You can see the binary representation of the floating number `1.0`

with the following lines of code:

```
#include <stdio.h>
int main(void) {
float a = 1.0;
printf("in hex, this is %08x\n", *((int*)(&a)));
printf("the int representation is %d\n", *((int*)(&a)));
return 0;
}
```

This results in

```
in hex, this is 3f800000
the int representation is 1065353216
```

The format of a 32 bit floating point number is given by

```
1 sign bit (s) = 0
8 exponent bits (e) = 7F = 127
23 mantissa bits (m) = 0
```

You add a (implied) 1 in front of the mantissa - in the above case the mantissa is all zeros, and the implied value is

```
1000 0000 0000 0000 0000 0000
```

This is 2^23 or 8388608. Now you multiply by `(-1)^sign`

- which is `1`

in this case.

Finally, you multiply by 2^(exponent-150). Really, you should express the mantissa as a fraction (1.0000000) and multiply by 2^(exponent-127), but that's the same thing. Either way, the result is `1.0`

That should clear it up for you.

**UPDATE** it was pointed out in the comments that my code example may invoke undefined behavior, although my `gcc`

compiler generated no warnings / errors. The below code is a more correct way to prove that `1.0`

is `1065353216`

in `int`

(for 32 bit `int`

and `float`

...):

```
#include <stdio.h>
union {
int i;
float a;
} either;
int main(void) {
either.a = 1.0;
printf("in hex, this is %08x\n", either.i);
printf("the int representation is %d\n", either.i);
return 0;
}
```