7

If I have code like this

    for (long i = 0; i < Long.MAX_VALUE; i++)
    {
        //do something trivial
    }

How long will it take theoretically for the loop to finish?

  • 2
    The title of the question does not align with the actual question posed. Please edit one or the other. Are you interested in modulo arithmetic or execution speed? – seh Jul 31 '10 at 1:08
  • done. the new title reflects the post much better IMHO – pdeva Jul 31 '10 at 1:21
  • oh, about 68 years, for sufficiently short longs and mid-sized "something trivials" en.wikipedia.org/wiki/Year_2038_problem – msw Jul 31 '10 at 3:41
  • I thought JIT would remove the loop if "something trivial" could be calculated without it. It didn't. – Denis Tulskiy Jul 31 '10 at 17:57
19

Suppose, just for argument's sake, that you've got a very fast computer that can perform about 2 billion loop iterations per second (a 2 GHz machine could just barely do that if there really isn't anything in the loop). Since Long.MAX_VALUE is 2 billion times 4 billion, that loop will take around 4 billion seconds, or something over 120 years.

There's no point in starting that loop today. Wait until computers get faster, and then it will be done sooner.

  • 1
    I think longs are half that--I'm not sure I've got my decimals right, but longs are signed so it's 2^63/4bil=2.3bil. – Bill K Jul 31 '10 at 1:06
  • The math already accounts for that. Hence the "2 billion times 4 billion" (2^31 * 2^32). – cHao Jul 31 '10 at 2:16
  • How did you calculate "2 GHz machine can perform about 2 billion loop iterations per second"? – Dennis C Jul 31 '10 at 3:58
  • 1
    @Dennis 2 GHz = 2 billion clock ticks per second. So if you'd have a processor which could do 1 "loop operation" per clock tick (which is overly optimistic), that's what you'd get. It's just a ballpark figure for the example, not an exact value. – Jesper Jul 31 '10 at 5:58
6

I believe the answer you are looking for is: It will not finish in your lifetime.

Edit: I should qualify that--On existing hardware or any hardware I can conceive of; perhaps when quantum computing becomes popular you will have to re-evaluate this question.

  • I don't see any valid reason to downvote this. So adding +1 to compensate. – Chathuranga Chandrasekara Jul 31 '10 at 1:13
  • 1
    i don't think this is correct. If computers continue on the trend they have been on, this will easily be doable in a lifetime. Every time a computer doubles in speed it cuts the time in half, which means one doubling of speed will make it 60 years. Also, loop iteration is not in the class of problems quantum computers will be able to solve using their black magic. – hvgotcodes Jul 31 '10 at 1:14
  • @hvgotcodes - It is implicit that the OP is asking about starting the computation "now" using a computer he can obtain "now", and letting the computation run uninterrupted until it is finished. Otherwise, the question has no sensible answer. – Stephen C Jul 31 '10 at 1:25
  • @stephen, i think it is a general question; nothing is implied. OP did not mention the hardware, so I think it is peferctly legit to theorize on modern hardware, then talk about trends. regardless, quantum computers wouldn't help in loop iteration. – hvgotcodes Jul 31 '10 at 1:38
  • @hvgotcodes - so what is the answer then? How many years on your hypothetical computer? And why does this make @Bill K's answer incorrect? – Stephen C Jul 31 '10 at 1:56
2

This might take a life time to run.

But according to the title of the question, I guess you are trying to run a loop for very high number of times and you are planning to break the loop when a certain condition occurs. i.e. You have some

if (ancondition == true)
{ 
   break; 
}

And you just need to make sure you are not getting any exception due to overflows. (ex: you are going to monitor a seismic sensor for years.) So in that scope you are safe to go.

But in the other hand this is not a good programming approach. Definitely you can improve the code by using another way.(May be periodical checks)

1

one possible answer is zero second. the compiler could be very aggressive and optimize off your entire loop, since it apparently doesn't do anything interesting...

here's a great related story: compilers optimized off a loop which searches for Fermat's Last Theorem's counter example. because the Theorem is correct (so we are told) and there is no counter example, the loop should never terminate. but compilers decide it should terminate.

http://blog.regehr.org/archives/161

(the article mentions that a java compiler is not allowed to terminate the fermat loop)

  • Switching to ints, on 5u20 I got 0.409u 0.133s 0:00.59 89.8% 0+0k 0+4io 2pf+0w (I think that means about half a second.) – Tom Hawtin - tackline Jul 31 '10 at 14:35
0

put this into wolframalpha.com

(2^63 -1)/(2*10^9) seconds

the 2^63-1 is the current value of MAX_VALUE, and 2*10^9 is a 2 GHZ processor that increments the loop once every clock tick.

now put

(2^63 -1)/(4*10^9) seconds

that represents a doubling of machine speed to 4 GHZ.

the fastest supercomputer does 1.75 petaflops (10^15). Thats a parallelized application, so its not one big loop, but if you ask "how long would it take to do 2^63-1 flops", on that machine its

http://www.wolframalpha.com/input/?i=(2^63+-1)/(1.75*10^15)+seconds

The fastest speed we have gotten a transistor to run at is 500 GHZ. from http://en.wikipedia.org/wiki/Moore's_law

"the transistor operated above 500 GHz at 4.5 K (−451 °F/−268.65 °C)[41] and simulations showed that it could likely run at 1 THz (1,000 GHz). However, this trial only tested a single transistor."

so if you plug that into wolfram alpha, you get 7 months. So a single transistor is not a loop processing unit, but you get the point. Conceivable hardware is within our technological grasp, even to churn through 2^63-1 loop iterations. If you consider the OP to be "how long to do 2^63 bit flips", then this machine meets that criteria, and easily completes in a lifetime.

But when we move to 128 bit computing, we have no chance...

  • I wouldn't expect 128-bit computing any time soon. It may seem cliche to say "64 bits ought to be big enough for everybody", but for the most part it is. How often do you have to store numbers larger than 2^63? – Gabe Jul 31 '10 at 4:02

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