# Find maximum of three number in C without using conditional statement and ternary operator

I have to find maximum of three number provided by user but with some restrictions. Its not allowed to use any conditional statement. I tried using ternary operator like below.

``````max=(a>b?a:b)>c?(a>b?a:b):c
``````

But again its restricted to use ternary operator. Now I am not getting any idea how to do this?

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This definitely falls in the "unlikely to help anyone in the future" category (unless they're a student of an incompetent educator). Use the tools you have, this sort of question indicates that your course is probably a waste of time. –  paxdiablo Aug 16 '11 at 5:42
@paxdiablo. Its not wastage of time. Rather its good challenge. There are some possible ways but restricted so challenge to find new ways.. –  Chirag Fanse Aug 16 '11 at 5:50
@Chirag, a challenge with no useful result is a useless challenge. In what piece of real world code would you ever use such a beast? You'd be tarred and feathered at a code review. John, if you want to teach someone about short circuit ops, there are better ways than using dubious puzzles. –  paxdiablo Aug 16 '11 at 6:03
@paxdiablo: Such puzzles are good for mental exercise, especially when you're student. :-) –  Nawaz Aug 16 '11 at 6:04
@paxdiablo: honestly i think this is a exercise in bit operations –  Foo Bah Aug 16 '11 at 6:08

Taking advantage of short-circuiting in boolean expressions:

``````int max(int a, int b, int c)
{
int m = a;
(m < b) && (m = b); //these are not conditional statements.
(m < c) && (m = c); //these are just boolean expressions.
return m;
}
``````

Explanation:

In boolean `AND` operation such as `x && y`, y is evaluated if and only if `x` is true. If `x` is false, then `y` is not evaluated, because the whole expression would be false which can be deduced without even evaluating `y`. This is called short-circuiting when the value of a boolean expression can be deduced without evaluating all operands in it.

Apply this principle to the above code. Initially `m` is `a`. Now if `(m < b)` is true, then that means, `b` is greater than `m` (which is actually `a`), so the second subexpression `(m = b)` is evaluated and `m` is set to `b`. If however `(m < b)` is false, then second subexpression will not be evaluated and `m` will remain `a` (which is greater than `b`). In a similar way, second expression is evaluated (on the next line).

In short, you can read the expression `(m < x) && (m = x)` as follows : set `m` to `x` if and only if `m` is less than `x` i.e `(m < x)` is true. Hope this helps you understanding the code.

Test code:

``````int main() {
printf("%d\n", max(1,2,3));
printf("%d\n", max(2,3,1));
printf("%d\n", max(3,1,2));
return 0;
}
``````

Output:

``````3
3
3
``````

Online Demo: http://www.ideone.com/8045P

Note the implementation of `max` gives warnings because evaluated expressions are not used:

prog.c:6: warning: value computed is not used
prog.c:7: warning: value computed is not used

To avoid these (harmless) warnings, you can implement `max` as:

``````int max(int a, int b, int c)
{
int m = a;
(void)((m < b) && (m = b)); //these are not conditional statements.
(void)((m < c) && (m = c)); //these are just boolean expressions.
return m;
}
``````

The trick is that now we're casting the boolean expressions to `void`, which causes suppression of the warnings:

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Can you provide bit explanation?? –  Chirag Fanse Aug 16 '11 at 5:46
Hah. That's clever and sneaky. –  GWW Aug 16 '11 at 5:46
@Chirag Fanse: He's taking advantage of short circuiting. –  GWW Aug 16 '11 at 5:47
@Foo, no, it's an expression with side effects, not a conditional. Naked expressions like `42;` are perfectly valid C statements (although not very useful without side effects). –  paxdiablo Aug 16 '11 at 5:56
+1 What a logic! –  Pankaj Kumar Aug 16 '11 at 8:17

Assuming you are dealing with integers, how about:

``````#define max(x,y) (x ^ ((x ^ y) & -(x < y)))
int max3(int x, int y, int z) {
return max(max(x,y),z);
}
``````
-

Just to add another alternative to avoid conditional execution (which is not the one I would use, but seemed missing from the set of solutions):

``````int max( int a, int b, int c ) {
int l1[] = { a, b };
int l2[] = { l1[ a<b ], c };
return l2[ l2[0] < c ];
}
``````

The approach uses (as most others), the fact that the result of a boolean expression when converted to int yields either 0 or 1. The simplified version for two values would be:

``````int max( int a, int b ) {
int lookup[] { a, b };
return lookup[ a < b ];
}
``````

If the expression `a<b` is correct we return `b`, carefully stored in the first index of the lookup array. If the expression yields false, then we return `a` that is stored as element `0` of the lookup array. Using this as a building block, you can say:

``````int max( int a, int b, int c ) {
int lookup[ max(a,b), c ];
return lookup[ max(a,b) < c ];
}
``````

Which can be trivially transformed to the code above by avoiding the second call to the inner `max` using the result already stored in `lookup[0]` and inlining the original call to `max(int,int)`.

(This part is just another proof that you have to measure before jumping into conclusions, see the edit at the end)

As to which would I actually use... well, probably the one by @Foo Baa here modified to use an inline function rather than a macro. The next option would be either this one or the one by @MSN here.

The common denominator of these three solutions not present in the accepted answer is that they do not only avoid the syntactic construct of `if` or the ternary operator `?:`, but that they avoid branching altogether, and that can have an impact in performance. The branch-predictor in the CPU cannot possibly miss when there are no branches.

When considering performance, first measure then think

I have actually implemented a few of the different options for a 2-way max, and analyzed the generated code by the compiler. The following three solutions generate all the same assembly code:

``````int max( int a, int b ) { if ( a < b ) return b; else return a; }
int max( int a, int b ) { return (a < b? b : a ); }
int max( int a, int b ) {
(void)((a < b) && (a = b));
return a;
}
``````

Which is not surprising, since all of the three represent the exact same operation. The interesting bit of information is that the generated code does not contain any branch. The implementation is simple with the `cmovge` instruction (test carried out with g++ in an intel x64 platform):

``````movl    %edi, %eax       # move a into the return value
cmpl    %edi, %esi       # compare a and b
cmovge  %esi, %eax       # if (b>a), move b into the return value
ret
``````

The trick is in the conditional move instruction, that avoids any potential branch.

None of the other solutions has any branches, but all of them translate to more cpu instructions than any of this, which at the end of the day reassures us that we should always write simple code and let the compiler optimize it for us.

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+1. I liked this solution. :-) –  Nawaz Aug 25 '11 at 9:43
+1 this is quite clever,good work! –  Serdalis Sep 29 '11 at 10:06
`cmovge` is a branch statement. It looks a the result of a previous conditional and takes an action accordingly. It happens to be a pretty good conditional instruction for this, but it's still a branch. –  Flexo Nov 11 '11 at 19:07
@awoodland: I don't think you can call that a branch, the code flow cannot possibly go in two directions. It does take into account the previous value to produce one or other outcome, but it cannot be mispredicted, it will not have to flush the instruction pipeline... It will probably be slower than other instructions (it cannot be reordered, the execution depends on the previous execution, so it cannot be parallelized with it...) but it does not branch, unless I am missing something here. –  David Rodríguez - dribeas Nov 11 '11 at 22:19
Its behaviour depends on the condition register which I would have said was the very definition of a branch. Logically its behaviour looks like a branch - the values in memory can become one of two things after the instruction has completed. If that can be predicted and consequently mis-predicted I'm less sure on for current processor designs. It's not inconceivable that a prediction of the "do nothing" path could be made erroneously and prediction/mis-prediction is not a prerequisite for an instruction being a branch anyway. (I agree it answers the question - it's not a conditional statement) –  Flexo Nov 11 '11 at 22:30

Ok, here's mine:

``````int max3(int a, int b, int c)
{
return a * (a > b & a > c) +
b * (b > a & b > c) +
c * (c > a & c > b);
}
``````

Note that the use of `&` rather than `&&` avoids any conditional code; it relies on the fact that `>` always yields 0 or 1. (The code generated for `a > b` might involve conditional jumps, but they're not visible from C.)

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``````int fast_int_max(int a, int b)
{
int select= -(a < b);

}

int fast_int_max3(int a, int b, int c)
{
return fast_int_max(a, fast_int_max(b, c));
}
``````
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Boolean valued operators (including <, &&, etc) typically translate to conditional operations at the machine code level, so don't fulfill the spirit of the challenge. Here's a solution that any reasonable compiler would translate to only arithmetic instructions with no conditional jumps (assuming long has more bits than int and that long is 64 bits). The idea is that "m" captures and replicates the sign bit of b - a, so m is either all 1 bits (if a > b) or all zero bits (if a <= b). Note that long is used to avoid overflow. If for some reason you know that b - a doesn't over/under-flow, then the use of long isn't needed.

``````int max(int a, int b)
{
long d = (long)b - (long)a;
int m = (int)(d >> 63);
return a & m | b & ~m;
}

int max(int a, int b, int c)
{
long d;
int m;
d = (long)b - (long)a;
m = (int)(d >> 63);
a = a & m | b & ~m;
d = (long)c - (long)a;
m = (int)(d >> 63);
return a & m | c & ~m;
}
``````
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No conditionals. Only a cast to uint. Perfect solution.

``````int abs (a) { return (int)((unsigned int)a); }
int max (a, b) { return (a + b + abs(a - b)) / 2; }
int min (a, b) { return (a + b - abs(a - b)) / 2; }

void sort (int & a, int & b, int & c)
{
int max = max(max(a,b), c);
int min = min(min(a,b), c);
int middle = middle = a + b + c - max - min;
a = max;
b = middle;
c = min;
}
``````
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``````#include "stdafx.h"
#include <iostream>
int main()
{
int x,y,z;
scanf("%d %d %d", &x,&y, &z);
int max = ((x+y) + abs(x-y)) /2;
max = ((max+z) + abs(max-z)) /2;
printf("%d ", max);
return 0;
}
``````
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``````int compare(int a,int b, intc)
{
return (a > b ? (a > c ? a : c) : (b > c ? b : c))
}
``````
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There's three ternary operators in this one. –  joar Sep 27 '12 at 10:17

No conditional statements, just loops and assignments. And completely different form others' answers :)

``````while (a > b)
{
while (a > c)
{
tmp = a;
goto finish;
}
tmp = c;
goto finish;
}
while (b > c)
{
tmp = b;
goto finish;
}
tmp = c;
finish: max = tmp;
``````
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``````max =  a > b ? ( a > c ? a : c ) : ( b > c ? b : c ) ;
``````
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@hari.I tried like this but again, you are using ternary operator which is not allowed... –  Chirag Fanse Aug 16 '11 at 5:45
That's a ternary by the way, already discounted as a possibility. –  paxdiablo Aug 16 '11 at 5:45