# -*- encoding: utf-8 -*- # # Licensed to the Apache Software Foundation (ASF) under one or more # contributor license agreements. See the NOTICE file distributed with # this work for additional information regarding copyright ownership. # The ASF licenses this file to You under the Apache License, Version 2.0 # (the "License"); you may not use this file except in compliance with # the License. You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # """ Unit tests for pyspark.sql; additional tests are implemented as doctests in individual modules. """ import os import sys import subprocess import pydoc import shutil import tempfile import threading import pickle import functools import time import datetime import array import ctypes import warnings import py4j from contextlib import contextmanager try: import xmlrunner except ImportError: xmlrunner = None if sys.version_info[:2] <= (2, 6): try: import unittest2 as unittest except ImportError: sys.stderr.write('Please install unittest2 to test with Python 2.6 or earlier') sys.exit(1) else: import unittest from pyspark.util import _exception_message _pandas_requirement_message = None try: from pyspark.sql.utils import require_minimum_pandas_version require_minimum_pandas_version() except ImportError as e: # If Pandas version requirement is not satisfied, skip related tests. _pandas_requirement_message = _exception_message(e) _pyarrow_requirement_message = None try: from pyspark.sql.utils import require_minimum_pyarrow_version require_minimum_pyarrow_version() except ImportError as e: # If Arrow version requirement is not satisfied, skip related tests. _pyarrow_requirement_message = _exception_message(e) _test_not_compiled_message = None try: from pyspark.sql.utils import require_test_compiled require_test_compiled() except Exception as e: _test_not_compiled_message = _exception_message(e) _have_pandas = _pandas_requirement_message is None _have_pyarrow = _pyarrow_requirement_message is None _test_compiled = _test_not_compiled_message is None from pyspark import SparkConf, SparkContext from pyspark.sql import SparkSession, SQLContext, HiveContext, Column, Row from pyspark.sql.types import * from pyspark.sql.types import UserDefinedType, _infer_type, _make_type_verifier from pyspark.sql.types import _array_signed_int_typecode_ctype_mappings, _array_type_mappings from pyspark.sql.types import _array_unsigned_int_typecode_ctype_mappings from pyspark.sql.types import _merge_type from pyspark.tests import QuietTest, ReusedPySparkTestCase, PySparkTestCase, SparkSubmitTests from pyspark.sql.functions import UserDefinedFunction, sha2, lit from pyspark.sql.window import Window from pyspark.sql.utils import AnalysisException, ParseException, IllegalArgumentException class UTCOffsetTimezone(datetime.tzinfo): """ Specifies timezone in UTC offset """ def __init__(self, offset=0): self.ZERO = datetime.timedelta(hours=offset) def utcoffset(self, dt): return self.ZERO def dst(self, dt): return self.ZERO class ExamplePointUDT(UserDefinedType): """ User-defined type (UDT) for ExamplePoint. """ @classmethod def sqlType(self): return ArrayType(DoubleType(), False) @classmethod def module(cls): return 'pyspark.sql.tests' @classmethod def scalaUDT(cls): return 'org.apache.spark.sql.test.ExamplePointUDT' def serialize(self, obj): return [obj.x, obj.y] def deserialize(self, datum): return ExamplePoint(datum[0], datum[1]) class ExamplePoint: """ An example class to demonstrate UDT in Scala, Java, and Python. """ __UDT__ = ExamplePointUDT() def __init__(self, x, y): self.x = x self.y = y def __repr__(self): return "ExamplePoint(%s,%s)" % (self.x, self.y) def __str__(self): return "(%s,%s)" % (self.x, self.y) def __eq__(self, other): return isinstance(other, self.__class__) and \ other.x == self.x and other.y == self.y class PythonOnlyUDT(UserDefinedType): """ User-defined type (UDT) for ExamplePoint. """ @classmethod def sqlType(self): return ArrayType(DoubleType(), False) @classmethod def module(cls): return '__main__' def serialize(self, obj): return [obj.x, obj.y] def deserialize(self, datum): return PythonOnlyPoint(datum[0], datum[1]) @staticmethod def foo(): pass @property def props(self): return {} class PythonOnlyPoint(ExamplePoint): """ An example class to demonstrate UDT in only Python """ __UDT__ = PythonOnlyUDT() class MyObject(object): def __init__(self, key, value): self.key = key self.value = value class SQLTestUtils(object): """ This util assumes the instance of this to have 'spark' attribute, having a spark session. It is usually used with 'ReusedSQLTestCase' class but can be used if you feel sure the the implementation of this class has 'spark' attribute. """ @contextmanager def sql_conf(self, pairs): """ A convenient context manager to test some configuration specific logic. This sets `value` to the configuration `key` and then restores it back when it exits. """ assert isinstance(pairs, dict), "pairs should be a dictionary." assert hasattr(self, "spark"), "it should have 'spark' attribute, having a spark session." keys = pairs.keys() new_values = pairs.values() old_values = [self.spark.conf.get(key, None) for key in keys] for key, new_value in zip(keys, new_values): self.spark.conf.set(key, new_value) try: yield finally: for key, old_value in zip(keys, old_values): if old_value is None: self.spark.conf.unset(key) else: self.spark.conf.set(key, old_value) class ReusedSQLTestCase(ReusedPySparkTestCase, SQLTestUtils): @classmethod def setUpClass(cls): super(ReusedSQLTestCase, cls).setUpClass() cls.spark = SparkSession(cls.sc) @classmethod def tearDownClass(cls): super(ReusedSQLTestCase, cls).tearDownClass() cls.spark.stop() def assertPandasEqual(self, expected, result): msg = ("DataFrames are not equal: " + "\n\nExpected:\n%s\n%s" % (expected, expected.dtypes) + "\n\nResult:\n%s\n%s" % (result, result.dtypes)) self.assertTrue(expected.equals(result), msg=msg) class DataTypeTests(unittest.TestCase): # regression test for SPARK-6055 def test_data_type_eq(self): lt = LongType() lt2 = pickle.loads(pickle.dumps(LongType())) self.assertEqual(lt, lt2) # regression test for SPARK-7978 def test_decimal_type(self): t1 = DecimalType() t2 = DecimalType(10, 2) self.assertTrue(t2 is not t1) self.assertNotEqual(t1, t2) t3 = DecimalType(8) self.assertNotEqual(t2, t3) # regression test for SPARK-10392 def test_datetype_equal_zero(self): dt = DateType() self.assertEqual(dt.fromInternal(0), datetime.date(1970, 1, 1)) # regression test for SPARK-17035 def test_timestamp_microsecond(self): tst = TimestampType() self.assertEqual(tst.toInternal(datetime.datetime.max) % 1000000, 999999) def test_empty_row(self): row = Row() self.assertEqual(len(row), 0) def test_struct_field_type_name(self): struct_field = StructField("a", IntegerType()) self.assertRaises(TypeError, struct_field.typeName) def test_invalid_create_row(self): row_class = Row("c1", "c2") self.assertRaises(ValueError, lambda: row_class(1, 2, 3)) class SparkSessionBuilderTests(unittest.TestCase): def test_create_spark_context_first_then_spark_session(self): sc = None session = None try: conf = SparkConf().set("key1", "value1") sc = SparkContext('local[4]', "SessionBuilderTests", conf=conf) session = SparkSession.builder.config("key2", "value2").getOrCreate() self.assertEqual(session.conf.get("key1"), "value1") self.assertEqual(session.conf.get("key2"), "value2") self.assertEqual(session.sparkContext, sc) self.assertFalse(sc.getConf().contains("key2")) self.assertEqual(sc.getConf().get("key1"), "value1") finally: if session is not None: session.stop() if sc is not None: sc.stop() def test_another_spark_session(self): session1 = None session2 = None try: session1 = SparkSession.builder.config("key1", "value1").getOrCreate() session2 = SparkSession.builder.config("key2", "value2").getOrCreate() self.assertEqual(session1.conf.get("key1"), "value1") self.assertEqual(session2.conf.get("key1"), "value1") self.assertEqual(session1.conf.get("key2"), "value2") self.assertEqual(session2.conf.get("key2"), "value2") self.assertEqual(session1.sparkContext, session2.sparkContext) self.assertEqual(session1.sparkContext.getConf().get("key1"), "value1") self.assertFalse(session1.sparkContext.getConf().contains("key2")) finally: if session1 is not None: session1.stop() if session2 is not None: session2.stop() class SQLTests(ReusedSQLTestCase): @classmethod def setUpClass(cls): ReusedSQLTestCase.setUpClass() cls.tempdir = tempfile.NamedTemporaryFile(delete=False) os.unlink(cls.tempdir.name) cls.testData = [Row(key=i, value=str(i)) for i in range(100)] cls.df = cls.spark.createDataFrame(cls.testData) @classmethod def tearDownClass(cls): ReusedSQLTestCase.tearDownClass() shutil.rmtree(cls.tempdir.name, ignore_errors=True) def test_sqlcontext_reuses_sparksession(self): sqlContext1 = SQLContext(self.sc) sqlContext2 = SQLContext(self.sc) self.assertTrue(sqlContext1.sparkSession is sqlContext2.sparkSession) def tearDown(self): super(SQLTests, self).tearDown() # tear down test_bucketed_write state self.spark.sql("DROP TABLE IF EXISTS pyspark_bucket") def test_row_should_be_read_only(self): row = Row(a=1, b=2) self.assertEqual(1, row.a) def foo(): row.a = 3 self.assertRaises(Exception, foo) row2 = self.spark.range(10).first() self.assertEqual(0, row2.id) def foo2(): row2.id = 2 self.assertRaises(Exception, foo2) def test_range(self): self.assertEqual(self.spark.range(1, 1).count(), 0) self.assertEqual(self.spark.range(1, 0, -1).count(), 1) self.assertEqual(self.spark.range(0, 1 << 40, 1 << 39).count(), 2) self.assertEqual(self.spark.range(-2).count(), 0) self.assertEqual(self.spark.range(3).count(), 3) def test_duplicated_column_names(self): df = self.spark.createDataFrame([(1, 2)], ["c", "c"]) row = df.select('*').first() self.assertEqual(1, row[0]) self.assertEqual(2, row[1]) self.assertEqual("Row(c=1, c=2)", str(row)) # Cannot access columns self.assertRaises(AnalysisException, lambda: df.select(df[0]).first()) self.assertRaises(AnalysisException, lambda: df.select(df.c).first()) self.assertRaises(AnalysisException, lambda: df.select(df["c"]).first()) def test_column_name_encoding(self): """Ensure that created columns has `str` type consistently.""" columns = self.spark.createDataFrame([('Alice', 1)], ['name', u'age']).columns self.assertEqual(columns, ['name', 'age']) self.assertTrue(isinstance(columns[0], str)) self.assertTrue(isinstance(columns[1], str)) def test_explode(self): from pyspark.sql.functions import explode, explode_outer, posexplode_outer d = [ Row(a=1, intlist=[1, 2, 3], mapfield={"a": "b"}), Row(a=1, intlist=[], mapfield={}), Row(a=1, intlist=None, mapfield=None), ] rdd = self.sc.parallelize(d) data = self.spark.createDataFrame(rdd) result = data.select(explode(data.intlist).alias("a")).select("a").collect() self.assertEqual(result[0][0], 1) self.assertEqual(result[1][0], 2) self.assertEqual(result[2][0], 3) result = data.select(explode(data.mapfield).alias("a", "b")).select("a", "b").collect() self.assertEqual(result[0][0], "a") self.assertEqual(result[0][1], "b") result = [tuple(x) for x in data.select(posexplode_outer("intlist")).collect()] self.assertEqual(result, [(0, 1), (1, 2), (2, 3), (None, None), (None, None)]) result = [tuple(x) for x in data.select(posexplode_outer("mapfield")).collect()] self.assertEqual(result, [(0, 'a', 'b'), (None, None, None), (None, None, None)]) result = [x[0] for x in data.select(explode_outer("intlist")).collect()] self.assertEqual(result, [1, 2, 3, None, None]) result = [tuple(x) for x in data.select(explode_outer("mapfield")).collect()] self.assertEqual(result, [('a', 'b'), (None, None), (None, None)]) def test_and_in_expression(self): self.assertEqual(4, self.df.filter((self.df.key <= 10) & (self.df.value <= "2")).count()) self.assertRaises(ValueError, lambda: (self.df.key <= 10) and (self.df.value <= "2")) self.assertEqual(14, self.df.filter((self.df.key <= 3) | (self.df.value < "2")).count()) self.assertRaises(ValueError, lambda: self.df.key <= 3 or self.df.value < "2") self.assertEqual(99, self.df.filter(~(self.df.key == 1)).count()) self.assertRaises(ValueError, lambda: not self.df.key == 1) def test_udf_with_callable(self): d = [Row(number=i, squared=i**2) for i in range(10)] rdd = self.sc.parallelize(d) data = self.spark.createDataFrame(rdd) class PlusFour: def __call__(self, col): if col is not None: return col + 4 call = PlusFour() pudf = UserDefinedFunction(call, LongType()) res = data.select(pudf(data['number']).alias('plus_four')) self.assertEqual(res.agg({'plus_four': 'sum'}).collect()[0][0], 85) def test_udf_with_partial_function(self): d = [Row(number=i, squared=i**2) for i in range(10)] rdd = self.sc.parallelize(d) data = self.spark.createDataFrame(rdd) def some_func(col, param): if col is not None: return col + param pfunc = functools.partial(some_func, param=4) pudf = UserDefinedFunction(pfunc, LongType()) res = data.select(pudf(data['number']).alias('plus_four')) self.assertEqual(res.agg({'plus_four': 'sum'}).collect()[0][0], 85) def test_udf(self): self.spark.catalog.registerFunction("twoArgs", lambda x, y: len(x) + y, IntegerType()) [row] = self.spark.sql("SELECT twoArgs('test', 1)").collect() self.assertEqual(row[0], 5) # This is to check if a deprecated 'SQLContext.registerFunction' can call its alias. sqlContext = self.spark._wrapped sqlContext.registerFunction("oneArg", lambda x: len(x), IntegerType()) [row] = sqlContext.sql("SELECT oneArg('test')").collect() self.assertEqual(row[0], 4) def test_udf2(self): self.spark.catalog.registerFunction("strlen", lambda string: len(string), IntegerType()) self.spark.createDataFrame(self.sc.parallelize([Row(a="test")]))\ .createOrReplaceTempView("test") [res] = self.spark.sql("SELECT strlen(a) FROM test WHERE strlen(a) > 1").collect() self.assertEqual(4, res[0]) def test_udf3(self): two_args = self.spark.catalog.registerFunction( "twoArgs", UserDefinedFunction(lambda x, y: len(x) + y)) self.assertEqual(two_args.deterministic, True) [row] = self.spark.sql("SELECT twoArgs('test', 1)").collect() self.assertEqual(row[0], u'5') def test_udf_registration_return_type_none(self): two_args = self.spark.catalog.registerFunction( "twoArgs", UserDefinedFunction(lambda x, y: len(x) + y, "integer"), None) self.assertEqual(two_args.deterministic, True) [row] = self.spark.sql("SELECT twoArgs('test', 1)").collect() self.assertEqual(row[0], 5) def test_udf_registration_return_type_not_none(self): with QuietTest(self.sc): with self.assertRaisesRegexp(TypeError, "Invalid returnType"): self.spark.catalog.registerFunction( "f", UserDefinedFunction(lambda x, y: len(x) + y, StringType()), StringType()) def test_nondeterministic_udf(self): # Test that nondeterministic UDFs are evaluated only once in chained UDF evaluations from pyspark.sql.functions import udf import random udf_random_col = udf(lambda: int(100 * random.random()), IntegerType()).asNondeterministic() self.assertEqual(udf_random_col.deterministic, False) df = self.spark.createDataFrame([Row(1)]).select(udf_random_col().alias('RAND')) udf_add_ten = udf(lambda rand: rand + 10, IntegerType()) [row] = df.withColumn('RAND_PLUS_TEN', udf_add_ten('RAND')).collect() self.assertEqual(row[0] + 10, row[1]) def test_nondeterministic_udf2(self): import random from pyspark.sql.functions import udf random_udf = udf(lambda: random.randint(6, 6), IntegerType()).asNondeterministic() self.assertEqual(random_udf.deterministic, False) random_udf1 = self.spark.catalog.registerFunction("randInt", random_udf) self.assertEqual(random_udf1.deterministic, False) [row] = self.spark.sql("SELECT randInt()").collect() self.assertEqual(row[0], 6) [row] = self.spark.range(1).select(random_udf1()).collect() self.assertEqual(row[0], 6) [row] = self.spark.range(1).select(random_udf()).collect() self.assertEqual(row[0], 6) # render_doc() reproduces the help() exception without printing output pydoc.render_doc(udf(lambda: random.randint(6, 6), IntegerType())) pydoc.render_doc(random_udf) pydoc.render_doc(random_udf1) pydoc.render_doc(udf(lambda x: x).asNondeterministic) def test_nondeterministic_udf3(self): # regression test for SPARK-23233 from pyspark.sql.functions import udf f = udf(lambda x: x) # Here we cache the JVM UDF instance. self.spark.range(1).select(f("id")) # This should