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In the software I'm writing, I'm doing millions of multiplication or division by 2 (or powers of 2) of my values. I would really like these values to be int so that I could access the bitshift operators

int a = 1;
int b = a<<24

However, I cannot, and I have to stick with doubles.

My question is : as there is a standard representation of doubles (sign, exponent, mantissa), is there a way to play with the exponent to get fast multiplications/divisions by a power of 2?

I can even assume that the number of bits is going to be fixed (the software will work on machines that will always have 64 bits long doubles)

P.S : And yes, the algorithm mostly does these operations only. This is the bottleneck (it's already multithreaded).

Edit : Or am I completely mistaken and clever compilers already optimize things for me?


Temporary results (with Qt to measure time, overkill, but I don't care):

#include <QtCore/QCoreApplication>
#include <QtCore/QElapsedTimer>
#include <QtCore/QDebug>

#include <iostream>
#include <math.h>

using namespace std;

int main(int argc, char *argv[])
{
QCoreApplication a(argc, argv);

while(true)
{
    QElapsedTimer timer;
    timer.start();

    int n=100000000;
    volatile double d=12.4;
    volatile double D;
    for(unsigned int i=0; i<n; ++i)
    {
        //D = d*32;      // 200 ms
        //D = d*(1<<5);  // 200 ms
        D = ldexp (d,5); // 6000 ms
    }

    qDebug() << "The operation took" << timer.elapsed() << "milliseconds";
}

return a.exec();
}

Runs suggest that D = d*(1<<5); and D = d*32; run in the same time (200 ms) whereas D = ldexp (d,5); is much slower (6000 ms). I know that this is a micro benchmark, and that suddenly, my RAM has exploded because Chrome has suddenly asked to compute Pi in my back every single time I run ldexp(), so this benchmark is worth nothing. But I'll keep it nevertheless.

On the other had, I'm having trouble doing reinterpret_cast<uint64_t *> because there's a const violation (seems the volatile keyword interferes)

share|improve this question
    
Don't assume that it's the bottleneck just because it's multithreaded. We had a multithreaded app that we found out was bottlenecked in many places different from what we expected? How accurately have you profiled? –  Chris A. Oct 11 '11 at 2:30
1  
As always, the application is never profiled enough. I mean, I used CacheGrind, and it seems I spend most of my time in a function that does mostly multiplications. It seems. But I wrote that it was the bottleneck because I'm more interested in the theoretical ideas behind the multiplication by 2 than in "petty considerations" (sure, I could optimize my SQL requests, but honestly, I'm pretty sure it'll be meaningless when compared to the multiplication stuff, and, mostly, I don't care ^^) –  Fezvez Oct 11 '11 at 2:47
1  
Yeah, I "know" ^^ But there's been talk about how you may obfuscate the compiler with weird stuff (basically, some operations boil down to *32 but the compiler doesn't "see" it). And it was just a line =) –  Fezvez Oct 11 '11 at 4:05
1  
What can I say else than : I used CacheGrind, and it seems I spend most of my time in a function that does mostly multiplications? Yeah, of course, the function also makes addition, and allocate data on the stack, but I guess I have a good estimate of the situation. –  Fezvez Oct 11 '11 at 10:09
1  
@Fezvez: 1) Your loop needs unrolling. 2) CacheGrind says you're mostly in some math routine? That's an alarm! Single-step the code at the assembly language level and make sure it's doing nothing more than you expect. It shouldn't be calling anything. 3) Multi-threading doesn't make code faster. It just spreads it out on more processors, at best. 4) If performance is what you actually care about, learn this technique. –  Mike Dunlavey Oct 11 '11 at 13:56

6 Answers 6

up vote 5 down vote accepted

You can pretty safely assume IEEE 754 formatting, the details of which can get pretty gnarley (esp. when you get into subnormals). In the common cases, however, this should work:

const int DOUBLE_EXP_SHIFT = 52;
const unsigned long long DOUBLE_MANT_MASK = (1ull << DOUBLE_EXP_SHIFT) - 1ull;
const unsigned long long DOUBLE_EXP_MASK = ((1ull << 63) - 1) & ~DOUBLE_MANT_MASK; 
void unsafe_shl(double* d, int shift) { 
    unsigned long long* i = (unsigned long long*)d; 
    if ((*i & DOUBLE_EXP_MASK) && ((*i & DOUBLE_EXP_MASK) != DOUBLE_EXP_MASK)) { 
        *i += (unsigned long long)shift << DOUBLE_EXP_SHIFT; 
    } else if (*i) {
        *d *= (1 << shift);
    }
} 

