Curiosity: Why does Expression<…> when compiled run faster than a minimal DynamicMethod?
I\'m currently doing some last-measure optimizations, mostly for fun and learning, and discovered something that left me with a couple of questions.
First, the questions
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The method created via
DynamicMethodgoes through two thunks, while the method created viaExpression<>doesn't go through any.Here's how it works. Here's the calling sequence for invoking
fn(0, 1)in theTimemethod (I hard-coded the arguments to 0 and 1 for ease of debugging):00cc032c 6a01 push 1 // 1 argument 00cc032e 8bcf mov ecx,edi 00cc0330 33d2 xor edx,edx // 0 argument 00cc0332 8b410c mov eax,dword ptr [ecx+0Ch] 00cc0335 8b4904 mov ecx,dword ptr [ecx+4] 00cc0338 ffd0 call eax // 1 arg on stack, two in edx, ecxFor the first invocation I investigated,
DynamicMethod, thecall eaxline comes up like so:00cc0338 ffd0 call eax {003c2084} 0:000> !u 003c2084 Unmanaged code 003c2084 51 push ecx 003c2085 8bca mov ecx,edx 003c2087 8b542408 mov edx,dword ptr [esp+8] 003c208b 8b442404 mov eax,dword ptr [esp+4] 003c208f 89442408 mov dword ptr [esp+8],eax 003c2093 58 pop eax 003c2094 83c404 add esp,4 003c2097 83c010 add eax,10h 003c209a ff20 jmp dword ptr [eax]This appears to be doing some stack swizzling to rearrange arguments. I speculate that it's owing to the difference between delegates that use the implicit 'this' argument and those that don't.
That jump at the end resolves like so:
003c209a ff20 jmp dword ptr [eax] ds:0023:012f7edc=0098c098 0098c098 e963403500 jmp 00ce0100The remainder of the code at 0098c098 looks like a JIT thunk, whose start got rewritten with a
jmpafter the JIT. It's only after this jump that we get to real code:0:000> !u eip Normal JIT generated code DynamicClass.TestMethod(Int32, Int32) Begin 00ce0100, size 5 >>> 00ce0100 03ca add ecx,edx 00ce0102 8bc1 mov eax,ecx 00ce0104 c3 retThe invocation sequence for the method created via
Expression<>is different - it's missing the stack swizzling code. Here it is, from the first jump viaeax:00cc0338 ffd0 call eax {00ce00a8} 0:000> !u eip Normal JIT generated code DynamicClass.lambda_method(System.Runtime.CompilerServices.ExecutionScope, Int32, Int32) Begin 00ce00a8, size b >>> 00ce00a8 8b442404 mov eax,dword ptr [esp+4] 00ce00ac 03d0 add edx,eax 00ce00ae 8bc2 mov eax,edx 00ce00b0 c20400 ret 4Now, how did things get like this?
- Stack swizzling wasn't necessary (the implicit first argument from the delegate is actually used, i.e. not like a delegate bound to a static method)
- The JIT must have been forced by LINQ compilation logic so that the delegate held the real destination address rather than a fake one.
I don't know how the LINQ forced the JIT, but I do know how to force a JIT myself - by calling the function at least once. UPDATE: I found another way to force a JIT: use the
restrictedSkipVisibilityargumetn to the constructor and passtrue. So, here's modified code that eliminates stack swizzling by using the implicit 'this' parameter, and uses the alternate constructor to pre-compile so that the bound address is the real address, rather than the thunk:using System; using System.Linq.Expressions; using System.Reflection.Emit; using System.Diagnostics; namespace Sandbox { public class Program { public static void Main(String[] args) { DynamicMethod method = new DynamicMethod("TestMethod", typeof(Int32), new Type[] { typeof(object), typeof(Int32), typeof(Int32) }, true); var il = method.GetILGenerator(); il.Emit(OpCodes.Ldarg_1); il.Emit(OpCodes.Ldarg_2); il.Emit(OpCodes.Add); il.Emit(OpCodes.Ret); Func<Int32, Int32, Int32> f1 = (Func<Int32, Int32, Int32>)method.CreateDelegate( typeof(Func<Int32, Int32, Int32>), null); Func<Int32, Int32, Int32> f2 = (Int32 a, Int32 b) => a + b; Func<Int32, Int32, Int32> f3 = Sum; Expression<Func<Int32, Int32, Int32>> f4x = (a, b) => a + b; Func<Int32, Int32, Int32> f4 = f4x.Compile(); for (Int32 pass = 1; pass <= 2; pass++) { // Pass 1 just runs all the code without writing out anything // to avoid JIT overhead influencing the results Time(f1, "DynamicMethod", pass); Time(f2, "Lambda", pass); Time(f3, "Method", pass); Time(f4, "Expression", pass); } } private static void Time(Func<Int32, Int32, Int32> fn, String name, Int32 pass) { Stopwatch sw = new Stopwatch(); sw.Start(); for (Int32 index = 0; index <= 100000000; index++) { Int32 result = fn(index, 1); } sw.Stop(); if (pass == 2) Console.WriteLine(name + ": " + sw.ElapsedMilliseconds + " ms"); } private static Int32 Sum(Int32 a, Int32 b) { return a + b; } } }Here's the runtimes on my system:
DynamicMethod: 312 ms Lambda: 417 ms Method: 417 ms Expression: 312 msUPDATED TO ADD:
I tried running this code on my new system, which is an Core i7 920 running Windows 7 x64 with .NET 4 beta 2 installed (mscoree.dll ver. 4.0.30902), and the results are, well, variable.
csc 3.5, /platform:x86, runtime v2.0.50727 (via .config) Run #1 DynamicMethod: 214 ms Lambda: 571 ms Method: 570 ms Expression: 249 ms Run #2 DynamicMethod: 463 ms Lambda: 392 ms Method: 392 ms Expression: 463 ms Run #3 DynamicMethod: 463 ms Lambda: 570 ms Method: 570 ms Expression: 463 msPerhaps this is Intel SpeedStep affecting results, or possibly Turbo Boost. In any case, it's very annoying.
csc 3.5, /platform:x64, runtime v2.0.50727 (via .config) DynamicMethod: 428 ms Lambda: 392 ms Method: 392 ms Expression: 428 ms csc 3.5, /platform:x64, runtime v4 DynamicMethod: 428 ms Lambda: 356 ms Method: 356 ms Expression: 428 ms csc 4, /platform:x64, runtime v4 DynamicMethod: 428 ms Lambda: 356 ms Method: 356 ms Expression: 428 ms csc 4, /platform:x86, runtime v4 DynamicMethod: 463 ms Lambda: 570 ms Method: 570 ms Expression: 463 ms csc 3.5, /platform:x86, runtime v4 DynamicMethod: 214 ms Lambda: 570 ms Method: 571 ms Expression: 249 msMany of these results will be accidents of timing, whatever it is that is causing the random speedups in the C# 3.5 / runtime v2.0 scenario. I'll have to reboot to see if SpeedStep or Turbo Boost is responsible for these effects.
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