# Why is Math.DivRem so inefficient

In my computer this code takes 17 seconds (1000 millons times)

``````static void Main(string[] args) {
var sw = new Stopwatch(); sw.Start();
int r;
for (int i = 1; i <= 100000000; i++) {
for (int j = 1; j <= 10; j++) {
MyDivRem (i,j, out r);
}
}
Console.WriteLine(sw.ElapsedMilliseconds);
}

static int MyDivRem(int dividend, int divisor, out int remainder) {
int quotient = dividend / divisor;
remainder = dividend - divisor * quotient;
return quotient;
}
``````

while Math.DivRem takes 27 seconds. Reflector gives me this code for Math.DivRem:

``````public static int DivRem(int a, int b, out int result)
{
result = a % b;
return (a / b);
}
``````

edit: IL

``````.method public hidebysig static int32 DivRem(int32 a, int32 b, [out] int32& result) cil managed
{
.maxstack 8
L_0000: ldarg.2
L_0001: ldarg.0
L_0002: ldarg.1
L_0003: rem
L_0004: stind.i4
L_0005: ldarg.0
L_0006: ldarg.1
L_0007: div
L_0008: ret
}
``````

Theorically it may be faster for computers with multiple cores, but in fact it shouldn't need to do two operations in the first place because x86 CPUs return both the quotient and remainder when they do a integer division using DIV or IDIV ( http://www.arl.wustl.edu/~lockwood/class/cs306/books/artofasm/Chapter_6/CH06-2.html#HEADING2-451 ) !!!

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what happens when you're running .NET on non-x86? –  Jimmy Jan 15 '09 at 15:53
x64 is a superset of x86 and if the CPU is not compatible with x86 is just a matter of using different code for the .net framework for that CPU –  ggf31416 Jan 15 '09 at 16:01
Right but .NET is also implemented as Mono and should therefore run on other archs such as ppc etc. –  André Jan 15 '09 at 20:41
You can't tell that by looking at the IL. Rather, you need to see what the JIT compiler actually produces. –  Mehrdad Afshari Apr 26 '09 at 16:27
Omg, I can't believe this! Today I've noticed in my app that calling DivRem is slightly slower than simply doing / and %. Now I tested your DivRem function and it's indeed considerably faster than both! (~20% on my PC.) –  Bus Sep 1 '10 at 13:19
show 1 more comment

Grrr. The only reason for this function to exist is to take advantage of the CPU instruction for this, and they didn't even do it!

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Wouldn't you have to look at the IL to prove this? –  Austin Salonen Jan 15 '09 at 16:08
No. If they did it that way .NET Reflector would tell you that this function is in the native stubs. –  Joshua Jan 15 '09 at 17:01
(for the record, though, the jitter doesn't actually do this in .NET 4: the disassembly includes two `idiv`s, two `cdq`s and a whole bunch of `mov`s) –  romkyns Aug 3 '11 at 11:12
@romkyns: If the jitter could do it for DivRem, then it could do it for your code. –  Joshua Jan 4 at 20:07

Wow, that really looks stupid, doesn't it?

The problem is that -- according to the Microsoft Press book ".NET IL Assembler" by Lidin -- the IL rem and div atithmetic instructions are exactly that: compute remainder and compute divisor.

All arithmetical operations except the negation operation take two operands from the stack and put the result on the stack.

Apparently, the way the IL assembler language is designed, it's not possible to have an IL instruction that produces two outputs and pushes them onto the eval stack. Given that limitation, you can't have a division instruction in IL assembler that computes both the way the x86 DIV or IDIV instructions do.

IL was designed for security, verifiability, and stability, NOT for performance. Anyone who has a compute-intensive application and is concerned primarily with performance will be using native code and not .NET.

I recently attended Supercomputing '08, and in one of the technical sessions, an evangelist for Microsoft Compute Server gave the rough rule of thumb that .NET was usually half the speed of native code -- which is exactly the case here!.

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While this is true, there is no reason that `Math.DivRem` can't be implemented in the runtime and marked with `[MethodImpl(MethodImplOptions.InternalCall), SecuritySafeCritical]` like many of the other methods on `System.Math` are. –  codekaizen Dec 28 '10 at 23:26
Do you have a source for the claim that IL is inherently unable to produce two values on the stack? I'm not saying it's false; it's easy to imagine the JITter making heavy use of this assumption, but a proper source would be handy. –  romkyns Jan 4 at 22:24

The answer is probably that nobody has thought this a priority - it's good enough. The fact that this has not been fixed with any new version of the .NET Framework is an indicator of how rarely this is used - most likely, nobody has ever complained.

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Does anyone else get the opposite when testing this?

``````Math.DivRem = 11.029 sec, 11.780 sec
MyDivRem = 27.330 sec, 27.562 sec
DivRem = 29.689 sec, 30.338 sec
``````

FWIW, I'm running an Intel Core 2 Duo.

The numbers above were with a debug build...

