# A bias free alternative.

Many of the other solutions use clipping to avoid an undefined gradient. Depending on your problem, clipping introduces bias and may not be acceptable in all cases. As the following code demonstrates, we need only handle the point of discontinuity--not the region near it.

# Specific Answer

```
def cross_entropy(x, y, axis=-1):
safe_y = tf.where(tf.equal(x, 0.), tf.ones_like(y), y)
return -tf.reduce_sum(x * tf.log(safe_y), axis)
def entropy(x, axis=-1):
return cross_entropy(x, x, axis)
```

*But did it work?*

```
x = tf.constant([0.1, 0.2, 0., 0.7])
e = entropy(x)
# ==> 0.80181855
g = tf.gradients(e, x)[0]
# ==> array([1.30258512, 0.60943794, 0., -0.64332503], dtype=float32) Yay! No NaN.
```

(Note: deleted dup cross-post.)

# General Recipe

Use an inner `tf.where`

to ensure the function has no asymptote.
That is, alter the input to the inf generating function such that no inf can be created.
Then use a second `tf.where`

to always select the valid code-path.
That is, implement the mathematical condition as you would "normally", i.e., the "naive" implementation.

In Python code, the recipe is:

Instead of this:

```
tf.where(x_ok, f(x), safe_f(x))
```

Do this:

```
safe_x = tf.where(x_ok, x, safe_x)
tf.where(x_ok, f(safe_x), safe_f(x))
```

## Example

Suppose you wish to compute:

```
f(x) = { 1/x, x!=0
{ 0, x=0
```

A naive implementation results in NaNs in the gradient, i.e.,

```
def f(x):
x_ok = tf.not_equal(x, 0.)
f = lambda x: 1. / x
safe_f = tf.zeros_like
return tf.where(x_ok, f(x), safe_f(x))
```

*Does it work?*

```
x = tf.constant([-1., 0, 1])
tf.gradients(f(x), x)[0].eval()
# ==> array([ -1., nan, -1.], dtype=float32)
# ...bah! We have a NaN at the asymptote despite not having
# an asymptote in the non-differentiated result.
```

The basic pattern for avoiding NaN gradients when using `tf.where`

is to call `tf.where`

twice. The innermost `tf.where`

ensures that the result `f(x)`

is always finite. The outermost `tf.where`

ensures the correct result is chosen. For the running example, the trick plays out like this:

```
def safe_f(x):
x_ok = tf.not_equal(x, 0.)
f = lambda x: 1. / x
safe_f = tf.zeros_like
safe_x = tf.where(x_ok, x, tf.ones_like(x))
return tf.where(x_ok, f(safe_x), safe_f(x))
```

*But did it work?*

```
x = tf.constant([-1., 0, 1])
tf.gradients(safe_f(x), x)[0].eval()
# ==> array([-1., 0., -1.], dtype=float32)
# ...yay! double-where trick worked. Notice that the gradient
# is now a constant at the asymptote (as opposed to being NaN).
```