I've been using `parseInt()`

and `parseFloat()`

in various contexts for a while now, and I'd like to think I know all the ins and outs of the two. But recently I had a curious thought which I so far haven't been able to definitively work out a proof for.

Consider the following function:

```
function testProof(strInteger) {
assert(strInteger === '' + parseInt(strInteger, 10));
assert(parseInt(strInteger, 10) === parseFloat(strInteger));
}
// Sample calls...
testProof("5");
testProof("109");
testProof("-55");
```

First we `assert`

that converting the input to an integer and then converting back to a string produces the original string again. This guards against cases where `parseInt("100bucks")`

returns `100`

, and it also makes sure there is no fractional part that's getting truncated off by the conversion -- we want to make sure that the input is actually a whole number, integer string.

If that succeeds, we then `assert`

that `parseInt(..., 10)`

returns the same value as `parseFloat(...)`

.

There are many reasons why the first `assert`

would fail:

- Input is not a whole number (
`"1.5"`

) - Input has leading zeros (
`"0050"`

) - Input has trailing garbage (
`"100bucks"`

) - Input is in exponential notation (
`"1e3"`

), or it's so large it becomes exponential - Input is not parseable, resulting in
`NaN`

- Maybe others?

**But here's the question:** As long as the first `assert`

passes, can the second `assert`

ever fail? Put another way, if we know ahead of time that the input is an integer inside a string, can `parseFloat(...)`

function as a drop-in replacement for `parseInt(..., 10)`

? (Not saying it's a *good* replacement... :-P)