Given two floating-point numbers, I'm looking for an *efficient* way to check if they have the same sign, *given that if any of the two values is zero (+0.0 or -0.0), they should be considered to have the same sign*.

For instance,

- SameSign(1.0, 2.0) should return true
- SameSign(-1.0, -2.0) should return true
- SameSign(-1.0, 2.0) should return false
**SameSign(0.0, 1.0) should return true****SameSign(0.0, -1.0) should return true****SameSign(-0.0, 1.0) should return true****SameSign(-0.0, -1.0) should return true**

A naive but correct implementation of `SameSign`

in C++ would be:

```
bool SameSign(float a, float b)
{
if (fabs(a) == 0.0f || fabs(b) == 0.0f)
return true;
return (a >= 0.0f) == (b >= 0.0f);
}
```

Assuming the IEEE floating-point model, here's a variant of `SameSign`

that compiles to branchless code (at least with with Visual C++ 2008):

```
bool SameSign(float a, float b)
{
int ia = binary_cast<int>(a);
int ib = binary_cast<int>(b);
int az = (ia & 0x7FFFFFFF) == 0;
int bz = (ib & 0x7FFFFFFF) == 0;
int ab = (ia ^ ib) >= 0;
return (az | bz | ab) != 0;
}
```

with `binary_cast`

defined as follow:

```
template <typename Target, typename Source>
inline Target binary_cast(Source s)
{
union
{
Source m_source;
Target m_target;
} u;
u.m_source = s;
return u.m_target;
}
```

I'm looking for two things:

**A faster, more efficient implementation of**, using bit tricks, FPU tricks or even SSE intrinsics.`SameSign`

**An efficient extension of**.`SameSign`

to three values

Edit:

I've made some performance measurements on the three variants of `SameSign`

(the two variants described in the original question, plus Stephen's one). Each function was run 200-400 times, on all consecutive pairs of values in an array of 101 floats filled at random with -1.0, -0.0, +0.0 and +1.0. Each measurement was repeated 2000 times and the minimum time was kept (to weed out all cache effects and system-induced slowdowns). The code was compiled with Visual C++ 2008 SP1 with maximum optimization and SSE2 code generation enabled. The measurements were done on a Core 2 Duo P8600 2.4 Ghz.

Here are the timings, not counting the overhead of fetching input values from the array, calling the function and retrieving the result (which amount to 6-7 clockticks):

- Naive variant: 15 ticks
- Bit magic variant: 13 ticks
**Stephens's variant: 6 ticks**