reset the cache to set the deterministic status correctly. f = f.asNondeterministic() # Check the deterministic status of udf. df = self.spark.range(1).select(f("id")) deterministic = df._jdf.logicalPlan().projectList().head().deterministic() self.assertFalse(deterministic) def test_nondeterministic_udf_in_aggregate(self): from pyspark.sql.functions import udf, sum import random udf_random_col = udf(lambda: int(100 * random.random()), 'int').asNondeterministic() df = self.spark.range(10) with QuietTest(self.sc): with self.assertRaisesRegexp(AnalysisException, "nondeterministic"): df.groupby('id').agg(sum(udf_random_col())).collect() with self.assertRaisesRegexp(AnalysisException, "nondeterministic"): df.agg(sum(udf_random_col())).collect() def test_chained_udf(self): self.spark.catalog.registerFunction("double", lambda x: x + x, IntegerType()) [row] = self.spark.sql("SELECT double(1)").collect() self.assertEqual(row[0], 2) [row] = self.spark.sql("SELECT double(double(1))").collect() self.assertEqual(row[0], 4) [row] = self.spark.sql("SELECT double(double(1) + 1)").collect() self.assertEqual(row[0], 6) def test_single_udf_with_repeated_argument(self): # regression test for SPARK-20685 self.spark.catalog.registerFunction("add", lambda x, y: x + y, IntegerType()) row = self.spark.sql("SELECT add(1, 1)").first() self.assertEqual(tuple(row), (2, )) def test_multiple_udfs(self): self.spark.catalog.registerFunction("double", lambda x: x * 2, IntegerType()) [row] = self.spark.sql("SELECT double(1), double(2)").collect() self.assertEqual(tuple(row), (2, 4)) [row] = self.spark.sql("SELECT double(double(1)), double(double(2) + 2)").collect() self.assertEqual(tuple(row), (4, 12)) self.spark.catalog.registerFunction("add", lambda x, y: x + y, IntegerType()) [row] = self.spark.sql("SELECT double(add(1, 2)), add(double(2), 1)").collect() self.assertEqual(tuple(row), (6, 5)) def test_udf_in_filter_on_top_of_outer_join(self): from pyspark.sql.functions import udf left = self.spark.createDataFrame([Row(a=1)]) right = self.spark.createDataFrame([Row(a=1)]) df = left.join(right, on='a', how='left_outer') df = df.withColumn('b', udf(lambda x: 'x')(df.a)) self.assertEqual(df.filter('b = "x"').collect(), [Row(a=1, b='x')]) def test_udf_in_filter_on_top_of_join(self): # regression test for SPARK-18589 from pyspark.sql.functions import udf left = self.spark.createDataFrame([Row(a=1)]) right = self.spark.createDataFrame([Row(b=1)]) f = udf(lambda a, b: a == b, BooleanType()) df = left.crossJoin(right).filter(f("a", "b")) self.assertEqual(df.collect(), [Row(a=1, b=1)]) def test_udf_in_join_condition(self): # regression test for SPARK-25314 from pyspark.sql.functions import udf left = self.spark.createDataFrame([Row(a=1)]) right = self.spark.createDataFrame([Row(b=1)]) f = udf(lambda a, b: a == b, BooleanType()) df = left.join(right, f("a", "b")) with self.assertRaisesRegexp(AnalysisException, 'Detected implicit cartesian product'): df.collect() with self.sql_conf({"spark.sql.crossJoin.enabled": True}): self.assertEqual(df.collect(), [Row(a=1, b=1)]) def test_udf_in_left_semi_join_condition(self): # regression test for SPARK-25314 from pyspark.sql.functions import udf left = self.spark.createDataFrame([Row(a=1, a1=1, a2=1), Row(a=2, a1=2, a2=2)]) right = self.spark.createDataFrame([Row(b=1, b1=1, b2=1)]) f = udf(lambda a, b: a == b, BooleanType()) df = left.join(right, f("a", "b"), "leftsemi") with self.assertRaisesRegexp(AnalysisException, 'Detected implicit cartesian product'): df.collect() with self.sql_conf({"spark.sql.crossJoin.enabled": True}): self.assertEqual(df.collect(), [Row(a=1, a1=1, a2=1)]) def test_udf_and_common_filter_in_join_condition(self): # regression test for SPARK-25314 # test the complex scenario with both udf and common filter from pyspark.sql.functions import udf left = self.spark.createDataFrame([Row(a=1, a1=1, a2=1), Row(a=2, a1=2, a2=2)]) right = self.spark.createDataFrame([Row(b=1, b1=1, b2=1), Row(b=1, b1=3, b2=1)]) f = udf(lambda a, b: a == b, BooleanType()) df = left.join(right, [f("a", "b"), left.a1 == right.b1]) # do not need spark.sql.crossJoin.enabled=true for udf is not the only join condition. self.assertEqual(df.collect(), [Row(a=1, a1=1, a2=1, b=1, b1=1, b2=1)]) def test_udf_and_common_filter_in_left_semi_join_condition(self): # regression test for SPARK-25314 # test the complex scenario with both udf and common filter from pyspark.sql.functions import udf left = self.spark.createDataFrame([Row(a=1, a1=1, a2=1), Row(a=2, a1=2, a2=2)]) right = self.spark.createDataFrame([Row(b=1, b1=1, b2=1), Row(b=1, b1=3, b2=1)]) f = udf(lambda a, b: a == b, BooleanType()) df = left.join(right, [f("a", "b"), left.a1 == right.b1], "left_semi") # do not need spark.sql.crossJoin.enabled=true for udf is not the only join condition. self.assertEqual(df.collect(), [Row(a=1, a1=1, a2=1)]) def test_udf_not_supported_in_join_condition(self): # regression test for SPARK-25314 # test python udf is not supported in join type besides left_semi and inner join. from pyspark.sql.functions import udf left = self.spark.createDataFrame([Row(a=1, a1=1, a2=1), Row(a=2, a1=2, a2=2)]) right = self.spark.createDataFrame([Row(b=1, b1=1, b2=1), Row(b=1, b1=3, b2=1)]) f = udf(lambda a, b: a == b, BooleanType()) def runWithJoinType(join_type, type_string): with self.assertRaisesRegexp( AnalysisException, 'Using PythonUDF.*%s is not supported.' % type_string): left.join(right, [f("a", "b"), left.a1 == right.b1], join_type).collect() runWithJoinType("full", "FullOuter") runWithJoinType("left", "LeftOuter") runWithJoinType("right", "RightOuter") runWithJoinType("leftanti", "LeftAnti") def test_udf_without_arguments(self): self.spark.catalog.registerFunction("foo", lambda: "bar") [row] = self.spark.sql("SELECT foo()").collect() self.assertEqual(row[0], "bar") def test_udf_with_array_type(self): d = [Row(l=list(range(3)), d={"key": list(range(5))})] rdd = self.sc.parallelize(d) self.spark.createDataFrame(rdd).createOrReplaceTempView("test") self.spark.catalog.registerFunction("copylist", lambda l: list(l), ArrayType(IntegerType())) self.spark.catalog.registerFunction("maplen", lambda d: len(d), IntegerType()) [(l1, l2)] = self.spark.sql("select copylist(l), maplen(d) from test").collect() self.assertEqual(list(range(3)), l1) self.assertEqual(1, l2) def test_broadcast_in_udf(self): bar = {"a": "aa", "b": "bb", "c": "abc"} foo = self.sc.broadcast(bar) self.spark.catalog.registerFunction("MYUDF", lambda x: foo.value[x] if x else '') [res] = self.spark.sql("SELECT MYUDF('c')").collect() self.assertEqual("abc", res[0]) [res] = self.spark.sql("SELECT MYUDF('')").collect() self.assertEqual("", res[0]) def test_udf_with_filter_function(self): df = self.spark.createDataFrame([(1, "1"), (2, "2"), (1, "2"), (1, "2")], ["key", "value"]) from pyspark.sql.functions import udf, col from pyspark.sql.types import BooleanType my_filter = udf(lambda a: a < 2, BooleanType()) sel = df.select(col("key"), col("value")).filter((my_filter(col("key"))) & (df.value < "2")) self.assertEqual(sel.collect(), [Row(key=1, value='1')]) def test_udf_with_aggregate_function(self): df = self.spark.createDataFrame([(1, "1"), (2, "2"), (1, "2"), (1, "2")], ["key", "value"]) from pyspark.sql.functions import udf, col, sum from pyspark.sql.types import BooleanType my_filter = udf(lambda a: a == 1, BooleanType()) sel = df.select(col("key")).distinct().filter(my_filter(col("key"))) self.assertEqual(sel.collect(), [Row(key=1)]) my_copy = udf(lambda x: x, IntegerType()) my_add = udf(lambda a, b: int(a + b), IntegerType()) my_strlen = udf(lambda x: len(x), IntegerType()) sel = df.groupBy(my_copy(col("key")).alias("k"))\ .agg(sum(my_strlen(col("value"))).alias("s"))\ .select(my_add(col("k"), col("s")).alias("t")) self.assertEqual(sel.collect(), [Row(t=4), Row(t=3)]) def test_udf_in_generate(self): from pyspark.sql.functions import udf, explode df = self.spark.range(5) f = udf(lambda x: list(range(x)), ArrayType(LongType())) row = df.select(explode(f(*df))).groupBy().sum().first() self.assertEqual(row[0], 10) df = self.spark.range(3) res = df.select("id", explode(f(df.id))).collect() self.assertEqual(res[0][0], 1) self.assertEqual(res[0][1], 0) self.assertEqual(res[1][0], 2) self.assertEqual(res[1][1], 0) self.assertEqual(res[2][0], 2) self.assertEqual(res[2][1], 1) range_udf = udf(lambda value: list(range(value - 1, value + 1)), ArrayType(IntegerType())) res = df.select("id", explode(range_udf(df.id))).collect() self.assertEqual(res[0][0], 0) self.assertEqual(res[0][1], -1) self.assertEqual(res[1][0], 0) self.assertEqual(res[1][1], 0) self.assertEqual(res[2][0], 1) self.assertEqual(res[2][1], 0) self.assertEqual(res[3][0], 1) self.assertEqual(res[3][1], 1) def test_udf_with_order_by_and_limit(self): from pyspark.sql.functions import udf my_copy = udf(lambda x: x, IntegerType()) df = self.spark.range(10).orderBy("id") res = df.select(df.id, my_copy(df.id).alias("copy")).limit(1) res.explain(True) self.assertEqual(res.collect(), [Row(id=0, copy=0)]) def test_udf_registration_returns_udf(self): df = self.spark.range(10) add_three = self.spark.udf.register("add_three", lambda x: x + 3, IntegerType()) self.assertListEqual( df.selectExpr("add_three(id) AS plus_three").collect(), df.select(add_three("id").alias("plus_three")).collect() ) # This is to check if a 'SQLContext.udf' can call its alias. sqlContext = self.spark._wrapped add_four = sqlContext.udf.register("add_four", lambda x: x + 4, IntegerType()) self.assertListEqual( df.selectExpr("add_four(id) AS plus_four").collect(), df.select(add_four("id").alias("plus_four")).collect() ) def test_non_existed_udf(self): spark = self.spark self.assertRaisesRegexp(AnalysisException, "Can not load class non_existed_udf", lambda: spark.udf.registerJavaFunction("udf1", "non_existed_udf")) # This is to check if a deprecated 'SQLContext.registerJavaFunction' can call its alias. sqlContext = spark._wrapped self.assertRaisesRegexp(AnalysisException, "Can not load class non_existed_udf", lambda: sqlContext.registerJavaFunction("udf1", "non_existed_udf")) def test_non_existed_udaf(self): spark = self.spark self.assertRaisesRegexp(AnalysisException, "Can not load class non_existed_udaf", lambda: spark.udf.registerJavaUDAF("udaf1", "non_existed_udaf")) def test_linesep_text(self): df = self.spark.read.text("python/test_support/sql/ages_newlines.csv", lineSep=",") expected = [Row(value=u'Joe'), Row(value=u'20'), Row(value=u'"Hi'), Row(value=u'\nI am Jeo"\nTom'), Row(value=u'30'), Row(value=u'"My name is Tom"\nHyukjin'), Row(value=u'25'), Row(value=u'"I am Hyukjin\n\nI love Spark!"\n')] self.assertEqual(df.collect(), expected) tpath = tempfile.mkdtemp() shutil.rmtree(tpath) try: df.write.text(tpath, lineSep="!") expected = [Row(value=u'Joe!20!"Hi!'), Row(value=u'I am Jeo"'), Row(value=u'Tom!30!"My name is Tom"'), Row(value=u'Hyukjin!25!"I am Hyukjin'), Row(value=u''), Row(value=u'I love Spark!"'), Row(value=u'!')] readback = self.spark.read.text(tpath) self.assertEqual(readback.collect(), expected) finally: shutil.rmtree(tpath) def test_multiline_json(self): people1 = self.spark.read.json("python/test_support/sql/people.json") people_array = self.spark.read.json("python/test_support/sql/people_array.json", multiLine=True) self.assertEqual(people1.collect(), people_array.collect()) def test_encoding_json(self): people_array = self.spark.read\ .json("python/test_support/sql/people_array_utf16le.json", multiLine=True, encoding="UTF-16LE") expected = [Row(age=30, name=u'Andy'), Row(age=19, name=u'Justin')] self.assertEqual(people_array.collect(), expected) def test_linesep_json(self): df = self.spark.read.json("python/test_support/sql/people.json", lineSep=",") expected = [Row(_corrupt_record=None, name=u'Michael'), Row(_corrupt_record=u' "age":30}\n{"name":"Justin"', name=None), Row(_corrupt_record=u' "age":19}\n', name=None)] self.assertEqual(df.collect(), expected) tpath = tempfile.mkdtemp() shutil.rmtree(tpath) try: df = self.spark.read.json("python/test_support/sql/people.json") df.write.json(tpath, lineSep="!!") readback = self.spark.read.json(tpath, lineSep="!!") self.assertEqual(readback.collect(), df.collect()) finally: shutil.rmtree(tpath) def test_multiline_csv(self): ages_newlines = self.spark.read.csv( "python/test_support/sql/ages_newlines.csv", multiLine=True) expected = [Row(_c0=u'Joe', _c1=u'20', _c2=u'Hi,\nI am Jeo'), Row(_c0=u'Tom', _c1=u'30', _c2=u'My name is Tom'), Row(_c0=u'Hyukjin', _c1=u'25', _c2=u'I am Hyukjin\n\nI love Spark!')] self.assertEqual(ages_newlines.collect(), expected) def test_ignorewhitespace_csv(self): tmpPath = tempfile.mkdtemp() shutil.rmtree(tmpPath) self.spark.createDataFrame([[" a", "b ", " c "]]).write.csv( tmpPath, ignoreLeadingWhiteSpace=False, ignoreTrailingWhiteSpace=False) expected = [Row(value=u' a,b , c ')] readback = self.spark.read.text(tmpPath) self.assertEqual(readback.collect(), expected) shutil.rmtree(tmpPath) def test_read_multiple_orc_file(self): df = self.spark.read.orc(["python/test_support/sql/orc_partitioned/b=0/c=0", "python/test_support/sql/orc_partitioned/b=1/c=1"]) self.assertEqual(2, df.count()) def test_udf_with_input_file_name(self): from pyspark.sql.functions import udf, input_file_name sourceFile = udf(lambda path: path, StringType()) filePath = "python/test_support/sql/people1.json" row = self.spark.read.json(filePath).select(sourceFile(input_file_name())).first() self.assertTrue(row[0].find("people1.json") != -1) def test_udf_with_input_file_name_for_hadooprdd(self): from pyspark.sql.functions import udf, input_file_name def filename(path): return path sameText = udf(filename, StringType()) rdd = self.sc.textFile('python/test_support/sql/people.json') df = self.spark.read.json(rdd).select(input_file_name().alias('file')) row = df.select(sameText(df['file'])).first() self.assertTrue(row[0].find("people.json") != -1) rdd2 = self.sc.newAPIHadoopFile( 'python/test_support/sql/people.json', 'org.apache.hadoop.mapreduce.lib.input.TextInputFormat', 'org.apache.hadoop.io.LongWritable', 'org.apache.hadoop.io.Text') df2 = self.spark.read.json(rdd2).select(input_file_name().alias('file')) row2 = df2.select(sameText(df2['file'])).first() self.assertTrue(row2[0].find("people.json") != -1) def test_udf_defers_judf_initialization(self): # This is separate of UDFInitializationTests # to avoid context initialization # when udf is called from pyspark.sql.functions import UserDefinedFunction f = UserDefinedFunction(lambda x: x, StringType()) self.assertIsNone( f._judf_placeholder, "judf should not be initialized before the first call." ) self.assertIsInstance(f("foo"), Column, "UDF call should return a Column.") self.assertIsNotNone( f._judf_placeholder, "judf should be initialized after UDF has been called." ) def test_udf_with_string_return_type(self): from pyspark.sql.functions import UserDefinedFunction add_one = UserDefinedFunction(lambda x: x + 1, "integer") make_pair = UserDefinedFunction(lambda x: (-x, x), "struct") make_array = UserDefinedFunction( lambda x: [float(x) for x in range(x, x + 3)], "array") expected = (2, Row(x=-1, y=1), [1.0, 2.0, 3.0]) actual = (self.spark.range(1, 2).toDF("x") .select(add_one("x"), make_pair("x"), make_array("x")) .first()) self.assertTupleEqual(expected, actual) def test_udf_shouldnt_accept_noncallable_object(self): from pyspark.sql.functions import UserDefinedFunction non_callable = None self.assertRaises(TypeError, UserDefinedFunction, non_callable, StringType()) def test_udf_with_decorator(self): from pyspark.sql.functions import lit, udf from pyspark.sql.types import IntegerType, DoubleType @udf(IntegerType()) def add_one(x): if x is not None: return x + 1 @udf(returnType=DoubleType()) def add_two(x): if x is not None: return float(x + 2) @udf def to_upper(x): if x is not None: return x.upper() @udf() def to_lower(x): if x is not None: return x.lower() @udf def substr(x, start, end): if x is not None: return x[start:end] @udf("long") def trunc(x): return int(x) @udf(returnType="double") def as_double(x): return float(x) df = ( self.spark .createDataFrame( [(1, "Foo", "foobar", 3.0)], ("one", "Foo", "foobar", "float")) .select( add_one("one"), add_two("one"), to_upper("Foo"), to_lower("Foo"), substr("foobar", lit(0), lit(3)), trunc("float"), as_double("one"))) self.assertListEqual( [tpe for _, tpe in df.dtypes], ["int", "double", "string", "string", "string", "bigint", "double"] ) self.assertListEqual( list(df.first()), [2, 3.0, "FOO", "foo", "foo", 3, 1.0] ) def test_udf_wrapper(self): from pyspark.sql.functions import udf from pyspark.sql.types import IntegerType def f(x): """Identity""" return x return_type = IntegerType() f_ = udf(f, return_type) self.assertTrue(f.