Many things are left unspecified in the definition of the C language, including the size of numeric types and what happens in case of overflow or loss of precision. So it is common to get different results with different implementations (different compilers, different hardware, different operating systems) when you don't check numeric type ranges or when you use floating point.

Given the information provided by self. in two comments, here is a plausible explanation of what's happening. I don't have Pelles C to check.

Pelles warns:

warning #2215: Conversion from 'unsigned long long int' to 'long double'; possible loss of data.
warning #2215: Conversion from 'long double' to 'unsigned long int'; possible loss of data

Conjecture #1: the mathematical value 2^64-1 cannot be represented exactly in a `long double`

(this is likely, as 2^64-1 requires 64 bits of mantissa and few implementations have that much). It is rounded to 2^64, which can be represented exactly.

The value of `number`

is 2^64-1, and it is an `unsigned long long`

. Since the function `sqrtl`

expects a `long double`

argument, the value is converted to that type. Given conjecture #1, `sqrtl`

receives a value of 2^64. The result is therefore 2^32. Since this is an integer, `truncl`

returns the same value.

Conjecture #2: `unsigned long`

is a 32-bit type (this is pretty much the norm on 32-bit machines, and is also the case on 64-bit versions of Windows, at least with the Microsoft compiler).

If `unsigned long`

is a 32-bit type, then the value 2^32 overflows it. What happens in case of overflow in a conversion from a floating-point value to an integer value is not defined by the C standard, compilers can choose to do whatever they want.

Conjecture #3: In Pelles C, when a floating-point value is converted to an integer type, it is wrapped modulo the size of the type, like what happens when converting to a smaller integer type.

Under conjecture #3, trying to assign the value 2^32 to `trsq`

, which is of type `unsigned long`

and 32-bit wide, sets it to 0. Thus `trsq`

has the value 0, the `for`

loop runs 0 times, and the program erroneously reports that the number is prime.

An easy fix is to change `trsq`

to be `unsigned long long`

.

Note that your program may report some numbers as prime if their largest prime factor is very close to their square root (e.g. if the number is the square of a prime), because the conversion of `number`

to a floating-point value may round it down, so `trsq`

may end up being less than the square root, even less than the largest integer that is smaller than the square root.

You can avoid all this trouble by performing an integer square root computation.

warning #2215: Conversion from 'unsigned long long int' to 'long double'; possible loss of data.andwarning #2215: Conversion from 'long double' to 'unsigned long int'; possible loss of data.so there is your problem. and if you hard code the value:warning #2072: Overflow in constant '18446744073709551615'.– this Jan 30 '14 at 22:09`int`

and`long int`

are the same size on Windows, which is not the case here. @self. has the correct answer for you. – CmdrMoozy Jan 30 '14 at 22:16`long double`

, then its square root is 2^32, which overflows a 32-bit`unsigned long`

. This overflow may well cause`trsq`

to have the value 0. If this happens, the loop runs 0 times and the program reports a prime. – Gilles Jan 30 '14 at 22:56