# StackOverflowError in Math.Random

This is the context of my program.

A function has 50% chance to do nothing, 50% to call itself twice. What is the probability that the program will finish?

I wrote this piece of code, and it works great apparently. The answer which may not be obvious to everyone is that this program has 100% chance to finish. But there is a StackOverflowError (how convenient ;) ) when I run this program, occuring in Math.Random(). Could someone point to me where does it come from, and tell me if maybe my code is wrong?

``````static int bestDepth =0;
static int numberOfPrograms =0;
@Test
public void testProba(){
for(int i = 0; i <1000; i++){
long time = System.currentTimeMillis();
bestDepth = 0;
numberOfPrograms = 0;
loop(0);
LOGGER.info("Best depth:"+ bestDepth +" in "+(System.currentTimeMillis()-time)+"ms");
}
}

public boolean loop(int depth){
numberOfPrograms++;
if(depth> bestDepth){
bestDepth = depth;
}
if(proba()){
return true;
}
else{
return loop(depth + 1) && loop(depth + 1);
}
}

public boolean proba(){
return Math.random()>0.5;
}
``````

.

``````java.lang.StackOverflowError
at java.util.Random.nextDouble(Random.java:394)
at java.lang.Math.random(Math.java:695)
``````

. I suspect the stack and the amount of function in it is limited, but I don't really see the problem here.

Any advice or clue are obviously welcome.

Fabien

EDIT: Thanks for your answers, I ran it with java -Xss4m and it worked great.

-
That it happens at `random()` is just a coincidence. The cause is the deep recursion in `loop()`. – kiheru Aug 8 '13 at 12:17
The problem with the logic behind "it always finishes" is the same as behind the logic that tells you that you can always win by doubling your bet after a loss: bad luck is bound to have a streak that would be long enough to overflow your stack, or empty your purse. – dasblinkenlight Aug 8 '13 at 12:18
StackOverflowErrors frequently show up in a leaf function called by the real culprit. The real culprit (`loop`) nearly fills the stack, then it calls something else and it's that call that finally crosses the limit. That's quite common really. – harold Aug 8 '13 at 12:18
Not related to your issue at all, but `Math.random()>0.5` should be `Math.random()>=0.5`. `random` returns a value from 0 inclusive to 1 exclusive, so as it is now there's actually slightly less than 50% chance a recursion will occur. – Syon Aug 8 '13 at 12:41
@dasblinkenlight I just realised that my program is wrong. When I use " return loop(depth + 1) && loop(depth + 1);", it doesn't evaluate the second item if the first one is false. I need to rewrite it. – Fabinout Aug 8 '13 at 14:55

Whenever a function is called or a non-static variable is created, the stack is used to place and reserve space for it.

Now, it seems that you are recursively calling the `loop` function. This places the arguments in the stack, along with the code segment and the return address. This means that a lot of information is being placed on the stack.

However, the stack is limited. The CPU has built-in mechanics that protect against issues where data is pushed into the stack, and eventually override the code itself (as the stack grows down). This is called a `General Protection Fault`. When that general protection fault happens, the OS notifies the currently running task. Thus, originating the `Stackoverflow`.

This seems to be happening in `Math.random()`.

In order to handle your problem, I suggest you to increase the stack size using the -Xss option of `Java`.

-
My further question was: "why does it happen every time in Math.Random?" Is it possible that the stack can accept an even number of functions, and that Math.random() is in fact always the uneven-th function added in the stack? – Fabinout Aug 8 '13 at 12:24
It depends on how much space is allocated for the stack by the JVM. This happening in the `Math.random()` is a pure coincidence. – Levente Kurusa Aug 8 '13 at 12:25
@Fabinout My bet is that `Math.random()` requires more space then `loop()` on stack (for allocating local variables, etc...), so the probability of it happening there is higher, and might even be 1 if it requires more then double the space. Just a guess though. – amit Aug 8 '13 at 12:33
@LeventeKurusa Yes, with Java -Xss4m, I could ran this 10.000 times!! Thanks a lot ;) – Fabinout Aug 8 '13 at 12:35
Haha, I am not here for the reputation. I enjoy to help others :p – Levente Kurusa Aug 8 '13 at 12:40

