It is also obvious that `3.3 * 2.0`

is numerically identical to `6.6`

. The latter computation is nothing more than an increment of the binary exponent as it is the result of a multiplication with a power of two. You can see this in the following:

```
| s exponent significant
----+-------------------------------------------------------------------
1.1 | 0 01111111111 0001100110011001100110011001100110011001100110011010
2.2 | 0 10000000000 0001100110011001100110011001100110011001100110011010
3.3 | 0 10000000000 1010011001100110011001100110011001100110011001100110
6.6 | 0 10000000001 1010011001100110011001100110011001100110011001100110
```

Above you see the binary representation of the floating point numbers `3.3`

and `6.6`

. The only difference in the two numbers is the exponent since they are only multiplied with two. We know that IEEE-754 will:

- approximate a decimal number with the smallest numerical error
- can represent all integers up to
`2^53`

exactly (for binary64)

So since `2.0`

is exactly representable, a multiplication with this number will be nothing more than a change in the exponent. So all the following will create the same floating point numbers:

```
6.6 == 0.825 * 16.0 == 1.65 * 4.0 == 3.3*2.0 == 13.2 * 0.5 == ...
```

Does this mean that `2.2*3.0`

is different from `6.6`

because of the significant? No, this was just due to rounding errors in the multiplication.

An example where it would have worked would have been `5.5*2.0 == 2.2*5.0 == 11.0`

. Here the rounding was favourable

`==`

. Use`abs(a-b) < Threshold`

if you really want to.`abs(a-b) <= rel_prec * max(abs(a), abs(b))`

is better (with rel_prec close to 1e-16, for instance, for Python's double precision floats). In addition to this, the case of a zero value should be handled too. I did not fully check this, but the following might work:`abs(a-b) <= rel_prec * (max(abs(a), abs(b)) if a != 0 != b else 1)`

.`==`

. It works correctly.`==`

to compare two floating-point numbers." That's horrible advice and it enforces unjustified superstitions.`goto`

and floating-point numbers. Situations where`==`

is appropriate: If you can prove no roundoff error will occur, you use`==`

. For instance, Graham's scan can be implemented correctly with`double`

s if your points have, say, integer coordinates in [-2^24, 2^24]. The cases where youcan'tuse`==`

are scarier, since it means you probably need to fall back to MPFR to see whether your predicate is actually true or actually false.11more comments