__doc__ in f_.__doc__) self.assertEqual(f, f_.func) self.assertEqual(return_type, f_.returnType) class F(object): """Identity""" def __call__(self, x): return x f = F() return_type = IntegerType() f_ = udf(f, return_type) self.assertTrue(f.__doc__ in f_.__doc__) self.assertEqual(f, f_.func) self.assertEqual(return_type, f_.returnType) f = functools.partial(f, x=1) return_type = IntegerType() f_ = udf(f, return_type) self.assertTrue(f.__doc__ in f_.__doc__) self.assertEqual(f, f_.func) self.assertEqual(return_type, f_.returnType) def test_validate_column_types(self): from pyspark.sql.functions import udf, to_json from pyspark.sql.column import _to_java_column self.assertTrue("Column" in _to_java_column("a").getClass().toString()) self.assertTrue("Column" in _to_java_column(u"a").getClass().toString()) self.assertTrue("Column" in _to_java_column(self.spark.range(1).id).getClass().toString()) self.assertRaisesRegexp( TypeError, "Invalid argument, not a string or column", lambda: _to_java_column(1)) class A(): pass self.assertRaises(TypeError, lambda: _to_java_column(A())) self.assertRaises(TypeError, lambda: _to_java_column([])) self.assertRaisesRegexp( TypeError, "Invalid argument, not a string or column", lambda: udf(lambda x: x)(None)) self.assertRaises(TypeError, lambda: to_json(1)) def test_basic_functions(self): rdd = self.sc.parallelize(['{"foo":"bar"}', '{"foo":"baz"}']) df = self.spark.read.json(rdd) df.count() df.collect() df.schema # cache and checkpoint self.assertFalse(df.is_cached) df.persist() df.unpersist(True) df.cache() self.assertTrue(df.is_cached) self.assertEqual(2, df.count()) df.createOrReplaceTempView("temp") df = self.spark.sql("select foo from temp") df.count() df.collect() def test_apply_schema_to_row(self): df = self.spark.read.json(self.sc.parallelize(["""{"a":2}"""])) df2 = self.spark.createDataFrame(df.rdd.map(lambda x: x), df.schema) self.assertEqual(df.collect(), df2.collect()) rdd = self.sc.parallelize(range(10)).map(lambda x: Row(a=x)) df3 = self.spark.createDataFrame(rdd, df.schema) self.assertEqual(10, df3.count()) def test_infer_schema_to_local(self): input = [{"a": 1}, {"b": "coffee"}] rdd = self.sc.parallelize(input) df = self.spark.createDataFrame(input) df2 = self.spark.createDataFrame(rdd, samplingRatio=1.0) self.assertEqual(df.schema, df2.schema) rdd = self.sc.parallelize(range(10)).map(lambda x: Row(a=x, b=None)) df3 = self.spark.createDataFrame(rdd, df.schema) self.assertEqual(10, df3.count()) def test_apply_schema_to_dict_and_rows(self): schema = StructType().add("b", StringType()).add("a", IntegerType()) input = [{"a": 1}, {"b": "coffee"}] rdd = self.sc.parallelize(input) for verify in [False, True]: df = self.spark.createDataFrame(input, schema, verifySchema=verify) df2 = self.spark.createDataFrame(rdd, schema, verifySchema=verify) self.assertEqual(df.schema, df2.schema) rdd = self.sc.parallelize(range(10)).map(lambda x: Row(a=x, b=None)) df3 = self.spark.createDataFrame(rdd, schema, verifySchema=verify) self.assertEqual(10, df3.count()) input = [Row(a=x, b=str(x)) for x in range(10)] df4 = self.spark.createDataFrame(input, schema, verifySchema=verify) self.assertEqual(10, df4.count()) def test_create_dataframe_schema_mismatch(self): input = [Row(a=1)] rdd = self.sc.parallelize(range(3)).map(lambda i: Row(a=i)) schema = StructType([StructField("a", IntegerType()), StructField("b", StringType())]) df = self.spark.createDataFrame(rdd, schema) self.assertRaises(Exception, lambda: df.show()) def test_serialize_nested_array_and_map(self): d = [Row(l=[Row(a=1, b='s')], d={"key": Row(c=1.0, d="2")})] rdd = self.sc.parallelize(d) df = self.spark.createDataFrame(rdd) row = df.head() self.assertEqual(1, len(row.l)) self.assertEqual(1, row.l[0].a) self.assertEqual("2", row.d["key"].d) l = df.rdd.map(lambda x: x.l).first() self.assertEqual(1, len(l)) self.assertEqual('s', l[0].b) d = df.rdd.map(lambda x: x.d).first() self.assertEqual(1, len(d)) self.assertEqual(1.0, d["key"].c) row = df.rdd.map(lambda x: x.d["key"]).first() self.assertEqual(1.0, row.c) self.assertEqual("2", row.d) def test_infer_schema(self): d = [Row(l=[], d={}, s=None), Row(l=[Row(a=1, b='s')], d={"key": Row(c=1.0, d="2")}, s="")] rdd = self.sc.parallelize(d) df = self.spark.createDataFrame(rdd) self.assertEqual([], df.rdd.map(lambda r: r.l).first()) self.assertEqual([None, ""], df.rdd.map(lambda r: r.s).collect()) df.createOrReplaceTempView("test") result = self.spark.sql("SELECT l[0].a from test where d['key'].d = '2'") self.assertEqual(1, result.head()[0]) df2 = self.spark.createDataFrame(rdd, samplingRatio=1.0) self.assertEqual(df.schema, df2.schema) self.assertEqual({}, df2.rdd.map(lambda r: r.d).first()) self.assertEqual([None, ""], df2.rdd.map(lambda r: r.s).collect()) df2.createOrReplaceTempView("test2") result = self.spark.sql("SELECT l[0].a from test2 where d['key'].d = '2'") self.assertEqual(1, result.head()[0]) def test_infer_schema_not_enough_names(self): df = self.spark.createDataFrame([["a", "b"]], ["col1"]) self.assertEqual(df.columns, ['col1', '_2']) def test_infer_schema_fails(self): with self.assertRaisesRegexp(TypeError, 'field a'): self.spark.createDataFrame(self.spark.sparkContext.parallelize([[1, 1], ["x", 1]]), schema=["a", "b"], samplingRatio=0.99) def test_infer_nested_schema(self): NestedRow = Row("f1", "f2") nestedRdd1 = self.sc.parallelize([NestedRow([1, 2], {"row1": 1.0}), NestedRow([2, 3], {"row2": 2.0})]) df = self.spark.createDataFrame(nestedRdd1) self.assertEqual(Row(f1=[1, 2], f2={u'row1': 1.0}), df.collect()[0]) nestedRdd2 = self.sc.parallelize([NestedRow([[1, 2], [2, 3]], [1, 2]), NestedRow([[2, 3], [3, 4]], [2, 3])]) df = self.spark.createDataFrame(nestedRdd2) self.assertEqual(Row(f1=[[1, 2], [2, 3]], f2=[1, 2]), df.collect()[0]) from collections import namedtuple CustomRow = namedtuple('CustomRow', 'field1 field2') rdd = self.sc.parallelize([CustomRow(field1=1, field2="row1"), CustomRow(field1=2, field2="row2"), CustomRow(field1=3, field2="row3")]) df = self.spark.createDataFrame(rdd) self.assertEqual(Row(field1=1, field2=u'row1'), df.first()) def test_create_dataframe_from_dict_respects_schema(self): df = self.spark.createDataFrame([{'a': 1}], ["b"]) self.assertEqual(df.columns, ['b']) def test_create_dataframe_from_objects(self): data = [MyObject(1, "1"), MyObject(2, "2")] df = self.spark.createDataFrame(data) self.assertEqual(df.dtypes, [("key", "bigint"), ("value", "string")]) self.assertEqual(df.first(), Row(key=1, value="1")) def test_select_null_literal(self): df = self.spark.sql("select null as col") self.assertEqual(Row(col=None), df.first()) def test_apply_schema(self): from datetime import date, datetime rdd = self.sc.parallelize([(127, -128, -32768, 32767, 2147483647, 1.0, date(2010, 1, 1), datetime(2010, 1, 1, 1, 1, 1), {"a": 1}, (2,), [1, 2, 3], None)]) schema = StructType([ StructField("byte1", ByteType(), False), StructField("byte2", ByteType(), False), StructField("short1", ShortType(), False), StructField("short2", ShortType(), False), StructField("int1", IntegerType(), False), StructField("float1", FloatType(), False), StructField("date1", DateType(), False), StructField("time1", TimestampType(), False), StructField("map1", MapType(StringType(), IntegerType(), False), False), StructField("struct1", StructType([StructField("b", ShortType(), False)]), False), StructField("list1", ArrayType(ByteType(), False), False), StructField("null1", DoubleType(), True)]) df = self.spark.createDataFrame(rdd, schema) results = df.rdd.map(lambda x: (x.byte1, x.byte2, x.short1, x.short2, x.int1, x.float1, x.date1, x.time1, x.map1["a"], x.struct1.b, x.list1, x.null1)) r = (127, -128, -32768, 32767, 2147483647, 1.0, date(2010, 1, 1), datetime(2010, 1, 1, 1, 1, 1), 1, 2, [1, 2, 3], None) self.assertEqual(r, results.first()) df.createOrReplaceTempView("table2") r = self.spark.sql("SELECT byte1 - 1 AS byte1, byte2 + 1 AS byte2, " + "short1 + 1 AS short1, short2 - 1 AS short2, int1 - 1 AS int1, " + "float1 + 1.5 as float1 FROM table2").first() self.assertEqual((126, -127, -32767, 32766, 2147483646, 2.5), tuple(r)) def test_struct_in_map(self): d = [Row(m={Row(i=1): Row(s="")})] df = self.sc.parallelize(d).toDF() k, v = list(df.head().m.items())[0] self.assertEqual(1, k.i) self.assertEqual("", v.s) def test_convert_row_to_dict(self): row = Row(l=[Row(a=1, b='s')], d={"key": Row(c=1.0, d="2")}) self.assertEqual(1, row.asDict()['l'][0].a) df = self.sc.parallelize([row]).toDF() df.createOrReplaceTempView("test") row = self.spark.sql("select l, d from test").head() self.assertEqual(1, row.asDict()["l"][0].a) self.assertEqual(1.0, row.asDict()['d']['key'].c) def test_udt(self): from pyspark.sql.types import _parse_datatype_json_string, _infer_type, _make_type_verifier from pyspark.sql.tests import ExamplePointUDT, ExamplePoint def check_datatype(datatype): pickled = pickle.loads(pickle.dumps(datatype)) assert datatype == pickled scala_datatype = self.spark._jsparkSession.parseDataType(datatype.json()) python_datatype = _parse_datatype_json_string(scala_datatype.json()) assert datatype == python_datatype check_datatype(ExamplePointUDT()) structtype_with_udt = StructType([StructField("label", DoubleType(), False), StructField("point", ExamplePointUDT(), False)]) check_datatype(structtype_with_udt) p = ExamplePoint(1.0, 2.0) self.assertEqual(_infer_type(p), ExamplePointUDT()) _make_type_verifier(ExamplePointUDT())(ExamplePoint(1.0, 2.0)) self.assertRaises(ValueError, lambda: _make_type_verifier(ExamplePointUDT())([1.0, 2.0])) check_datatype(PythonOnlyUDT()) structtype_with_udt = StructType([StructField("label", DoubleType(), False), StructField("point", PythonOnlyUDT(), False)]) check_datatype(structtype_with_udt) p = PythonOnlyPoint(1.0, 2.0) self.assertEqual(_infer_type(p), PythonOnlyUDT()) _make_type_verifier(PythonOnlyUDT())(PythonOnlyPoint(1.0, 2.0)) self.assertRaises( ValueError, lambda: _make_type_verifier(PythonOnlyUDT())([1.0, 2.0])) def test_simple_udt_in_df(self): schema = StructType().add("key", LongType()).add("val", PythonOnlyUDT()) df = self.spark.createDataFrame( [(i % 3, PythonOnlyPoint(float(i), float(i))) for i in range(10)], schema=schema) df.collect() def test_nested_udt_in_df(self): schema = StructType().add("key", LongType()).add("val", ArrayType(PythonOnlyUDT())) df = self.spark.createDataFrame( [(i % 3, [PythonOnlyPoint(float(i), float(i))]) for i in range(10)], schema=schema) df.collect() schema = StructType().add("key", LongType()).add("val", MapType(LongType(), PythonOnlyUDT())) df = self.spark.createDataFrame( [(i % 3, {i % 3: PythonOnlyPoint(float(i + 1), float(i + 1))}) for i in range(10)], schema=schema) df.collect() def test_complex_nested_udt_in_df(self): from pyspark.sql.functions import udf schema = StructType().add("key", LongType()).add("val", PythonOnlyUDT()) df = self.spark.createDataFrame( [(i % 3, PythonOnlyPoint(float(i), float(i))) for i in range(10)], schema=schema) df.collect() gd = df.groupby("key").agg({"val": "collect_list"}) gd.collect() udf = udf(lambda k, v: [(k, v[0])], ArrayType(df.schema)) gd.select(udf(*gd)).collect() def test_udt_with_none(self): df = self.spark.range(0, 10, 1, 1) def myudf(x): if x > 0: return PythonOnlyPoint(float(x), float(x)) self.spark.catalog.registerFunction("udf", myudf, PythonOnlyUDT()) rows = [r[0] for r in df.selectExpr("udf(id)").take(2)] self.assertEqual(rows, [None, PythonOnlyPoint(1, 1)]) def test_nonparam_udf_with_aggregate(self): import pyspark.sql.functions as f df = self.spark.createDataFrame([(1, 2), (1, 2)]) f_udf = f.udf(lambda: "const_str") rows = df.distinct().withColumn("a", f_udf()).collect() self.assertEqual(rows, [Row(_1=1, _2=2, a=u'const_str')]) def test_infer_schema_with_udt(self): from pyspark.sql.tests import ExamplePoint, ExamplePointUDT row = Row(label=1.0, point=ExamplePoint(1.0, 2.0)) df = self.spark.createDataFrame([row]) schema = df.schema field = [f for f in schema.fields if f.name == "point"][0] self.assertEqual(type(field.dataType), ExamplePointUDT) df.createOrReplaceTempView("labeled_point") point = self.spark.sql("SELECT point FROM labeled_point").head().point self.assertEqual(point, ExamplePoint(1.0, 2.0)) row = Row(label=1.0, point=PythonOnlyPoint(1.0, 2.0)) df = self.spark.createDataFrame([row]) schema = df.schema field = [f for f in schema.fields if f.name == "point"][0] self.assertEqual(type(field.dataType), PythonOnlyUDT) df.createOrReplaceTempView("labeled_point") point = self.spark.sql("SELECT point FROM labeled_point").head().point self.assertEqual(point, PythonOnlyPoint(1.0, 2.0)) def test_apply_schema_with_udt(self): from pyspark.sql.tests import ExamplePoint, ExamplePointUDT row = (1.0, ExamplePoint(1.0, 2.0)) schema = StructType([StructField("label", DoubleType(), False), StructField("point", ExamplePointUDT(), False)]) df = self.spark.createDataFrame([row], schema) point = df.head().point self.assertEqual(point, ExamplePoint(1.0, 2.0)) row = (1.0, PythonOnlyPoint(1.0, 2.0)) schema = StructType([StructField("label", DoubleType(), False), StructField("point", PythonOnlyUDT(), False)]) df = self.spark.createDataFrame([row], schema) point = df.head().point self.assertEqual(point, PythonOnlyPoint(1.0, 2.0)) def test_udf_with_udt(self): from pyspark.sql.tests import ExamplePoint, ExamplePointUDT row = Row(label=1.0, point=ExamplePoint(1.0, 2.0)) df = self.spark.createDataFrame([row]) self.assertEqual(1.0, df.rdd.map(lambda r: r.point.x).first()) udf = UserDefinedFunction(lambda p: p.y, DoubleType()) self.assertEqual(2.0, df.select(udf(df.point)).first()[0]) udf2 = UserDefinedFunction(lambda p: ExamplePoint(p.x + 1, p.y + 1), ExamplePointUDT()) self.assertEqual(ExamplePoint(2.0, 3.0), df.select(udf2(df.point)).first()[0]) row = Row(label=1.0, point=PythonOnlyPoint(1.0, 2.0)) df = self.spark.createDataFrame([row]) self.assertEqual(1.0, df.rdd.map(lambda r: r.point.x).first()) udf = UserDefinedFunction(lambda p: p.y, DoubleType()) self.assertEqual(2.0, df.select(udf(df.point)).first()[0]) udf2 = UserDefinedFunction(lambda p: PythonOnlyPoint(p.x + 1, p.y + 1), PythonOnlyUDT()) self.assertEqual(PythonOnlyPoint(2.0, 3.0), df.select(udf2(df.point)).first()[0]) def test_parquet_with_udt(self): from pyspark.sql.tests import ExamplePoint, ExamplePointUDT row = Row(label=1.0, point=ExamplePoint(1.0, 2.0)) df0 = self.spark.createDataFrame([row]) output_dir = os.path.join(self.tempdir.name, "labeled_point") df0.write.parquet(output_dir) df1 = self.spark.read.parquet(output_dir) point = df1.head().point self.assertEqual(point, ExamplePoint(1.0, 2.0)) row = Row(label=1.0, point=PythonOnlyPoint(1.0, 2.0)) df0 = self.spark.createDataFrame([row]) df0.write.parquet(output_dir, mode='overwrite') df1 = self.spark.read.parquet(output_dir) point = df1.head().point self.assertEqual(point, PythonOnlyPoint(1.0, 2.0)) def test_union_with_udt(self): from pyspark.sql.tests import ExamplePoint, ExamplePointUDT row1 = (1.0, ExamplePoint(1.0, 2.0)) row2 = (2.0, ExamplePoint(3.0, 4.0)) schema = StructType([StructField("label", DoubleType(), False), StructField("point", ExamplePointUDT(), False)]) df1 = self.spark.createDataFrame([row1], schema) df2 = self.spark.createDataFrame([row2], schema) result = df1.union(df2).orderBy("label").collect() self.assertEqual( result, [ Row(label=1.0, point=ExamplePoint(1.0, 2.0)), Row(label=2.0, point=ExamplePoint(3.0, 4.0)) ] ) def test_cast_to_string_with_udt(self): from pyspark.sql.tests import ExamplePointUDT, ExamplePoint from pyspark.sql.functions import col row = (ExamplePoint(1.0, 2.0), PythonOnlyPoint(3.0, 4.0)) schema = StructType([StructField("point", ExamplePointUDT(), False), StructField("pypoint", PythonOnlyUDT(), False)]) df = self.spark.createDataFrame([row], schema) result = df.select(col('point').cast('string'), col('pypoint').cast('string')).head() self.assertEqual(result, Row(point=u'(1.0, 