The inconsistency is because the *Number::toString* abstract operation is underspecified.

Your question boils down to `BigInt(String(x))`

≟ `BigInt(x)`

, which might assumed to be an equality for integer numbers `x`

but is in fact not.

In your particular case, for `x=18446744073709551616`

or `x=18446744073709552000`

(or anything in between, and even a bit around), the string representation of the number yields `'18446744073709552000'`

whereas the exact mathematical value is 18446744073709551616. (We know this because the *NumberToBigInt* operation is exact - it gets you the mathematical value of the number, or an error if it's not an integer).

We also find the following note on `Number.prototype.toFixed`

:

The output of `toFixed`

may be more precise than `toString`

for some values because `toString`

only prints enough significant digits to distinguish the number from adjacent Number values. For example,

`(1000000000000000128).toString()`

returns `"1000000000000000100"`

, while

`(1000000000000000128).toFixed(0)`

returns `"1000000000000000128"`

.

To answer the titular question

Why does Number(“x”) == BigInt(“x”) … only sometimes?

It's because the limited precision of floating point Number values. There are multiple numeric literals that are parsed to exactly the same number. Similar to your first example, let's take the bigint `20000000000000000n`

. There is a floating point number with the same mathematical value, specifically

`+1`

× `0b10001110000110111100100110111111000001`

× 2^{0b10001}

= 1 × 152587890625 × 2^{17}

= 20000000000000000

There are multiple integer number literals that evaluate to this Number value: `19999999999999998`

, `19999999999999999`

, `20000000000000000`

, `20000000000000001`

, and `20000000000000002`

. (Notice it's not always rounding up). This is also what happens when you take these as strings and use unary `+`

or `Number`

on them.

But if you take the respective bigint literals with the same textual representation, they will evaluate to 5 *different* BigInt values. **Only one** of which will compare equal (with `==`

) to, i.e. have the same mathematical value as, the Number value.

This is consistent: there's always exactly one, and it's the one that can be represented precisely as a floating point number.

Why isn't this behavior consistent?

Your confusion comes from the string representation of the Number value 18446744073709551616. When printing the number literal `18446744073709551616`

, or also `+'18446744073709551616'`

, you got `18446744073709552000`

(because the console uses `String()`

/`.toString()`

internally), which made you assume that 18446744073709552000 was its mathematical value, and that `18446744073709552000n`

should compare equal to it. But it's not :-/

```
console.log(18446744073709551616..toString());
console.log(18446744073709551616..toFixed());
console.log(18446744073709552000..toString());
console.log(18446744073709552000..toFixed());
```

Which to believe?

`BigInt(18446744073709552000) === BigInt(18446744073709551616) === 18446744073709551616n`

. But I still don't see why that's the case. – jtbandes Jun 24 at 0:07`console.log(18446744073709551616) //=> 18446744073709552000`

and`String(18446744073709551616) //=> "18446744073709552000"`

but`BigInt(18446744073709551616) //=> 18446744073709551616n`

while`BigInt(String(18446744073709551616)) //=> 18446744073709552000n`

– Thomas Jun 24 at 0:483more comments