checking the source code gives me this (I cut out the implementations for the ranges)

```
bool approxEqual(T, U, V)(T lhs, U rhs, V maxRelDiff, V maxAbsDiff = 1e-5)
{
if (rhs == 0)
{
return fabs(lhs) <= maxAbsDiff;
}
static if (is(typeof(lhs.infinity)) && is(typeof(rhs.infinity)))
{
if (lhs == lhs.infinity && rhs == rhs.infinity ||
lhs == -lhs.infinity && rhs == -rhs.infinity) return true;
}
return fabs((lhs - rhs) / rhs) <= maxRelDiff
|| maxAbsDiff != 0 && fabs(lhs - rhs) <= maxAbsDiff;
}
```

this last line is what we'll need to study:

```
return fabs((lhs - rhs) / rhs) <= maxRelDiff
|| maxAbsDiff != 0 && fabs(lhs - rhs) <= maxAbsDiff;
```

in other words the function returns true if the numbers are either *relatively* different by no more than a factor of `maxRelDiff`

OR *absolutely* different by no more than `maxAbsDiff`

so using a `maxRelDiff`

of `0.01`

(or `1E-2`

) compares with an accuracy of 2 (decimal) digits

and using `maxAbsDiff`

different from 0 allows numbers close to 0 to be considered equal even though there relative difference is greater than `maxRelDiff`

**edit**: basically first decide how accurate the comparison needs to be and choose your `maxRelDiff`

based on that, then decide at what point should a number be equal to 0

with the examples in the comments:

```
approxEqual(1+1e-10, 1.0, 1e-10, 1e-30)
approxEqual(1+1e-10, 1.0, 1e-9, 1e-30)
```

this compares values close to 1 so `maxRelDiff`

trumps here and choosing any `maxAbsDiff`

(lower than `maxRelDiff`

) wont change anything

```
approxEqual(0, 1e-10, 1e-10, 1e-30)
approxEqual(0, 1e-9, 1e-9, 1e-30)
```

this compares values close to 0 to 0 so the RelDiff (`fabs((lhs - rhs) / rhs)`

) will be 1 and `maxAbsDiff`

trumps