With the release build:

``````Math.DivRem = 10.314
DivRem = 10.324
MyDivRem = 5.380
``````

Looks like the "rem" IL command is less efficient than the "mul,sub" combo in MyDivRem.

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64 bits windows? –  ggf31416 Jan 15 '09 at 16:11
Nope... XP with SP3 –  Austin Salonen Jan 15 '09 at 16:13
I think you got it the wrong way around :) –  leppie Jan 15 '09 at 16:33
Wow, what CPU you have? –  leppie Jan 15 '09 at 16:49
@leppie -- release build data added but the numbers were accurate for the debug build. –  Austin Salonen Jan 15 '09 at 16:49
show 1 more comment

The efficiency may very well depend on the numbers involved. You are testing a TINY fraction of the available problem space, and all front-loaded. You are checking the first 1 million * 10 = 1 billion contiguous input combinations, but the actual problem space is approx 4.2 billion squared, or 1.8e19 combinations.

The performance of general library math operations like this needs to be amortized over the whole problem space. I'd be interested to see the results of a more normalized input distribution.

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Plus, I'd say performing 1 billion runs in under 30 seconds is pretty good, so what's the fuss? –  Michael Haren Jan 15 '09 at 17:52
I tested almost the entire space incrementing each variable by a large primes and Math.DivRem is still inefficient –  ggf31416 Jan 15 '09 at 19:54

Here's my numbers:

``````15170 MyDivRem
29579 DivRem (same code as below)
29579 Math.DivRem
30031 inlined
``````

Test slightly changed, added added assignment to return value. Running release build.

Core 2 Duo 2.4

Opinion;

You seemed to have found a nice optimization ;)

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If I had to take a wild guess, I'd say that whoever implemented Math.DivRem had no idea that x86 processors are capable of doing it in a single instruction, so they wrote it as two operations. That's not necessarily a bad thing if the optimizer works correctly, though it is yet another indicator that low-level knowledge is sadly lacking in most programmers nowadays. I would expect the optimizer to collapse modulus and then divide operations into one instruction, and the people who write optimizers should know these sorts of low-level things...

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just like the compiler or the JIT should replace Math.Pow(x,3) with x*x*x but that seems be asking too much... –  ggf31416 Jan 15 '09 at 17:27

I would guess that the majority of the added cost is in the set-up and tear-down of the static method call.

As for why it exists, I would guess that it does in part for completeness and in part for the benefit of other languages that may not have easy to use implementations of integer division and modulus computation.

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This is really just a comment, but I don't get enough room.

Here is some C# using `Math.DivRem()`:

``````    [Fact]
public void MathTest()
{
for (var i = 1; i <= 10; i++)
{
int remainder;
var result = Math.DivRem(10, i, out remainder);
// Use the values so they aren't optimized away
Assert.True(result >= 0);
Assert.True(remainder >= 0);
}
}
``````

Here is the corresponding IL:

``````.method public hidebysig instance void MathTest() cil managed
{
.custom instance void [xunit]Xunit.FactAttribute::.ctor()
.maxstack 3
.locals init (
[0] int32 i,
[1] int32 remainder,
[2] int32 result)
L_0000: ldc.i4.1
L_0001: stloc.0
L_0002: br.s L_002b
L_0004: ldc.i4.s 10
L_0006: ldloc.0
L_0007: ldloca.s remainder
L_0009: call int32 [mscorlib]System.Math::DivRem(int32, int32, int32&)
L_000e: stloc.2
L_000f: ldloc.2
L_0010: ldc.i4.0
L_0011: clt
L_0013: ldc.i4.0
L_0014: ceq
L_0016: call void [xunit]Xunit.Assert::True(bool)
L_001b: ldloc.1
L_001c: ldc.i4.0
L_001d: clt
L_001f: ldc.i4.0
L_0020: ceq
L_0022: call void [xunit]Xunit.Assert::True(bool)
L_0027: ldloc.0
L_0028: ldc.i4.1
L_002a: stloc.0
L_002b: ldloc.0
L_002c: ldc.i4.s 10
L_002e: ble.s L_0004
L_0030: ret
}
``````

Here is the (relevant) optimized x86 assembly generated:

``````       for (var i = 1; i <= 10; i++)
00000000  push        ebp
00000001  mov         ebp,esp
00000003  push        esi
00000004  push        eax
00000005  xor         eax,eax
00000007  mov         dword ptr [ebp-8],eax
0000000a  mov         esi,1
{
int remainder;
var result = Math.DivRem(10, i, out remainder);
0000000f  mov         eax,0Ah
00000014  cdq
00000015  idiv        eax,esi
00000017  mov         dword ptr [ebp-8],edx
0000001a  mov         eax,0Ah
0000001f  cdq
00000020  idiv        eax,esi
``````

Note the 2 calls to `idiv`. The first stores the remainder (`EDX`) into the `remainder` parameter on the stack. The 2nd is to determine the quotient (`EAX`). This 2nd call is not really needed, since `EAX` has the correct value after the first call to `idiv`.

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