EDIT: After doing some timing, this method is oddly slower than the double method on my compiler and machine, even stripped to the minimum executed code:

    double ds[0x1000];
    for (int i = 0; i != 0x1000; i++)
        ds[i] = 1.2;

    clock_t t = clock();

    for (int j = 0; j != 1000000; j++)
        for (int i = 0; i != 0x1000; i++)
#if DOUBLE_SHIFT
            ds[i] *= 1 << 4;
#else
            ((unsigned int*)&ds[i])[1] += 4 << 20;
#endif

    clock_t e = clock();

    printf("%g\n", (float)(e - t) / CLOCKS_PER_SEC);

In the DOUBLE_SHIFT completes in 1.6 seconds, with an inner loop of

movupd xmm0,xmmword ptr [ecx]  
lea    ecx,[ecx+10h]  
mulpd  xmm0,xmm1  
movupd xmmword ptr [ecx-10h],xmm0

Versus 2.4 seconds otherwise, with an inner loop of:

add dword ptr [ecx],400000h
lea ecx, [ecx+8]  

Truly unexpected!

EDIT 2: Mystery solved! One of the changes for VC11 is now it always vectorizes floating point loops, effectively forcing /arch:SSE2, though VC10, even with /arch:SSE2 is still worse with 3.0 seconds with an inner loop of:

movsd xmm1,mmword ptr [esp+eax*8+38h]  
mulsd xmm1,xmm0  
movsd mmword ptr [esp+eax*8+38h],xmm1  
inc   eax

VC10 without /arch:SSE2 (even with /arch:SSE) is 5.3 seconds... with 1/100th of the iterations!!, inner loop:

fld         qword ptr [esp+eax*8+38h]  
inc         eax  
fmul        st,st(1)  
fstp        qword ptr [esp+eax*8+30h]

I knew the x87 FP stack was aweful, but 500 times worse is kinda ridiculous. You probably won't see these kinds of speedups converting, i.e. matrix ops to SSE or int hacks, since this is the worst case loading into the FP stack, doing one op, and storing from it, but it's a good example for why x87 is not the way to go for anything perf. related.

share|improve this answer
    
I'll try to see if it's efficient! –  Fezvez Oct 11 '11 at 2:21
1  
Somehow, I don't think a conditional branch is going to be faster than just doing an FP multiply. –  Nicol Bolas Oct 11 '11 at 2:59
    
I tend to agree, but you can always be surprised (well, I'd like to be surprised!) –  Fezvez Oct 11 '11 at 3:06
    
@Nicol: My understanding is that floating point is pretty slow on x86 - at least getting values into the FP stack and out again is. Regardless, this is how to do it if you want to avoid the FP stack in the (very) common case. –  Simon Buchan Oct 11 '11 at 3:13
4  
Note that using the plain old multiply has allowed the compiler to vectorise the loop - it's processing two doubles at a time. That's likely why it runs faster - and let that be a lesson to all who pass this way! ;) –  caf Oct 11 '11 at 6:04

This is one of those highly-application specific things. It may help in some cases and not in others. (In the vast majority of cases, a straight-forward multiplication is still best.)

The "intuitive" way of doing this is just to extract the bits into a 64-bit integer and add the shift value directly into the exponent. (this will work as long as you don't hit NAN or INF)

So something like this:

union{
    uint64 i;
    double f;
};

f = 123.;
i += 0x0010000000000000ull;

//  Check for zero. And if it matters, denormals as well.

Note that this code is not C-compliant in any way, and is shown just to illustrate the idea. Any attempt to implement this should be done directly in assembly or SSE intrinsics.

However, in most cases the overhead of moving the data from the FP unit to the integer unit (and back) will cost much more than just doing a multiplication outright. This is especially the case for pre-SSE era where the value needs to be stored from the x87 FPU into memory and then read back into the integer registers.

In the SSE era, the Integer SSE and FP SSE use the same ISA registers (though they still have separate register files). According the Agner Fog, there's a 1 to 2 cycle penalty for moving data between the Integer SSE and FP SSE execution units. So the cost is much better than the x87 era, but it's still there.

All-in-all, it will depend on what else you have on your pipeline. But in most cases, multiplying will still be faster. I've run into this exact same problem before so I'm speaking from first-hand experience.

