Is there a reliable way in JavaScript to obtain the number of decimal places of an arbitrary number?

It's important to note that I'm not looking for a rounding function. I am looking for a function that returns the number of decimal places in an arbitrary number's simplified decimal representation. That is, we have the following:

decimalPlaces(5555.0);     //=> 0
decimalPlaces(5555);       //=> 0
decimalPlaces(555.5);      //=> 1
decimalPlaces(555.50);     //=> 1
decimalPlaces(0.0000005);  //=> 7
decimalPlaces(5e-7);       //=> 7
decimalPlaces(0.00000055); //=> 8
decimalPlaces(5.5e-7);     //=> 8

My first instinct was to use the string representations: split on '.', then on 'e-', and do the math, like so (the example is verbose):

function decimalPlaces(number) {
  var parts = number.toString().split('.', 2),
    integerPart = parts[0],
    decimalPart = parts[1],
    exponentPart;

  if (integerPart.charAt(0) === '-') {
    integerPart = integerPart.substring(1);
  }

  if (decimalPart !== undefined) {
    parts = decimalPart.split('e-', 2);
    decimalPart = parts[0];
  }
  else {
    parts = integerPart.split('e-', 2);
    integerPart = parts[0];
  }
  exponentPart = parts[1];

  if (exponentPart !== undefined) {
    return integerPart.length +
      (decimalPart !== undefined ? decimalPart.length : 0) - 1 +
      parseInt(exponentPart);
  }
  else {
    return decimalPart !== undefined ? decimalPart.length : 0;
  }
}

For my examples above, this function works. However, I'm not satisfied until I've tested every possible value, so I busted out Number.MIN_VALUE.

Number.MIN_VALUE;                      //=> 5e-324
decimalPlaces(Number.MIN_VALUE);       //=> 324

Number.MIN_VALUE * 100;                //=> 4.94e-322
decimalPlaces(Number.MIN_VALUE * 100); //=> 324

This looked reasonable at first, but then on a double take I realized that 5e-324 * 10 should be 5e-323! And then it hit me: I'm dealing with the effects of quantization of very small numbers. Not only are numbers being quantized before storage; additionally, some numbers stored in binary have unreasonably long decimal representations, so their decimal representations are being truncated. This is unfortunate for me, because it means that I can't get at their true decimal precision using their string representations.

So I come to you, StackOverflow community. Does anyone among you know a reliable way to get at a number's true post-decimal-point precision?

The purpose of this function, should anyone ask, is for use in another function that converts a float into a simplified fraction (that is, it returns the relatively coprime integer numerator and nonzero natural denominator). The only missing piece in this outer function is a reliable way to determine the number of decimal places in the float so I can multiply it by the appropriate power of 10. Hopefully I'm overthinking it.

Historical note: the comment thread below may refer to first and second implementations. I swapped the order in September 2017 since leading with a buggy implementation caused confusion.

If you want something that maps "0.1e-100" to 101, then you can try something like

function decimalPlaces(n) {
  // Make sure it is a number and use the builtin number -> string.
  var s = "" + (+n);
  // Pull out the fraction and the exponent.
  var match = /(?:\.(\d+))?(?:[eE]([+\-]?\d+))?$/.exec(s);
  // NaN or Infinity or integer.
  // We arbitrarily decide that Infinity is integral.
  if (!match) { return 0; }
  // Count the number of digits in the fraction and subtract the
  // exponent to simulate moving the decimal point left by exponent places.
  // 1.234e+2 has 1 fraction digit and '234'.length -  2 == 1
  // 1.234e-2 has 5 fraction digit and '234'.length - -2 == 5
  return Math.max(
      0,  // lower limit.
      (match[1] == '0' ? 0 : (match[1] || '').length)  // fraction length
      - (match[2] || 0));  // exponent
}

According to the spec, any solution based on the builtin number->string conversion can only be accurate to 21 places beyond the exponent.

9.8.1 ToString Applied to the Number Type

5. Otherwise, let n, k, and s be integers such that k ≥ 1, 10k−1 ≤ s < 10k, the Number value for s × 10n−k is m, and k is as small as possible. Note that k is the number of digits in the decimal representation of s, that s is not divisible by 10, and that the least significant digit of s is not necessarily uniquely determined by these criteria.
6. If k ≤ n ≤ 21, return the String consisting of the k digits of the decimal representation of s (in order, with no leading zeroes), followed by n−k occurrences of the character ‘0’.
7. If 0 < n ≤ 21, return the String consisting of the most significant n digits of the decimal representation of s, followed by a decimal point ‘.’, followed by the remaining k−n digits of the decimal representation of s.
8. If −6 < n ≤ 0, return the String consisting of the character ‘0’, followed by a decimal point ‘.’, followed by −n occurrences of the character ‘0’, followed by the k digits of the decimal representation of s.

Historical note: The implementation below is problematic. I leave it here as context for the comment thread.

Based on the definition of Number.prototype.toFixed, it seems like the following should work but due to the IEEE-754 representation of double values, certain numbers will produce false results. For example, decimalPlaces(0.123) will return 20.

function decimalPlaces(number) {
  // toFixed produces a fixed representation accurate to 20 decimal places
  // without an exponent.
  // The ^-?\d*\. strips off any sign, integer portion, and decimal point
  // leaving only the decimal fraction.
  // The 0+$ strips off any trailing zeroes.
  return ((+number).toFixed(20)).replace(/^-?\d*\.?|0+$/g, '').length;
}

// The OP's examples:
console.log(decimalPlaces(5555.0));  // 0
console.log(decimalPlaces(5555));  // 0
console.log(decimalPlaces(555.5));  // 1
console.log(decimalPlaces(555.50));  // 1
console.log(decimalPlaces(0.0000005));  // 7
console.log(decimalPlaces(5e-7));  // 7
console.log(decimalPlaces(0.00000055));  // 8
console.log(decimalPlaces(5e-8));  // 8
console.log(decimalPlaces(0.123));  // 20 (!)

Well, I use a solution based on the fact that if you multiply a floating-point number by the right power of 10, you get an integer.

For instance, if you multiply 3.14 * 10 ^ 2, you get 314 (an integer). The exponent represents then the number of decimals the floating-point number has.

So, I thought that if I gradually multiply a floating-point by increasing powers of 10, you eventually arrive to the solution.

let decimalPlaces = function () {
   function isInt(n) {
      return typeof n === 'number' && 
             parseFloat(n) == parseInt(n, 10) && !isNaN(n);
   }
   return function (n) {
      const a = Math.abs(n);
      let c = a, count = 1;
      while (!isInt(c) && isFinite(c)) {
         c = a * Math.pow(10, count++);
      }
      return count - 1;
   };
}();

for (const x of [
  0.0028, 0.0029, 0.0408,
  0, 1.0, 1.00, 0.123, 1e-3,
  3.14, 2.e-3, 2.e-14, -3.14e-21,
  5555.0, 5555, 555.5, 555.50, 0.0000005, 5e-7, 0.00000055, 5e-8,
  0.000006, 0.0000007,
  0.123, 0.121, 0.1215
]) console.log(x, '->', decimalPlaces(x));