I am working with small numbers in `tensorflow`

, which sometimes results in **numerical instability**.

I would like to increase the precision of my results, or at the very least **determine bounds on my result**.

The following code shows a specific example of numerical errors (it outputs `nan`

instead of `0.0`

, because `float64`

is not precise enough to handle `1+eps/2`

):

```
import numpy as np
import tensorflow as tf
# setup
eps=np.finfo(np.float64).eps
v=eps/2
x_init=np.array([v,1.0,-1.0],dtype=np.float64)
x=tf.get_variable("x", initializer=tf.constant(x_init))
square=tf.reduce_sum(x)
root=tf.sqrt(square-v)
# run
with tf.Session() as session:
init = tf.global_variables_initializer()
session.run(init)
ret=session.run(root)
print(ret)
```

I am assuming there is no way to increase the precision of values in tensorflow. But maybe it is possible to set the rounding mode, as in C++ using `std::fesetround(FE_UPWARD)`

? Then, I could force tensorflow to always round up, which would make sure that I am taking the square root of a non-negative number.

**What I tried:** I tried to follow this question that outlines how to set the rounding mode for python/numpy. However, this does not seem to work, because the following code still prints `nan`

:

```
import numpy as np
import tensorflow as tf
import ctypes
FE_TONEAREST = 0x0000 # these constants may be system-specific
FE_DOWNWARD = 0x0400
FE_UPWARD = 0x0800
FE_TOWARDZERO = 0x0c00
libc = ctypes.CDLL('libm.so.6') # may need 'libc.dylib' on some systems
libc.fesetround(FE_UPWARD)
# setup
eps=np.finfo(np.float64).eps
v=eps/2
x_init=np.array([v,1.0,-1.0],dtype=np.float64)
x=tf.get_variable("x", initializer=tf.constant(x_init))
square=tf.reduce_sum(x)
root=tf.sqrt(square-v)
# run
with tf.Session() as session:
init = tf.global_variables_initializer()
session.run(init)
ret=session.run(root)
print(ret)
```

`square=tf.reduce_sum(x) # equals v`

followed by`root=tf.sqrt(square-v)`

`eps=np.finfo(np.float32).eps`

is unacceptably large?`0`

, but it returns`nan`

). In real life, these errors can e.g. occur when calculating the sample variance or sample correlation of an array.`eps`

is not too large in itself, but it can lead to wrong results due to cancellation (as`nan`

in my example).`tf.reduce_sum(x)`

with`x[0]+x[1]+x[2]`

, then you get`nan`

. I'm using tensorflow v1.3.0. How about you?`nan`

. So, something changed between v1.3 and v1.4 in reduce_sum that changes it's ability to handle intermediary results falling outside precision (and it's still there). If operations like reduce_sum were able to work like tf.reduce_sum does in v1.3.0, would that satisfy your requirements (if not your question)? (I'm assuming that you'll be doing vectorised operations like that)2more comments