As you said, the `loop` function recursively calls itself. Now, tail recursive calls can be rewritten to loops by the compiler, and not occupy any stack space (this is called the tail call optimization, TCO). Unfortunately, java compiler does not do that. And also your `loop` is not tail-recursive. Your options here are:

1. Increase the stack size, as suggested by the other answers. Note that this will just defer the problem further in time: no matter how large your stack is, its size is still finite. You just need a longer chain of recursive calls to break out of the space limit.
2. Rewrite the function in terms of loops
3. Use a language, which has a compiler that performs TCO
1. You will still need to rewrite the function to be tail-recursive
2. Or rewrite it with trampolines (only minor changes are needed). A good paper, explaining trampolines and generalizing them further is called "Stackless Scala with Free Monads".

To illustrate the point in 3.2, here's how the rewritten function would look like:

``````def loop(depth: Int): Trampoline[Boolean] = {
numberOfPrograms = numberOfPrograms + 1
if(depth > bestDepth) {
bestDepth = depth
}
if(proba()) done(true)
else for {
r1 <- loop(depth + 1)
r2 <- loop(depth + 1)
} yield r1 && r2
}
``````

And initial call would be `loop(0).run`.

-

Increasing the stack-size is a nice temporary fix. However, as proved by this post, though the `loop()` function is guaranteed to return eventually, the average stack-depth required by `loop()` is infinite. Thus, no matter how much you increase the stack by, your program will eventually run out of memory and crash.

There is nothing we can do to prevent this for certain; we always need to encode the stack in memory somehow, and we'll never have infinite memory. However, there is a way to reduce the amount of memory you're using by about 2 orders of magnitude. This should give your program a significantly higher chance of returning, rather than crashing.

We can do this by noticing that, at each layer in the stack, there's really only one piece of information we need to run your program: the piece that tells us if we need to call `loop()` again or not after returning. Thus, we can emulate the recursion using a stack of bits. Each emulated stack-frame will require only one bit of memory (right now it requires 64-96 times that, depending on whether you're running in 32- or 64-bit).

The code would look something like this (though I don't have a Java compiler right now so I can't test it):

``````static int bestDepth = 0;
static int numLoopCalls = 0;

public void emulateLoop() {
//Our fake stack.  We'll push a 1 when this point on the stack needs a second call to loop() made yet, a 0 if it doesn't
BitSet fakeStack = new BitSet();
long currentDepth = 0;
numLoopCalls = 0;

while(currentDepth >= 0)
{
numLoopCalls++;

if(proba()) {
//"return" from the current function, going up the callstack until we hit a point that we need to "call loop()"" a second time
fakeStack.clear(currentDepth);
while(!fakeStack.get(currentDepth))
{
currentDepth--;
if(currentDepth < 0)
{
return;
}
}

//At this point, we've hit a point where loop() needs to be called a second time.
//Mark it as called, and call it
fakeStack.clear(currentDepth);
currentDepth++;
}
else {
//Need to call loop() twice, so we push a 1 and continue the while-loop
fakeStack.set(currentDepth);
currentDepth++;
if(currentDepth > bestDepth)
{
bestDepth = currentDepth;
}
}
}
}
``````

This will probably be slightly slower, but it will use about 1/100th the memory. Note that the `BitSet` is stored on the heap, so there is no longer any need to increase the stack-size to run this. If anything, you'll want to increase the heap-size.

-

The downside of recursion is that it starts filling up your stack which will eventually cause a stack overflow if your recursion is too deep. If you want to ensure that the test ends you can increase your stack size using the answers given in the follow Stackoverflow thread:

How to increase to Java stack size?

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