# Tensorflow NaN bug?

I'm using TensorFlow and I modified the tutorial example to take my RGB images.

The algorithm works flawlessly out of the box on the new image set, until suddenly (still converging, it's around 92% accuracy usually), it crashes with the error that ReluGrad received non-finite values. Debugging shows that nothing unusual happens with the numbers until very suddenly, for unknown reason, the error is thrown. Adding

``````print "max W vales: %g %g %g %g"%(tf.reduce_max(tf.abs(W_conv1)).eval(),tf.reduce_max(tf.abs(W_conv2)).eval(),tf.reduce_max(tf.abs(W_fc1)).eval(),tf.reduce_max(tf.abs(W_fc2)).eval())
print "max b vales: %g %g %g %g"%(tf.reduce_max(tf.abs(b_conv1)).eval(),tf.reduce_max(tf.abs(b_conv2)).eval(),tf.reduce_max(tf.abs(b_fc1)).eval(),tf.reduce_max(tf.abs(b_fc2)).eval())
``````

as debug code to each loop, yields the following output:

``````Step 8600
max W vales: 0.759422 0.295087 0.344725 0.583884
max b vales: 0.110509 0.111748 0.115327 0.124324
Step 8601
max W vales: 0.75947 0.295084 0.344723 0.583893
max b vales: 0.110516 0.111753 0.115322 0.124332
Step 8602
max W vales: 0.759521 0.295101 0.34472 0.5839
max b vales: 0.110521 0.111747 0.115312 0.124365
Step 8603
max W vales: -3.40282e+38 -3.40282e+38 -3.40282e+38 -3.40282e+38
max b vales: -3.40282e+38 -3.40282e+38 -3.40282e+38 -3.40282e+38
``````

Since none of my values is very high, the only way a NaN can happen is by a badly handled 0/0, but since this tutorial code doesn't do any divisions or similar operations, I see no other explanation than that this comes from the internal TF code.

I'm clueless on what to do with this. Any suggestions? The algorithm is converging nicely, its accuracy on my validation set was steadily climbing and just reached 92.5% at iteration 8600.

Actually, it turned out to be something stupid. I'm posting this in case anyone else would run into a similar error.

``````cross_entropy = -tf.reduce_sum(y_*tf.log(y_conv))
``````

is actually a horrible way of computing the cross-entropy. In some samples, certain classes could be excluded with certainty after a while, resulting in y_conv=0 for that sample. That's normally not a problem since you're not interested in those, but in the way cross_entropy is written there, it yields 0*log(0) for that particular sample/class. Hence the NaN.

Replacing it with

``````cross_entropy = -tf.reduce_sum(y_*tf.log(tf.clip_by_value(y_conv,1e-10,1.0)))
``````

solved all my problems.

• Glad you solved it! As an additional note, you might find convolutional.py a better starting point if you're handling real data. It's parameterized with NUM_CHANNELS at the top of the file, and if you switch it from 1 to 3, you should be good to go with RGB data. I've used it out of the box for classifying some larger RGB datasets that were downsized to "mnist size" (28x28) and it works pretty decently. The key is using tf.nn.softmax_cross_entropy_with_logits
– dga
Commented Nov 14, 2015 at 21:40
• @dga here's the updated link to convolution.py as it is no longer in the tensorflow master branch Commented Jan 9, 2017 at 14:37
• Note: this solution introduces bias. Ive posted an answer below which avoids this problem. Commented Feb 27, 2017 at 23:11
• Why not just `tf.nn.softmax_cross_entropy_with_logits(labels=y_,logits=y)` (usually no need to manually clip logits), instead of your `y_*tf.log(tf.clip_by_value(y_conv,1e-10,1.0))`? This was mentioned in the beginner tutorial. Commented Jun 7, 2017 at 16:09
• @YiboYang I think you should consider posting this comment as an answer. Pointing out that this was covered in the beginner tutorial is a valuable contribution here, since many people with this problem may have seen the hand-written formula in the tutorial and missed the pointer to `tf.nn.softmax_cross_entropy_with_logits` (like I did). It is helpful to be shown that the tutorial can still be trusted. Commented Oct 18, 2017 at 20:11

