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A friend sent me a comparison between a recent version of Delphi and Java (source code available if you want it). Believe it or not (better believe it) Java is now significant faster than Delphi because Delphi compiler won't take advantage of modern CPU instructions! A big breakthrough for the 'slow' Java.

My question is: How can we use modern CPU instructions in Delphi (without resorting to ASM)?

The FastCode project was a partial answer to the above question but it is now abandoned. There is any other project similar to FastCode?

This is another article showing that Java and C# it is indeed MUCH faster than Delphi: http://webandlife.blogspot.com/2011/12/c-performance-vs-delphi-performance.html


JAVA

import java.util.Date;

public class j
{
  public static void xxx(int n, int m)
  {
        double t;
        int i, j;
        double d, r;
        t = 0.0;
        for (j = 1; j <= n; j++)
        {
          t = t / 1000.0;
          for (i = 1; i <= m; i++)
          {
                t = t + i / 999999.0;
                d = t * t + i;
                r = (t + d) / (200000.0 * (i + 1));
                t = t - r;
          }
        }
        System.out.println(t);
  }

  public static void main(String [] args)
  {
        Date t1, t2;

        t1 = new Date();
        xxx(1, 999999999);
        t2 = new Date();
        System.out.println((t2.getTime() - t1.getTime())/1000);
        t1 = new Date();
        xxx(1, 999999999);
        t2 = new Date();
        System.out.println((t2.getTime() - t1.getTime())/1000);
  }
}

25 sec

DELPHI

program d;
{$APPTYPE CONSOLE}
uses
  System.SysUtils, System.DateUtils;
var
  t1, t2: TDateTime;

procedure xxx (n: integer; m: integer);
var
  t: double;
  i, j: integer;
  d, r: double;
begin
  t:= 0.0;
  for j:= 1 to n do
  begin
        t:= t / 1000.0;
        for i:= 1 to m do
        begin
          t:= t + i / 999999.0;
          d:= t * t + i;
          r:= (t + d) / (200000.0 * (i + 1));
          t:= t - r;
        end;
  end;
  writeln(t);
end;

begin
  t1:= Now;
  xxx(1, 999999999);
  t2:= Now;
  writeln(SecondsBetween(t2,t1));

  t1:= Now;
  xxx(1, 999999999);
  t2:= Now;
  writeln(SecondsBetween(t2,t1));
end.

37 sec

share|improve this question
1  
Yes. It is sad indeed. –  thelight Sep 4 '13 at 9:44
3  
The only "clarification" I see is "without using ASM". And who is "They"? I believe a game from 1997 runs with way more than 5 times your Vsync on a modern machine if it was compiled as a "real" C or delphi program. Also, real time rendering benchmarks don't tell anything about compiler performance since most of those benchmarks run on the GPU anyway. What are "modern" instructions? Do you mean stuff like SSE or MMX? That would certainly be interesting and be closer to the "real world" instead of just dividing some random numbers. –  Günther the Beautiful Sep 4 '13 at 11:00
2  
The accepted answer is directly referring to code - which apparently has been removed from the question, so now the answer doesn't quite fit. –  Jerry Dodge Sep 4 '13 at 12:13
1  
@Altar It's tool late to remove the code. Two of your answers refer to it. –  David Heffernan Sep 4 '13 at 13:13
1  
@DavidHeffernan In 2011 Delphi got demolished by both Java and C# in the Scimark benchmark. There was a big dust-up on the Internet about it, but it was the same cause: lack of modern instruction set usage. –  alcalde Sep 4 '13 at 18:18

4 Answers 4

up vote 10 down vote accepted

According to your code, what is slow with the 32 bit Delphi compiler is the floating point arithmetic support, which is far from optimized, and copy a lot of content on/to the FPU stack.

In respect to floating point arithmetic, not only Java JITted code will be faster. Even modern JavaScript JIT compilers can be much better than Delphi!

This blog article is just a reference about this, and provide asm-level explanation about Delphi slowness for floating point:

enter image description here

But if you use the Delphi compiler targeting the Win64 platform, it will emit not x87 but SSE2 opcodes, and will be much faster. I suspect comparable to Java JITted executable.

And, in respect to Java, any Delphi executable will use much less memory than the JVM, so here, Delphi executables are perfectly on the track!

