Calculating the speed of routines?

What would be the best and most accurate way to determine how long it took to process a routine, such as a procedure of function?

I ask because I am currently trying to optimize a few functions in my Application, when i test the changes it is hard to determine just by looking at it if there was any improvements at all. So if I could return an accurate or near accurate time it took to process a routine, I then have a more clear idea of how well, if any changes to the code have been made.

I considered using GetTickCount, but I am unsure if this would be anything near accurate?

It would be useful to have a resuable function/procedure to calculate the time of a routine, and use it something like this:

``````// < prepare for calcuation of code
...
ExecuteSomeCode; // < code to test
...
// < stop calcuating code and return time it took to process
``````

I look forward to hearing some suggestions.

Thanks.

Craig.

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From my knowledge, the most accurate method is by using QueryPerformanceFrequency:

code:

``````var
Freq, StartCount, StopCount: Int64;
TimingSeconds: real;
begin
QueryPerformanceFrequency(Freq);
QueryPerformanceCounter(StartCount);
// Execute process that you want to time: ...
QueryPerformanceCounter(StopCount);
TimingSeconds := (StopCount - StartCount) / Freq;
// Display timing: ...
end;
``````
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Convert seconds to milliseconds by dividing by 1000 –  David Heffernan May 17 '11 at 12:43
@David: You mean multiplying, don't you? –  Ken White May 17 '11 at 12:49
@Ken, @David, dividing the divider before the division might be a better idea! That is, `Freq := Freq div 1000` before `TimingMilliseconds := (Stop - Start) / Freq`. –  Cosmin Prund May 17 '11 at 12:58
oh dear, why I didnt I think of doing this! –  user741875 May 17 '11 at 13:17
@RBA, the overhead when using QueryPerformanceCount is 19 microseconds per call according to: support.microsoft.com/kb/172338. If you use RDTSC the overhead is a few cycles of the CPU. On short routines, the overhead of QueryPerformanceCounter can be much larger than the total running time of your code. –  Johan May 17 '11 at 13:27

Try Eric Grange's Sampling Profiler.

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+1. That's a good profiler. –  Cosmin Prund May 17 '11 at 12:38
+1 very good and efficient profiler. –  RBA May 17 '11 at 12:47
+1 I'd always prefer to use a profiler than roll my own routines. However, try and measure with your wristwatch once you've done your optimisation to take a reality check! –  David Heffernan May 17 '11 at 12:57
I read the blurb. I can't tell from the wording if it 1) samples the call stack, 2) reports by line the percent of samples containing that line, 3) samples on wall-clock time. Do you know if it does? –  Mike Dunlavey May 17 '11 at 13:19
To measure exactly a single routine a sampling profiler may not be the best choice, it is better when you have to understand where a larger code is slow and then drill down. When it comes to relatively small pieces of code a classic profiler would usually return more precise informations. –  user160694 May 17 '11 at 13:34

From Delphi 6 upwards you can use the x86 Timestamp counter.
This counts CPU cycles, on a 1 Ghz processor, each count takes one nanosecond.
Can't get more accurate than that.

``````function RDTSC: Int64; assembler;
asm
// RDTSC can be executed out of order, so the pipeline needs to be flushed
// to prevent RDTSC from executing before your code is finished.
// Flush the pipeline
XOR eax, eax
PUSH EBX
CPUID
POP EBX
RDTSC  //Get the CPU's time stamp counter.
end;
``````

Use the above code to get the timestamp before and after executing your code.
Most accurate method possible and easy as pie.

Note that you need to run a test at least 10 times to get a good result, on the first pass the cache will be cold, and random harddisk reads and interrupts can throw off your timings.
Because this thing is so accurate it can give you the wrong idea if you only time the first run.

Why you should not use QueryPerformanceCounter()
`QueryPerformanceCounter()` gives the same amount of time if the CPU slows down, it compensates for CPU thottling. Whilst RDTSC will give you the same amount of cycles if your CPU slows down due to overheating or whatnot.
So if your CPU starts running hot and needs to throttle down, `QueryPerformanceCounter()` will say that your routine is taking more time (which is misleading) and RDTSC will say that it takes the same amount of cycles (which is accurate).
This is what you want because you're interested in the amount of CPU-cycles your code uses, not the wall-clock time.

From the lastest intel docs: http://software.intel.com/en-us/articles/measure-code-sections-using-the-enhanced-timer/?wapkw=%28rdtsc%29

Using the Processor Clocks

This timer is very accurate. On a system with a 3GHz processor, this timer can measure events that last less than one nanosecond. [...] If the frequency changes while the targeted code is running, the final reading will be redundant since the initial and final readings were not taken using the same clock frequency. The number of clock ticks that occurred during this time will be accurate, but the elapsed time will be an unknown.

When not to use RDTSC
RDTSC is useful for basic timing. If you're timing multithreaded code on a single CPU machine, RDTSC will work fine. If you have multiple CPU's the startcount may come from one CPU and the endcount from another.
So don't use RDTSC to time multithreaded code on a multi-CPU machine. On a single CPU machine it works fine, or single threaded code on a multi-CPU machine it is also fine.
Also remember that RDTSC counts CPU cycles. If there is something that takes time but doesn't use the CPU, like disk-IO or network than RDTSC is not a good tool.

But the documentation says RDTSC is not accurate on modern CPU's
RDTSC is not a tool for keeping track of time, it's a tool for keeping track of CPU-cycles.
For that it is the only tool that is accurate. Routines that keep track of time are not accurate on modern CPU's because the CPU-clock is not absolute like it used to be.

