6

I'd like to find an efficient method to create spare vectors in PySpark using dataframes.

Let's say given the transactional input:

df = spark.createDataFrame([
    (0, "a"),
    (1, "a"),
    (1, "b"),
    (1, "c"),
    (2, "a"),
    (2, "b"),
    (2, "b"),
    (2, "b"),
    (2, "c"),
    (0, "a"),
    (1, "b"),
    (1, "b"),
    (2, "cc"),
    (3, "a"),
    (4, "a"),
    (5, "c")
], ["id", "category"])
+---+--------+
| id|category|
+---+--------+
|  0|       a|
|  1|       a|
|  1|       b|
|  1|       c|
|  2|       a|
|  2|       b|
|  2|       b|
|  2|       b|
|  2|       c|
|  0|       a|
|  1|       b|
|  1|       b|
|  2|      cc|
|  3|       a|
|  4|       a|
|  5|       c|
+---+--------+

In a summed up format:

df.groupBy(df["id"],df["category"]).count().show()
+---+--------+-----+
| id|category|count|
+---+--------+-----+
|  1|       b|    3|
|  1|       a|    1|
|  1|       c|    1|
|  2|      cc|    1|
|  2|       c|    1|
|  2|       a|    1|
|  1|       a|    1|
|  0|       a|    2|
+---+--------+-----+

My aim is to get this output by id:

+---+-----------------------------------------------+
| id|                                       feature |
+---+-----------------------------------------------+
|  2|SparseVector({a: 1.0, b: 3.0, c: 1.0, cc: 1.0})|

Could you please point me in the right direction? With mapreduce in Java it seemed to be way easier for me.

16

This can be done pretty easily with pivot and VectorAssembler. Replace aggregation with pivot:

 pivoted = df.groupBy("id").pivot("category").count().na.fill(0)

and assemble:

from pyspark.ml.feature import VectorAssembler

input_cols = [x for x in pivoted.columns if x != id]

result = (VectorAssembler(inputCols=input_cols, outputCol="features")
    .transform(pivoted)
    .select("id", "features"))

with the result being as follows. This will choose more efficient representation depending on sparsity:

+---+---------------------+
|id |features             |
+---+---------------------+
|0  |(5,[1],[2.0])        |
|5  |(5,[0,3],[5.0,1.0])  |
|1  |[1.0,1.0,3.0,1.0,0.0]|
|3  |(5,[0,1],[3.0,1.0])  |
|2  |[2.0,1.0,3.0,1.0,1.0]|
|4  |(5,[0,1],[4.0,1.0])  |
+---+---------------------+

but of course you can still convert it to a single representation:

from pyspark.ml.linalg import SparseVector, VectorUDT
import numpy as np

def to_sparse(c):
    def to_sparse_(v):
        if isinstance(v, SparseVector):
            return v
        vs = v.toArray()
        nonzero = np.nonzero(vs)[0]
        return SparseVector(v.size, nonzero, vs[nonzero])
    return udf(to_sparse_, VectorUDT())(c)
+---+-------------------------------------+
|id |features                             |
+---+-------------------------------------+
|0  |(5,[1],[2.0])                        |
|5  |(5,[0,3],[5.0,1.0])                  |
|1  |(5,[0,1,2,3],[1.0,1.0,3.0,1.0])      |
|3  |(5,[0,1],[3.0,1.0])                  |
|2  |(5,[0,1,2,3,4],[2.0,1.0,3.0,1.0,1.0])|
|4  |(5,[0,1],[4.0,1.0])                  |
+---+-------------------------------------+
4

If you convert your dataframe to a RDD, you can follow a mapreduce-like framework reduceByKey. The only real tricky part here is to formatting the date for spark's sparseVector

Import packages, create data

from pyspark.ml.feature import StringIndexer
from pyspark.ml.linalg import Vectors
df = sqlContext.createDataFrame([
    (0, "a"),
    (1, "a"),
    (1, "b"),
    (1, "c"),
    (2, "a"),
    (2, "b"),
    (2, "b"),
    (2, "b"),
    (2, "c"),
    (0, "a"),
    (1, "b"),
    (1, "b"),
    (2, "cc"),
    (3, "a"),
    (4, "a"),
    (5, "c")
], ["id", "category"])

Create numerical representation for category (needed for sparse vectors)

indexer = StringIndexer(inputCol="category", outputCol="categoryIndex")
df = indexer.fit(df).transform(df) 

Group by index, get counts

df = df.groupBy(df["id"],df["categoryIndex"]).count()

Convert to a rdd, map the data to key-value pairs of id & [categoryIndex, count]

rdd = df.rdd.map(lambda x: (x.id, [(x.categoryIndex, x['count'])]))

Reduce by key to get key value pairs of id & list of all the [categoryIndex, count] for that id

rdd = rdd.reduceByKey(lambda a, b: a + b)

Map the data to convert the list of all the [categoryIndex, count] for each id into a sparse vector

rdd = rdd.map(lambda x: (x[0], Vectors.sparse(len(x[1]), x[1])))

Convert back to a dataframe

finalDf = sqlContext.createDataFrame(rdd, ['id', 'feature'])

Data check

finalDf.take(5)

 [Row(id=0, feature=SparseVector(1, {1: 2.0})),
  Row(id=1, feature=SparseVector(3, {0: 3.0, 1: 1.0, 2: 1.0})),
  Row(id=2, feature=SparseVector(4, {0: 3.0, 1: 1.0, 2: 1.0, 3: 1.0})),
  Row(id=3, feature=SparseVector(1, {1: 1.0})),
  Row(id=4, feature=SparseVector(1, {1: 1.0}))]

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