If you want your code to be faster, do not use asm nor low-level optimization trick, but change your algorithm. It could be order of magnitude faster than compilation hints. Dedicated process will be achieved with inlined asm opcodes - take a look at this great set of articles for such low level hacks. But it is not easy to master, and usually, proper software profiling and adding some cache is the best way to performance!

share|improve this answer
1  
In fact the code emitted by the Delphi x64 compiler for this example is no faster than that emitted by the x86 compiler. –  David Heffernan Sep 4 '13 at 11:15
    
thanks for the delphitools.info/samplingprofiler link –  Altar Sep 4 '13 at 11:33
1  
I disagree that there is no place for ASM optimization. Compilers can't know everything, and especially for compact elementary operations there are a lot of things they can't know. I have a custom ASM routine, for example, that simultaneously computes a complex number subtraction followed by the complex square root of the result - one for x87 and one for SSE. Both benefit from re-use of intermediates, optimized stack manipulation (x87) or simultaneous calculation (SSE), and conditional branching (on intermediate signs or zeroes, etc). No compiled algorithm has scope to do this. –  J... Sep 4 '13 at 11:47
1  
@J... I did not write there is no place for ASM optimization: I wrote "Dedicated process will be achieved with inlined asm opcodes" and only stated that this is not easy. ASM should be only the last ressort, when your code is proven and stable, and you have time and need for a dedicated version. Do not forget also that you should better have a "pure pascal" version in addition to tuned ASM version, if you want to be truly cross-platform. This is what we did for our code (e.g. for JSON parsing or generation). –  Arnaud Bouchez Sep 4 '13 at 12:45
1  
@DavidHeffernan If you know how to minimize the x87 stack use, you can achieve good speed with FPU code, of course. But sometimes, the Delphi 32 bit compiler just produces awfully slow code. Look at this, and weap. For non floating-point code, Win64 will usually be slower as a target platform, since the RTL is much less optimized, and some emitted code is not as good as with 32 bit backend (e.g. "case"). And pointer size increase can also be a problem of CPU cache miss. –  Arnaud Bouchez Sep 4 '13 at 12:47

To follow on from Arnaud's point - I actually compiled this in delphi for x86 and x64.

32-bit compiler :

Unit1.pas.36: t:= t / 1000.0;
0051274D DD45F0           fld qword ptr [ebp-$10]
00512750 D835E4275100     fdiv dword ptr [$005127e4]
00512756 DD5DF0           fstp qword ptr [ebp-$10]
00512759 9B               wait 
Unit1.pas.37: for i:= 1 to m do
0051275A 8B45F8           mov eax,[ebp-$08]
0051275D 85C0             test eax,eax
0051275F 7E57             jle $005127b8
00512761 8945D0           mov [ebp-$30],eax
00512764 C745EC01000000   mov [ebp-$14],$00000001
Unit1.pas.39: t:= t + i / 999999.0;
0051276B DB45EC           fild dword ptr [ebp-$14]
0051276E D835E8275100     fdiv dword ptr [$005127e8]
00512774 DC45F0           fadd qword ptr [ebp-$10]
00512777 DD5DF0           fstp qword ptr [ebp-$10]
0051277A 9B               wait 
Unit1.pas.40: d:= t * t + i;
0051277B DD45F0           fld qword ptr [ebp-$10]
0051277E DC4DF0           fmul qword ptr [ebp-$10]
00512781 DB45EC           fild dword ptr [ebp-$14]
00512784 DEC1             faddp st(1)
00512786 DD5DE0           fstp qword ptr [ebp-$20]
00512789 9B               wait 
Unit1.pas.41: r:= (t + d) / (200000.0 * (i + 1));
0051278A DD45F0           fld qword ptr [ebp-$10]
0051278D DC45E0           fadd qword ptr [ebp-$20]
00512790 8B45EC           mov eax,[ebp-$14]
00512793 40               inc eax
00512794 8945CC           mov [ebp-$34],eax
00512797 DB45CC           fild dword ptr [ebp-$34]
0051279A D80DEC275100     fmul dword ptr [$005127ec]
005127A0 DEF9             fdivp st(1)
005127A2 DD5DD8           fstp qword ptr [ebp-$28]
005127A5 9B               wait 
Unit1.pas.42: t:= t - r;
005127A6 DD45F0           fld qword ptr [ebp-$10]
005127A9 DC65D8           fsub qword ptr [ebp-$28]
005127AC DD5DF0           fstp qword ptr [ebp-$10]
005127AF 9B               wait 
Unit1.pas.43: end;
005127B0 FF45EC           inc dword ptr [ebp-$14]
Unit1.pas.37: for i:= 1 to m do
005127B3 FF4DD0           dec dword ptr [ebp-$30]
005127B6 75B3             jnz $0051276b
Unit1.pas.44: end;
005127B8 FF45E8           inc dword ptr [ebp-$18]

