# Number type boundaries in Common LISP and Stack flowing over in GHCI

First question ever here, and newbie in both Common LISP and Haskell, please be kind. I have a function in Common LISP - code below - which is intended to tell whether the area of a triangle is an integral number (integer?).

``````(defun area-int-p (a b c)
(let* ((s (/ (+ a b c) 2))
(area (sqrt (* s (- s a) (- s b) (- s c)))))
(if (equal (ceiling area) (floor area))
t
nil)))
``````

This is supposed to use Heron's formula to calculate the area of the triangle, given the size of the three sides, and decide whether it is an integer comparing the ceiling and the floor. We are told that the area of an equilateral triangle is never an integer. Therefore, to test whether the function is working, I ran it with the arguments `333`. Here is what I got in return:

``````CL-USER> (area-int-p 333 333 333)
NIL
``````

Perfect! It works. To test it even more, I ran it with the arguments `3333`. This is what I got in return:

``````CL-USER> (area-int-p 3333 3333 3333)
T
``````

Something is wrong, this is not supposed to happen! So, I try the following, hopefully equivalent Haskell function to see what happens:

``````areaIntP :: (Integral a) => a -> a -> a -> Bool
areaIntP a b c =
let aa = fromIntegral a
bb = fromIntegral b
cc = fromIntegral c
perimeter = aa + bb + cc
s = perimeter/2
area = sqrt(s * (s - aa) * (s - bb) * (s - cc))
in  if ceiling area == floor area
then True
else False
``````

This is what I get:

``````*Main> areaIntP 3333 3333 3333
False
*Main> areaIntP 333 333 333
False
``````

Looks perfect. Encouraged by this, I use the below functions in Haskell to sum the perimeters of of isosceles triangles with the third side differing just one unit from the other sides, an integral area, and perimeter below 1,000,000,000.

``````toplamArtilar :: Integral a => a -> a -> a -> a
toplamArtilar altSinir ustSinir toplam =
if ustSinir == altSinir
then toplam
else if areaIntP ustSinir ustSinir (ustSinir + 1) == True
then toplamArtilar altSinir (ustSinir - 1) (toplam + (3 * ustSinir + 1))
else toplamArtilar altSinir (ustSinir - 1) toplam

toplamEksiler :: Integral a => a -> a -> a -> a
toplamEksiler altSinir ustSinir toplam =
if ustSinir == altSinir
then toplam
else if areaIntP ustSinir ustSinir (ustSinir - 1) == True
then toplamEksiler altSinir (ustSinir - 1) (toplam + (3 * ustSinir - 1))
else toplamEksiler altSinir (ustSinir - 1) toplam

sonuc altSinir ustSinir =
toplamEksiler altSinir ustSinir (toplamArtilar altSinir ustSinir 0)
``````

(`ustSinir` means upper limit, `altSinir` lower limit by the way.) Running `sonuc` with the arguments `2` and `333333333` however, my stack flows over. Runnning the equivalent functions in Common LISP the stack is OK, but `area-int-p` function is not reliable, probably because of the boundaries of the number type the interpreter deduces. After all this, my question is two-fold:

1) How do I get round the problem in the Common LISP function `area-int-p`?

2) How do I prevent the stack overflow with the Haskell functions above, either within Emacs or with GHCi run from the terminal?

Note for those who figure out what I am trying to achieve here: please don't tell me to use Java `BigDecimal` and `BigInteger`.

Edit after very good replies: I asked two questions in one, and received perfectly satisfying, newbie friendly answers and a note on style from very helpful people. Thank you.

• This should be two separate questions. Oct 6, 2016 at 22:57
• You're right. I asked them together because I thought maybe both problems had something to do with the memory limit in emacs and could be fixed by changing some parameter about that. Of course that was before seeing luqui's answer about the Haskell part. Oct 7, 2016 at 5:19

Let's define an intermediate Common Lisp function:

``````(defun area (a b c)
(let ((s (/ (+ a b c) 2)))
(sqrt (* s (- s a) (- s b) (- s c)))))
``````

``````CL-USER> (area 333 333 333)
48016.344

CL-USER> (area 3333 3333 3333)
4810290.0
``````

In the second case, it should be clear that both the ceiling and floor are equal. This is not the case in Haskell where the second test, with 3333, returns:

``````4810290.040910754
``````

### Floating point

In Common Lisp, the value from which we take a square root is:

``````370222244442963/16
``````

This is because computations are made with rational numbers. Up to this point, the precision is maximal. However, `SQRT` is free to return either a rational, when possible, or an approximate result. As a special case, the result can be an integer on some implementations, as Rainer Joswig pointed out in a comment. It makes sense because both integer and ratio are disjoint subtypes of the rational type. But as your problem shows, some square roots are irrational (e.g. √2), and in that case CL can return a float approximating the value (or a complex float).