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RDTSC is not to be used on Windows with modern CPU. In fact, its results depends on the current CPU state: modern CPUs can change its frequency (e.g. TurboBoost technology), and multi-core design makes it even more difficult to get accurate results, therefore rdtsc is NOT to be used. QueryPerformanceCounter() IS to be used instead. See msdn.microsoft.com/en-us/library/ee417693%28VS.85%29.aspx –  Arnaud Bouchez May 17 '11 at 15:45
@Bouchez, this is exactly why you want to use RDTSC! If your processor slows down, RDTSC will still give the correct running time in cycles. As for multithreading issues, standard Delphi code is single threaded so that issue only applies if you use multiple threads. It is `QueryPerformanceCounter()` that does not give accurate results when the CPU slows down. –  Johan May 17 '11 at 16:50
@Johan Who on earth has a single core dev PC today? What's the profit of running the application with the thread affinity set to ONE CPU just for using RDTSC? The `QueryPerformanceCounter` overhead is NOT a problem, because you'll compute diff of timestamps. And the doc you're quoting is not "latest" doc. The date on top of page is the date of the page layour refresh. This Intel doc deals with Pentium II and refers to a SpeedStep techo dated from 2003 !!!!! –  Arnaud Bouchez May 18 '11 at 5:57
If you are using CPUID, you will have to PUSH EBX before executing it and POP EBX afterwards. This is because CPUID (also) modifies the EBX register, but Delphi expects ASM statments/routines to preserve EBX. –  PhiS May 18 '11 at 7:06
@A.Bouchez - you can set the affinity of the executing thread to one logical processor, then you make sure you get comparable readings from the Time Stamp Counter using this method. –  PhiS May 18 '11 at 7:09

You didn't specify your Delphi version, but Delphi XE has a TStopWatch declared in unit Diagnostics. This will allow you to measure the runtime with reasonable precision.

``````uses
Diagnostics;
var
sw: TStopWatch;
begin
sw := TStopWatch.StartNew;
<dosomething>
Writeln(Format('runtime: %d ms', [sw.ElapsedMilliseconds]));
end;
``````
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I don't have Delphi XE, but I believe that is the same class as here delphi.about.com/od/windowsshellapi/a/… –  RBA May 17 '11 at 13:31
IN XE I would profile with AQ Time to understand exactly where performance matters. –  user160694 May 17 '11 at 13:32
@RBA, the XE implementation is based on a record instead of a class, but the other stuff looks quite similar. –  Uwe Raabe May 17 '11 at 15:51
the 'T' from the TStopWatch suggested me that is a class. good to know how is implemented in XE. –  RBA May 18 '11 at 6:20
Why? The standard Delphi usage of 'T' is to indicate "Type", as in "this is a data type". Nearly all types start with a T but many of them are not classes. See TRect and TDateTime just to name a couple. –  Jon Robertson Jan 23 '13 at 10:27

I ask because I am currently trying to optimize a few functions

It is natural to think that measuring is how you find out what to optimize, but there's a better way.

If something takes a large enough fraction of time (F) to be worth optimizing, then if you simply pause it at random, F is the probability you will catch it in the act. Do that several times, and you will see precisely why it's doing it, down to the exact lines of code.

Fix it, and then do an overall measurement to see how much you saved, which should be about F. Rinse and repeat.

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+1 for brilliant insight. But beware to not optimize the idle loop :-). –  Johan May 17 '11 at 13:44
@Johan: Thanks for the heads-up. I'll be careful :-) –  Mike Dunlavey May 17 '11 at 16:53

Here are some procedures I made to handle checking the duration of a function. I stuck them in a unit I called `uTesting` and then just throw into the uses clause during my testing.

Declaration

``````  Procedure TST_StartTiming(Index : Integer = 1);
//Starts the timer by storing now in Time
//Index is the index of the timer to use. 100 are available

Procedure TST_StopTiming(Index : Integer = 1;Display : Boolean = True; DisplaySM : Boolean = False);
//Stops the timer and stores the difference between time and now into time
//Displays the result if Display is true
//Index is the index of the timer to use. 100 are available

Procedure TST_ShowTime(Index : Integer = 1;Detail : Boolean = True; DisplaySM : Boolean = False);
//In a ShowMessage displays time
//Uses DateTimeToStr if Detail is false else it breaks it down (H,M,S,MS)
//Index is the index of the timer to use. 100 are available
``````

variables declared

``````var
Time : array[1..100] of TDateTime;
``````

Implementation

``````  Procedure TST_StartTiming(Index : Integer = 1);
begin
Time[Index] := Now;
end;

Procedure TST_StopTiming(Index : Integer = 1;Display : Boolean = True; DisplaySM : Boolean = False);
begin
Time[Index] := Now - Time[Index];
if Display then TST_ShowTime;
end;

Procedure TST_ShowTime(Index : Integer = 1;Detail : Boolean = True; DisplaySM : Boolean = False);
var
H,M,S,MS : Word;
begin
if Detail then
begin
DecodeTime(Time[Index],H,M,S,MS);
if DisplaySM then
ShowMessage('Hour   =   ' + FloatToStr(H)  + #13#10 +
'Min     =   ' + FloatToStr(M)  + #13#10 +
'Sec      =   ' + FloatToStr(S)  + #13#10 +
'MS      =   ' + FloatToStr(MS) + #13#10)
else
OutputDebugString(PChar('Hour   =   ' + FloatToStr(H)  + #13#10 +
'Min     =   ' + FloatToStr(M)  + #13#10 +
'Sec      =   ' + FloatToStr(S)  + #13#10 +
'MS      =   ' + FloatToStr(MS) + #13#10));
end
else
ShowMessage(TimeToStr(Time[Index]));
OutputDebugString(Pchar(TimeToStr(Time[Index])));
end;
``````
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