64-bit compiler

Unit1.pas.36: t:= t / 1000.0;
000000000059F94E F20F104548       movsd xmm0,qword ptr [rbp+$48]
000000000059F953 F20F5E05BD000000 divsd xmm0,qword ptr [rel $000000bd]
000000000059F95B F20F114548       movsd qword ptr [rbp+$48],xmm0
000000000059F960 C7C001000000     mov eax,$00000001
000000000059F966 8B5568           mov edx,[rbp+$68]
000000000059F969 894544           mov [rbp+$44],eax
000000000059F96C 395544           cmp [rbp+$44],edx
000000000059F96F 7F73             jnle xxx + $C4
000000000059F971 83C201           add edx,$01
Unit1.pas.39: t:= t + i / 999999.0;
000000000059F974 F20F2A4544       cvtsi2sd xmm0,dword ptr [rbp+$44]
000000000059F979 F20F5E059F000000 divsd xmm0,qword ptr [rel $0000009f]
000000000059F981 F20F104D48       movsd xmm1,qword ptr [rbp+$48]
000000000059F986 F20F58C8         addsd xmm1,xmm0
000000000059F98A F20F114D48       movsd qword ptr [rbp+$48],xmm1
Unit1.pas.40: d:= t * t + i;
000000000059F98F F20F104548       movsd xmm0,qword ptr [rbp+$48]
000000000059F994 F20F594548       mulsd xmm0,qword ptr [rbp+$48]
000000000059F999 F20F2A4D44       cvtsi2sd xmm1,dword ptr [rbp+$44]
000000000059F99E F20F58C1         addsd xmm0,xmm1
000000000059F9A2 F20F114538       movsd qword ptr [rbp+$38],xmm0
Unit1.pas.41: r:= (t + d) / (200000.0 * (i + 1));
000000000059F9A7 F20F104548       movsd xmm0,qword ptr [rbp+$48]
000000000059F9AC F20F584538       addsd xmm0,qword ptr [rbp+$38]
000000000059F9B1 8B4544           mov eax,[rbp+$44]
000000000059F9B4 83C001           add eax,$01
000000000059F9B7 F20F2AC8         cvtsi2sd xmm1,eax
000000000059F9BB F20F590D65000000 mulsd xmm1,qword ptr [rel $00000065]
000000000059F9C3 F20F5EC1         divsd xmm0,xmm1
000000000059F9C7 F20F114530       movsd qword ptr [rbp+$30],xmm0
Unit1.pas.42: t:= t - r;
000000000059F9CC F20F104548       movsd xmm0,qword ptr [rbp+$48]
000000000059F9D1 F20F5C4530       subsd xmm0,qword ptr [rbp+$30]
000000000059F9D6 F20F114548       movsd qword ptr [rbp+$48],xmm0
Unit1.pas.43: end;
000000000059F9DB 83454401         add dword ptr [rbp+$44],$01
000000000059F9DF 395544           cmp [rbp+$44],edx
000000000059F9E2 7590             jnz xxx + $54
000000000059F9E4 90               nop
Unit1.pas.44: end;
000000000059F9E5 83454001         add dword ptr [rbp+$40],$01
000000000059F9E9 394D40           cmp [rbp+$40],ecx
000000000059F9EC 0F855CFFFFFF     jnz xxx + $2E
000000000059F9F2 90               nop
Unit1.pas.45: writeln(t);
000000000059F9F3 488B0D9E150300   mov rcx,[rel $0003159e]

Oddly, in this case, the x87 fpu code was actually about ~5% faster. The conclusion is probably nothing more than the fact that Delphi's 32-bit/x87 compiler is extremely mature and rather well optimized and the 64-bit compiler probably has some room to refine in a bit of performance. I can easily see a few places where the SSE code can be optimized here; i, for example, could be stored in an XMM register and re-used rather than being re-converted each time with cvtsi2sd, d could be held in an XMM register for the next calculation rather than being stored and re-loaded, etc.

Unaligned MOVs in and out of XMM registers can be actualy surprisingly expensive. The actual SSE calculations are faster, but the excessive data movement is probably evening out the score. Maybe Java forces 16-byte alignment on the stack? I know MacOS does this and there are definite benefits for SSE to use aligned rather than unaligned moves (at the expense of consuming more stack space, of course).

