# Haskell sine and cosine functions not working

Okay, this is a pretty weird problem.

The built-in Haskell sine function (sin) does not seem to work.

`sin 0` gives, correctly, `0`.

`sin pi` gives, for whatever reason, `1.2246467991473532e-16`

These are using the built in prelude functions. I simply start up ghci (the Haskell interpreter), and type in `sin pi` and get the wrong answer.

Also, `cos (pi/2)` gives `6.123233995736766e-17`

Any ideas why this might be? It looks like the build in functions are simply wrong.. which seems extremely unlikely seeing how mathematically-oriented the Haskell standard library is.

edit: Heh, I just simply overlooked the e-16.. I guess that's what I get for coding late at night. Thanks anyhow everyone!

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Perhaps you should try `1 + sin pi` so you can see how close it actually is to the right answer. –  augustss Jul 10 '13 at 10:25
You can also install the numbers package and use the type `Data.Number.CReal.CReal` instead of `Double`. It's slow and accurate. –  augustss Jul 10 '13 at 10:28

This is Matlab

``````>> sin(pi)
ans =
1.2246e-016
``````

And here's Python

``````>>> from math import sin, pi
>>> sin(pi)
1.2246467991473532e-16
``````

You're running into the limits of floating point precision. I recommend having a read of What Every Computer Scientist Should Know About Floating Point Arithmetic.

The `e` at the end of these numbers indicates that they're in (a compact form of) scientific notation, and stands for "× 10^". For instance, in this notation, `2e3` corresponds to 2 × 103 = 2000. Here, you have a number that's multiplied by 10-16, which is tiny; written out in full, `1.2246467991473532e-16` = 0.00000000000000012246467991473532, so the amount of error is very small.

If you want accurate real-number computations in Haskell, you can use the `CReal` package as follows.

``````>>> import Data.Number.CReal
>>> sin (0.0  :: CReal)
0.0
>>> sin (pi   :: CReal)
0.0
>>> cos (pi/2 :: CReal)
0.0
``````

This works because "under the hood" a `CReal` is a function `Int -> Integer`. Given a number of digits `d` to output, the function produces the `Integer` that, when divided by `10^d`, would give the real number correct to `d` decimal places.

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The real problem here is `pi` itself. –  devnull Jul 10 '13 at 9:46
I understand about floating point precision, it just didn't occur to me since 1.2 is so far from 0. Do you know how, mathematically, this much error makes sense? –  Nathan Jul 10 '13 at 9:50
@Nathan The result is `1.22 * 10^(-16)` which is (relatively speaking) quite close to zero - it is roughly `0.000000000000000122`. –  Chris Taylor Jul 10 '13 at 9:58
@Nathan did you see the `e-16` there? This means the result is very close to zero. –  Ingo Jul 10 '13 at 10:01
Haha yeah, I just realized that a little bit ago. Simply overlooked the e-16. That's what I get for coding late at night. Thanks for the clarification guys. –  Nathan Jul 10 '13 at 20:52

The error in the double precision pi itself is -2.3846200000000026e-17, so losing another decimal in accuracy for a function like sin is not bad.

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