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I have a set of integers (x, y, z) and a function that takes 3 integers (u, v, w). How can I test if (x,y,z) == (u,v,w)? The naive way is:

bool match = (x == u || x == v || x == w) && (y == u || y == v || y == w) && (z == u || z == v || z == w);

Does anyone know of some smart bit operations/arithmetic to do the same thing?

Edit: I can assume that neither (x, y, z) or (u, v, w) contain duplicates.

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Before you make this "optimization," are you sure that this is an actual performance bottleneck in your program? –  James McNellis Mar 9 '11 at 20:59
(5, 42, -100) matches (42, 42, 42)? In your naive way it does! –  pmg Mar 9 '11 at 21:03
@pmg (42, 42, 42) isn't a strict set, it's a multiset. If you assume duplicates aren't allowed the original algorithm appears to work. –  Mark B Mar 9 '11 at 21:13
@Mark: ok, I can ask with the proper names rather than with a example. @user408952: do you mean strict sets or multisets? :D –  pmg Mar 9 '11 at 21:18
@pmg both sets are strict sets, not multisets. I updated the question to emphasize it. –  user408952 Mar 9 '11 at 21:23

5 Answers 5

up vote 3 down vote accepted

In this case, you can replace the logical operations by bitwise operations to eliminate the branching:

bool match = (x == u | x == v | x == w)
           & (y == u | y == v | y == w)
           & (z == u | z == v | z == w);

However, you would have to measure the performance effect to see if this is faster or slower.

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Now I feel a bit stupid :) Thanks. –  user408952 Mar 9 '11 at 21:33
Fred's comment is worth heeding though; that's always nine conditionals whereas your original implementation may finish in as few as three, in two separate ways. If the conditionals turn into branches as per the architecture and the compiler then the naive solution may perform better. –  Tommy Mar 9 '11 at 21:37
@Tommy: Yes, that's correct. You really need to profile this to see which one is the fastest. On this specific platform branching is so horrible that I would be surprised if the the branching version is faster. –  user408952 Mar 9 '11 at 21:50
@user408952: Is this what you were looking for? To me it seems like a version of your code but by replacing boolean with binary logic loosing the short-circuit. In your version and in this version you still have to do the branching based on the value of match. –  eznme Mar 9 '11 at 22:27
Of course, this assumes that the platform can perform a = (b==c) without a branch. If it can't, then this version is almost certainly slower. –  Robᵩ Mar 9 '11 at 23:35

You can eliminate a bunch of unequal vectors up front by converting to unsigned and comparing the sums before doing the real test.

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sums can overflow (above INT_MAX or below INT_MIN) and generate UB –  pmg Mar 9 '11 at 21:19
@pmg: integers can be converted to unsigned ;-p –  Steve Jessop Mar 9 '11 at 21:22
Converting to unsigned works :) ... I'm not sure adding first is an improvement though –  pmg Mar 9 '11 at 21:41

If a and b are the same then a^b is zero. So !(a^b) is non-zero only when a and b are the same. Supposing your platform can do logical 'not' without a branch, you can therefore test whether a is a member of (u, v, w) with a single branch using:

if(!(a^u) | !(a^v) | !(a^w))

And hence whether all of (x, y, z) are members of (u, v, w) using:

    (!(a^u) | !(a^v) | !(a^w))) &
    (!(b^u) | !(b^v) | !(b^w))) &
    (!(c^u) | !(c^v) | !(c^w))))

i.e. just doing a bitwise and on the various results, and again only a single branch.

If your platform needs a branch to perform !, e.g. if it's performed essentially as a ? 0 : -1, then that's ten conditionals and no better than the naive solution.

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If !(a ^ b) doesn't branch I imagine a decent compiler would compile a == b to !(a ^ b) for efficiency. Most implementations don't branch for ==. They have to branch on || and && to achieve the short-circuit behavior. –  Chris Lutz Mar 9 '11 at 21:37
You can reduce this to match = ~(((x^u)&(x^v)&(x^w))|((x^u)&...(z^w))), and avoid the logical ! –  AShelly Mar 9 '11 at 21:41
@AShelly is there not a risk that e.g. x and u will differ only in the seventh bit, x and v in the sixth, x and w in the fifth, and hence (x^u)&(x^v)&(x^w) will be zero even though x isn't equal to u, v or w? –  Tommy Mar 9 '11 at 21:46
@Tommy, good point - that's the danger of trying to treat bitwise operations exactly like the logical counterpart. I retract my comment. –  AShelly Mar 9 '11 at 21:49
@Chris Lutz: that would make my answer exactly equivalent in generated code to the accepted answer by FredOverflow, which I failed to spot in advance. But interesting to note. –  Tommy Mar 9 '11 at 21:50

In C there is no way to do this without branching.

If you are willing to inline-assembly you can do this with some CMPXCHG instructions.

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To be more specific: the chain you will have to program is this: x->u, x->v, x->w, A, y->u, y->v, y->w, B, z->u, z->v, z->w, C. "x->u" symbolizes x is in eax and u is the first cmpxchg operand (or other compare-and-swap on your platform). The second operand of the cmpxchg is always 1. You can then use the points marked with ABC to insert the cmpxchg's that compare the result (was the 1 set?) and swap the instructionpointer with the target of the jump. No branching. –  eznme Mar 9 '11 at 21:27

As pointed out in the comments, your 'naive' way matches whenever all the elements in (x,y,z) are contained in the set (u,v,w). If you really want to test if the sets are equivalent, you probably want

 (x==u && ((y==v && z==w) || (y==w && z==v))) ||
 (y==u && ((z==v && x==w) || (x==w && z==v))) ||
 (z==u && ((x==v && y==w) || (y==w && x==v)));

You can quickly filter out many mismatches with

  bad = (x+y+z) - (u+v+w);

Some processors have a non-branching 'min' and 'max' instructions, which would allow you to do

  a = min(x,y)
  b = max(x,y)
  c = min(b,z)
  x = min(a,c)
  y = max(a,c)
  z = max(b,z) 
  //repeat sorting sequence for u,v,w
  match = (x==u)&(y==v)&(z==w);
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Wikpedia: In computer science, a set is an abstract data structure that can store certain values, without any particular order, and no repeated values –  user408952 Mar 9 '11 at 21:17
Ok, with no repeats, the expanded test is unneeded, your method works. –  AShelly Mar 9 '11 at 21:28
Noted elsewhere already, but you should cast to an unsigned type (unless you're using one from the start) before summing to prevent overflow. –  Chris Lutz Mar 9 '11 at 21:32

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