with tf.GradientTape() as tape:

        logits = mnist_model(images, training=True)

        loss_value = tf.losses.sparse_softmax_cross_entropy(labels, logits)

            #  loss_value 必须在tape内部

    grads = tape.gradient(loss_value, mnist_model.variables)

    optimizer.apply_gradients(zip(grads, mnist_model.variables),

                            global_step=tf.train.get_or_create_global_step())

# coding: utf-8

# pytorch: loss.backward(), optimizer.step()完成梯度计算和参数更新；

# tf2.0通过： grads = tape.gradient(), optimizer.apply_gradients()来实现！

# reference: https://github.com/aymericdamien/TensorFlow-Examples/blob/master/tensorflow_v2/notebooks/3_NeuralNetworks/convolutional_network.ipynb

from __future__ import absolute_import,division,print_function

import tensorflow as tf

from tensorflow.keras import Model, layers

import numpy as np

# MNIST dataset parameters.

num_classes = 10 # total classes (0-9 digits).

# Training parameters.

learning_rate = 0.001

training_steps = 200

batch_size = 128

display_step = 10

# Network parameters.

conv1_filters = 32 # number of filters for 1st conv layer.

conv2_filters = 64 # number of filters for 2nd conv layer.

fc1_units = 1024 # number of neurons for 1st fully-connected layer.

# Prepare MNIST data.

from tensorflow.keras.datasets import mnist

(x_train, y_train), (x_test, y_test) = mnist.load_data()

# Convert to float32.

x_train, x_test = np.array(x_train, np.float32), np.array(x_test, np.float32)

# Normalize images value from [0, 255] to [0, 1].

x_train, x_test = x_train / 255., x_test / 255.

# Use tf.data API to shuffle and batch data.

train_data = tf.data.Dataset.from_tensor_slices((x_train, y_train))

train_data = train_data.repeat().shuffle(5000).batch(batch_size).prefetch(1)

# Create TF Model.

class ConvNet(Model):

    # Set layers.

    def __init__(self):

        super(ConvNet, self).__init__()

        # Convolution Layer with 32 filters and a kernel size of 5.

        self.conv1 = layers.Conv2D(32, kernel_size=5, activation=tf.nn.relu)

        # Max Pooling (down-sampling) with kernel size of 2 and strides of 2.

        self.maxpool1 = layers.MaxPool2D(2, strides=2)

        # Convolution Layer with 64 filters and a kernel size of 3.

        self.conv2 = layers.Conv2D(64, kernel_size=3, activation=tf.nn.relu)

        # Max Pooling (down-sampling) with kernel size of 2 and strides of 2.

        self.maxpool2 = layers.MaxPool2D(2, strides=2)

        # Flatten the data to a 1-D vector for the fully connected layer.

        self.flatten = layers.Flatten()

        # Fully connected layer.

        self.fc1 = layers.Dense(1024)

        # Apply Dropout (if is_training is False, dropout is not applied).

        self.dropout = layers.Dropout(rate=0.5)

        # Output layer, class prediction.

        self.out = layers.Dense(num_classes)

    # Set forward pass.

    def call(self, x, is_training=False):

        x = tf.reshape(x, [-1, 28, 28, 1])

        x = self.conv1(x)

        x = self.maxpool1(x)

        x = self.conv2(x)

        x = self.maxpool2(x)

        x = self.flatten(x)

        x = self.fc1(x)

        x = self.dropout(x, training=is_training)

        x = self.out(x)

        if not is_training:

            # tf cross entropy expect logits without softmax, so only

            # apply softmax when not training.

            x = tf.nn.softmax(x)

        return x

# Build neural network model.

conv_net = ConvNet()

# Cross-Entropy Loss.

# Note that this will apply 'softmax' to the logits.

def cross_entropy_loss(x, y):

    # Convert labels to int 64 for tf cross-entropy function.

    y = tf.cast(y, tf.int64)

    # Apply softmax to logits and compute cross-entropy.

    loss = tf.nn.sparse_softmax_cross_entropy_with_logits(labels=y, logits=x)

    # Average loss across the batch.

    return tf.reduce_mean(loss)

# Accuracy metric.

def accuracy(y_pred, y_true):

    # Predicted class is the index of highest score in prediction vector (i.e. argmax).

    correct_prediction = tf.equal(tf.argmax(y_pred, 1), tf.cast(y_true, tf.int64))

    return tf.reduce_mean(tf.cast(correct_prediction, tf.float32), axis=-1)

# Stochastic gradient descent optimizer.

optimizer = tf.optimizers.Adam(learning_rate)

# Optimization process.

def run_optimization(x, y):

    # Wrap computation inside a GradientTape for automatic differentiation.

    with tf.GradientTape() as g:

        # Forward pass.

        pred = conv_net(x, is_training=True)

        # Compute loss.

        loss = cross_entropy_loss(pred, y)

    # Variables to update, i.e. trainable variables.

    trainable_variables = conv_net.trainable_variables

    # Compute gradients.

    gradients = g.gradient(loss, trainable_variables)

    # Update W and b following gradients.

    optimizer.apply_gradients(zip(gradients, trainable_variables))

# Run training for the given number of steps.

for step, (batch_x, batch_y) in enumerate(train_data.take(training_steps), 1):

    # Run the optimization to update W and b values.

    run_optimization(batch_x, batch_y)

    if step % display_step == 0:

        pred = conv_net(batch_x)

        loss = cross_entropy_loss(pred, batch_y)

        acc = accuracy(pred, batch_y)

        print("step: %i, loss: %f, accuracy: %f" % (step, loss, acc))

# Test model on validation set.

pred = conv_net(x_test)

print("Test Accuracy: %f" % accuracy(pred, y_test))