2.0)', pypoint=u'[3.0, 4.0]')) def test_column_operators(self): ci = self.df.key cs = self.df.value c = ci == cs self.assertTrue(isinstance((- ci - 1 - 2) % 3 * 2.5 / 3.5, Column)) rcc = (1 + ci), (1 - ci), (1 * ci), (1 / ci), (1 % ci), (1 ** ci), (ci ** 1) self.assertTrue(all(isinstance(c, Column) for c in rcc)) cb = [ci == 5, ci != 0, ci > 3, ci < 4, ci >= 0, ci <= 7] self.assertTrue(all(isinstance(c, Column) for c in cb)) cbool = (ci & ci), (ci | ci), (~ci) self.assertTrue(all(isinstance(c, Column) for c in cbool)) css = cs.contains('a'), cs.like('a'), cs.rlike('a'), cs.asc(), cs.desc(),\ cs.startswith('a'), cs.endswith('a'), ci.eqNullSafe(cs) self.assertTrue(all(isinstance(c, Column) for c in css)) self.assertTrue(isinstance(ci.cast(LongType()), Column)) self.assertRaisesRegexp(ValueError, "Cannot apply 'in' operator against a column", lambda: 1 in cs) def test_column_getitem(self): from pyspark.sql.functions import col self.assertIsInstance(col("foo")[1:3], Column) self.assertIsInstance(col("foo")[0], Column) self.assertIsInstance(col("foo")["bar"], Column) self.assertRaises(ValueError, lambda: col("foo")[0:10:2]) def test_column_select(self): df = self.df self.assertEqual(self.testData, df.select("*").collect()) self.assertEqual(self.testData, df.select(df.key, df.value).collect()) self.assertEqual([Row(value='1')], df.where(df.key == 1).select(df.value).collect()) def test_freqItems(self): vals = [Row(a=1, b=-2.0) if i % 2 == 0 else Row(a=i, b=i * 1.0) for i in range(100)] df = self.sc.parallelize(vals).toDF() items = df.stat.freqItems(("a", "b"), 0.4).collect()[0] self.assertTrue(1 in items[0]) self.assertTrue(-2.0 in items[1]) def test_aggregator(self): df = self.df g = df.groupBy() self.assertEqual([99, 100], sorted(g.agg({'key': 'max', 'value': 'count'}).collect()[0])) self.assertEqual([Row(**{"AVG(key#0)": 49.5})], g.mean().collect()) from pyspark.sql import functions self.assertEqual((0, u'99'), tuple(g.agg(functions.first(df.key), functions.last(df.value)).first())) self.assertTrue(95 < g.agg(functions.approxCountDistinct(df.key)).first()[0]) self.assertEqual(100, g.agg(functions.countDistinct(df.value)).first()[0]) def test_first_last_ignorenulls(self): from pyspark.sql import functions df = self.spark.range(0, 100) df2 = df.select(functions.when(df.id % 3 == 0, None).otherwise(df.id).alias("id")) df3 = df2.select(functions.first(df2.id, False).alias('a'), functions.first(df2.id, True).alias('b'), functions.last(df2.id, False).alias('c'), functions.last(df2.id, True).alias('d')) self.assertEqual([Row(a=None, b=1, c=None, d=98)], df3.collect()) def test_approxQuantile(self): df = self.sc.parallelize([Row(a=i, b=i+10) for i in range(10)]).toDF() for f in ["a", u"a"]: aq = df.stat.approxQuantile(f, [0.1, 0.5, 0.9], 0.1) self.assertTrue(isinstance(aq, list)) self.assertEqual(len(aq), 3) self.assertTrue(all(isinstance(q, float) for q in aq)) aqs = df.stat.approxQuantile(["a", u"b"], [0.1, 0.5, 0.9], 0.1) self.assertTrue(isinstance(aqs, list)) self.assertEqual(len(aqs), 2) self.assertTrue(isinstance(aqs[0], list)) self.assertEqual(len(aqs[0]), 3) self.assertTrue(all(isinstance(q, float) for q in aqs[0])) self.assertTrue(isinstance(aqs[1], list)) self.assertEqual(len(aqs[1]), 3) self.assertTrue(all(isinstance(q, float) for q in aqs[1])) aqt = df.stat.approxQuantile((u"a", "b"), [0.1, 0.5, 0.9], 0.1) self.assertTrue(isinstance(aqt, list)) self.assertEqual(len(aqt), 2) self.assertTrue(isinstance(aqt[0], list)) self.assertEqual(len(aqt[0]), 3) self.assertTrue(all(isinstance(q, float) for q in aqt[0])) self.assertTrue(isinstance(aqt[1], list)) self.assertEqual(len(aqt[1]), 3) self.assertTrue(all(isinstance(q, float) for q in aqt[1])) self.assertRaises(ValueError, lambda: df.stat.approxQuantile(123, [0.1, 0.9], 0.1)) self.assertRaises(ValueError, lambda: df.stat.approxQuantile(("a", 123), [0.1, 0.9], 0.1)) self.assertRaises(ValueError, lambda: df.stat.approxQuantile(["a", 123], [0.1, 0.9], 0.1)) def test_corr(self): import math df = self.sc.parallelize([Row(a=i, b=math.sqrt(i)) for i in range(10)]).toDF() corr = df.stat.corr(u"a", "b") self.assertTrue(abs(corr - 0.95734012) < 1e-6) def test_sampleby(self): df = self.sc.parallelize([Row(a=i, b=(i % 3)) for i in range(10)]).toDF() sampled = df.stat.sampleBy(u"b", fractions={0: 0.5, 1: 0.5}, seed=0) self.assertTrue(sampled.count() == 3) def test_cov(self): df = self.sc.parallelize([Row(a=i, b=2 * i) for i in range(10)]).toDF() cov = df.stat.cov(u"a", "b") self.assertTrue(abs(cov - 55.0 / 3) < 1e-6) def test_crosstab(self): df = self.sc.parallelize([Row(a=i % 3, b=i % 2) for i in range(1, 7)]).toDF() ct = df.stat.crosstab(u"a", "b").collect() ct = sorted(ct, key=lambda x: x[0]) for i, row in enumerate(ct): self.assertEqual(row[0], str(i)) self.assertTrue(row[1], 1) self.assertTrue(row[2], 1) def test_math_functions(self): df = self.sc.parallelize([Row(a=i, b=2 * i) for i in range(10)]).toDF() from pyspark.sql import functions import math def get_values(l): return [j[0] for j in l] def assert_close(a, b): c = get_values(b) diff = [abs(v - c[k]) < 1e-6 for k, v in enumerate(a)] return sum(diff) == len(a) assert_close([math.cos(i) for i in range(10)], df.select(functions.cos(df.a)).collect()) assert_close([math.cos(i) for i in range(10)], df.select(functions.cos("a")).collect()) assert_close([math.sin(i) for i in range(10)], df.select(functions.sin(df.a)).collect()) assert_close([math.sin(i) for i in range(10)], df.select(functions.sin(df['a'])).collect()) assert_close([math.pow(i, 2 * i) for i in range(10)], df.select(functions.pow(df.a, df.b)).collect()) assert_close([math.pow(i, 2) for i in range(10)], df.select(functions.pow(df.a, 2)).collect()) assert_close([math.pow(i, 2) for i in range(10)], df.select(functions.pow(df.a, 2.0)).collect()) assert_close([math.hypot(i, 2 * i) for i in range(10)], df.select(functions.hypot(df.a, df.b)).collect()) def test_rand_functions(self): df = self.df from pyspark.sql import functions rnd = df.select('key', functions.rand()).collect() for row in rnd: assert row[1] >= 0.0 and row[1] <= 1.0, "got: %s" % row[1] rndn = df.select('key', functions.randn(5)).collect() for row in rndn: assert row[1] >= -4.0 and row[1] <= 4.0, "got: %s" % row[1] # If the specified seed is 0, we should use it. # https://issues.apache.org/jira/browse/SPARK-9691 rnd1 = df.select('key', functions.rand(0)).collect() rnd2 = df.select('key', functions.rand(0)).collect() self.assertEqual(sorted(rnd1), sorted(rnd2)) rndn1 = df.select('key', functions.randn(0)).collect() rndn2 = df.select('key', functions.randn(0)).collect() self.assertEqual(sorted(rndn1), sorted(rndn2)) def test_string_functions(self): from pyspark.sql.functions import col, lit df = self.spark.createDataFrame([['nick']], schema=['name']) self.assertRaisesRegexp( TypeError, "must be the same type", lambda: df.select(col('name').substr(0, lit(1)))) if sys.version_info.major == 2: self.assertRaises( TypeError, lambda: df.select(col('name').substr(long(0), long(1)))) def test_array_contains_function(self): from pyspark.sql.functions import array_contains df = self.spark.createDataFrame([(["1", "2", "3"],), ([],)], ['data']) actual = df.select(array_contains(df.data, "1").alias('b')).collect() self.assertEqual([Row(b=True), Row(b=False)], actual) def test_between_function(self): df = self.sc.parallelize([ Row(a=1, b=2, c=3), Row(a=2, b=1, c=3), Row(a=4, b=1, c=4)]).toDF() self.assertEqual([Row(a=2, b=1, c=3), Row(a=4, b=1, c=4)], df.filter(df.a.between(df.b, df.c)).collect()) def test_struct_type(self): struct1 = StructType().add("f1", StringType(), True).add("f2", StringType(), True, None) struct2 = StructType([StructField("f1", StringType(), True), StructField("f2", StringType(), True, None)]) self.assertEqual(struct1.fieldNames(), struct2.names) self.assertEqual(struct1, struct2) struct1 = StructType().add("f1", StringType(), True).add("f2", StringType(), True, None) struct2 = StructType([StructField("f1", StringType(), True)]) self.assertNotEqual(struct1.fieldNames(), struct2.names) self.assertNotEqual(struct1, struct2) struct1 = (StructType().add(StructField("f1", StringType(), True)) .add(StructField("f2", StringType(), True, None))) struct2 = StructType([StructField("f1", StringType(), True), StructField("f2", StringType(), True, None)]) self.assertEqual(struct1.fieldNames(), struct2.names) self.assertEqual(struct1, struct2) struct1 = (StructType().add(StructField("f1", StringType(), True)) .add(StructField("f2", StringType(), True, None))) struct2 = StructType([StructField("f1", StringType(), True)]) self.assertNotEqual(struct1.fieldNames(), struct2.names) self.assertNotEqual(struct1, struct2) # Catch exception raised during improper construction self.assertRaises(ValueError, lambda: StructType().add("name")) struct1 = StructType().add("f1", StringType(), True).add("f2", StringType(), True, None) for field in struct1: self.assertIsInstance(field, StructField) struct1 = StructType().add("f1", StringType(), True).add("f2", StringType(), True, None) self.assertEqual(len(struct1), 2) struct1 = StructType().add("f1", StringType(), True).add("f2", StringType(), True, None) self.assertIs(struct1["f1"], struct1.fields[0]) self.assertIs(struct1[0], struct1.fields[0]) self.assertEqual(struct1[0:1], StructType(struct1.fields[0:1])) self.assertRaises(KeyError, lambda: struct1["f9"]) self.assertRaises(IndexError, lambda: struct1[9]) self.assertRaises(TypeError, lambda: struct1[9.9]) def test_parse_datatype_string(self): from pyspark.sql.types import _all_atomic_types, _parse_datatype_string for k, t in _all_atomic_types.items(): if t != NullType: self.assertEqual(t(), _parse_datatype_string(k)) self.assertEqual(IntegerType(), _parse_datatype_string("int")) self.assertEqual(DecimalType(1, 1), _parse_datatype_string("decimal(1 ,1)")) self.assertEqual(DecimalType(10, 1), _parse_datatype_string("decimal( 10,1 )")) self.assertEqual(DecimalType(11, 1), _parse_datatype_string("decimal(11,1)")) self.assertEqual( ArrayType(IntegerType()), _parse_datatype_string("array")) self.assertEqual( MapType(IntegerType(), DoubleType()), _parse_datatype_string("map< int, double >")) self.assertEqual( StructType([StructField("a", IntegerType()), StructField("c", DoubleType())]), _parse_datatype_string("struct")) self.assertEqual( StructType([StructField("a", IntegerType()), StructField("c", DoubleType())]), _parse_datatype_string("a:int, c:double")) self.assertEqual( StructType([StructField("a", IntegerType()), StructField("c", DoubleType())]), _parse_datatype_string("a INT, c DOUBLE")) def test_metadata_null(self): schema = StructType([StructField("f1", StringType(), True, None), StructField("f2", StringType(), True, {'a': None})]) rdd = self.sc.parallelize([["a", "b"], ["c", "d"]]) self.spark.createDataFrame(rdd, schema) def test_save_and_load(self): df = self.df tmpPath = tempfile.mkdtemp() shutil.rmtree(tmpPath) df.write.json(tmpPath) actual = self.spark.read.json(tmpPath) self.assertEqual(sorted(df.collect()), sorted(actual.collect())) schema = StructType([StructField("value", StringType(), True)]) actual = self.spark.read.json(tmpPath, schema) self.assertEqual(sorted(df.select("value").collect()), sorted(actual.collect())) df.write.json(tmpPath, "overwrite") actual = self.spark.read.json(tmpPath) self.assertEqual(sorted(df.collect()), sorted(actual.collect())) df.write.save(format="json", mode="overwrite", path=tmpPath, noUse="this options will not be used in save.") actual = self.spark.read.load(format="json", path=tmpPath, noUse="this options will not be used in load.") self.assertEqual(sorted(df.collect()), sorted(actual.collect())) defaultDataSourceName = self.spark.conf.get("spark.sql.sources.default", "org.apache.spark.sql.parquet") self.spark.sql("SET spark.sql.sources.default=org.apache.spark.sql.json") actual = self.spark.read.load(path=tmpPath) self.assertEqual(sorted(df.collect()), sorted(actual.collect())) self.spark.sql("SET spark.sql.sources.default=" + defaultDataSourceName) csvpath = os.path.join(tempfile.mkdtemp(), 'data') df.write.option('quote', None).format('csv').save(csvpath) shutil.rmtree(tmpPath) def test_save_and_load_builder(self): df = self.df tmpPath = tempfile.mkdtemp() shutil.rmtree(tmpPath) df.write.json(tmpPath) actual = self.spark.read.json(tmpPath) self.assertEqual(sorted(df.collect()), sorted(actual.collect())) schema = StructType([StructField("value", StringType(), True)]) actual = self.spark.read.json(tmpPath, schema) self.assertEqual(sorted(df.select("value").collect()), sorted(actual.collect())) df.write.mode("overwrite").json(tmpPath) actual = self.spark.read.json(tmpPath) self.assertEqual(sorted(df.collect()), sorted(actual.collect())) df.write.mode("overwrite").options(noUse="this options will not be used in save.")\ .option("noUse", "this option will not be used in save.")\ .format("json").save(path=tmpPath) actual =\ self.spark.read.format("json")\ .load(path=tmpPath, noUse="this options will not be used in load.") self.assertEqual(sorted(df.collect()), sorted(actual.collect())) defaultDataSourceName = self.spark.conf.get("spark.sql.sources.default", "org.apache.spark.sql.parquet") self.spark.sql("SET spark.sql.sources.default=org.apache.spark.sql.json") actual = self.spark.read.load(path=tmpPath) self.assertEqual(sorted(df.collect()), sorted(actual.collect())) self.spark.sql("SET spark.sql.sources.default=" + defaultDataSourceName) shutil.rmtree(tmpPath) def test_stream_trigger(self): df = self.spark.readStream.format('text').load('python/test_support/sql/streaming') # Should take at least one arg try: df.writeStream.trigger() except ValueError: pass # Should not take multiple args try: df.writeStream.trigger(once=True, processingTime='5 seconds') except ValueError: pass # Should not take multiple args try: df.writeStream.trigger(processingTime='5 seconds', continuous='1 second') except ValueError: pass # Should take only keyword args try: df.writeStream.trigger('5 seconds') self.fail("Should have thrown an exception") except TypeError: pass def test_stream_read_options(self): schema = StructType([StructField("data", StringType(), False)]) df = self.spark.readStream\ .format('text')\ .option('path', 'python/test_support/sql/streaming')\ .schema(schema)\ .load() self.assertTrue(df.isStreaming) self.assertEqual(df.schema.simpleString(), "struct") def test_stream_read_options_overwrite(self): bad_schema = StructType([StructField("test", IntegerType(), False)]) schema = StructType([StructField("data", StringType(), False)]) df = self.spark.readStream.format('csv').option('path', 'python/test_support/sql/fake') \ .schema(bad_schema)\ .load(path='python/test_support/sql/streaming', schema=schema, format='text') self.assertTrue(df.isStreaming) self.assertEqual(df.schema.simpleString(), "struct") def test_stream_save_options(self): df = self.spark.readStream.format('text').load('python/test_support/sql/streaming') \ .withColumn('id', lit(1)) for q in self.spark._wrapped.streams.active: q.stop() tmpPath = tempfile.mkdtemp() shutil.rmtree(tmpPath) self.assertTrue(df.isStreaming) out = os.path.join(tmpPath, 'out') chk = os.path.join(tmpPath, 'chk') q = df.writeStream.option('checkpointLocation', chk).queryName('this_query') \ .format('parquet').partitionBy('id').outputMode('append').option('path', out).start() try: self.assertEqual(q.name, 'this_query') self.assertTrue(q.isActive) q.processAllAvailable() output_files = [] for _, _, files in os.walk(out): output_files.extend([f for f in files if not f.startswith('.')]) self.assertTrue(len(output_files) > 0) self.assertTrue(len(os.listdir(chk)) > 0) finally: q.stop() shutil.rmtree(tmpPath) def test_stream_save_options_overwrite(self): df = self.spark.readStream.format('text').load('python/test_support/sql/streaming') for q in self.spark._wrapped.streams.active: q.stop() tmpPath = tempfile.mkdtemp() shutil.rmtree(tmpPath) self.assertTrue(df.isStreaming) out = os.path.join(tmpPath, 'out') chk = os.path.join(tmpPath, 'chk') fake1 = os.path.join(tmpPath, 'fake1') fake2 = os.path.join(tmpPath, 'fake2') q = df.writeStream.option('checkpointLocation', fake1)\ .format('memory').option('path', fake2) \ .queryName('fake_query').outputMode('append') \ .start(path=out, format='parquet', queryName='this_query', checkpointLocation=chk) try: self.assertEqual(q.name, 'this_query') self.assertTrue(q.isActive) q.processAllAvailable() output_files = [] for _, _, files in os.walk(out): output_files.extend([f for f in files if not f.startswith('.')]) self.assertTrue(len(output_files) > 0) self.assertTrue(len(os.listdir(chk)) > 0) self.assertFalse(os.path.isdir(fake1)) # should not have been created self.assertFalse(os.path.isdir(fake2)) # should not have been created finally: q.stop() shutil.rmtree(tmpPath) def test_stream_status_and_progress(self): df = self.spark.readStream.format('text').load('python/test_support/sql/streaming') for q in self.spark._wrapped.streams.active: q.stop() tmpPath = tempfile.mkdtemp() shutil.rmtree(tmpPath) self.assertTrue(df.isStreaming) out = os.path.join(tmpPath, 'out') chk = os.path.join(tmpPath, 'chk') def func(x): time.sleep(1) return x from pyspark.sql.functions import col, udf sleep_udf = udf(func) # Use "sleep_udf" to delay the progress update so that we can test `lastProgress` when there # were no updates. q = df.select(sleep_udf(col("value")).alias('value')).writeStream \ .start(path=out, format='parquet', queryName='this_query', checkpointLocation=chk) try: # "lastProgress" will return None in most cases. However, as it may be flaky when # Jenkins is very slow, we don't assert it. If there is something wrong, "lastProgress" # may throw error with a high chance and make this test flaky, so we should still be # able to detect broken codes. q.lastProgress q.processAllAvailable() lastProgress = q.lastProgress recentProgress = q.recentProgress status = q.status self.assertEqual(lastProgress['name'], q.name) self.assertEqual(lastProgress['id'], q.id) self.assertTrue(any(p == lastProgress for p in recentProgress)) self.assertTrue( "message" in status and "isDataAvailable" in status and "isTriggerActive" in status) finally: q.stop() shutil.rmtree(tmpPath) def test_stream_await_termination(self): df = self.spark.readStream.format('text').load('python/test_support/sql/streaming') for q in self.spark._wrapped.streams.active: q.stop() tmpPath = tempfile.mkdtemp() shutil.rmtree(tmpPath) self.assertTrue(df.isStreaming) out = os.path.join(tmpPath, 'out') chk = os.path.join(tmpPath, 'chk') q = df.writeStream\ .start(path=out, format='parquet', queryName='this_query', checkpointLocation=chk) try: self.assertTrue(q.isActive) try: q.awaitTermination("hello") self.fail("Expected a value exception") except ValueError: pass now = time.time() # test should take at least 2 seconds res = q.awaitTermination(2.6) duration = time.time() - now self.assertTrue(duration >= 2) self.assertFalse(res) finally: q.stop() shutil.rmtree(tmpPath) def test_stream_exception(self): sdf = self.spark.readStream.format('text').load('python/test_support/sql/streaming') sq = sdf.writeStream.format('memory').queryName('query_explain').start() try: sq.processAllAvailable() self.assertEqual(sq.exception(), None) finally: sq.stop() from pyspark.sql.functions import col, udf from pyspark.sql.utils import StreamingQueryException bad_udf = udf(lambda x: 1 / 0) sq = sdf.select(bad_udf(col("value")))\ .writeStream\ .format('memory')\ .queryName('this_query')\ .start() try: # Process some data to fail the query sq.processAllAvailable() self.fail("bad udf should fail the query") except StreamingQueryException as e: # This is expected self.assertTrue("ZeroDivisionError" in e.desc) finally: sq.stop() self.assertTrue(type(sq.exception()) is StreamingQueryException) self.assertTrue("ZeroDivisionError" in sq.exception().desc) def test_query_manager_await_termination(self): df = self.spark.readStream.format('text').load('python/test_support/sql/streaming') for q in self.spark._wrapped.streams.active: q.stop() tmpPath = tempfile.mkdtemp() shutil.rmtree(tmpPath) self.assertTrue(df.isStreaming) out = os.path.join(tmpPath, 'out') chk = os.path.join(tmpPath, 'chk') q = df.writeStream\ .start(path=out, format='parquet', queryName='this_query', checkpointLocation=chk) try: self.assertTrue(q.isActive) try: self.spark._wrapped.streams.awaitAnyTermination("hello") self.fail("Expected a value exception") except ValueError: pass now = time.time() # test should take at least 2 seconds res = self.spark._wrapped.streams.awaitAnyTermination(2.6) duration = time.time() - now self.assertTrue(duration >= 2) self.assertFalse(res) finally: q.stop() shutil.rmtree(tmpPath) class ForeachWriterTester: def __init__(self, spark): self.spark = spark def write_open_event(self, partitionId, epochId): self._write_event( self.open_events_dir, {'partition': partitionId, 'epoch': epochId}) def write_process_event(self, row): self._write_event(self.process_events_dir, {'value': 'text'}) def write_close_event(self, error): self._write_event(self.close_events_dir, {'error': str(error)}) def write_input_file(self): self._write_event(self.input_dir, "text") def open_events(self): return self._read_events(self.open_events_dir, 'partition INT, epoch INT') def process_events(self): return self._read_events(self.process_events_dir, 'value STRING') def close_events(self): return self._read_events(self.close_events_dir, 'error STRING') def run_streaming_query_on_writer(self, writer, num_files): self._reset() try: sdf = self.spark.readStream.format('text').load(self.input_dir) sq = sdf.writeStream.foreach(writer).start() for i in range(num_files): self.write_input_file() sq.processAllAvailable() finally: self.stop_all() def assert_invalid_writer(self, writer, msg=None): self._reset() try: sdf = self.spark.readStream.format('text').load(self.input_dir) sq = sdf.writeStream.foreach(writer).start() self.write_input_file() sq.processAllAvailable() self.fail("invalid writer %s did not fail the query" % str(writer)) # not expected except Exception as e: if msg: assert msg in str(e), "%s not in %s" % (msg, str(e)) finally: self.stop_all() def stop_all(self): for q in self.spark._wrapped.streams.active: q.stop() def _reset(self): self.input_dir = tempfile.mkdtemp() self.open_events_dir = tempfile.mkdtemp() self.process_events_dir = tempfile.mkdtemp() self.close_events_dir = tempfile.mkdtemp() def _read_events(self, dir, json): rows = self.spark.read.schema(json).json(dir).collect() dicts = [row.asDict() for row in rows] return dicts def _write_event(self, dir, event): import uuid with open(os.path.join(dir, str(uuid.uuid4())), 'w') as f: f.write("%s\n" % str(event)) def __getstate__(self): return (self.open_events_dir, self.process_events_dir, self.close_events_dir) def __setstate__(self, state): self.open_events_dir, self.process_events_dir, self.close_events_dir = state # Those foreach tests are failed in Python 3.6 and macOS High Sierra by defined rules # at http://sealiesoftware.com/blog/archive/2017/6/5/Objective-C_and_fork_in_macOS_1013.html # To work around this, OBJC_DISABLE_INITIALIZE_FORK_SAFETY=YES. def test_streaming_foreach_with_simple_function(self): tester = self.ForeachWriterTester(self.spark) def foreach_func(row): tester.write_process_event(row) tester.run_streaming_query_on_writer(foreach_func, 2) self.assertEqual(len(tester.process_events()), 2) def test_streaming_foreach_with_basic_open_process_close(self): tester = self.ForeachWriterTester(self.spark) class ForeachWriter: def open(self, partitionId, epochId): tester.write_open_event(partitionId, epochId) return True def process(self, row): tester.write_process_event(row) def close(self, error): tester.write_close_event(error) tester.run_streaming_query_on_writer(ForeachWriter(), 2) open_events = tester.open_events() self.assertEqual(len(open_events), 2) self.assertSetEqual(set([e['epoch'] for e in open_events]), {0, 1}) self.assertEqual(len(tester.process_events()), 2) close_events = tester.close_events() self.assertEqual(len(close_events), 2) self.assertSetEqual(set([e['error'] for e in close_events]), {'None'}) def test_streaming_foreach_with_open_returning_false(self): tester = self.ForeachWriterTester(self.spark) class ForeachWriter: def open(self, partition_id, epoch_id): tester.write_open_event(partition_id, epoch_id) return False def process(self, row): tester.write_process_event(row) def close(self, error): tester.write_close_event(error) tester.run_streaming_query_on_writer(ForeachWriter(), 2) self.assertEqual(len(tester.open_events()), 2) self.assertEqual(len(tester.process_events()), 0) # no row was processed close_events = tester.close_events() self.assertEqual(len(close_events), 2) self.assertSetEqual(set([e['error'] for e in close_events]), {'None'}) def test_streaming_foreach_without_open_method(self): tester = self.ForeachWriterTester(self.spark) class ForeachWriter: def process(self, row): tester.write_process_event(row) def close(self, error): tester.write_close_event(error) tester.run_streaming_query_on_writer(ForeachWriter(), 2) self.assertEqual(len(tester.open_events()), 0) # no open events self.assertEqual(len(tester.process_events()), 2) self.assertEqual(len(tester.close_events()), 2) def test_streaming_foreach_without_close_method(self): tester = self.ForeachWriterTester(self.spark) class ForeachWriter: def open(self, partition_id, epoch_id): tester.write_open_event(partition_id, epoch_id) return True def process(self, row): tester.write_process_event(row) tester.run_streaming_query_on_writer(ForeachWriter(), 2) self.assertEqual(len(tester.open_events()), 2) # no open events self.assertEqual(len(tester.process_events()), 2) self.assertEqual(len(tester.close_events()), 0) def test_streaming_foreach_without_open_and_close_methods(self): tester = self.ForeachWriterTester(self.spark) class ForeachWriter: def process(self, row): tester.write_process_event(row) tester.run_streaming_query_on_writer(ForeachWriter(), 2) self.assertEqual(len(tester.open_events()), 0) # no open events self.assertEqual(len(tester.process_events()), 2) self.assertEqual(len(tester.close_events()), 0) def test_streaming_foreach_with_process_throwing_error(self): from pyspark.sql.utils import StreamingQueryException tester = self.ForeachWriterTester(self.spark) class ForeachWriter: def process(self, row): raise Exception("test error") def close(self, error): tester.write_close_event(error) try: tester.run_streaming_query_on_writer(ForeachWriter(), 1) self.fail("bad writer did not fail the query") # this is not expected except StreamingQueryException as e: # TODO: Verify whether original error message is inside the exception pass self.assertEqual(len(tester.process_events()), 0) # no row was processed close_events = tester.close_events() self.assertEqual(len(close_events), 1) # TODO: Verify whether original error message is inside the exception def test_streaming_foreach_with_invalid_writers(self): tester = self.ForeachWriterTester(self.spark) def func_with_iterator_input(iter): for x in iter: print(x) tester.assert_invalid_writer(func_with_iterator_input) class WriterWithoutProcess: def open(self, partition): pass tester.assert_invalid_writer(WriterWithoutProcess(), "does not have a 'process'") class WriterWithNonCallableProcess(): process = True tester.assert_invalid_writer(WriterWithNonCallableProcess(), "'process' in provided object is not callable") class WriterWithNoParamProcess(): def process(self): pass tester.assert_invalid_writer(WriterWithNoParamProcess()) # Abstract class for tests below class WithProcess(): def process(self, row): pass class WriterWithNonCallableOpen(WithProcess): open = True tester.assert_invalid_writer(WriterWithNonCallableOpen(), "'open' in provided object is not callable") class WriterWithNoParamOpen(WithProcess): def open(self): pass tester.assert_invalid_writer(WriterWithNoParamOpen()) class WriterWithNonCallableClose(WithProcess): close = True tester.assert_invalid_writer(WriterWithNonCallableClose(), "'close' in provided object is not callable") def test_streaming_foreachBatch(self): q = None collected = dict() def collectBatch(batch_df, batch_id): collected[batch_id] = batch_df.collect() try: df = self.spark.readStream.format('text').load('python/test_support/sql/streaming') q = df.writeStream.foreachBatch(collectBatch).start() q.processAllAvailable() self.assertTrue(0 in collected) self.assertTrue(len(collected[0]), 2) finally: if q: q.stop() def test_streaming_foreachBatch_propagates_python_errors(self): from pyspark.sql.utils import StreamingQueryException q = None def collectBatch(df, id): raise Exception("this should fail the query") try: df = self.spark.readStream.format('text').load('python/test_support/sql/streaming') q = df.writeStream.foreachBatch(collectBatch).start() q.processAllAvailable() self.fail("Expected a failure") except StreamingQueryException as e: self.assertTrue("this should fail" in str(e)) finally: if q: q.stop() def test_help_command(self): # Regression test for SPARK-5464 rdd = self.sc.parallelize(['{"foo":"bar"}', '{"foo":"baz"}']) df = self.spark.read.json(rdd) # render_doc() reproduces the help() exception without printing output pydoc.render_doc(df) pydoc.render_doc(df.foo) pydoc.render_doc(df.take(1)) def test_access_column(self): df = self.df self.assertTrue(isinstance(df.key, Column)) self.assertTrue(isinstance(df['key'], Column)) self.assertTrue(isinstance(df[0], Column)) self.assertRaises(IndexError, lambda: df[2]) self.assertRaises(AnalysisException, lambda: df["bad_key"]) self.assertRaises(TypeError, lambda: df[{}]) def test_column_name_with_non_ascii(self): if sys.version >= '3': columnName = "数量" self.assertTrue(isinstance(columnName, str)) else: columnName = unicode("数量", "utf-8") self.assertTrue(isinstance(columnName, unicode)) schema = StructType([StructField(columnName, LongType(), True)]) df = self.spark.createDataFrame([(1,)], schema) self.assertEqual(schema, df.schema) self.assertEqual("DataFrame[数量: bigint]", str(df)) self.assertEqual([("数量", 'bigint')], df.dtypes) self.assertEqual(1, df.select("数量").first()[0]) self.assertEqual(1, df.select(df["数量"]).first()[0]) def test_access_nested_types(self): df = self.sc.parallelize([Row(l=[1], r=Row(a=1, b="b"), d={"k": "v"})]).toDF() self.assertEqual(1, df.select(df.l[0]).first()[0]) self.assertEqual(1, df.select(df.l.getItem(0)).first()[0]) self.assertEqual(1, df.select(df.r.a).first()[0]) self.assertEqual("b", df.select(df.r.getField("b")).first()[0]) self.assertEqual("v", df.select(df.d["k"]).first()[0]) self.assertEqual("v", df.select(df.d.getItem("k")).first()[0]) def test_field_accessor(self): df = self.sc.parallelize([Row(l=[1], r=Row(a=1, b="b"), d={"k": "v"})]).toDF() self.assertEqual(1, df.select(df.l[0]).first()[0]) self.assertEqual(1, df.select(df.r["a"]).first()[0]) self.assertEqual(1, df.select(df["r.a"]).first()[0]) self.assertEqual("b", df.select(df.r["b"]).first()[0]) self.assertEqual("b", df.select(df["r.b"]).first()[0]) self.assertEqual("v", df.select(df.d["k"]).first()[0]) def test_infer_long_type(self): longrow = [Row(f1='a', f2=100000000000000)] df = self.sc.parallelize(longrow).toDF() self.assertEqual(df.schema.fields[1].dataType, LongType()) # this saving as Parquet caused issues as well. output_dir = os.path.join(self.tempdir.name, "infer_long_type") df.write.parquet(output_dir) df1 = self.spark.read.parquet(output_dir) self.assertEqual('a', df1.first().f1) self.assertEqual(100000000000000, df1.first().f2) self.assertEqual(_infer_type(1), LongType()) self.assertEqual(_infer_type(2**10), LongType()) self.assertEqual(_infer_type(2**20), LongType()) self.assertEqual(_infer_type(2**31 - 1), LongType()) self.assertEqual(_infer_type(2**31), LongType()) self.assertEqual(_infer_type(2**61), LongType()) self.assertEqual(_infer_type(2**71), LongType()) def test_merge_type(self): self.assertEqual(_merge_type(LongType(), NullType()), LongType()) self.assertEqual(_merge_type(NullType(), LongType()), LongType()) self.assertEqual(_merge_type(LongType(), LongType()), LongType()) self.assertEqual(_merge_type( ArrayType(LongType()), ArrayType(LongType()) ), ArrayType(LongType())) with self.assertRaisesRegexp(TypeError, 'element in array'): _merge_type(ArrayType(LongType()), ArrayType(DoubleType())) self.assertEqual(_merge_type( MapType(StringType(), LongType()), MapType(StringType(), LongType()) ), MapType(StringType(), LongType())) with self.assertRaisesRegexp(TypeError, 'key of