I guess i is a 32-bit integer variable and is therefore always smaller than 10 billion (which is more than 2^32), whereas 1 billion still fits into the 32-bit range (which ends at about 2 or 4 billion, depending on signedness). Though I don't know how the compiler promotes this 10 billion constant, but he seems to realize the overflow issue and makes it an infite loop.
What happens when you make i a long long int (and maybe the 10000000000 a 10000000000L, but that seems to be no problem)?
i to a long long and switching 10000000000 to 10000000000L worked. Thanks.
I would guess that you're not putting the code you've benchmarked here. The code as is might get optimized by the compiler to not run at all. It also may be that i overflows and then your loop will never end.
However, if you use i as index to a data structure (especially if its an array), then you have the memory paging and data caching which affects the performance greatly.
The difference is that 1,000,000,000 fits into a 32 bit integer while 10,000,000,000 is 64 bit. If it's a 32 bit, which I'm going to assume that it is, it is just overflowing and will result in your loop becoming infinite.
Is your i a 64 bit variable?
If this helps to anybody:
When a 32 bit signed number exceds its range 2^31 - 1 the number is interpreted as a negative number (due to the 2C format). I.E:
For a 16 bit number:
0111 1111 1111 1111 (32767)
+ 0000 0000 0000 0001 (1)
---------------------
1000 0000 0000 0000 (Shoulbe 32769 but instead is -32768)
+ 0000 0000 0000 0001
--------------------
1000 0000 0000 0001 (-32767)....
So the infinite loop is because you are just going through all the possible values for an 32 bit signed int.
iis a 32-bit integer? So you may not be doing the same number of iterations than you expect.iis a 32-bit integer, it's never going to exceed 10 billion.>).