Now with 256-bit AVX instructions that only support FP instructions, there's even less of an incentive to play tricks like this.

share|improve this answer
1  
Re "this will work as long as ...": it's not guaranteed to work at all. It may work for a given implementation but the standard explicitly states that this (setting one type of a union and using a different type to read it back) is not mandated. No downvote for this one since we're already into optimisation/non-standard-safe behaviour by the looks of it. –  paxdiablo Oct 11 '11 at 2:17
1  
@paxdiablo: Correct. We're already way beyond the standard. I threw this example out just to demonstrate the idea. It's more practically done using SSE registers. –  Mysticial Oct 11 '11 at 2:19
1  
@paxdiablo: It works when you know the machine's floating point representation. So long as you know this won't be run on VAXs (maybe some older IBM mainframes too), you know that will be IEEE 754. –  Simon Buchan Oct 11 '11 at 2:20
1  
SSE = Streaming SIMD Extensions, ISA = Instruction Set Architecture, FP = Floating-Point, AVX = Advanced Vector Extensions –  Mysticial Oct 11 '11 at 2:26
1  
@paxdiablo: Sure, aliasing rules in particular are a pain - I'm just against the somewhat common idea that it's somehow immoral to use non-portable code (obviously where it makes sense). –  Simon Buchan Oct 11 '11 at 2:35

How about ldexp?

Any half-decent compiler will generate optimal code on your platform.

But as @Clinton points out, simply writing it in the "obvious" way should do just as well. Multiplying and dividing by powers of two is child's play for a modern compiler.

Directly munging the floating point representation, besides being non-portable, will almost certainly be no faster (and might well be slower).

And of course, you should not waste time even thinking about this question unless your profiling tool tells you to. But the kind of people who listen to this advice will never need it, and the ones who need it will never listen.

[update]

OK, so I just tried ldexp with g++ 4.5.2. The cmath header inlines it as a call to __builtin_ldexp, which in turn...

...emits a call to the libm ldexp function. I would have thought this builtin would be trivial to optimize, but I guess the GCC developers never got around to it.

So, multiplying by 1 << p is probably your best bet, as you have discovered.

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VC does the same for most floating point operations - I beleive it's so it can respect precision control (_control87(), _controlfp(), etc...). Try fiddling with the floating precision compiler switches... –  Simon Buchan Oct 12 '11 at 1:36
1  
ldexp is 6 times slower than the regular x*pow(2,exp) source: benchmarked on intel Xeon –  Flavien Volken Apr 10 '12 at 19:51

The fastest way to do this is probably:

x *= (1 << p);

This sort of thing may simply be done by calling an machine instruction to add p to the exponent. Telling the compiler to instead extract the some bits with a mask and doing something manually to it will probably make things slower, not faster.

Remember, C/C++ is not assembly language. Using a bitshift operator does not necessarily compile to a bitshift assembly operation, not does using multiplication necessarily compile to multiplication. There's all sorts of weird and wonderful things going on like what registers are being used and what instructions can be run simultaneously which I'm not smart enough to understand. But your compiler, with many man years of knowledge and experience and lots of computational power, is much better at making these judgements.

p.s. Keep in mind, if your doubles are in an array or some other flat data structure, your compiler might be really smart and use SSE to multiple 2, or even 4 doubles at the same time. However, doing a lot of bit shifting is probably going to confuse your compiler and prevent this optimisation.

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I am unaware of any architecture with a "machine instruction to add p to the exponent". But maybe there should be one. –  masterxilo Oct 26 at 1:15

What other operations does this algorithm require? You might be able to break your floats into int pairs (sign/mantissa and magnitude), do your processing, and reconstitute them at the end.

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Erm, well, I do a bit of stuff here and there (matrix multiplication, etc...) I guess that might be a nice idea, but I think that'll be a load of work (redefining +, -, *, ...) –  Fezvez Oct 11 '11 at 2:26

Multiplying by 2 can be replaced by an addition: x *= 2 is equivalent to x += x.

Division by 2 can be replaced by multiplication by 0.5. Multiplication is usually significantly faster than division.

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That is totally true, but it becomes untractable as soon as I want to do something like x *= 33554432 –  Fezvez Oct 11 '11 at 3:07
    
@Fezvez, that multiplication is likely to be done by the floating point unit faster than any optimization you can come up with. –  Mark Ransom Oct 11 '11 at 3:11
    
Well, it's just adding 25 to the exponent, so I guess there's some sense behind my interrogations =) –  Fezvez Oct 11 '11 at 3:13
    
@Fezvez, don't underestimate the speed of the modern multiply instruction. If you doubt me, measure and see. –  Mark Ransom Oct 11 '11 at 4:14
    
I mean, the whole point of this post is to check whether there's a faster way to do some very specific kind of multiplications. I'm not saying there exists a faster way, but I find it legitimate to ask. –  Fezvez Oct 11 '11 at 10:08

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