map'): _merge_type( MapType(StringType(), LongType()), MapType(DoubleType(), LongType())) with self.assertRaisesRegexp(TypeError, 'value of map'): _merge_type( MapType(StringType(), LongType()), MapType(StringType(), DoubleType())) self.assertEqual(_merge_type( StructType([StructField("f1", LongType()), StructField("f2", StringType())]), StructType([StructField("f1", LongType()), StructField("f2", StringType())]) ), StructType([StructField("f1", LongType()), StructField("f2", StringType())])) with self.assertRaisesRegexp(TypeError, 'field f1'): _merge_type( StructType([StructField("f1", LongType()), StructField("f2", StringType())]), StructType([StructField("f1", DoubleType()), StructField("f2", StringType())])) self.assertEqual(_merge_type( StructType([StructField("f1", StructType([StructField("f2", LongType())]))]), StructType([StructField("f1", StructType([StructField("f2", LongType())]))]) ), StructType([StructField("f1", StructType([StructField("f2", LongType())]))])) with self.assertRaisesRegexp(TypeError, 'field f2 in field f1'): _merge_type( StructType([StructField("f1", StructType([StructField("f2", LongType())]))]), StructType([StructField("f1", StructType([StructField("f2", StringType())]))])) self.assertEqual(_merge_type( StructType([StructField("f1", ArrayType(LongType())), StructField("f2", StringType())]), StructType([StructField("f1", ArrayType(LongType())), StructField("f2", StringType())]) ), StructType([StructField("f1", ArrayType(LongType())), StructField("f2", StringType())])) with self.assertRaisesRegexp(TypeError, 'element in array field f1'): _merge_type( StructType([ StructField("f1", ArrayType(LongType())), StructField("f2", StringType())]), StructType([ StructField("f1", ArrayType(DoubleType())), StructField("f2", StringType())])) self.assertEqual(_merge_type( StructType([ StructField("f1", MapType(StringType(), LongType())), StructField("f2", StringType())]), StructType([ StructField("f1", MapType(StringType(), LongType())), StructField("f2", StringType())]) ), StructType([ StructField("f1", MapType(StringType(), LongType())), StructField("f2", StringType())])) with self.assertRaisesRegexp(TypeError, 'value of map field f1'): _merge_type( StructType([ StructField("f1", MapType(StringType(), LongType())), StructField("f2", StringType())]), StructType([ StructField("f1", MapType(StringType(), DoubleType())), StructField("f2", StringType())])) self.assertEqual(_merge_type( StructType([StructField("f1", ArrayType(MapType(StringType(), LongType())))]), StructType([StructField("f1", ArrayType(MapType(StringType(), LongType())))]) ), StructType([StructField("f1", ArrayType(MapType(StringType(), LongType())))])) with self.assertRaisesRegexp(TypeError, 'key of map element in array field f1'): _merge_type( StructType([StructField("f1", ArrayType(MapType(StringType(), LongType())))]), StructType([StructField("f1", ArrayType(MapType(DoubleType(), LongType())))]) ) def test_filter_with_datetime(self): time = datetime.datetime(2015, 4, 17, 23, 1, 2, 3000) date = time.date() row = Row(date=date, time=time) df = self.spark.createDataFrame([row]) self.assertEqual(1, df.filter(df.date == date).count()) self.assertEqual(1, df.filter(df.time == time).count()) self.assertEqual(0, df.filter(df.date > date).count()) self.assertEqual(0, df.filter(df.time > time).count()) def test_filter_with_datetime_timezone(self): dt1 = datetime.datetime(2015, 4, 17, 23, 1, 2, 3000, tzinfo=UTCOffsetTimezone(0)) dt2 = datetime.datetime(2015, 4, 17, 23, 1, 2, 3000, tzinfo=UTCOffsetTimezone(1)) row = Row(date=dt1) df = self.spark.createDataFrame([row]) self.assertEqual(0, df.filter(df.date == dt2).count()) self.assertEqual(1, df.filter(df.date > dt2).count()) self.assertEqual(0, df.filter(df.date < dt2).count()) def test_time_with_timezone(self): day = datetime.date.today() now = datetime.datetime.now() ts = time.mktime(now.timetuple()) # class in __main__ is not serializable from pyspark.sql.tests import UTCOffsetTimezone utc = UTCOffsetTimezone() utcnow = datetime.datetime.utcfromtimestamp(ts) # without microseconds # add microseconds to utcnow (keeping year,month,day,hour,minute,second) utcnow = datetime.datetime(*(utcnow.timetuple()[:6] + (now.microsecond, utc))) df = self.spark.createDataFrame([(day, now, utcnow)]) day1, now1, utcnow1 = df.first() self.assertEqual(day1, day) self.assertEqual(now, now1) self.assertEqual(now, utcnow1) # regression test for SPARK-19561 def test_datetime_at_epoch(self): epoch = datetime.datetime.fromtimestamp(0) df = self.spark.createDataFrame([Row(date=epoch)]) first = df.select('date', lit(epoch).alias('lit_date')).first() self.assertEqual(first['date'], epoch) self.assertEqual(first['lit_date'], epoch) def test_dayofweek(self): from pyspark.sql.functions import dayofweek dt = datetime.datetime(2017, 11, 6) df = self.spark.createDataFrame([Row(date=dt)]) row = df.select(dayofweek(df.date)).first() self.assertEqual(row[0], 2) def test_decimal(self): from decimal import Decimal schema = StructType([StructField("decimal", DecimalType(10, 5))]) df = self.spark.createDataFrame([(Decimal("3.14159"),)], schema) row = df.select(df.decimal + 1).first() self.assertEqual(row[0], Decimal("4.14159")) tmpPath = tempfile.mkdtemp() shutil.rmtree(tmpPath) df.write.parquet(tmpPath) df2 = self.spark.read.parquet(tmpPath) row = df2.first() self.assertEqual(row[0], Decimal("3.14159")) def test_dropna(self): schema = StructType([ StructField("name", StringType(), True), StructField("age", IntegerType(), True), StructField("height", DoubleType(), True)]) # shouldn't drop a non-null row self.assertEqual(self.spark.createDataFrame( [(u'Alice', 50, 80.1)], schema).dropna().count(), 1) # dropping rows with a single null value self.assertEqual(self.spark.createDataFrame( [(u'Alice', None, 80.1)], schema).dropna().count(), 0) self.assertEqual(self.spark.createDataFrame( [(u'Alice', None, 80.1)], schema).dropna(how='any').count(), 0) # if how = 'all', only drop rows if all values are null self.assertEqual(self.spark.createDataFrame( [(u'Alice', None, 80.1)], schema).dropna(how='all').count(), 1) self.assertEqual(self.spark.createDataFrame( [(None, None, None)], schema).dropna(how='all').count(), 0) # how and subset self.assertEqual(self.spark.createDataFrame( [(u'Alice', 50, None)], schema).dropna(how='any', subset=['name', 'age']).count(), 1) self.assertEqual(self.spark.createDataFrame( [(u'Alice', None, None)], schema).dropna(how='any', subset=['name', 'age']).count(), 0) # threshold self.assertEqual(self.spark.createDataFrame( [(u'Alice', None, 80.1)], schema).dropna(thresh=2).count(), 1) self.assertEqual(self.spark.createDataFrame( [(u'Alice', None, None)], schema).dropna(thresh=2).count(), 0) # threshold and subset self.assertEqual(self.spark.createDataFrame( [(u'Alice', 50, None)], schema).dropna(thresh=2, subset=['name', 'age']).count(), 1) self.assertEqual(self.spark.createDataFrame( [(u'Alice', None, 180.9)], schema).dropna(thresh=2, subset=['name', 'age']).count(), 0) # thresh should take precedence over how self.assertEqual(self.spark.createDataFrame( [(u'Alice', 50, None)], schema).dropna( how='any', thresh=2, subset=['name', 'age']).count(), 1) def test_fillna(self): schema = StructType([ StructField("name", StringType(), True), StructField("age", IntegerType(), True), StructField("height", DoubleType(), True), StructField("spy", BooleanType(), True)]) # fillna shouldn't change non-null values row = self.spark.createDataFrame([(u'Alice', 10, 80.1, True)], schema).fillna(50).first() self.assertEqual(row.age, 10) # fillna with int row = self.spark.createDataFrame([(u'Alice', None, None, None)], schema).fillna(50).first() self.assertEqual(row.age, 50) self.assertEqual(row.height, 50.0) # fillna with double row = self.spark.createDataFrame( [(u'Alice', None, None, None)], schema).fillna(50.1).first() self.assertEqual(row.age, 50) self.assertEqual(row.height, 50.1) # fillna with bool row = self.spark.createDataFrame( [(u'Alice', None, None, None)], schema).fillna(True).first() self.assertEqual(row.age, None) self.assertEqual(row.spy, True) # fillna with string row = self.spark.createDataFrame([(None, None, None, None)], schema).fillna("hello").first() self.assertEqual(row.name, u"hello") self.assertEqual(row.age, None) # fillna with subset specified for numeric cols row = self.spark.createDataFrame( [(None, None, None, None)], schema).fillna(50, subset=['name', 'age']).first() self.assertEqual(row.name, None) self.assertEqual(row.age, 50) self.assertEqual(row.height, None) self.assertEqual(row.spy, None) # fillna with subset specified for string cols row = self.spark.createDataFrame( [(None, None, None, None)], schema).fillna("haha", subset=['name', 'age']).first() self.assertEqual(row.name, "haha") self.assertEqual(row.age, None) self.assertEqual(row.height, None) self.assertEqual(row.spy, None) # fillna with subset specified for bool cols row = self.spark.createDataFrame( [(None, None, None, None)], schema).fillna(True, subset=['name', 'spy']).first() self.assertEqual(row.name, None) self.assertEqual(row.age, None) self.assertEqual(row.height, None) self.assertEqual(row.spy, True) # fillna with dictionary for boolean types row = self.spark.createDataFrame([Row(a=None), Row(a=True)]).fillna({"a": True}).first() self.assertEqual(row.a, True) def test_bitwise_operations(self): from pyspark.sql import functions row = Row(a=170, b=75) df = self.spark.createDataFrame([row]) result = df.select(df.a.bitwiseAND(df.b)).collect()[0].asDict() self.assertEqual(170 & 75, result['(a & b)']) result = df.select(df.a.bitwiseOR(df.b)).collect()[0].asDict() self.assertEqual(170 | 75, result['(a | b)']) result = df.select(df.a.bitwiseXOR(df.b)).collect()[0].asDict() self.assertEqual(170 ^ 75, result['(a ^ b)']) result = df.select(functions.bitwiseNOT(df.b)).collect()[0].asDict() self.assertEqual(~75, result['~b']) def test_expr(self): from pyspark.sql import functions row = Row(a="length string", b=75) df = self.spark.createDataFrame([row]) result = df.select(functions.expr("length(a)")).collect()[0].asDict() self.assertEqual(13, result["length(a)"]) def test_repartitionByRange_dataframe(self): schema = StructType([ StructField("name", StringType(), True), StructField("age", IntegerType(), True), StructField("height", DoubleType(), True)]) df1 = self.spark.createDataFrame( [(u'Bob', 27, 66.0), (u'Alice', 10, 10.0), (u'Bob', 10, 66.0)], schema) df2 = self.spark.createDataFrame( [(u'Alice', 10, 10.0), (u'Bob', 10, 66.0), (u'Bob', 27, 66.0)], schema) # test repartitionByRange(numPartitions, *cols) df3 = df1.repartitionByRange(2, "name", "age") self.assertEqual(df3.rdd.getNumPartitions(), 2) self.assertEqual(df3.rdd.first(), df2.rdd.first()) self.assertEqual(df3.rdd.take(3), df2.rdd.take(3)) # test repartitionByRange(numPartitions, *cols) df4 = df1.repartitionByRange(3, "name", "age") self.assertEqual(df4.rdd.getNumPartitions(), 3) self.assertEqual(df4.rdd.first(), df2.rdd.first()) self.assertEqual(df4.rdd.take(3), df2.rdd.take(3)) # test repartitionByRange(*cols) df5 = df1.repartitionByRange("name", "age") self.assertEqual(df5.rdd.first(), df2.rdd.first()) self.assertEqual(df5.rdd.take(3), df2.rdd.take(3)) def test_replace(self): schema = StructType([ StructField("name", StringType(), True), StructField("age", IntegerType(), True), StructField("height", DoubleType(), True)]) # replace with int row = self.spark.createDataFrame([(u'Alice', 10, 10.0)], schema).replace(10, 20).first() self.assertEqual(row.age, 20) self.assertEqual(row.height, 20.0) # replace with double row = self.spark.createDataFrame( [(u'Alice', 80, 80.0)], schema).replace(80.0, 82.1).first() self.assertEqual(row.age, 82) self.assertEqual(row.height, 82.1) # replace with string row = self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace(u'Alice', u'Ann').first() self.assertEqual(row.name, u"Ann") self.assertEqual(row.age, 10) # replace with subset specified by a string of a column name w/ actual change row = self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace(10, 20, subset='age').first() self.assertEqual(row.age, 20) # replace with subset specified by a string of a column name w/o actual change row = self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace(10, 20, subset='height').first() self.assertEqual(row.age, 10) # replace with subset specified with one column replaced, another column not in subset # stays unchanged. row = self.spark.createDataFrame( [(u'Alice', 10, 10.0)], schema).replace(10, 20, subset=['name', 'age']).first() self.assertEqual(row.name, u'Alice') self.assertEqual(row.age, 20) self.assertEqual(row.height, 10.0) # replace with subset specified but no column will be replaced row = self.spark.createDataFrame( [(u'Alice', 10, None)], schema).replace(10, 20, subset=['name', 'height']).first() self.assertEqual(row.name, u'Alice') self.assertEqual(row.age, 10) self.assertEqual(row.height, None) # replace with lists row = self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace([u'Alice'], [u'Ann']).first() self.assertTupleEqual(row, (u'Ann', 10, 80.1)) # replace with dict row = self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace({10: 11}).first() self.assertTupleEqual(row, (u'Alice', 11, 80.1)) # test backward compatibility with dummy value dummy_value = 1 row = self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace({'Alice': 'Bob'}, dummy_value).first() self.assertTupleEqual(row, (u'Bob', 10, 80.1)) # test dict with mixed numerics row = self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace({10: -10, 80.1: 90.5}).first() self.assertTupleEqual(row, (u'Alice', -10, 90.5)) # replace with tuples row = self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace((u'Alice', ), (u'Bob', )).first() self.assertTupleEqual(row, (u'Bob', 10, 80.1)) # replace multiple columns row = self.spark.createDataFrame( [(u'Alice', 10, 80.0)], schema).replace((10, 80.0), (20, 90)).first() self.assertTupleEqual(row, (u'Alice', 20, 90.0)) # test for mixed numerics row = self.spark.createDataFrame( [(u'Alice', 10, 80.0)], schema).replace((10, 80), (20, 90.5)).first() self.assertTupleEqual(row, (u'Alice', 20, 90.5)) row = self.spark.createDataFrame( [(u'Alice', 10, 80.0)], schema).replace({10: 20, 80: 90.5}).first() self.assertTupleEqual(row, (u'Alice', 20, 90.5)) # replace with boolean row = (self .spark.createDataFrame([(u'Alice', 10, 80.0)], schema) .selectExpr("name = 'Bob'", 'age <= 15') .replace(False, True).first()) self.assertTupleEqual(row, (True, True)) # replace string with None and then drop None rows row = self.spark.createDataFrame( [(u'Alice', 10, 80.0)], schema).replace(u'Alice', None).dropna() self.assertEqual(row.count(), 0) # replace with number and None row = self.spark.createDataFrame( [(u'Alice', 10, 80.0)], schema).replace([10, 80], [20, None]).first() self.assertTupleEqual(row, (u'Alice', 20, None)) # should fail if subset is not list, tuple or None with self.assertRaises(ValueError): self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace({10: 11}, subset=1).first() # should fail if to_replace and value have different length with self.assertRaises(ValueError): self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace(["Alice", "Bob"], ["Eve"]).first() # should fail if when received unexpected type with self.assertRaises(ValueError): from datetime import datetime self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace(datetime.now(), datetime.now()).first() # should fail if provided mixed type replacements with self.assertRaises(ValueError): self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace(["Alice", 10], ["Eve", 20]).first() with self.assertRaises(ValueError): self.spark.createDataFrame( [(u'Alice', 10, 80.1)], schema).replace({u"Alice": u"Bob", 10: 20}).first() with self.assertRaisesRegexp( TypeError, 'value argument is required when to_replace is not a dictionary.'): self.spark.createDataFrame( [(u'Alice', 10, 80.0)], schema).replace(["Alice", "Bob"]).first() def test_capture_analysis_exception(self): self.assertRaises(AnalysisException, lambda: self.spark.sql("select abc")) self.assertRaises(AnalysisException, lambda: self.df.selectExpr("a + b")) def test_capture_parse_exception(self): self.assertRaises(ParseException, lambda: