Sometimes the shape of a tensor depends on a value that is computed at runtime. Let's take the following example, where `x`

is defined as a `tf.placeholder()`

vector with four elements:

```
x = tf.placeholder(tf.int32, shape=[4])
print x.get_shape()
# ==> '(4,)'
```

The value of `x.get_shape()`

is the static shape of `x`

, and the `(4,`

) means that it is a vector of length 4. Now let's apply the `tf.unique()`

op to `x`

```
y, _ = tf.unique(x)
print y.get_shape()
# ==> '(?,)'
```

The `(?,)`

means that `y`

is a vector of unknown length. Why is it unknown? `tf.unique(x)`

returns the unique values from `x`

, and the values of `x`

are unknown because it is a `tf.placeholder()`

, so it doesn't have a value until you feed it. Let's see what happens if you feed two different values:

```
sess = tf.Session()
print sess.run(y, feed_dict={x: [0, 1, 2, 3]}).shape
# ==> '(4,)'
print sess.run(y, feed_dict={x: [0, 0, 0, 0]}).shape
# ==> '(1,)'
```

Hopefully this makes it clear that a tensor can have a different static and dynamic shape. The dynamic shape is always fully definedâ€”it has no `?`

dimensionsâ€”but the static shape can be less specific. This is what allows TensorFlow to support operations like `tf.unique()`

and `tf.dynamic_partition()`

, which can have variable-sized outputs, and are used in advanced applications.

Finally, the `tf.shape()`

op can be used to get the dynamic shape of a tensor and use it in a TensorFlow computation:

```
z = tf.shape(y)
print sess.run(z, feed_dict={x: [0, 1, 2, 3]})
# ==> [4]
print sess.run(z, feed_dict={x: [0, 0, 0, 0]})
# ==> [1]
```

Here's a schematic image showing both: