# Neatest / Fastest Algorithm for Smallest Positive Number

Simple question - In c++, what's the neatest way of getting which of two numbers (u0 and u1) is the smallest positive number? (that's still efficient)

Every way I try it involves big if statements or complicated conditional statements.

Thanks, Dan

Here's a simple example:

bool lowestPositive(int a, int b, int& result)
{
//checking code
result = b;
return true;
}

lowestPositive(5, 6, result);
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Sorry, what's the answer if both are negative? –  Brent.Longborough Dec 26 '08 at 15:30
return false! ie - no answer, i'll edit the question to provide an example... –  Dan Dec 26 '08 at 15:32
What should result be? 0? Unchanged? lowest absolute value of the two? –  Joel Coehoorn Dec 26 '08 at 15:48

I prefer clarity over compactness:

bool lowestPositive( int a, int b, int& result )
{
if (a > 0 && a <= b) // a is positive and smaller than or equal to b
result = a;
else if (b > 0) // b is positive and either smaller than a or a is negative
result = b;
else
result = -1; // neither are positive

return result > 0;  // zero is not positive
}
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Cool. I prefer this clarity too :) –  Gant Dec 26 '08 at 16:37
And no constraints on the sign of the inputs. :) –  tvanfosson Dec 26 '08 at 16:41
almost perfect, it's probably always faster to return true or false right after the assignments (gcc actually tests the result again as it is now, even though it's already known whether the result is positive when the return statement is reached) –  mjy Dec 27 '08 at 1:19

If the values are represented in twos complement, then

result = ((unsigned )a < (unsigned )b) ? a : b;

will work since negative values in twos complement are larger, when treated as unsigned, than positive values. As with Jeff's answer, this assumes at least one of the values is positive.

return result >= 0;
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Clever. A bit of a kludge, but still clever. –  Tall Jeff Dec 26 '08 at 15:56
@tvanfosson: if both arguments are negative then result is negative and the function returns false therefore the concrete value of the result doesn't matter in this case. –  J.F. Sebastian Dec 26 '08 at 17:03
@Shmoopty: Could you provide an example when the function gives an incorrect answer? –  J.F. Sebastian Dec 26 '08 at 17:09
@JF -- I see now. Still the fact that I was able to miss that makes it a "magic" solution to me. I tend to avoid cleverness and go with the easier to read solution. In this case, the actual text of the answer threw me off. Another lesson: read the code, not the documentation! :-) –  tvanfosson Dec 26 '08 at 17:37
It is unclear whether OP considers positive or non-negative numbers therefore I've posted an answer for positive numbers i.e., excluding zero. stackoverflow.com/questions/393885/… –  J.F. Sebastian Dec 26 '08 at 19:22
unsigned int mask = 1 << 31;
while ((a & m) == (b & m)) {
m >>= 1;
}
result = (a & m) ? b : a;

EDIT: Thought this is not so interesting so I deleted it. But on the second thought, just leave it here for fun :) This can be considered as a dump version of Doug's answer :)

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This code being modded down is ridiculous. It does what it's meant to do, and rather cleverly I might add. So I vote +1. –  mstrobl Dec 26 '08 at 16:40
-1: Code should be concise and readable. Yours is neither. –  Juliet Dec 26 '08 at 16:40
The topic is inviting to play around a little. Why must we always be so earnest, Princess? :) Hey, it's clever code. Why waste it into the -1 nirvana? –  mstrobl Dec 26 '08 at 16:47
To cope with integers not 32 bits wide, what about a mask like (1 << std::numeric_limits<int>::digits) or without templates ((1 << (CHAR_BIT * (sizeof (int)-1))) << (CHAR_BIT-1)) –  Johannes Schaub - litb Dec 27 '08 at 0:44
Right. It's not meant to cope with different sizes. Another way to do it is (unsigned int) -1 ^ ( (unsigned int) -1 >> 1 ), which should work on almost any C compiler. –  PolyThinker Dec 27 '08 at 2:10

Might get me modded down, but just for kicks, here is the result without any comparisons, because comparisons are for whimps. :-)

bool lowestPositive(int u, int v, int& result)
{
result = (u + v - abs(u - v))/2;
return (bool) result - (u + v + abs(u - v)) / 2;
}

Note: Fails if (u + v) > max_int. At least one number must be positive for the return code to be correct. Also kudos to polythinker's solution :)

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That is really horrible. –  dmckee Dec 26 '08 at 17:25
Yes, it's called maths. And it's intended to be read tongue-in-cheek. :) –  mstrobl Dec 26 '08 at 17:28
@dmckee: Maybe this reads better as: "midpoint=(u+v)/2;dist=abs(u-v)/2; result = midpoint-dist;" --which shows that result does always get the smaller of the two values (irrespective of what the signs are) but that the "return (bool)result-(midpoint+dist);" returns true unless u=v: so it's wrong :P –  ShreevatsaR Dec 26 '08 at 18:16
@ShreevatsaR: I must admit, I did not test the code. Great analysis! ;) The incorrect return value boils down to an error in my thinking. return result > 0 is correct, but unfortunately has one of those whimpy comparisons in it. –  mstrobl Dec 26 '08 at 18:32
Don't mistake me. I'm suitably impressed. Deliberately using the wrong tool is cool, but only if it is really awkward. This one qualifies. –  dmckee Dec 26 '08 at 23:57

Here's a fast solution in C using bit twiddling to find min(x, y). It is a modified version of @Doug Currie's answer and inspired by the answer to the Find the Minimum Positive Value question:

bool lowestPositive(int a, int b, int* pout)
{
/* exclude zero, make a negative number to be larger any positive number */
unsigned x = (a - 1), y = (b - 1);
/* min(x, y) + 1 */
*pout = y + ((x - y) & -(x < y)) + 1;
return *pout > 0;
}

Example:

/** gcc -std=c99 *.c && a */
#include <assert.h>
#include <limits.h>
#include <stdio.h>
#include <stdbool.h>

void T(int a, int b)
{
int result = 0;
printf("%d %d ", a, b);
if (lowestPositive(a, b, &result))
printf(": %d\n", result);
else
printf(" are not positive\n");
}

int main(int argc, char *argv[])
{
T(5, 6);
T(6, 5);
T(6, -1);
T(-1, -2);

T(INT_MIN, INT_MAX);
T(INT_MIN, INT_MIN);
T(INT_MAX, INT_MIN);
T(0, -1);
T(0, INT_MIN);
T(-1, 0);
T(INT_MIN, 0);
T(INT_MAX, 0);
T(0, INT_MAX);
T(0, 0);

return 0;
}

Output:

5 6 : 5
6 5 : 5
6 -1 : 6
-1 -2  are not positive
-2147483648 2147483647 : 2147483647
-2147483648 -2147483648  are not positive
2147483647 -2147483648 : 2147483647
0 -1  are not positive
0 -2147483648  are not positive
-1 0  are not positive
-2147483648 0  are not positive
2147483647 0 : 2147483647
0 2147483647 : 2147483647
0 0  are not positive
-

Hack using "magic constant" -1:

enum
{
INVALID_POSITIVE = -1
};

int lowestPositive(int a, int b)
{
return (a>=0 ? ( b>=0 ? (b > a ? a : b ) : INVALID_POSITIVE ) : INVALID_POSITIVE );
}

This makes no assumptions about the numbers being positive.

-

Pseudocode because I have no compiler on hand:

////0 if both negative, 1 if u0 positive, 2 if u1 positive, 3 if both positive
switch((u0 > 0 ? 1 : 0) + (u1 > 0 ? 2 : 0)) {
case 0:
return false; //Note that this leaves the result value undef.
case 1:
result = u0;
return true;
case 2:
result = u1;
return true;
case 3:
result = (u0 < u1 ? u0 : u1);
return true;
default: //undefined and probably impossible condition
return false;
}

This is compact without a lot of if statements, but relies on the ternary " ? : " operator, which is just a compact if, then, else statement. "(true ? "yes" : "no")" returns "yes", "(false ? "yes" : "no") returns "no".

In a normal switch statement after every case you should have a break;, to exit the switch. In this case we have a return statement, so we're exiting the entire function.

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-1: Sorry, but this just isn't the type of code I'd want to see in production. There are more concise ways to get the results the OP wants, and the comment above your switch statement indicate that you're aware the code is so "clever" that its no longer readable. –  Juliet Dec 26 '08 at 16:37

I suggest you refactor the function into simpler functions. Furthermore, this allows your compiler to better enforce expected input data (though, what I've coded should produce a warning in the call to smallerInt)

unsigned int smallerInt( unsigned int a, unsigned int b )
{
return ( a < b ) ? a : b;
}

bool lowestPositive( int a, int b, int& result )
{
if ( a < 0 || b < 0 )
{
return false;
}

result = smallerInt( a, b );
return true;
}
-
That returns the highest positive. –  Doug Currie Dec 26 '08 at 15:47
Haha - good call. Fixed. Thanks Doug. –  antik Dec 26 '08 at 15:51
a = -1 b = 1 should return 1 but doesn't –  pro Dec 26 '08 at 16:10
According the problem set, I'm working on the set of integers > 0 both because my if statement enforces that and because that's what the OP asked for. Furthermore, what I'm trying to demonstrate is that by refactoring the function into smaller pieces, the logic becomes far simpler. –  antik Dec 26 '08 at 16:22
The sense of your first if statement is incorrect. It will return false if both a and b are positive, not false if a and b are negative. –  tvanfosson Dec 26 '08 at 16:35

This will handle all possible inputs as you request.

bool lowestPositive(int a, int b, int& result)
{
if ( a < 0 and b < 0 )
return false

result = std::min<unsigned int>( a, b );
return true;
}

That being said, the signature you supply allows sneaky bugs to appear, as it is easy to ignore the return value of this function or not even remember that there is a return value that has to be checked to know if the result is correct.