The relevant section regarding floats and mathematical functions is 12.1.3.3 Rule of Float Substitutability. Long story short, the result is converted to a `single-float` when you compute the square root, which happens to loose some precision. In order to have a double, you have to be more explicit:

``````(defun area (a b c)
(let ((s (/ (+ a b c) 2)))
(sqrt (float (* s (- s a) (- s b) (- s c)) 0d0))))
``````

I could also have used `(coerce ... 'double-float)`, but here I chose to call the `FLOAT` conversion function. The optional second argument is a float prototype, ie. a value of the target type. Above, it is `0d0`, a double float. You could also use `0l0` for long doubles or `0s0` for short. This parameter is useful if you want to have the same precision as an input float, but can be used with literals too, like in the example. The exact meaning of short, single, double or long float types is implementation-defined, but they shall respect some rules. Current implementations generally give more precision that the minimum required.

``````CL-USER> (area 3333 3333 3333)
4810290.040910754d0
``````

Now, if I wanted to test if the result is integral, I would truncate the float and look if the second returned value, the remainder, is zero.

``````CL-USER> (zerop (nth-value 1 (truncate 4810290.040910754d0)))
NIL
``````

### Arbitrary-precision

Note that regardless of the implementation language (Haskell, CL or another one) the approach is going to give incorrect results for some inputs, given how floats are represented. Indeed, the same problem you had with CL could arise for some inputs with more precise floats, where the result would be very close to an integer. You might need another mathematical approach or something like MPFR for arbitrary precision floating point computations. SBCL ships with `sb-mpfr`:

``````CL-USER> (require :sb-mpfr)
("SB-MPFR" "SB-GMP")

CL-USER> (in-package :sb-mpfr)
#<PACKAGE "SB-MPFR">
``````

And then:

``````SB-MPFR> (with-precision 256
(sqrt (coerce 370222244442963/16 'mpfr-float)))
.4810290040910754427104204965311207243133723228299086361205561385039201180068712e+7
-1
``````
• Yep, note also that in some implementations the result of (sqrt 9.0) may be an integer. Oct 7, 2016 at 8:13
• as an illustration, `(- (floor 370222244442964) (floor 370222244442963))` is `1`, but `(- (floor 370222244442964.0) (floor 370222244442963.0))` is `0`. Oct 7, 2016 at 10:52

I will answer your second question, I'm not sure about the first. In Haskell, because it's a lazy language, when you use tail recursion with an accumulator parameter, an "accumulation of thunks" can take place. A thunk is an expression that is suspended and not yet evaluated. To take a much simpler example, summing all the numbers from 0 to `n`:

``````tri :: Int -> Int -> Int
tri 0 accum = accum
tri n accum = tri (n-1) (accum + n)
``````

If we trace the evaluation, we can see what's going on:

``````tri 3 0
= tri (3-1) (0+3)
= tri 2 (0+3)
= tri (2-1) ((0+3)+2)
= tri 1 ((0+3)+2)
= tri (1-1) (((0+3)+2)+1)
= tri 0 (((0+3)+2)+1)
= ((0+3)+2)+1     -- here is where ghc uses the C stack
= (0+3)+2        (+1) on stack
= 0+3            (+2) (+1) on stack
= 0              (+3) (+2) (+1) on stack
= 3              (+2) (+1) on stack
= 5              (+1) on stack
= 6
``````

This is a simplification of course, but it's an intuition that can help you understand both stack overflows and space leaks caused by thunk buildup. GHC only evalues a thunk when it's needed. We ask whether the value of `n` is 0 each time through `tri` so there is no thunk buildup in that parameter, but nobody needs to know the value of `accum` until the very end, which might be a really huge thunk as you can see from the example. In evaluating that huge thunk the stack can overflow.

The solution is to make `tri` evaluate `accum` sooner. This is usually done using a `BangPattern` (but can be done with `seq` if you don't like extensions).

``````{-# LANGUAGE BangPatterns #-}
tri :: Int -> Int -> Int
tri 0 !accum = accum
tri n !accum = tri (n-1) (accum + n)
``````

The `!` before `accum` means "evaluate this parameter at the moment of pattern matching" (even though the pattern doesn't technically need to know its value). Then we get this evaluation trace:

``````tri 3 0
= tri (3-1) (0+3)
= tri 2 3          -- we evaluate 0+3 because of the bang pattern
= tri (2-1) (3+2)
= tri 1 5
= tri (1-1) (5+1)
= tri 0 6
= 6
``````

I hope this helps.

• Thanks four your effort. I'm reading about `BangPatterns`. I'm keeping the question open though, in the hope of getting an answer about the Common LISP part. Oct 7, 2016 at 5:29

``````(if (predicate? ...) t nil)
``````(predicate? ...)
You are checking with your `IF`, if `T` is `T` and then return `T`. But `T` is already `T`, so you can just return it.