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I have two integral variables a and b and a constant s resp. d. I need to calculate the value of (a*b)>>s resp. a*b/d. The problem is that the multiplication may overflow and the final result will not be correct even though a*b/d could fit in the given integral type.

How could that be solved efficiently? The straightforward solution is to expand the variable a or b to a larger integral type, but there may not be a larger integral type. Is there any better way to solve the problem?

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I infer that d is always 1<<s. Is that true? – Robᵩ Apr 4 '11 at 17:26
@pwny: That may result in reduced accuracy, particularly if d and b are large. – Oliver Charlesworth Apr 4 '11 at 17:35
What does resp. mean? – Swiss Apr 4 '11 at 17:38
@Swiss: ", respectively". – R.. Apr 4 '11 at 17:46
Do you want a rounded integral or a floating point as an answer? – Swiss Apr 4 '11 at 17:53
up vote 10 down vote accepted

If there isn't a larger type, you will either need to find a big-int style library, or deal with it manually, using long multiplication.

For instance, assume a and b are 16-bit. Then you can rewrite them as a = (1<<8)*aH + aL, and b = (1<<8)*bH + bL (where all the individual components are 8-bit numbers). Then you know that the overall result will be:

(a*b) = (1<<16)*aH*bH
      + (1<<8)*aH*bL
      + (1<<8)*aL*bH
      + aL*bL

Each of these 4 components will fit a 16-bit register. You can now perform e.g. right-shifts on each of the individual components, being careful to deal with carries appropriately.

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I think the problem as stated is that ab might not fit into 16 bits, although ab/d is guaranteed to fit. Thus your solution doesn't help. – Mark Ransom Apr 4 '11 at 17:40
@Mark Ransom: It does. With my method, you need no 32-bit values. – Oliver Charlesworth Apr 4 '11 at 17:42
Yes, this would work, but there seems to be some wasted calculations in this solution. I wonder if it could not be somehow merged with the division (right shift) to get a more efficient code. – Juraj Blaho Apr 4 '11 at 17:44
@Juraj: If s is larger than 8 or 16, then yes, you can eliminate some of the less-significant calculations. But in the general case, it's probably quicker to calculate all of them, rather than doing conditional operations. – Oliver Charlesworth Apr 4 '11 at 17:48
If s is a compile-time constant and you use templates (C++), the compiler will do all the necessary optimizations. – anatolyg Apr 4 '11 at 19:00

If the larger type is just 64 bits then the straight forward solution will most likely result in efficient code. On x86 CPUs any multiplication of two 32 bit numbers will give the overflow in another register. So if your compiler understands that, it can generate efficient code for Int64 result=(Int64)a*(Int64)b.

I had the same problem in C#, and the compiler generated pretty good code. And C++ compilers typically create better code than the .net JIT.

I recommend writing the code with the casts to the larger types and then inspect the generated assembly code to check if it's good.

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I have looked at disassembly and int32_t result = (int64_t(a)*int64_t(b))>>2 generates nice code (just imul for multiplication). But when the b is constant, compiler generates call _allmul. That seems a little strange. I will have to look deeper into it. – Juraj Blaho Apr 4 '11 at 20:41

I haven't exhaustively tested this, but could you do the division first, then account for the remainder, at the expense of extra operations? Since d is a power of two, all the divisions can be reduced to bitwise operations.

For example, always assume a > b (you want to divide the larger number first). Then a * b / d = ((a / d) * b) + (((a % d) * b) / d)

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I think (a % d) * b could still overflow (the largest possible value is (d-1)*b). – Oliver Charlesworth Apr 4 '11 at 17:50
you can use the same technique as Mark B explained for the ((a%d)*b)/d part, seeing a%d as b and b as a. – steabert Apr 4 '11 at 17:54
@steabart: Yes, that's true. You need to recurse as many times as it takes to be safe. – Oliver Charlesworth Apr 4 '11 at 18:08
divisions are expensive. So expensive that the VC++ compiler replaces a division(with constant denominator) by an overflowing multiplication combined with some bit fiddling. – CodesInChaos Apr 4 '11 at 19:20

In certain cases (historically LCG random number generators with selected constants), it is possible to do what you want, for some values of a and d.

This is called Schrage's method, see eg. there.

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