# Correct usage of Java System.currentTimeMillis() method?

I am comparing the time to compute both iterative and recursive factorial procedures in Java. I am trying to use the `System.currentTimeMillis` method to compare the time it takes for each algorithm to compute, but I can't seem to calculate the difference. I am not sure what the proper way to use this method is, but any event here is what I am trying to achieve in my code:

``````// ... more code above

System.out.println();

// demonstrate recursive factorial and calculate
// how long it took to complete the algorithm
long time1 = System.currentTimeMillis();
int fact1 = factRecursive(integer);
long time2 = System.currentTimeMillis();
System.out.format("Result of recursive factorial %s is %d\n", integer, fact1);
System.out.format("Algorithm took %d milliseconds\n\n", (time2 - time1));

// ... more code below
``````

Here is the output:

``````Please enter an integer: 25

Result of recursive factorial 25 is 2076180480
Algorithm took 0 milliseconds

Result of iterative factorial 25 is 2076180480
Algorithm took 0 milliseconds
``````

Clearly I must be doing something wrong here, as the amount of time expected to compute factorials for both cases shouldn't be zero.

EDIT: Here are my solutions for factorial, if anyone is interested (not particularly unique, but here they are anyway):

``````// factRecursive uses a recursive algorithm for
// caluclating factorials.
public static long factRecursive(long n)
{
return n = (n == 1)? 1 : n * factRecursive(n - 1);
}

// factIterative uses an iterative algorithm for
// calculating factorials.
public static long factIterative(long n)
{
long product = 1;

if(n == 1) return n;

for(int i = 1; i <= n; ++i)
product *= i;

return product;
}
``````

And is some output. Surprisingly, the recursive version holds up well. It isn't until about 39! that the iterative version starts performing noticeably better.

``````Please enter an integer: 39

Result of recursive factorial 39 is 2304077777655037952
Algorithm took 5828 nanoseconds

Result of iterative factorial 39 is 2304077777655037952
Algorithm took 5504 nanoseconds
``````
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I finished in the past! –  Dave Newton Apr 11 '12 at 1:16

A well-written factorial function should execute very quickly for n = 25, so having it run in approximately 0ms isn't terribly surprising. You have three options:

1. Use a larger n. This will cause the factorial function to take longer, and give you something to measure.
2. Measure time in approximate nanoseconds rather than milliseconds, using System.nanoTime.
3. I recommend doing both 1 and 2.

As other answerers have pointed out, you are indeed subtracting end from start, which is backwards. Obviously, you should fix that too. But that change only affects the sign of the result, not the absolute value.

EDIT: Just to see how fast it is to find the factorial of 25, I wrote this Python implementation

``````>>> def fact(n):
...     def _fact(n, acc):
...             if n == 1:
...                     return acc
...             return _fact(n - 1, n * acc)
...     if n < 0:
...             return 0 # Or raise an exception
...     if n < 2:
...             return 1
...     return _fact(n, 1)
...
>>> fact(25)
15511210043330985984000000L
>>> import timeit
>>> t = timeit.Timer("fact(25)", "from __main__ import fact")
>>> print t.timeit()
6.2074379921
``````

Even though Python is an interpreted dynamically typed language without tail call optimization, a simple recursive solution with an accumulator can find `fact(25)` a million times in 6.2 seconds on my machine. So the average execution time is 6.2 microseconds. Not a chance of measuring a substantial difference between an iterative and recursive solution on a single run with millisecond clock precision.

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Okay, thank you. I was wondering the the execution time might be much quicker than this, so I tried a larger number. But it seems there will be an integer overflow if i use to large of a number for `n`. –  Dylan Apr 11 '12 at 1:19
@Dylan You'll need to use a long rather than an int in order to represent larger factorial values. If you try to take the factorial of a number that's too big, you'll have to switch to BigInteger‌​, which allows arbitrary-sized integers and thus can represent the factorial of pretty much any number you throw at it. Just be aware that, although I expect an equal effect for both solutions, this will slow down factorial compared to native ints and longs. –  Adam Mihalcin Apr 11 '12 at 1:21
Running a few unit tests on my Java program -- I noticed that the performance of the iterative version was better overall, especially once I tested for large numbers, while the recursive version was better for smaller values; I am curious to know what the big-O of both these algorithms are. –  Dylan Apr 11 '12 at 3:51
@Dylan If you're implementing factorial in the "classic way" i.e. multiply the numbers 1, 2, ..., n together somehow, the Big-O will be the same for both implementations. However, making a method call is more expensive than jumping to the beginning of a loop, so I would expect the recursive solution to be slower than the iterative solution by a constant factor. –  Adam Mihalcin Apr 11 '12 at 4:16

The resolution of `System.currentTimeMillis()` can vary, depending on your system; it appears that your algorithm is too fast to measure with this timer.

Use `System.nanoTime()` instead. Its accuracy is also system dependent, but at least it is capable of high resolution time measurement.

Just-in-time compilation can have a big impact on performance, but most virtual machines require a method to be invoked many times before recompiling it. This makes it difficult to get accurate results from this kind of micro-benchmark.

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You need to do (finish time - start time), you have it backward.

try this:

``````System.out.format("Algorithm took %d milliseconds\n\n", (time2 - time1));
``````
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Factorial of 25 isn't really all that large, the speed at which your hardware can compute that is probably really quick, instead of time in milliseconds try nanoseconds. `System.nanoTime()` –  Hunter McMillen Apr 11 '12 at 1:20

very usual mistake. You should be subtracting time1 from time2.

It will help if you name your variables sensibly - for example `startTime` and `endTime` so you would know or at least spot that you have to do `endTime - startTime` as `endTime` > `startTime`

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Good idea. Well documented code is always a plus. –  Dylan Apr 11 '12 at 1:21

Looks like your fast recursive may not be doing such a heavy processing after all.

Please use `System.nanoTime()` instead. It returns nano seconds

http://docs.oracle.com/javase/7/docs/api/java/lang/System.html

nanoTime() Returns the current value of the running Java Virtual Machine's high-resolution time source, in nanoseconds.

Another way to test is by iterating your factorial say a 1000 times. then divide the time difference by 1000.00 (double)

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I would include a Javadoc from version 7 and version 6 is soon to be EOL. –  Peter Lawrey Apr 11 '12 at 6:03
that's right, will update –  Olivier Refalo Apr 11 '12 at 12:26
I would ignore the first 10000 as they might not be compiled. –  Peter Lawrey Apr 11 '12 at 12:32

To get a meaningful timed result you need to repeat it, and ignore, at least the first 10,000 times you call a method (so the code is compiled) and you need to run it for a further 2-10 seconds (repeatedly).

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