### Spark 2.0+:

You can use `approxQuantile`

method which implements Greenwald-Khanna algorithm:

**Python**:

```
df.approxQuantile("x", [0.5], 0.25)
```

**Scala**:

```
df.stat.approxQuantile("x", Array(0.5), 0.25)
```

where the last parameter is a relative error. The lower the number the more accurate results and more expensive computation.

Since Spark 2.2 (SPARK-14352) it supports estimation on multiple columns:

```
df.approxQuantile(["x", "y", "z"], [0.5], 0.25)
```

and

```
df.approxQuantile(Array("x", "y", "z"), Array(0.5), 0.25)
```

### Spark < 2.0

**Python**

As I've mentioned in the comments it is most likely not worth all the fuss. If data is relatively small like in your case then simply collect and compute median locally:

```
import numpy as np
np.random.seed(323)
rdd = sc.parallelize(np.random.randint(1000000, size=700000))
%time np.median(rdd.collect())
np.array(rdd.collect()).nbytes
```

It takes around 0.01 second on my few years old computer and around 5.5MB of memory.

If data is much larger sorting will be a limiting factor so instead of getting an exact value it is probably better to sample, collect, and compute locally. But if you really want a to use Spark something like this should do the trick (if I didn't mess up anything):

```
from numpy import floor
import time
def quantile(rdd, p, sample=None, seed=None):
"""Compute a quantile of order p ∈ [0, 1]
:rdd a numeric rdd
:p quantile(between 0 and 1)
:sample fraction of and rdd to use. If not provided we use a whole dataset
:seed random number generator seed to be used with sample
"""
assert 0 <= p <= 1
assert sample is None or 0 < sample <= 1
seed = seed if seed is not None else time.time()
rdd = rdd if sample is None else rdd.sample(False, sample, seed)
rddSortedWithIndex = (rdd.
sortBy(lambda x: x).
zipWithIndex().
map(lambda (x, i): (i, x)).
cache())
n = rddSortedWithIndex.count()
h = (n - 1) * p
rddX, rddXPlusOne = (
rddSortedWithIndex.lookup(x)[0]
for x in int(floor(h)) + np.array([0L, 1L]))
return rddX + (h - floor(h)) * (rddXPlusOne - rddX)
```

And some tests:

```
np.median(rdd.collect()), quantile(rdd, 0.5)
## (500184.5, 500184.5)
np.percentile(rdd.collect(), 25), quantile(rdd, 0.25)
## (250506.75, 250506.75)
np.percentile(rdd.collect(), 75), quantile(rdd, 0.75)
(750069.25, 750069.25)
```

Finally lets define median:

```
from functools import partial
median = partial(quantile, p=0.5)
```

So far so good but it takes 4.66 s in a local mode without any network communication. There is probably way to improve this, but why even bother?

**Language independent** (*Hive UDAF*):

If you use `HiveContext`

you can also use Hive UDAFs. With integral values:

```
rdd.map(lambda x: (float(x), )).toDF(["x"]).registerTempTable("df")
sqlContext.sql("SELECT percentile_approx(x, 0.5) FROM df")
```

With continuous values:

```
sqlContext.sql("SELECT percentile(x, 0.5) FROM df")
```

In `percentile_approx`

you can pass an additional argument which determines a number of records to use.

`np.median`

:) Sure, you can sort and index as you described but my guess it will be around and order of magnitude slower. – zero323 Jul 15 '15 at 16:42