Succinctly, you don't.

The bitwise operators do not make sense when applied to double or float.

Both double and float have 3 sections - a sign bit, an exponent, and the mantissa. Suppose for a moment that you could shift a double right. The exponent, in particular, means that there is no simple translation to shifting a bit pattern right - the sign bit would move into the exponent, and the least significant bit of the exponent would shift into the mantissa, with completely non-obvious sets of meanings. In IEEE 754, there's an implied 1 bit in front of the actual mantissa bits, which also complicates the interpretation.

Similar comments apply to any of the other bit operators.

So, because there is no sane or useful interpretation of the bit operators to double values, they are not allowed.

From the comments:

I'm only interested in the binary representation. I just want to print it, not do anything useful with it.

This code was written several years ago for SPARC (big-endian) architecture.

```
#include <stdio.h>
union u_double
{
double dbl;
char data[sizeof(double)];
};
union u_float
{
float flt;
char data[sizeof(float)];
};
static void dump_float(union u_float f)
{
int exp;
long mant;
printf("32-bit float: sign: %d, ", (f.data[0] & 0x80) >> 7);
exp = ((f.data[0] & 0x7F) << 1) | ((f.data[1] & 0x80) >> 7);
printf("expt: %4d (unbiassed %5d), ", exp, exp - 127);
mant = ((((f.data[1] & 0x7F) << 8) | (f.data[2] & 0xFF)) << 8) | (f.data[3] & 0xFF);
printf("mant: %16ld (0x%06lX)\n", mant, mant);
}
static void dump_double(union u_double d)
{
int exp;
long long mant;
printf("64-bit float: sign: %d, ", (d.data[0] & 0x80) >> 7);
exp = ((d.data[0] & 0x7F) << 4) | ((d.data[1] & 0xF0) >> 4);
printf("expt: %4d (unbiassed %5d), ", exp, exp - 1023);
mant = ((((d.data[1] & 0x0F) << 8) | (d.data[2] & 0xFF)) << 8) | (d.data[3] & 0xFF);
mant = (mant << 32) | ((((((d.data[4] & 0xFF) << 8) | (d.data[5] & 0xFF)) << 8) | (d.data[6] & 0xFF)) << 8) | (d.data[7] & 0xFF);
printf("mant: %16lld (0x%013llX)\n", mant, mant);
}
static void print_value(double v)
{
union u_double d;
union u_float f;
f.flt = v;
d.dbl = v;
printf("SPARC: float/double of %g\n", v);
// image_print(stdout, 0, f.data, sizeof(f.data));
// image_print(stdout, 0, d.data, sizeof(d.data));
dump_float(f);
dump_double(d);
}
int main(void)
{
print_value(+1.0);
print_value(+2.0);
print_value(+3.0);
print_value( 0.0);
print_value(-3.0);
print_value(+3.1415926535897932);
print_value(+1e126);
return(0);
}
```

The commented out 'image_print()` function prints an arbitrary set of bytes in hex, with various minor tweaks. Contact me if you want the code (see my profile).

If you're using Intel (little-endian), you'll probably need to tweak the code to deal with the reverse bit order. But it shows how you can do it - using a `union`

.

`ieee754_float`

and`ieee754_double`

that define (endian safe) bitfields for reading the exponent, mantissa, sign-bit (negative), not-a-number bit etc. – Tony D Jan 20 '11 at 3:55