You may prefer one of these alternatives that makes it harder to overlook that a success result has to be checked:

boost::optional<int> lowestPositive(int a, int b)
{
boost::optional<int> result;
if ( a >= 0 or b >= 0 )
result = std::min<unsigned int>( a, b );
return result;
}

or

void lowestPositive(int a, int b, int& result, bool &success)
{
success = ( a >= 0 or b >= 0 )

if ( success )
result = std::min<unsigned int>( a, b );
}
-

tons of the answers here are ignoring the fact that zero isn't positive :)

with tricky casting and tern:

bool leastPositive(int a, int b, int& result) {
result = ((unsigned) a < (unsigned) b) ? a : b;
return result > 0;
}

less cute:

bool leastPositive(int a, int b, int& result) {
if(a > 0 && b > 0)
result = a < b ? a : b;
else
result = a > b ? a : b:
return result > 0;
}
-

With all due respect, your problem may be that the English phrase used to describe the problem really does hide some complexity (or at least some unresolved questions). In my experience, this is a common source of bugs and/or unfulfilled expectations in the "real world" as well. Here are some of the issues I observed:

• Some programmers use a naming convention in which a leading u implies unsigned, but you didn't state explicitly whether your "numbers" are unsigned or signed (or, for that matter, whether they are even supposed to be integral!)

• I suspect that all of us who read it assumed that if one argument is positive and the other is not, then the (only) positive argument value is the correct response, but that is not explicitly stated.

• The description also doesn't define the required behavior if both values are non-positive.

• Finally, some of the responses offered prior to this post seem to imply that the responder thought (mistakenly) that 0 is positive! A more specific requirements statement might help prevent any misunderstanding (or make it clear that the issue of zero hadn't been thought out completely when the requirement was written).

I'm not trying to be overly critical; I'm just suggesting that a more precisely-written requirement will probably help, and will probably also make it clear whether some of the complexity you're concerned about in the implementation is really implicit in the nature of the problem.

-

Three lines with the use (abuse?) of the ternary operator

int *smallest_positive(int *u1, int *u2) {
if (*u1 < 0) return *u2 >= 0 ? u2 : NULL;
if (*u2 < 0) return u1;
return *u1 < *u2 ? u1 : u2;
}

Don't know about efficiency or what to do if both u1 and u2 are negative. I opted to return NULL (which has to be checked in the caller); a return of a pointer to a static -1 might be more useful.

Edited to reflect the changes in the original question :)

bool smallest_positive(int u1, int u2, int& result) {
if (u1 < 0) {
if (u2 < 0) return false; /* result unchanged */
result = u2;
} else {
if (u2 < 0) result = u1;
else result = u1 < u2 ? u1 : u2;
}
return true;
}
-

My idea is based on using min and max. And categorized the result into three cases, where

• min <= 0 and max <= 0
• min <= 0 and max > 0
• min > 0 and max > 0

The best thing is that it's not look too complicated. Code:

bool lowestPositive(int a, int b, int& result)
{
int min = (a < b) ? a : b;
int max = (a > b) ? a : b;

bool smin = min > 0;
bool smax = max > 0;

if(!smax) return false;

if(smin) result = min;
else result = max;

return true;
}
-

After my first post was rejected, allow me to suggest that you are prematurely optimizing the problem and you shouldn't worry about having lots of if statements. The code you're writing naturally requires multiple 'if' statements, and whether they are expressed with the ternary if operator (A ? B : C) or classic if blocks, the execution time is the same, the compiler is going to optimize almost all of the code posted into very nearly the same logic.

Concern yourself with the readability and reliability of your code rather than trying to outwit your future self or anyone else who reads the code. Every solution posted is O(1) from what I can tell, that is, every single solution will contribute insignificantly to the performance of your code.

I would like to suggest that this post be tagged "premature optimization," the poster is not looking for elegant code.

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uint lowestPos(uint a, uint b) { return (a < b ? a : b); }

You are looking for the smallest positive, it is be wise to accept positive values only in that case. You don't have to catch the negative values problem in your function, you should solve it at an earlier point in the caller function. For the same reason I left the boolean oit.

A precondition is that they are not equal, you would use it like this in that way:

if (a == b)
cout << "equal";
else
{
uint lowest = lowestPos(a, b);
cout << (lowest == a ? "a is lowest" : "b is lowest");
}

You can introduce const when you want to prevent changes or references if you want to change the result. Under normal conditions the computer will optimize and even inline the function.

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Why did I get voted down? –  Tom Wijsman Dec 27 '08 at 1:20