# Review help regarding loops

As it is time to study for finals, I have to cover some detailed information regarding loops.I am currently stuck on this question

``````int main(void) {
int x = 0;
int y = 0;
while (y < 10) {
x = 0;
while (x != y) {//
x = x + 3; // how many times will we do this statement?
}
printf(“x is %d\n”, x);
y = y + 1;
}
}
``````

Basically, I am looking to see what the output is and how many times that statement we mentioned is run. In other words what does printf output look like.

I hope you can help me with this.

Thank you so much.

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It is mentioned on the code itself...how many times will that statement run –  bluejamesbond Dec 1 '12 at 8:48
use a debugger and you will soon find out –  mathematician1975 Dec 1 '12 at 8:50
I'll give you a clue -- it's a trick question. See if you can figure out why. –  Dunes Dec 1 '12 at 8:51
thank you but no thank you...i am trying to figure out the logic here and not exactly what to do using a debugger. I am looking to learn you logic that you used rather than finding the exact answer. –  bluejamesbond Dec 1 '12 at 8:51
A good idea is to get a pen and paper, write down the initial values of x and y and then go through each step, modifying x and y as necessary and writing down when a printf happens. When you get to a while statement look at your values of x and y to see what should happen. –  Dunes Dec 1 '12 at 8:54

This line causes a problem

`````` x = 0;
while (x != y) {//
x = x + 3; // how many times will we do this statement?
}
``````

when `y=1` since `x` will continue to increase until it reaches the maximum integer value (it cant equal y unless some overflow wrapping occurs - this will result in an infinite loop).

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yes the wrapping is the key –  bluejamesbond Dec 1 '12 at 9:07

First, due to the nature of the question and no official (that I know of) standard on overflow wrapping that isn't implementation-dependent, the answer is formally *indeterminable*.

That said, informally lets crunch some numbers just for the hell of it. I'll compute this for 32bit `int`, though the numbers for 64bit are way-more impressive. The choice of `3` as the increment is highly advantageous, (perhaps by design?) as neither 2^32 nor 2^64 are evenly divisible by it, thereby making it perfect for overflow continuity.

Some key numbers that will make things easier:

`````` 2147483646 := (715827882 * 3)
-2147483647 := (2147483646 + 3) with overflow
``````

Y=0, X=0 immediately, so no iteration statements are executed.

1. Y=1, X=0,3,6,9...2147483646 after 715827882 increments. The next increment will overflow and X=-2147483647. Another 715827882 increments later, X=-1. One more increment to get back in positive territory and X=2. Repeat the entire thing over again and X=1, A total of 4*715827882 + 3, sum=2863311531.
2. Y=2, X=0,3,6,9.... Recall from (1) above, it took 2*(715827882+1) increments to get around to 2, aka, one full pass. Therefore another 1431655766 executions, sum=4294967297
3. Y=3, For obvious reasons, Y=X=3 in one iteration. sum=4294967298
4. Y=4, Repeat (1), but add one more increment; Therefore 4*715827882 + 3 + 1 more iterations, or 2863311533. sum=7158278830
5. Y=5, Repeat (2), but add one more increment; Therefore 2*(715827882 + 1) + 1 more iterations, or 1431655767, sum=8589934597
6. Y=6, Repeat (3), but add one more increment; Therefore 1 + 1 more iterations, sum=8589934599
7. Y=7, Repeat (4), but add one more increment; Therefore 4*715827882 + 3 + 1 + 1 more iterations, or 2863311533. sum=11453246132
8. Y=8, Repeat (5), but add one more increment; Therefore 2*(715827882 + 1 + 1) + 1 more iterations, or 1431655768, sum=12884901900
9. Y=9, Repeat (6), but add one more increment; Therefore 1 + 1 + 1 more iterations, sum=12884901903

Assuming you can spin three hundred million iterations per second, it would take approximately 42.95 seconds to finish.

I'll leave the 64bit calculation to be food for thought. However, just to ponder the actual numbers, a (val+=3) increment through the 64bit integer space will require 6148914691236517206 iterations, and some steps above require we do it twice, others once, and others not at all.

Modified test program to ensure we use 32bit signed int values:

``````#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <stdint.h>
#include <inttypes.h>

int main(void)
{
int32_t x = 0;
int32_t y = 0;
uint64_t sum = 0;

while (y < 10)
{
x = 0;
while (x != y)
{
x = x + 3; ++sum;
}
printf("x is %d; sum=%" PRId64 "\n", x, sum);
y = y + 1;
}
return 0;
}
``````

Output

``````x is 0; sum=0
x is 1; sum=2863311531
x is 2; sum=4294967297
x is 3; sum=4294967298
x is 4; sum=7158278830
x is 5; sum=8589934597
x is 6; sum=8589934599
x is 7; sum=11453246132
x is 8; sum=12884901900
x is 9; sum=12884901903
``````
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i think your inner while, loops infinitly because of :

x = 0 and y = 1 then x = x + 3(x = 3) is always != 1 so it causes infinite loop

-

It's either a trick question, or a poorly thought out one (or perhaps is a more advanced question than it appears at first).

The answer is indeterminable since it depends on the properties of integer overflow.

I'll let you figure out why this is the case. If you don't see it at first, try working through a couple of iterations with pen and paper. If that raises further questions, feel free to ask. :)

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yes! it is correct –  bluejamesbond Dec 1 '12 at 8:52

`while (x != y) {` may make the while loop infinite which will never break.

E.g.

• First loop x = 0, y = 0
• 2nd while does not execute.
• 2nd iteration x = 0, y = 1
• In 2nd while loop
• iteration 1, x = 3
• iteration 2, x = 6
• And it continues as x will never be 1.
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