Why is a**2 != a * a for some floats?

``````\$ python --version
Python 2.7.15

\$ type test.py
import random

while True:
a = random.uniform(0, 1)
b = a ** 2
c = a * a
if b != c:
print "a = {}".format(a)
print "a ** 2 = {}".format(b)
print "a * a = {}".format(c)
break

\$ python test.py
a = 0.145376687586
a ** 2 = 0.0211343812936
a * a = 0.0211343812936
``````

I was only able to reproduce this on a Windows build of Python - to be precise: `Python 2.7.15 (v2.7.15:ca079a3ea3, Apr 30 2018, 16:30:26) [MSC v.1500 64 bit (AMD64)] on win32`. On my Arch Linux box installation of Python (`Python 2.7.15 (default, May 1 2018, 20:16:04) [GCC 7.3.1 20180406] on linux2`) the loop does not seem to terminate indicating that the `a**2 = a * a` invariant holds there.

What is going on here? I know that IEEE floats come with a plethora of misconceptions and idiosyncrasies (this, for example, does not answer my question), but I fail to see what part of the specification or what kind of implementation of `**` could possibly allow for this.

To address the duplicate flagging: This is most likely not directly an IEEE floating point math problem and more of a implementation issue of the `**` operator. Therefore, this is not a duplicate of questions which are only asking about floating point issues such as precision or associativity.

• Use `repr` to show more digits so we can see exactly what value it's failing on and how. Jun 1 '18 at 20:03
• … or, since you're already using `format`, use `{.30}` or something. Jun 1 '18 at 20:04
• This is not a duplicate of "Is floating-point math broken". The OP is asking why `a ** 2` is not implemented as `a * a`. Jun 1 '18 at 20:04
• @EricPostpischil: Exponentiation isn't an operation IEEE 754 requires to be correctly rounded. Relying on `a**2 == a*a` is just going to lead to pain. Jun 1 '18 at 20:08
• Welcome to floating point, where nothing is precise. Seriously. This sort of stuff comes up all the time. We don't need a new question on every application of it. It should surprise us more when anything in floating works precisely the way math suggests. Jun 2 '18 at 4:26

Python relies on the underlying platform for its floating-point arithmetic. I hypothesize that Python’s `**` operator uses a `pow` implementation (as used in C) (confirmed by user2357112 referring to Python 2.7.15 source code).

Generally, `pow` is implemented by using (approximations of) logarithms and exponentials, in part. This is necessary since `pow` supports non-integer arguments. (Of course, this general implementation does not preclude specializations for subsets of its domain.)

Microsoft’s `pow` implementation is notoriously not good. Hence, for `pow(a, 2)`, it may be returning a result not equal to `a*a`.

• You can see the use of C `pow` in `float.__pow__` here. Jun 1 '18 at 20:11
• That `float_pow` implementation is of course only for CPython—but if you look into Jython, IronPython, or PyPy, you'll see that they use similar functions in Java, .NET, and RPython. Jun 1 '18 at 20:15
• I have a hunch that small integer powers are special cased at least on linux, indeed, of `a*a, a**2, math.exp(2*math.log(a))` the first two seem to be equal all the time, while the third often deviates. Jun 1 '18 at 20:19
• @PaulPanzer: That's not necessarily an indication that integer powers are special cased. On a platform that had perfectly correctly-rounded power, exp and log, you'd expect to see exactly the same results: `math.exp(2 * math.log(a))` will often deviate thanks to the extra rounding error of the intermediate `math.log(a)` value. That error is then potentially magnified by the `exp` call (depending on the value of `a`). A good implementation of `pow` should be doing something more sophisticated than `exp(y*log(x))`. Jun 3 '18 at 7:51

`a ** 2` uses a floating point power function (like the one you can find in the standard C math lib), which is able to elevate any number to any power.

`a * a` is just multiplying once, it's more suitable for this case, and not liable to precision errors, (even more true for integers), like `a ** 2` would be.

For floating point `a`, if you want to elevate to a power of, say, 5, by using

``````a * a * a * a * a
``````

you'd be better off with `a**5` because repeated multiplication is now liable to floating point accumulation error, and it's much slower.

`a ** b` is more interesting when `b` is large, because it's more efficient, for instance. But the precision may differ because it uses a floating point algorithm.

• `float.__pow__` does not use the `math.pow` function, at least not in CPython. They do, however, both ultimately use the same `pow` function from the C stdlib (after a bunch of pre-checks and conversions that are not identical for the two), which is probably what you should be saying here. Jun 1 '18 at 20:12
• yep, slightly inaccurate. Jun 1 '18 at 20:13
• Even a * a can have precision errors if the original uses enough digits. 2.5 * 2.5 would be fine but 2.123456789 * 2.123456789 will have some precision loss. Jun 2 '18 at 0:29
• @LorenPechtel `2.5*2.5` only works because it's exactly representable in binary with only a few bits. Try `2.2*2.2` (`4.840000000000001`). Jun 2 '18 at 4:43
• @jpmc26 Yes. I deliberately picked a value with a short representation in floating point so there would be no precision loss. Jun 3 '18 at 0:13