Looking at the example in the documentation you link to:

```
with tf.device("/job:ps/task:0"):
weights_1 = tf.Variable(...)
biases_1 = tf.Variable(...)
with tf.device("/job:ps/task:1"):
weights_2 = tf.Variable(...)
biases_2 = tf.Variable(...)
with tf.device("/job:worker/task:7"):
input, labels = ...
layer_1 = tf.nn.relu(tf.matmul(input, weights_1) + biases_1)
logits = tf.nn.relu(tf.matmul(layer_1, weights_2) + biases_2)
# ...
train_op = ...
with tf.Session("grpc://worker7.example.com:2222") as sess:
for _ in range(10000):
sess.run(train_op)
```

You can see that the training is distributed on three machines which all share a copy of identical weights, but as is mentioned just below the example:

In the above example, the variables are created on two tasks in the ps job, and the compute-intensive part of the model is created in the worker job. TensorFlow will insert the appropriate data transfers between the jobs (from ps to worker for the forward pass, and from worker to ps for applying gradients).

In other words, one gpu is used to calculate the forward pass and then transmits the results to the other two machines, while each of the other machines calculate the back propagation for a part of the weights and then send the results to the other machines so they can all update their weights appropriately.

GPUs are used to speed up matrix multiplications and parallel mathematical operations which are very intensive for both forward pass and back propagation. So distributed training simply means that you distribute these operations on many GPUs, the model is still synced between the machines, but now the back propagation of different weights can be calculated in parallel and the forward pass on a different mini-batch can be calculated at the same time as backprop from the previous mini-batch is still being calculated. Distributed training does not mean that you have totally independent models and weights on each machine.