### TL;DR

The other answers appear to have solid implementations of the "R-7" version of computing quantiles. Below is some context and another JavaScript implementation borrowed from D3 using the same R-7 method, with the bonuses that **this solution is es5 compliant** (no JavaScript transpilation required) and probably covers a few more edge cases.

### Existing solution from D3 (ported to es5/"vanilla JS")

The "Some Background" section, below, should convince you to grab an existing implementation instead of writing your own.

One good candidate is D3's d3.array package. It has a quantile function that's essentially BSD licensed:

https://github.com/d3/d3-array/blob/master/src/quantile.js

I've quickly created a pretty straight port from es6 into vanilla JavaScript of d3's `quantileSorted`

function (the second function defined in that file) that **requires the array of elements to ***have already been sorted*. Here it is. I've tested it against d3's own results enough to feel it's a valid port, but your experience might differ (let me know in the comments if you find a difference, though!):

Again, remember that sorting must come *before* the call to this function, just as in D3's `quantileSorted`

.

```
//Credit D3: https://github.com/d3/d3-array/blob/master/LICENSE
function quantileSorted(values, p, fnValueFrom) {
var n = values.length;
if (!n) {
return;
}
fnValueFrom =
Object.prototype.toString.call(fnValueFrom) == "[object Function]"
? fnValueFrom
: function (x) {
return x;
};
p = +p;
if (p <= 0 || n < 2) {
return +fnValueFrom(values[0], 0, values);
}
if (p >= 1) {
return +fnValueFrom(values[n - 1], n - 1, values);
}
var i = (n - 1) * p,
i0 = Math.floor(i),
value0 = +fnValueFrom(values[i0], i0, values),
value1 = +fnValueFrom(values[i0 + 1], i0 + 1, values);
return value0 + (value1 - value0) * (i - i0);
}
```

Note that `fnValueFrom`

is a way to process a complex object into a value. You can see how that might work in a list of d3 usage examples here -- search down where `.quantile`

is used.

The quick version is if the `values`

are tortoises and you're sorting `tortoise.age`

in every case, your `fnValueFrom`

might be `x => x.age`

. More complicated versions, including ones that might require accessing the index (parameter 2) and entire collection (parameter 3) during the value calculation, are left up to the reader.

I've added a quick check here so that if nothing is given for `fnValueFrom`

or if what's given isn't a function the logic assumes the elements in `values`

are the actual sorted values themselves.

### Logical comparison to existing answers

I'm reasonably sure this reduces to the same version in the other two answers (see "The R-7 Method", below), but if you needed to justify why you're using this to a product manager or whatever maybe the below will help.

Quick comparison:

```
function Quartile(data, q) {
data=Array_Sort_Numbers(data); // we're assuming it's already sorted, above, vs. the function use here. same difference.
var pos = ((data.length) - 1) * q; // i = (n - 1) * p
var base = Math.floor(pos); // i0 = Math.floor(i)
var rest = pos - base; // (i - i0);
if( (data[base+1]!==undefined) ) {
// value0 + (i - i0) * (value1 which is values[i0+1] - value0 which is values[i0])
return data[base] + rest * (data[base+1] - data[base]);
} else {
// I think this is covered by if (p <= 0 || n < 2)
return data[base];
}
}
```

So that's logically close/appears to be exactly the same. I think d3's version that I ported covers a few more edge/invalid conditions and includes the `fnValueFrom`

integration, both of which could be useful.

### The R-7 Method vs. "Common Sense"

As mentioned in the TL;DR, the answers here, according to d3.array's readme, all use the "R-7 method".

This particular implementation [from d3] uses the R-7 method, which is the default for the R programming language and Excel.

Since the d3.array code matches the other answers here, we can safely say they're all using R-7.

### Background

After a little sleuthing on some math and stats StackExchange sites (1, 2), I found that there are "common sensical" ways of calculating each quantile, but that those don't typically mesh up with the results of the nine generally recognized ways to calculate them.

The answer at that second link from stats.stackexchange says of the common-sensical method that...

**Your textbook is confused.** Very few people or software define quartiles this way. (It tends to make the first quartile too small and the third quartile too large.)

The `quantile`

function in `R`

implements nine different ways to compute quantiles!

I thought that last bit was interesting, and here's what I dug up on those nine methods...

The differences between d3's use of "method 7" (R-7) to determine quantiles versus the common sensical approach is demonstrated nicely in the SO question "d3.quantile seems to be calculating q1 incorrectly", and the why is described in good detail in this post that can be found in philippe's original source for the php version.

Here's a bit from Google Translate (original is in German):

In our example, this value is at the (n + 1) / 4 digit = 5.25, i.e. between the 5th value (= 5) and the 6th value (= 7). The fraction (0.25) indicates that in addition to the value of 5, ¼ of the distance between 5 and 6 is added. Q1 is therefore 5 + 0.25 * 2 = 5.5.

All together, that tells me I probably shouldn't try to code something based on my understanding of what quartiles represent and should borrow someone else's solution.