# 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.

``````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
# ==> 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:

``````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])
# ==> 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])
# ==> 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).
``````
• I was a bit confused about the behavior with your naive impl. and using `tf.where` twice to solve this but it's easy to understand if you plot yourself the computation graph of the gradient. At some point there is `grad(1./x, x) * 0.0` which will result in nan. Btw, `tf.cond` does not have this issue but this is not really an alternative in most cases. Commented Jul 14, 2017 at 11:33
• Hi Albert--thanks for pointing this out. I've corrected a few bugs in the general procedure and improved the example. Commented Jul 21, 2017 at 19:33
• This! Great answer! It should be part of an advanced TensorFlow Tutorial/docs or similar Commented Jan 30, 2019 at 14:27
• Note: Ive also documented this answer here: github.com/tensorflow/probability/blob/master/discussion/… Commented Apr 7, 2020 at 16:12

Actually, clipping is not a good idea as it will stop the gradient from propagating backwards when the threshold is reached. Instead we can add a little bit of constant to the softmax output.

``````cross_entropy = -tf.reduce_sum(y_*tf.log(y_conv + 1e-10))
``````
• This is exactly what I'm doing in my network, but I'm still getting NaNs when computing what amounts to the following: `tf.log(1e-10 + 1 - 1)`. If I print out the data and compute the same value in Excel I get the correct value of -23. Commented Feb 22, 2017 at 19:21
• @fwc, I encountered the same issue. Increasing it to something like `tf.log(1e-7+...)` solved the problem. Commented Sep 19, 2017 at 19:38
• @fwc I was able to reproduce this issue and filled a bug report here: github.com/tensorflow/tensorflow/issues/25728 Commented Feb 13, 2019 at 21:33

If `y_conv` is the result of a softmax, say, `y_conv = tf.nn.softmax(x)`, then an even better solution is to replace it with `log_softmax`:

``````y = tf.nn.log_softmax(x)
cross_entropy = -tf.reduce_sum(y_*y)
``````

You are trying to calculate cross-entropy using the standard formula. Not only the value is undefinined when `x=0`, it is also numerically unstable.

It is better to use tf.nn.softmax_cross_entropy_with_logits or if you really want to use hand-crafted formula, to tf.clip_by_value zeros to very small number in the log.

Sometimes you use `tf.sqrt()` function without adding a small constant `1e-10` in it, inducing this `nan` problem.

• derviative of sqrt at 0 is infinite which likely causes the instability. Commented Apr 29, 2019 at 14:21
• It can also be "hidden" : I was using `tf.math.reduce_euclidean_norm` with compute the true norm (sic) instead of the squared one usually used for trainings... Commented Apr 30, 2020 at 13:29

I used LSTM for long sequences and got nan gradients. None of these answers helped me. But I came up with three own solutions. I hope they will be useful for some other people who came here from google search.

1. Gradient clipping didn't help me because gradients turned nan in one batch update. In this case, you can replace nans with zeros with such lines:

``````opt = tf.train.AdamOptimizer(args.lr)
``````

If you want to track if nans appeared you can use this code:

``````was_nan = tf.reduce_any(tf.convert_to_tensor([tf.reduce_any(tf.is_nan(g)) for g in grads]))
``````
2. Replace LSTMCell with LayerNormBasicLSTMCell - an LSTM cell with layer norm - something similar to batch norm between timesteps.

3. If you use regular recurrent state dropout you can replace it with "Recurrent Dropout without Memory Loss". Code:

``````LayerNormBasicLSTMCell(neurons, dropout_keep_prob=0.8)
``````

Note that you can also turn on the dropout feature alone without layer normalization:

``````LayerNormBasicLSTMCell(neurons, layer_norm=False, dropout_keep_prob=0.8)
``````

Besides all the great answers above, I will add mine. It's a scenario less common to run into, but does cause NaN: divide by zero.

In my network for a NLP task, there is a layer that does average pooling. Namely, each data is a sequence of tokens. My layer does some token embedding and then calculates the average of the embedded vector.

The average calculation is coded as