self.spark.sql("abc")) def test_capture_illegalargument_exception(self): self.assertRaisesRegexp(IllegalArgumentException, "Setting negative mapred.reduce.tasks", lambda: self.spark.sql("SET mapred.reduce.tasks=-1")) df = self.spark.createDataFrame([(1, 2)], ["a", "b"]) self.assertRaisesRegexp(IllegalArgumentException, "1024 is not in the permitted values", lambda: df.select(sha2(df.a, 1024)).collect()) try: df.select(sha2(df.a, 1024)).collect() except IllegalArgumentException as e: self.assertRegexpMatches(e.desc, "1024 is not in the permitted values") self.assertRegexpMatches(e.stackTrace, "org.apache.spark.sql.functions") def test_with_column_with_existing_name(self): keys = self.df.withColumn("key", self.df.key).select("key").collect() self.assertEqual([r.key for r in keys], list(range(100))) # regression test for SPARK-10417 def test_column_iterator(self): def foo(): for x in self.df.key: break self.assertRaises(TypeError, foo) # add test for SPARK-10577 (test broadcast join hint) def test_functions_broadcast(self): from pyspark.sql.functions import broadcast df1 = self.spark.createDataFrame([(1, "1"), (2, "2")], ("key", "value")) df2 = self.spark.createDataFrame([(1, "1"), (2, "2")], ("key", "value")) # equijoin - should be converted into broadcast join plan1 = df1.join(broadcast(df2), "key")._jdf.queryExecution().executedPlan() self.assertEqual(1, plan1.toString().count("BroadcastHashJoin")) # no join key -- should not be a broadcast join plan2 = df1.crossJoin(broadcast(df2))._jdf.queryExecution().executedPlan() self.assertEqual(0, plan2.toString().count("BroadcastHashJoin")) # planner should not crash without a join broadcast(df1)._jdf.queryExecution().executedPlan() def test_generic_hints(self): from pyspark.sql import DataFrame df1 = self.spark.range(10e10).toDF("id") df2 = self.spark.range(10e10).toDF("id") self.assertIsInstance(df1.hint("broadcast"), DataFrame) self.assertIsInstance(df1.hint("broadcast", []), DataFrame) # Dummy rules self.assertIsInstance(df1.hint("broadcast", "foo", "bar"), DataFrame) self.assertIsInstance(df1.hint("broadcast", ["foo", "bar"]), DataFrame) plan = df1.join(df2.hint("broadcast"), "id")._jdf.queryExecution().executedPlan() self.assertEqual(1, plan.toString().count("BroadcastHashJoin")) def test_sample(self): self.assertRaisesRegexp( TypeError, "should be a bool, float and number", lambda: self.spark.range(1).sample()) self.assertRaises( TypeError, lambda: self.spark.range(1).sample("a")) self.assertRaises( TypeError, lambda: self.spark.range(1).sample(seed="abc")) self.assertRaises( IllegalArgumentException, lambda: self.spark.range(1).sample(-1.0)) def test_toDF_with_schema_string(self): data = [Row(key=i, value=str(i)) for i in range(100)] rdd = self.sc.parallelize(data, 5) df = rdd.toDF("key: int, value: string") self.assertEqual(df.schema.simpleString(), "struct") self.assertEqual(df.collect(), data) # different but compatible field types can be used. df = rdd.toDF("key: string, value: string") self.assertEqual(df.schema.simpleString(), "struct") self.assertEqual(df.collect(), [Row(key=str(i), value=str(i)) for i in range(100)]) # field names can differ. df = rdd.toDF(" a: int, b: string ") self.assertEqual(df.schema.simpleString(), "struct") self.assertEqual(df.collect(), data) # number of fields must match. self.assertRaisesRegexp(Exception, "Length of object", lambda: rdd.toDF("key: int").collect()) # field types mismatch will cause exception at runtime. self.assertRaisesRegexp(Exception, "FloatType can not accept", lambda: rdd.toDF("key: float, value: string").collect()) # flat schema values will be wrapped into row. df = rdd.map(lambda row: row.key).toDF("int") self.assertEqual(df.schema.simpleString(), "struct") self.assertEqual(df.collect(), [Row(key=i) for i in range(100)]) # users can use DataType directly instead of data type string. df = rdd.map(lambda row: row.key).toDF(IntegerType()) self.assertEqual(df.schema.simpleString(), "struct") self.assertEqual(df.collect(), [Row(key=i) for i in range(100)]) def test_join_without_on(self): df1 = self.spark.range(1).toDF("a") df2 = self.spark.range(1).toDF("b") with self.sql_conf({"spark.sql.crossJoin.enabled": False}): self.assertRaises(AnalysisException, lambda: df1.join(df2, how="inner").collect()) with self.sql_conf({"spark.sql.crossJoin.enabled": True}): actual = df1.join(df2, how="inner").collect() expected = [Row(a=0, b=0)] self.assertEqual(actual, expected) # Regression test for invalid join methods when on is None, Spark-14761 def test_invalid_join_method(self): df1 = self.spark.createDataFrame([("Alice", 5), ("Bob", 8)], ["name", "age"]) df2 = self.spark.createDataFrame([("Alice", 80), ("Bob", 90)], ["name", "height"]) self.assertRaises(IllegalArgumentException, lambda: df1.join(df2, how="invalid-join-type")) # Cartesian products require cross join syntax def test_require_cross(self): from pyspark.sql.functions import broadcast df1 = self.spark.createDataFrame([(1, "1")], ("key", "value")) df2 = self.spark.createDataFrame([(1, "1")], ("key", "value")) # joins without conditions require cross join syntax self.assertRaises(AnalysisException, lambda: df1.join(df2).collect()) # works with crossJoin self.assertEqual(1, df1.crossJoin(df2).count()) def test_conf(self): spark = self.spark spark.conf.set("bogo", "sipeo") self.assertEqual(spark.conf.get("bogo"), "sipeo") spark.conf.set("bogo", "ta") self.assertEqual(spark.conf.get("bogo"), "ta") self.assertEqual(spark.conf.get("bogo", "not.read"), "ta") self.assertEqual(spark.conf.get("not.set", "ta"), "ta") self.assertRaisesRegexp(Exception, "not.set", lambda: spark.conf.get("not.set")) spark.conf.unset("bogo") self.assertEqual(spark.conf.get("bogo", "colombia"), "colombia") self.assertEqual(spark.conf.get("hyukjin", None), None) # This returns 'STATIC' because it's the default value of # 'spark.sql.sources.partitionOverwriteMode', and `defaultValue` in # `spark.conf.get` is unset. self.assertEqual(spark.conf.get("spark.sql.sources.partitionOverwriteMode"), "STATIC") # This returns None because 'spark.sql.sources.partitionOverwriteMode' is unset, but # `defaultValue` in `spark.conf.get` is set to None. self.assertEqual(spark.conf.get("spark.sql.sources.partitionOverwriteMode", None), None) def test_current_database(self): spark = self.spark spark.catalog._reset() self.assertEquals(spark.catalog.currentDatabase(), "default") spark.sql("CREATE DATABASE some_db") spark.catalog.setCurrentDatabase("some_db") self.assertEquals(spark.catalog.currentDatabase(), "some_db") self.assertRaisesRegexp( AnalysisException, "does_not_exist", lambda: spark.catalog.setCurrentDatabase("does_not_exist")) def test_list_databases(self): spark = self.spark spark.catalog._reset() databases = [db.name for db in spark.catalog.listDatabases()] self.assertEquals(databases, ["default"]) spark.sql("CREATE DATABASE some_db") databases = [db.name for db in spark.catalog.listDatabases()] self.assertEquals(sorted(databases), ["default", "some_db"]) def test_list_tables(self): from pyspark.sql.catalog import Table spark = self.spark spark.catalog._reset() spark.sql("CREATE DATABASE some_db") self.assertEquals(spark.catalog.listTables(), []) self.assertEquals(spark.catalog.listTables("some_db"), []) spark.createDataFrame([(1, 1)]).createOrReplaceTempView("temp_tab") spark.sql("CREATE TABLE tab1 (name STRING, age INT) USING parquet") spark.sql("CREATE TABLE some_db.tab2 (name STRING, age INT) USING parquet") tables = sorted(spark.catalog.listTables(), key=lambda t: t.name) tablesDefault = sorted(spark.catalog.listTables("default"), key=lambda t: t.name) tablesSomeDb = sorted(spark.catalog.listTables("some_db"), key=lambda t: t.name) self.assertEquals(tables, tablesDefault) self.assertEquals(len(tables), 2) self.assertEquals(len(tablesSomeDb), 2) self.assertEquals(tables[0], Table( name="tab1", database="default", description=None, tableType="MANAGED", isTemporary=False)) self.assertEquals(tables[1], Table( name="temp_tab", database=None, description=None, tableType="TEMPORARY", isTemporary=True)) self.assertEquals(tablesSomeDb[0], Table( name="tab2", database="some_db", description=None, tableType="MANAGED", isTemporary=False)) self.assertEquals(tablesSomeDb[1], Table( name="temp_tab", database=None, description=None, tableType="TEMPORARY", isTemporary=True)) self.assertRaisesRegexp( AnalysisException, "does_not_exist", lambda: spark.catalog.listTables("does_not_exist")) def test_list_functions(self): from pyspark.sql.catalog import Function spark = self.spark spark.catalog._reset() spark.sql("CREATE DATABASE some_db") functions = dict((f.name, f) for f in spark.catalog.listFunctions()) functionsDefault = dict((f.name, f) for f in spark.catalog.listFunctions("default")) self.assertTrue(len(functions) > 200) self.assertTrue("+" in functions) self.assertTrue("like" in functions) self.assertTrue("month" in functions) self.assertTrue("to_date" in functions) self.assertTrue("to_timestamp" in functions) self.assertTrue("to_unix_timestamp" in functions) self.assertTrue("current_database" in functions) self.assertEquals(functions["+"], Function( name="+", description=None, className="org.apache.spark.sql.catalyst.expressions.Add", isTemporary=True)) self.assertEquals(functions, functionsDefault) spark.catalog.registerFunction("temp_func", lambda x: str(x)) spark.sql("CREATE FUNCTION func1 AS 'org.apache.spark.data.bricks'") spark.sql("CREATE FUNCTION some_db.func2 AS 'org.apache.spark.data.bricks'") newFunctions = dict((f.name, f) for f in spark.catalog.listFunctions()) newFunctionsSomeDb = dict((f.name, f) for f in spark.catalog.listFunctions("some_db")) self.assertTrue(set(functions).issubset(set(newFunctions))) self.assertTrue(set(functions).issubset(set(newFunctionsSomeDb))) self.assertTrue("temp_func" in newFunctions) self.assertTrue("func1" in newFunctions) self.assertTrue("func2" not in newFunctions) self.assertTrue("temp_func" in newFunctionsSomeDb) self.assertTrue("func1" not in newFunctionsSomeDb) self.assertTrue("func2" in newFunctionsSomeDb) self.assertRaisesRegexp( AnalysisException, "does_not_exist", lambda: spark.catalog.listFunctions("does_not_exist")) def test_list_columns(self): from pyspark.sql.catalog import Column spark = self.spark spark.catalog._reset() spark.sql("CREATE DATABASE some_db") spark.sql("CREATE TABLE tab1 (name STRING, age INT) USING parquet") spark.sql("CREATE TABLE some_db.tab2 (nickname STRING, tolerance FLOAT) USING parquet") columns = sorted(spark.catalog.listColumns("tab1"), key=lambda c: c.name) columnsDefault = sorted(spark.catalog.listColumns("tab1", "default"), key=lambda c: c.name) self.assertEquals(columns, columnsDefault) self.assertEquals(len(columns), 2) self.assertEquals(columns[0], Column( name="age", description=None, dataType="int", nullable=True, isPartition=False, isBucket=False)) self.assertEquals(columns[1], Column( name="name", description=None, dataType="string", nullable=True, isPartition=False, isBucket=False)) columns2 = sorted(spark.catalog.listColumns("tab2", "some_db"), key=lambda c: c.name) self.assertEquals(len(columns2), 2) self.assertEquals(columns2[0], Column( name="nickname", description=None, dataType="string", nullable=True, isPartition=False, isBucket=False)) self.assertEquals(columns2[1], Column( name="tolerance", description=None, dataType="float", nullable=True, isPartition=False, isBucket=False)) self.assertRaisesRegexp( AnalysisException, "tab2", lambda: spark.catalog.listColumns("tab2")) self.assertRaisesRegexp( AnalysisException, "does_not_exist", lambda: spark.catalog.listColumns("does_not_exist")) def test_cache(self): spark = self.spark spark.createDataFrame([(2, 2), (3, 3)]).createOrReplaceTempView("tab1") spark.createDataFrame([(2, 2), (3, 3)]).createOrReplaceTempView("tab2") self.assertFalse(spark.catalog.isCached("tab1")) self.assertFalse(spark.catalog.isCached("tab2")) spark.catalog.cacheTable("tab1") self.assertTrue(spark.catalog.isCached("tab1")) self.assertFalse(spark.catalog.isCached("tab2")) spark.catalog.cacheTable("tab2") spark.catalog.uncacheTable("tab1") self.assertFalse(spark.catalog.isCached("tab1")) self.assertTrue(spark.catalog.isCached("tab2")) spark.catalog.clearCache() self.assertFalse(spark.catalog.isCached("tab1")) self.assertFalse(spark.catalog.isCached("tab2")) self.assertRaisesRegexp( AnalysisException, "does_not_exist", lambda: spark.catalog.isCached("does_not_exist")) self.assertRaisesRegexp( AnalysisException, "does_not_exist", lambda: spark.catalog.cacheTable("does_not_exist")) self.assertRaisesRegexp( AnalysisException, "does_not_exist", lambda: spark.catalog.uncacheTable("does_not_exist")) def test_read_text_file_list(self): df = self.spark.read.text(['python/test_support/sql/text-test.txt', 'python/test_support/sql/text-test.txt']) count = df.count() self.assertEquals(count, 4) def test_BinaryType_serialization(self): # Pyrolite version <= 4.9 could not serialize BinaryType with Python3 SPARK-17808 # The empty bytearray is test for SPARK-21534. schema = StructType([StructField('mybytes', BinaryType())]) data = [[bytearray(b'here is my data')], [bytearray(b'and here is some more')], [bytearray(b'')]] df = self.spark.createDataFrame(data, schema=schema) df.collect() # test for SPARK-16542 def test_array_types(self): # This test need to make sure that the Scala type selected is at least # as large as the python's types. This is necessary because python's # array types depend on C implementation on the machine. Therefore there # is no machine independent correspondence between python's array types # and Scala types. # See: https://docs.python.org/2/library/array.html def assertCollectSuccess(typecode, value): row = Row(myarray=array.array(typecode, [value])) df = self.spark.createDataFrame([row]) self.assertEqual(df.first()["myarray"][0], value) # supported string types # # String types in python's array are "u" for Py_UNICODE and "c" for char. # "u" will be removed in python 4, and "c" is not supported in python 3. supported_string_types = [] if sys.version_info[0] < 4: supported_string_types += ['u'] # test unicode assertCollectSuccess('u', u'a') if sys.version_info[0] < 3: supported_string_types += ['c'] # test string assertCollectSuccess('c', 'a') # supported float and double # # Test max, min, and precision for float and double, assuming IEEE 754 # floating-point format. supported_fractional_types = ['f', 'd'] assertCollectSuccess('f', ctypes.c_float(1e+38).value) assertCollectSuccess('f', ctypes.c_float(1e-38).value) assertCollectSuccess('f', ctypes.c_float(1.123456).value) assertCollectSuccess('d', sys.float_info.max) assertCollectSuccess('d', sys.float_info.min) assertCollectSuccess('d', sys.float_info.epsilon) # supported signed int types # # The size of C types changes with implementation, we need to make sure # that there is no overflow error on the platform running this test. supported_signed_int_types = list( set(_array_signed_int_typecode_ctype_mappings.keys()) .intersection(set(_array_type_mappings.keys()))) for t in supported_signed_int_types: ctype = _array_signed_int_typecode_ctype_mappings[t] max_val = 2 ** (ctypes.sizeof(ctype) * 8 - 1) assertCollectSuccess(t, max_val - 1) assertCollectSuccess(t, -max_val) # supported unsigned int types # # JVM does not have unsigned types. We need to be very careful to make # sure that there is no overflow error. supported_unsigned_int_types = list( set(_array_unsigned_int_typecode_ctype_mappings.keys()) .intersection(set(_array_type_mappings.keys()))) for t in supported_unsigned_int_types: ctype = _array_unsigned_int_typecode_ctype_mappings[t] assertCollectSuccess(t, 2 ** (ctypes.sizeof(ctype) * 8) - 1) # all supported types # # Make sure the types tested above: # 1. are all supported types # 2. cover all supported types supported_types = (supported_string_types + supported_fractional_types + supported_signed_int_types + supported_unsigned_int_types) self.assertEqual(set(supported_types), set(_array_type_mappings.keys())) # all unsupported types # # Keys in _array_type_mappings is a complete list of all supported types, # and types not in _array_type_mappings are considered unsupported. # `array.typecodes` are not supported in python 2. if sys.version_info[0] < 3: all_types = set(['c', 