EDIT (2): TL;DR
The code below may be modified to print out the overhead.
In that specific case that overhead is mostly due to the
microtime() function itself.
I have measured
microtime() to require 0.27 us, after an overhead of 0.11 us was removed.
This should answer the question: use the code to measure the overhead, that is what OP was asking for.
EDIT: to skeptics voting down
The point here is that measuring a dry run (the empty
dummy() function) really removes all the overhead, including such artifacts as the execution of the two
microtime() calls at the start and end and the
for loop and everything. But it's nice to see that not everybody gets it, measurement theory really is a complex matter. For those serious about the matter don't get confused by the accepted answer. Better read up some articles on the Internet instead of just looking at StackOverflow.
This question is pretty old but I must revive it and answer, because I see a lot of confusion here. The actually true answer is:
YES YOU CAN, if you know how to actually correctly measure code execution times in general.
This field of measurement is pretty complex so I'll try to reduce this exposition as much as possible.
Contrary to the accepted answer, you can actually approach asymptotically the correct value with an error less then epsilon (meaning, as precise as desired).
Let's start slowly: how to avoid interference in a multitasking system.
As you maybe know, the kernel of your OS will handle resources. Most notably, the CPU itself. Modern CPUs have a special functionality to quickly switch context (preemption, context switching).
During measurement, a context switch will inevitably taint your measure, so you'll want to avoid it as much as possible. Under Windows and/or Linux we have different means to mitigate this problem as much as possible, being:
- closing as many applications/daemons/services running concurrently and/or in background as possible;
- detach networks and peripherals like printers (to avoid I/O interrupts);
- use a pure terminal login instead of a graphical interface;
- remove everything else that might interfere.
Then you want to set the priority of the process to real-time so that the round-robin does not preempt a process. But this really depends on the actual kernel in use. There are Linux kernels which are specially compiled with RT in mind. On Windows right-click the application in Task Manager and set priority to the maximum and restrain the process to the second core (the first is sometimes preferred by the OS for kernel activities).
Next let's discuss how to avoid paging.
Paging is an effect of virtual memory. During execution, some memory pages may be saved into a paging file which resides on disk. The next moment you access a memory address in that page, it will be loaded transparently to the process. The CPU will trap a page-fault exception and activate the loading algorithm. Once the data is loaded into RAM, the process resumes completely unknowingly that a huge amount of time (milliseconds) have passed. In assembler an instruction such as:
MOV dest, src
will not take 1 CPU cycle as adevertised, but even billions of CPU cycles if dest or src are paged-out addresses.
To avoid this problem you will have to prefetch all data you will use so that it resides as near to the CPU as possible. The distance from the CPU would be:
PAGEFILE > RAM > L2 CPU CACHE > L1 CPU CACHE > CPU REGISTERS
With PHP this means you can't do that much to solve this problem. In assembler you would have huge optimization leeway in that regard. So, let's say we have to handle this problem in PHP as far as possible without relying on anything outside PHP.
Next, we will discuss noise reduction.
The idea of noise reduction is pretty simple. Instead of measuring once, do many measurements and then average across all values. This way the fluctuation of the single errors will be removed and only a hard base error will remain.
This means you'll measure in a cycle and over many instances, then average the cumulative value.
Next, we will discuss how to remove overhead, which apparently leads to much confusion.
If you measure an algorithm there will be inevitably additional instructions needed to get it going. But you don't really want to measure those, you just want to measure the gist of what you intend. The additional measurement is an overhead that must be removed from the actual measurement. Under lucky circumstances (which is our case, here) the above base error will still be present while the auxiliary code is under execution, and if you are good at measurements, you'll even have a chance on removing it completely, obtaining a pretty precise result.
Now let's wrap it all up and see not just example code but actual code that implements all those concepts. The comments in the code will point to the things said so far.
$dummy = function ()
// don't do anything
$f = function ()
function measure($callback, $repetitions)
for($i = 0; $i < 1000; $i++) // prefetch
$us = -microtime(true);
for($i = 0; $i < $repetitions; $i++)
$us += microtime(true);
$retries = 10;
$repetitions = 100000; // may be higher/lower depending on necessity
while ($retries-- > 0)
$ovrh = measure($dummy, $repetitions); // measure overhead, including function calls and everything...
$time = measure($f, $repetitions);
echo 'ovrh: ' . $ovrh / $repetitions . "\n"; // it's important you only divide in the end,
echo 'time: ' . ($time - $ovrh) / $repetitions . "\n"; // after computing the difference!
So, this should run pretty well for a minute or two, but I don't actually know because I've never run it. If there are typos and stuff it's because of this.
What you will do now is run this while there is no other interference. As the numbers are printed out the pauses allow the system to eventually recover from interference. You'll have to retry it many times (10 in the code above) because you'll have to watch it closely:
If the resulting numbers are always the same than that's the value you want!
If the numbers jump up and down then there's a problem and the measurement does not work.
At your leisure you want to substitute the code in
f() as you wish. Remember that the
dummy() must also contain the auxiliary code.
Example: you have
f() with an assignment as auxiliary code that you can't remove.
public function f()
$v = 3 * 4; // the assignment is auxiliary but cannot be removed
// note that the compiler may optimize the multiplication
// into the resulting number 12
// in that case execution time will be very near to the
// overhead and the difference will be 0 or, because of
// errors, by chance be less than 0!
public function dummy()
$v = 0; // this is the code you want to measure as overhead
Under circumstance it is possible to write the
dummy() function so that the overhead is correctly measured and removed. In some cases this is not entirely possible, but explaining which algorithms fall under this category is another story :)
Finally remember this:
WHAT do you want to measure? Purely ideal execution times or real-life realistic execution times?
In this second case, which is far more interesting and useful, you will have to put the code on the production server and run it WITH all the interference and concurrency from the OS.
I've just fixed a typo and some errors due to the habit of writing object-oriented code and not scripts. The above script should now run without errors from a Linux command line and probably on Windows as well.
I've measured 2.7 * 10^-7 seconds, while running a youtube video in gnome and with chrome and some other windows open. That's 0.27 microseconds. The actual results printed out are:
As we can see, it is relatively stable, so we can assume there is no measuring error due to paging or sporadic I/O interrupts. Context switching and continuous network traffic still have an impact, but I would consider it normal circumstances that have to be taken into account. Nobody would run a program in total isolation. It would be a nice theoretical exercise but of no real-life value.