``````tf.reduce_sum(embedded)/tf.reduce_sum(tf.not_equal(input, pad))
``````

Here `pad` is some dummy token I use in batch processing.

Now if some data contains empty token list (for whatever reason), its length (the denominator in the code snippet above) would be 0. Then it causes a divide by zero issue and the NaN will remain in all the following layers/ optimization steps.

In case anyone ran into this issue, I used `tf.where` to smooth those length:

``````sum_embedding = tf.reduce_sum(embedded, 1)
embedding_length = tf.reduce_sum(tf.cast(tf.not_equal(input, pad), dtype=tf.float32), axis=1, keep_dims=True)
embedding_length_smoothed = tf.where(tf.greater(embedding_length, 0.0), embedding_length, tf.ones(tf.shape(embedding_length)))
avg_embedding = sum_embedding / embedding_length_smoothed
``````

Essentially this treats all those data with 0-length token list to be of length 1, and avoids the NaN issue.

Here is the implementation of the binary (sigmoid) and categorical (softmax) cross-entropy losses in TensorFlow 1.1:

As one can see in the binary case they consider some special cases to achieve numerical stability:

``````# The logistic loss formula from above is
#   x - x * z + log(1 + exp(-x))
# For x < 0, a more numerically stable formula is
#   -x * z + log(1 + exp(x))
# Note that these two expressions can be combined into the following:
#   max(x, 0) - x * z + log(1 + exp(-abs(x)))
# To allow computing gradients at zero, we define custom versions of max and
# abs functions.
zeros = array_ops.zeros_like(logits, dtype=logits.dtype)
cond = (logits >= zeros)
relu_logits = array_ops.where(cond, logits, zeros)
neg_abs_logits = array_ops.where(cond, -logits, logits)
return math_ops.add(relu_logits - logits * labels,
math_ops.log1p(math_ops.exp(neg_abs_logits)),
name=name)
``````

`Tensorflow 1.x` to `Tensorflow 2.x`, is shown below:

Tensorflow 1.x :

`cross_entropy = -tf.reduce_sum(y_*tf.log(tf.clip_by_value(y_conv,1e-10,1.0)))`

Tensorflow 2.x:

`cross_entropy = -tf.compat.v2.reduce_sum(y_*tf.log(tf.compat.v2.clip_by_value(y_conv,1e-10,1.0)))`

or

`cross_entropy = -tf.compat.v2.math.reduce_sum(y_*tf.log(tf.compat.v1.clip_by_value(y_conv,1e-10,1.0)))`

I was getting nans sometimes and not other times while working on a standard feed-forward network. I have previously used similar TensorFlow code and it worked fine.

It turns out that I imported the variable names by accident. So, as soon as the first row (the variable names) was selected in a batch, the nan losses started. Maybe keep an eye out for that?

I will add here one of my previous problems with NaNs. I was using the sigmoid function as the activation of the last layer of my network. However, the sigmoid activation function uses the exponential function to be computed and I got some really big numbers entering the sigmoid.

It resulted in infinite gradients and some NaNs started to appear.

I've been using Tensorflow Estimator, which I believe account for those division by zero and other numerical stability issues, and occasionally get this error (`ERROR:tensorflow:Model diverged with loss = NaN during training`). Most of the time when I get this is because my inputs include `nan`s. So: be sure that your input dataframes (or whatever you use) don't have NaN values hidden somewhere in them.

Another option is to use `tf.math.xlogy` function. The function description says "Returns 0 if x == 0, and x * log(y) otherwise, elementwise." You can find the documentation here: https://www.tensorflow.org/api_docs/python/tf/math/xlogy

In `tf.log(y_conv)` if `y_conv` is the output of a sigmoid activation function, there is a better way to calculate `tf.log(y_conv)`.

Let `y_conv = sigmoid(x)`. Then,

``````   log(y_conv) = log(sigmoid(x))
=  log(1 / (1 + exp(-x)))
=  log(1 / (1 + exp(-x))) - x + x =
= -log(1 + exp(-x)) - log(exp(x)) + x =
= -log(1 + exp(x)) + x
=  x - softplus(x)
``````