# How to store a 64 bit integer in 2 32 bit integers and convert back again

I'm pretty sure its just a matter of some bitwise operations, I'm just not entirely sure of exactly what I should be doing, and all searches return back "64 bit vs 32 bit".

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pack:

``````u32 x, y;
u64 v = ((u64)x) << 32 | y;
``````

unpack:

``````x = (u32)((v & 0xFFFFFFFF00000000) >> 32);
y = (u32)(v & 0xFFFFFFFF);
``````
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You don't need the explicit bitmasks when unpacking; `x = (u32)(v>>32); y = (u32)v;` does the job. –  Mike Seymour May 11 '10 at 13:26
@MikeSeymour or Jack - Is it easy for you to find in the C++11 standard confirmation that this is guaranteed to work for all compliant compilers? –  Dan Nissenbaum Apr 21 '14 at 0:19
@DanNissenbaum: Shift operators are specified in 5.8 - well defined for all unsigned values if the shift is in range, as it is here. Unsigned integral conversions are specified in 4.7/2 - defined to preserve all the bits that fit in the new type (specified in terms of modular arithmetic). –  Mike Seymour Apr 21 '14 at 10:47

Or this, if you're not interested in what the two 32-bits numbers mean:

``````u32 x[2];
u64 z;
memcpy(x,&z,sizeof(z));
memcpy(&z,x,sizeof(z));
``````
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+1 for not introducing types and bitshifts. I'd prefer assignments over `memcpy` though. –  Michael Krelin - hacker May 11 '10 at 12:03
Those memcpys get optimised away under GCC and VC though ... –  Goz May 11 '10 at 12:21
Goz, it's not about performance, it's about my (my!) perception of code beauty. –  Michael Krelin - hacker May 11 '10 at 12:41

The basic method is as follows:

``````uint64_t int64;
uint32_t int32_1, int32_2;

int32_1 = int64 & 0xFFFFFFFF;
int32_2 = (int64 & (0xFFFFFFFF << 32) ) >> 32;

// ...

int64 = int32_1 | (int32_2 << 32);
``````

Note that your integers must be unsigned; or the operations are undefined.

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Use a union and get rid of the bit-operations:

``````<stdint.h> // for int32_t, int64_t

union {
int64_t big;
struct {
int32_t x;
int32_t y;
};
};
assert(&y == &x + sizeof(x));
``````

simple as that. big consists of both x and y.

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+1 for the union, but it would be better to use standard fixed size types from `<stdint.h>`, i.e. `int32_t`, `int64_t`, since sizeof(long) and sizeof(long long) are not guaranteed to be any particular value. –  Paul R May 11 '10 at 12:13
@Goz: how come? –  Viktor Sehr May 11 '10 at 12:40
My mistake it leads to undefined behaviour. According to the spec, if you write to big you can't assume that x and y contain anything. The only member of the union that contains valid data is big. Most compilers DO support it but it IS undefined behaviour. You really are better off using a fixed size memcpy that any optimiser worth its salt will optimise out anyway. –  Goz May 11 '10 at 13:02
@Viktor: You can ONLY guarantee that the element you just wrote in is valid. ie if you do myUnion.big = 64; then the only defined way to get the value again is by looking at myUnion.big. Anything else is undefined. –  Goz May 11 '10 at 13:57
@Everyone: Regardless of the anonymous-ness of any of those options if you write a value into big then the only defined way to get that value is through big. Using another entry in the union is undefined behaviour. It works on most compilers I totally agree but it is still undefined behaviour. –  Goz May 12 '10 at 8:46

I don't know if this is any better than the union or memcpy solutions, but I had to unpack/pack signed 64bit integers and didn't really want to mask or shift anything, so I ended up simply treating the 64bit value as two 32bit values and assign them directly like so:

``````#include <stdio.h>
#include <stdint.h>

void repack(int64_t in)
{
int32_t a, b;

printf("input:    %016llx\n", (long long int) in);

a = ((int32_t *) &in)[0];
b = ((int32_t *) &in)[1];

printf("unpacked: %08x %08x\n", b, a);

((int32_t *) &in)[0] = a;
((int32_t *) &in)[1] = b;

printf("repacked: %016llx\n\n", (long long int) in);
}
``````
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