The printed values *are not correct*. In your case `y`

is smaller than `1`

when using `float64`

and bigger or equal to `1`

when using `float32`

. this is expected since rounding errors depend on the size of the `float`

.

To avoid this kind of problems, when dealing with floating point numbers you should always decide a "minimum error", usually called `epsilon`

and, instead of comparing for equality, checking whether the result is at most distant `epsilon`

from the target value:

```
In [13]: epsilon = 1e-11
In [14]: number = np.float64(1) - 1e-16
In [15]: target = 1
In [16]: abs(number - target) < epsilon # instead of number == target
Out[16]: True
```

In particular, `numpy`

already provides `np.allclose`

which can be useful to compare arrays for equality given a certain tolerance. It works even when the arguments aren't arrays(e.g. `np.allclose(1 - 1e-16, 1) -> True`

).

Note however than `numpy.set_printoptions`

doesn't affect how `np.float32`

/`64`

are printed. It affects only how *arrays* are printed:

```
In [1]: import numpy as np
In [2]: np.float(1) - 1e-16
Out[2]: 0.9999999999999999
In [3]: np.array([1 - 1e-16])
Out[3]: array([ 1.])
In [4]: np.set_printoptions(precision=16)
In [5]: np.array([1 - 1e-16])
Out[5]: array([ 0.9999999999999999])
In [6]: np.float(1) - 1e-16
Out[6]: 0.9999999999999999
```

Also note that doing `print y`

or evaluating `y`

in the interactive interpreter gives different results:

```
In [1]: import numpy as np
In [2]: np.float(1) - 1e-16
Out[2]: 0.9999999999999999
In [3]: print(np.float64(1) - 1e-16)
1.0
```

The difference is that `print`

calls `str`

while evaluating calls `repr`

:

```
In [9]: str(np.float64(1) - 1e-16)
Out[9]: '1.0'
In [10]: repr(np.float64(1) - 1e-16)
Out[10]: '0.99999999999999989'
```

`y`

is less than one ni the`float64`

case, and is equal(or greater) to`1`

when using`float32`

due to rounding errors. When dealing with floating point values you whouldneveruse equal comparisons. Fix a minimum error(for example`epsilon=1e-16`

or smaller/bigger depending on the application) and do`if abs(number - 1) < epsilon: # number is sufficiently close to 1 to be considered as 1`

. – Bakuriu Aug 19 '13 at 10:01