# How are numbers greater than 2^32 handled by a 32 bit machine?

I am trying to understand how calculations involving numbers greater than 232 happen on a 32 bit machine.

C code

``````\$ cat size.c
#include<stdio.h>
#include<math.h>

int main() {

printf ("max unsigned long long = %llu\n",
(unsigned long long)(pow(2, 64) - 1));
}
\$
``````

gcc output

``````\$ gcc size.c -o size
\$ ./size
max unsigned long long = 18446744073709551615
\$
``````

Corresponding assembly code

``````\$ gcc -S size.c -O3
\$ cat size.s
.file   "size.c"
.section    .rodata.str1.4,"aMS",@progbits,1
.align 4
.LC0:
.string "max unsigned long long = %llu\n"
.text
.p2align 4,,15
.globl main
.type   main, @function
main:
pushl   %ebp
movl    %esp, %ebp
andl    \$-16, %esp
subl    \$16, %esp
movl    \$-1, 8(%esp)   #1
movl    \$-1, 12(%esp)  #2
movl    \$.LC0, 4(%esp) #3
movl    \$1, (%esp)     #4
call    __printf_chk
leave
ret
.size   main, .-main
.ident  "GCC: (Ubuntu 4.4.3-4ubuntu5) 4.4.3"
.section    .note.GNU-stack,"",@progbits
\$
``````

What exactly happens on the lines 1 - 4?

Is this some kind of string concatenation at the assembly level?

-
Using `pow` is a very very nasty and error-prone way to compute integer powers of 2. Don't use it. Note that if your floating point subtraction didn't get done as an 80-bit `long double`, `pow(2,64)-1` would be equal to `pow(2,64)`, and then casting it into `unsigned long long` would not work right. –  R.. Oct 9 '10 at 22:25

`__printf_chk` is a wrapper around `printf` which checks for stack overflow, and takes an additional first parameter, a flag (e.g. see here.)

`pow(2, 64) - 1` has been optimised to `0xffffffffffffffff` as the arguments are constants.

As per the usual calling conventions, the first argument to `__printf_chk()` (`int flag`) is a 32-bit value on the stack (at `%esp` at the time of the `call` instruction). The next argument, `const char * format`, is a 32-bit pointer (the next 32-bit word on the stack, i.e. at `%esp+4`). And the 64-bit quantity that is being printed occupies the next two 32-bit words (at `%esp+8` and `%esp+12`):

``````pushl   %ebp                 ; prologue
movl    %esp, %ebp           ; prologue
andl    \$-16, %esp           ; align stack pointer
subl    \$16, %esp            ; reserve bytes for stack frame
movl    \$-1, 8(%esp)   #1    ; store low half of 64-bit argument (a constant) to stack
movl    \$-1, 12(%esp)  #2    ; store high half of 64-bit argument (a constant) to stack
movl    \$.LC0, 4(%esp) #3    ; store address of format string to stack
movl    \$1, (%esp)     #4    ; store "flag" argument to __printf_chk to stack
call    __printf_chk         ; call routine
leave                        ; epilogue
ret                          ; epilogue
``````

The compiler has effectively rewritten this:

``````printf("max unsigned long long = %llu\n", (unsigned long long)(pow(2, 64) - 1));
``````

...into this:

``````__printf_chk(1, "max unsigned long long = %llu\n", 0xffffffffffffffffULL);
``````

...and, at runtime, the stack layout for the call looks like this (showing the stack as 32-bit words, with addresses increasing from the bottom of the diagram upwards):

``````        :                 :
:     Stack       :
:                 :
+-----------------+
%esp+12 |      0xffffffff | \
+-----------------+  } <-------------------------------------.
%esp+8  |      0xffffffff | /                                        |
+-----------------+                                          |
%esp+4  |address of string| <---------------.                        |
+-----------------+                 |                        |
%esp    |               1 | <--.            |                        |
+-----------------+    |            |                        |
__printf_chk(1, "max unsigned long long = %llu\n", |
0xffffffffffffffffULL);
``````
-
awesome, thanks @Matthew. –  Lazer Oct 10 '10 at 14:39

similar to the way as we handle numbers greater than 9, with only digits 0 - 9. (using positional digits). presuming the question is a conceptual one.

-
great insight, never thought about it that way! –  Lazer Oct 10 '10 at 15:07

In your case, the compiler knows that 2^64-1 is just 0xffffffffffffffff, so it has pushed -1 (low dword) and -1 (high dword) onto the stack as your argument to printf. It's just an optimization.

In general, 64-bit numbers (and even greater values) can be stored with multiple words, e.g. an `unsigned long long` uses two `dword`s. To add two 64-bit numbers, two additions are performed - one on the low 32 bits, and one on the high 32 bits, plus the carry:

``````; Add 64-bit number from esi onto edi:
mov     eax, [esi] ; get low 32 bits of source
; That add may have overflowed, and if it did, carry flag = 1.
mov     eax, [esi+4] ; get high 32 bits of source
``````

You can repeat this sequence of `add` and `adc`s as much as you like to add arbitrarily big numbers. The same thing can be done with subtraction - just use `sub` and `sbb` (subtract with borrow).

Multiplication and division are much more complicated, and the compiler usually produces some small helper functions to deal with these whenever you multiply 64-bit numbers together. Packages like GMP which support very, very large integers use SSE/SSE2 to speed things up. Take a look at this Wikipedia article for more information on multiplication algorithms.

-

The compiler actually made a static optimization of your code. lines #1 #2 #3 are parameters for printf()

-
Yes, I understand that. I want to know how exactly `printf` is prepared at these lines 1 - 4. –  Lazer Oct 9 '10 at 21:33
`subl \$16, %esp` makes some room for 4 arguments of 32bits. Line #1 and #2 moves the 64bits argument (so 2 32bits). Line #3 set the format string, and then "1" is pushed as an argument (which must be from the internal printf() call). –  Nicolas Viennot Oct 9 '10 at 21:36

As @Pafy mentions, the compiler has evaluated this as a constant.

2 to the 64th minus 1 is `0xffffffffffffffff`.

As 2 32-bit integers this is: `0xffffffff` and `0xffffffff`,
which if you take that as a pair of 32-bit signed types, ends up as: `-1`, and `-1`.

Thus for your compiler the code generated happens to be equivalent to:

``````printf("max unsigned long long = %llu\n", -1, -1);
``````

In the assembly it's written like this:

``````movl    \$-1, 8(%esp)   #Second -1 parameter
movl    \$-1, 12(%esp)  #First -1 parameter
movl    \$.LC0, 4(%esp) #Format string
movl    \$1, (%esp)     #A one.  Kind of odd, perhaps __printf_chk
#in your C library expects this.
call    __printf_chk
``````

By the way, a better way to calculate powers of 2 is to shift `1` left. Eg. `(1ULL << 64) - 1`.

-
shifting by 64 is undefined. –  GregS Oct 9 '10 at 22:11
The shift is useless. `-1ULL` will give the same result. –  R.. Oct 9 '10 at 22:24

Doh! My mistake, this post is edited.
There's no overflow. Unsigned long long is 64 bit ( for 32bit machines, it's a GNU extension), although it's not a standard type. Unfortunately, there's no guarantee for that.

-
I have updated my question with the gcc results. There is no overflow. –  Lazer Oct 9 '10 at 21:32
It's totally standard with C99 –  Nicolas Viennot Oct 9 '10 at 21:46
O.o Yeah, it really is in C99.. I didn't know that, thanks! –  Kiril Kirov Oct 9 '10 at 21:52