Exactly as you specified, you probably can't (reliably, that is); the floating point value isn't necessarily representable.
The internal representation of the floating point will have all its decimals, but by default it's shown with a fixed number of digits.
The closest you can arrive is using sprintf
:
$a = 1419714319.05059700;
print "$a\n";
print sprintf("%.8f\n", $a);
will output
1419714319.0506
1419714319.05059695
as you can see, there will be a small error. Of course another possibility is to separately store and handle the integer part and the decimal part, possibly pre-multiplying it by one million as a sort of scaling:
$not_a_float = implode('.', explode(' 0.', microtime()));
Note that $not_a_float
does hold the "real" value of microtime()
, but does so as a string. As soon as you perform any floating point operation on that value, it will revert to the floating point precision and the representation inaccuracy will creep back.
You can process separately the two parts; for time differences, you first calculate the difference between the integer parts, then add the second decimal part, then subtract the first:
((($after[0]-$before[0])+$after[1])-$before[1])
The parentheses guarantee to keep the inaccuracy to a minimum. Even so, be sure to keep all the processing possible after the timing, so that it doesn't affect timing itself:
$before_raw = microtime();
...
$after_raw = microtime();
$after = explode(' ', $after_raw);
$before = explode(' ', $before_raw);
$diff = ((($after[0]-$before[0])+$after[1])-$before[1]);