph_optimization_pass.cc:176] None of the MLIR Optimization Passes are enabled (registered 2) Epoch 1/5 3920/3920 [==============================] - 39s 10ms/step - loss: 0.9676 - accuracy: 0.6595 - val_loss: 1.8961 - val_accuracy: 0.5220 Epoch 2/5 3920/3920 [==============================] - 41s 10ms/step - loss: 0.3338 - accuracy: 0.8831 - val_loss: 3.3207 - val_accuracy: 0.5141 Epoch 3/5 3920/3920 [==============================] - 41s 10ms/step - loss: 0.1713 - accuracy: 0.9410 - val_loss: 4.2247 - val_accuracy: 0.5122 Epoch 4/5 3920/3920 [==============================] - 41s 10ms/step - loss: 0.1237 - accuracy: 0.9581 - val_loss: 4.9458 - val_accuracy: 0.5050 Epoch 5/5 3920/3920 [==============================] - 42s 11ms/step - loss: 0.1003 - accuracy: 0.9666 - val_loss: 5.2425 - val_accuracy: 0.5097
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