For example

  • fild : 1 op, 9 latency (x87)
  • cvtsi2sd : 2 op, 12 latency (SSE)

or

  • fld : 1 op, 4 latency (x87)
  • movsd [r,m] : 2op, 4 latency (SSE)

Delphi's compiler, while emitting SSE instructions, still seems to be treating the workflow in a similar way to the way it would do so with the x87 unit, which isn't necessarily the best way. In either case, David is correct - the compiler is what it is. You can't do anything to change it.

Where I need fast mathematical routines, I still code them in ASM myself - this will generally be superior to anything any compiler can do because you can customize the behaviour to the exact calculations you are doing. I have old legacy 32-bit applications with hand-tuned SSE3 ASM algorithms for complex number arithmetic and matrix operations. The key is that you don't need to optimize everything - you only need to optimize the bottlenecks. This is a rather important point to keep aware of.

share|improve this answer
    
Thanks J for your analysis. –  Altar Sep 4 '13 at 12:33
    
A lot of time sounds to be lost in the SSE generated code during single to double conversion. AFAIR you need to tune your code or emit some proper conditional. –  Arnaud Bouchez Sep 4 '13 at 12:51

I'm going to answer the meta question here: "why can't the Delphi compiler use more modern CPU instructions, and why can Java?"

Basically, there are two ways to compile code:

  1. pre-compiled on the developers machine
  2. post-compiled (including JITed) on the target machine

Examples of 1. include Delphi, C/C++, etc.
Examples of 2. include Java, .NET, JavaScript, etc.

Pre-compiled environments

Pre-compiled environments have you compile your code once, and run it on your target computers. Compiled programs cannot run on machines using older instruction sets than the compiled program uses. The minimum requirement is the lowest of what the compiler can do best, and the lowest architecture of all your the target machines. If you don't know your target machines, it limited by the compiler.

Post-compiled environments

Post-compiled environments compile on the target machine. You don't have to know what architecture it runs: the compiler that runs on it needs to know what it supports to take best benefit of it. The minimum requirement is the lowest of what the compiler can do best, and the architecture of the target machine.

The reason is that in a post-compiled, JITed or interpreted language environment, the compiler actually runs on the target machine. Which means that the compiler can use all features of that target architecture. It could even take into account aspects like physical memory, cache sizes or disk speed, and measure current run-time performance to do post-compile optimizations on running code.

Delphi and other tools

As for the Windows 32-bit Delphi compiler, I think the minimum requirement is 486 still or the Pentium (given the Pentium-Safe FDIV option). It uses x87 for CPU code because of that.
The Windows 64-bit Delphi compiler has a minimum requirement of SSE instructions which it uses for FPU code.
I've not yet checked the other compiler platforms on minimum requirements.

The minimum Delphi requirements have to do with the emphasis on backward compatibility.

Some other environments (most C/++ compilers, and likely others too) allow you to specify the minimum instruction set. Delphi hasn't. and I think the main reason is complexity of development and testing. The matrix (if it is indeed a 2-dimensional problem) of possibilities gets large really quickly.

JIT compilers usually do not fully support the latest hardware architecture benefits across the board, as it is very expensive to do so.

JIT compilers often do support optimizations for certain processor families (for instance when copying regions of memory).

I know that Java and .NET made quite some advances in this area over the last decade. There is a really good 2005 article on .NET JIT usage of CPU features.

share|improve this answer
1  
... and JIT suffers from some limitations, e.g. for application wide optmization. This is why the NGen tool was introduced by MS... but honestly it is mostly marketing stuff: NGen has also some drawbacks, e.g. reducing metaprogramming abilities. There is no perfect solution, no definitive word about performance. The main speed factor of any software about to be written is between the chair and the keyboard. –  Arnaud Bouchez Sep 4 '13 at 15:14
    
+1; @ArnaudBouchez if there were a silver bullet, we all would be without jobs (: –  Jeroen Wiert Pluimers Sep 4 '13 at 16:48
1  
The future: JIT and global static analysis when processors get fast enough. And as a consequence lots more dynamic typing too. :-) –  alcalde Sep 4 '13 at 18:23

How can we use modern CPU instructions in Delphi (without resorting to ASM)?

If the compiler won't emit the CPU instructions that you wish to use, then there is no alternative to generating the desired instructions yourself, for example by using the inline assembler.

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