'b', 'B', 'u', 'h', 'H', 'i', 'I', 'l', 'L', 'f', 'd']) else: all_types = set(array.typecodes) unsupported_types = all_types - set(supported_types) # test unsupported types for t in unsupported_types: with self.assertRaises(TypeError): a = array.array(t) self.spark.createDataFrame([Row(myarray=a)]).collect() def test_bucketed_write(self): data = [ (1, "foo", 3.0), (2, "foo", 5.0), (3, "bar", -1.0), (4, "bar", 6.0), ] df = self.spark.createDataFrame(data, ["x", "y", "z"]) def count_bucketed_cols(names, table="pyspark_bucket"): """Given a sequence of column names and a table name query the catalog and return number o columns which are used for bucketing """ cols = self.spark.catalog.listColumns(table) num = len([c for c in cols if c.name in names and c.isBucket]) return num # Test write with one bucketing column df.write.bucketBy(3, "x").mode("overwrite").saveAsTable("pyspark_bucket") self.assertEqual(count_bucketed_cols(["x"]), 1) self.assertSetEqual(set(data), set(self.spark.table("pyspark_bucket").collect())) # Test write two bucketing columns df.write.bucketBy(3, "x", "y").mode("overwrite").saveAsTable("pyspark_bucket") self.assertEqual(count_bucketed_cols(["x", "y"]), 2) self.assertSetEqual(set(data), set(self.spark.table("pyspark_bucket").collect())) # Test write with bucket and sort df.write.bucketBy(2, "x").sortBy("z").mode("overwrite").saveAsTable("pyspark_bucket") self.assertEqual(count_bucketed_cols(["x"]), 1) self.assertSetEqual(set(data), set(self.spark.table("pyspark_bucket").collect())) # Test write with a list of columns df.write.bucketBy(3, ["x", "y"]).mode("overwrite").saveAsTable("pyspark_bucket") self.assertEqual(count_bucketed_cols(["x", "y"]), 2) self.assertSetEqual(set(data), set(self.spark.table("pyspark_bucket").collect())) # Test write with bucket and sort with a list of columns (df.write.bucketBy(2, "x") .sortBy(["y", "z"]) .mode("overwrite").saveAsTable("pyspark_bucket")) self.assertSetEqual(set(data), set(self.spark.table("pyspark_bucket").collect())) # Test write with bucket and sort with multiple columns (df.write.bucketBy(2, "x") .sortBy("y", "z") .mode("overwrite").saveAsTable("pyspark_bucket")) self.assertSetEqual(set(data), set(self.spark.table("pyspark_bucket").collect())) def _to_pandas(self): from datetime import datetime, date schema = StructType().add("a", IntegerType()).add("b", StringType())\ .add("c", BooleanType()).add("d", FloatType())\ .add("dt", DateType()).add("ts", TimestampType()) data = [ (1, "foo", True, 3.0, date(1969, 1, 1), datetime(1969, 1, 1, 1, 1, 1)), (2, "foo", True, 5.0, None, None), (3, "bar", False, -1.0, date(2012, 3, 3), datetime(2012, 3, 3, 3, 3, 3)), (4, "bar", False, 6.0, date(2100, 4, 4), datetime(2100, 4, 4, 4, 4, 4)), ] df = self.spark.createDataFrame(data, schema) return df.toPandas() @unittest.skipIf(not _have_pandas, _pandas_requirement_message) def test_to_pandas(self): import numpy as np pdf = self._to_pandas() types = pdf.dtypes self.assertEquals(types[0], np.int32) self.assertEquals(types[1], np.object) self.assertEquals(types[2], np.bool) self.assertEquals(types[3], np.float32) self.assertEquals(types[4], np.object) # datetime.date self.assertEquals(types[5], 'datetime64[ns]') @unittest.skipIf(_have_pandas, "Required Pandas was found.") def test_to_pandas_required_pandas_not_found(self): with QuietTest(self.sc): with self.assertRaisesRegexp(ImportError, 'Pandas >= .* must be installed'): self._to_pandas() @unittest.skipIf(not _have_pandas, _pandas_requirement_message) def test_to_pandas_avoid_astype(self): import numpy as np schema = StructType().add("a", IntegerType()).add("b", StringType())\ .add("c", IntegerType()) data = [(1, "foo", 16777220), (None, "bar", None)] df = self.spark.createDataFrame(data, schema) types = df.toPandas().dtypes self.assertEquals(types[0], np.float64) # doesn't convert to np.int32 due to NaN value. self.assertEquals(types[1], np.object) self.assertEquals(types[2], np.float64) def test_create_dataframe_from_array_of_long(self): import array data = [Row(longarray=array.array('l', [-9223372036854775808, 0, 9223372036854775807]))] df = self.spark.createDataFrame(data) self.assertEqual(df.first(), Row(longarray=[-9223372036854775808, 0, 9223372036854775807])) @unittest.skipIf(not _have_pandas, _pandas_requirement_message) def test_create_dataframe_from_pandas_with_timestamp(self): import pandas as pd from datetime import datetime pdf = pd.DataFrame({"ts": [datetime(2017, 10, 31, 1, 1, 1)], "d": [pd.Timestamp.now().date()]}, columns=["d", "ts"]) # test types are inferred correctly without specifying schema df = self.spark.createDataFrame(pdf) self.assertTrue(isinstance(df.schema['ts'].dataType, TimestampType)) self.assertTrue(isinstance(df.schema['d'].dataType, DateType)) # test with schema will accept pdf as input df = self.spark.createDataFrame(pdf, schema="d date, ts timestamp") self.assertTrue(isinstance(df.schema['ts'].dataType, TimestampType)) self.assertTrue(isinstance(df.schema['d'].dataType, DateType)) @unittest.skipIf(_have_pandas, "Required Pandas was found.") def test_create_dataframe_required_pandas_not_found(self): with QuietTest(self.sc): with self.assertRaisesRegexp( ImportError, "(Pandas >= .* must be installed|No module named '?pandas'?)"): import pandas as pd from datetime import datetime pdf = pd.DataFrame({"ts": [datetime(2017, 10, 31, 1, 1, 1)], "d": [pd.Timestamp.now().date()]}) self.spark.createDataFrame(pdf) # Regression test for SPARK-23360 @unittest.skipIf(not _have_pandas, _pandas_requirement_message) def test_create_dateframe_from_pandas_with_dst(self): import pandas as pd from datetime import datetime pdf = pd.DataFrame({'time': [datetime(2015, 10, 31, 22, 30)]}) df = self.spark.createDataFrame(pdf) self.assertPandasEqual(pdf, df.toPandas()) orig_env_tz = os.environ.get('TZ', None) try: tz = 'America/Los_Angeles' os.environ['TZ'] = tz time.tzset() with self.sql_conf({'spark.sql.session.timeZone': tz}): df = self.spark.createDataFrame(pdf) self.assertPandasEqual(pdf, df.toPandas()) finally: del os.environ['TZ'] if orig_env_tz is not None: os.environ['TZ'] = orig_env_tz time.tzset() def test_sort_with_nulls_order(self): from pyspark.sql import functions df = self.spark.createDataFrame( [('Tom', 80), (None, 60), ('Alice', 50)], ["name", "height"]) self.assertEquals( df.select(df.name).orderBy(functions.asc_nulls_first('name')).collect(), [Row(name=None), Row(name=u'Alice'), Row(name=u'Tom')]) self.assertEquals( df.select(df.name).orderBy(functions.asc_nulls_last('name')).collect(), [Row(name=u'Alice'), Row(name=u'Tom'), Row(name=None)]) self.assertEquals( df.select(df.name).orderBy(functions.desc_nulls_first('name')).collect(), [Row(name=None), Row(name=u'Tom'), Row(name=u'Alice')]) self.assertEquals( df.select(df.name).orderBy(functions.desc_nulls_last('name')).collect(), [Row(name=u'Tom'), Row(name=u'Alice'), Row(name=None)]) def test_json_sampling_ratio(self): rdd = self.spark.sparkContext.range(0, 100, 1, 1) \ .map(lambda x: '{"a":0.1}' if x == 1 else '{"a":%s}' % str(x)) schema = self.spark.read.option('inferSchema', True) \ .option('samplingRatio', 0.5) \ .json(rdd).schema self.assertEquals(schema, StructType([StructField("a", LongType(), True)])) def test_csv_sampling_ratio(self): rdd = self.spark.sparkContext.range(0, 100, 1, 1) \ .map(lambda x: '0.1' if x == 1 else str(x)) schema = self.spark.read.option('inferSchema', True)\ .csv(rdd, samplingRatio=0.5).schema self.assertEquals(schema, StructType([StructField("_c0", IntegerType(), True)])) def test_checking_csv_header(self): path = tempfile.mkdtemp() shutil.rmtree(path) try: self.spark.createDataFrame([[1, 1000], [2000, 2]])\ .toDF('f1', 'f2').write.option("header", "true").csv(path) schema = StructType([ StructField('f2', IntegerType(), nullable=True), StructField('f1', IntegerType(), nullable=True)]) df = self.spark.read.option('header', 'true').schema(schema)\ .csv(path, enforceSchema=False) self.assertRaisesRegexp( Exception, "CSV header does not conform to the schema", lambda: df.collect()) finally: shutil.rmtree(path) def test_ignore_column_of_all_nulls(self): path = tempfile.mkdtemp() shutil.rmtree(path) try: df = self.spark.createDataFrame([["""{"a":null, "b":1, "c":3.0}"""], ["""{"a":null, "b":null, "c":"string"}"""], ["""{"a":null, "b":null, "c":null}"""]]) df.write.text(path) schema = StructType([ StructField('b', LongType(), nullable=True), StructField('c', StringType(), nullable=True)]) readback = self.spark.read.json(path, dropFieldIfAllNull=True) self.assertEquals(readback.schema, schema) finally: shutil.rmtree(path) # SPARK-24721 @unittest.skipIf(not _test_compiled, _test_not_compiled_message) def test_datasource_with_udf(self): from pyspark.sql.functions import udf, lit, col path = tempfile.mkdtemp() shutil.rmtree(path) try: self.spark.range(1).write.mode("overwrite").format('csv').save(path) filesource_df = self.spark.read.option('inferSchema', True).csv(path).toDF('i') datasource_df = self.spark.read \ .format("org.apache.spark.sql.sources.SimpleScanSource") \ .option('from', 0).option('to', 1).load().toDF('i') datasource_v2_df = self.spark.read \ .format("org.apache.spark.sql.sources.v2.SimpleDataSourceV2") \ .load().toDF('i', 'j') c1 = udf(lambda x: x + 1, 'int')(lit(1)) c2 = udf(lambda x: x + 1, 'int')(col('i')) f1 = udf(lambda x: False, 'boolean')(lit(1)) f2 = udf(lambda x: False, 'boolean')(col('i')) for df in [filesource_df, datasource_df, datasource_v2_df]: result = df.withColumn('c', c1) expected = df.withColumn('c', lit(2)) self.assertEquals(expected.collect(), result.collect()) for df in [filesource_df, datasource_df, datasource_v2_df]: result = df.withColumn('c', c2) expected = df.withColumn('c', col('i') + 1) self.assertEquals(expected.collect(), result.collect()) for df in [filesource_df, datasource_df, datasource_v2_df]: for f in [f1, f2]: result = df.filter(f) self.assertEquals(0, result.count()) finally: shutil.rmtree(path) def test_repr_behaviors(self): import re pattern = re.compile(r'^ *\|', re.MULTILINE) df = self.spark.createDataFrame([(1, "1"), (22222, "22222")], ("key", "value")) # test when eager evaluation is enabled and _repr_html_ will not be called with self.sql_conf({"spark.sql.repl.eagerEval.enabled": True}): expected1 = """+-----+-----+ || key|value| |+-----+-----+ || 1| 1| ||22222|22222| |+-----+-----+ |""" self.assertEquals(re.sub(pattern, '', expected1), df.__repr__()) with self.sql_conf({"spark.sql.repl.eagerEval.truncate": 3}): expected2 = """+---+-----+ ||key|value| |+---+-----+ || 1| 1| ||222| 222| |+---+-----+ |""" self.assertEquals(re.sub(pattern, '', expected2), df.__repr__()) with self.sql_conf({"spark.sql.repl.eagerEval.maxNumRows": 1}): expected3 = """+---+-----+ ||key|value| |+---+-----+ || 1| 1| |+---+-----+ |only showing top 1 row |""" self.assertEquals(re.sub(pattern, '', expected3), df.__repr__()) # test when eager evaluation is enabled and _repr_html_ will be called with self.sql_conf({"spark.sql.repl.eagerEval.enabled": True}): expected1 = """ | | | |
keyvalue
11
2222222222
|""" self.assertEquals(re.sub(pattern, '', expected1), df._repr_html_()) with self.sql_conf({"spark.sql.repl.eagerEval.truncate": 3}): expected2 = """ | | | |
keyvalue
11
222222
|""" self.assertEquals(re.sub(pattern, '', expected2), df._repr_html_()) with self.sql_conf({"spark.sql.repl.eagerEval.maxNumRows": 1}): expected3 = """ | | |
keyvalue
11
|only showing top 1 row |""" self.assertEquals(re.sub(pattern, '', expected3), df._repr_html_()) # test when eager evaluation is disabled and _repr_html_ will be called with self.sql_conf({"spark.sql.repl.eagerEval.enabled": False}): expected = "DataFrame[key: bigint, value: string]" self.assertEquals(None, df._repr_html_()) self.assertEquals(expected, df.__repr__()) with self.sql_conf({"spark.sql.repl.eagerEval.truncate": 3}): self.assertEquals(None, df._repr_html_()) self.assertEquals(expected, df.__repr__()) with self.sql_conf({"spark.sql.repl.eagerEval.maxNumRows": 1}): self.assertEquals(None, df._repr_html_()) self.assertEquals(expected, df.__repr__()) class HiveSparkSubmitTests(SparkSubmitTests): @classmethod def setUpClass(cls): # get a SparkContext to check for availability of Hive sc = SparkContext('local[4]', cls.__name__) cls.hive_available = True try: sc._jvm.org.apache.hadoop.hive.conf.HiveConf() except py4j.protocol.Py4JError: cls.hive_available = False except TypeError: cls.hive_available = False finally: # we don't need this SparkContext for the test sc.stop() def setUp(self): super(HiveSparkSubmitTests, self).setUp() if not self.hive_available: self.skipTest("Hive is not available.") def test_hivecontext(self): # This test checks that HiveContext is using Hive metastore (SPARK-16224). # It sets a metastore url and checks if there is a derby dir created by # Hive metastore. If this derby dir exists, HiveContext is using # Hive metastore. metastore_path = os.path.join(tempfile.mkdtemp(), "spark16224_metastore_db") metastore_URL = "jdbc:derby:;databaseName=" + metastore_path + ";create=true" hive_site_dir = os.path.join(self.programDir, "conf") hive_site_file = self.createTempFile("hive-site.xml", (""" | | | javax.jdo.option.ConnectionURL | %s | | """ % metastore_URL).lstrip(), "conf") script = self.createTempFile("test.py", """ |import os | |from pyspark.conf import SparkConf |from pyspark.context import SparkContext |from pyspark.sql import HiveContext | |conf = SparkConf() |sc = SparkContext(conf=conf) |hive_context = HiveContext(sc) |print(hive_context.sql("show databases").collect()) """) proc = subprocess.Popen( self.sparkSubmit + ["--master", "local-cluster[1,1,1024]", "--driver-class-path", hive_site_dir, script], stdout=subprocess.PIPE) out, err = proc.communicate() self.assertEqual(0, proc.returncode) self.assertIn("default", out.decode('utf-8')) self.assertTrue(os.path.exists(metastore_path)) class SQLTests2(ReusedSQLTestCase): # We can't include this test into SQLTests because we will stop class's SparkContext and cause # other tests failed. def test_sparksession_with_stopped_sparkcontext(self): self.sc.stop() sc = SparkContext('local[4]', self.sc.appName) spark = SparkSession.builder.getOrCreate() try: df = spark.createDataFrame([(1, 2)], ["c", "c"]) df.collect() finally: spark.stop() sc.stop() class QueryExecutionListenerTests(unittest.TestCase, SQLTestUtils): # These tests are separate because it uses 'spark.sql.queryExecutionListeners' which is # static and immutable. This can't be set or unset, for example, via `spark.conf`. @classmethod def setUpClass(cls): import glob from pyspark.find_spark_home import _find_spark_home SPARK_HOME = _find_spark_home() filename_pattern = ( "sql/core/target/scala-*/test-classes/org/apache/spark/sql/" "TestQueryExecutionListener.class") cls.has_listener = bool(glob.glob(os.path.join(SPARK_HOME, filename_pattern))) if cls.has_listener: # Note that 'spark.sql.queryExecutionListeners' is a static immutable configuration. cls.spark = SparkSession.builder \ .master("local[4]") \ .appName(cls.__name__) \ .config( "spark.sql.queryExecutionListeners", "org.apache.spark.sql.TestQueryExecutionListener") \ .getOrCreate() def setUp(self): if not self.has_listener: raise self.skipTest( "'org.apache.spark.sql.TestQueryExecutionListener' is not " "available. Will skip the related tests.") @classmethod def tearDownClass(cls): if hasattr(cls, "spark"): cls.spark.stop() def tearDown(self): self.spark._jvm.OnSuccessCall.clear() def test_query_execution_listener_on_collect(self): self.assertFalse( self.spark._jvm.OnSuccessCall.isCalled(), "The callback from the query execution listener should not be called before 'collect'") self.spark.sql("SELECT * FROM range(1)").collect() self.assertTrue( self.spark._jvm.OnSuccessCall.isCalled(), "The callback from the query execution listener should be called after 'collect'") @unittest.skipIf( not _have_pandas or not _have_pyarrow, _pandas_requirement_message or _pyarrow_requirement_message) def test_query_execution_listener_on_collect_with_arrow(self): with self.sql_conf({"spark.sql.execution.arrow.enabled": True}): self.assertFalse( self.spark._jvm.OnSuccessCall.isCalled(), "The callback from the query execution listener should not be " "called before 'toPandas'") self.spark.sql("SELECT * FROM range(1)").toPandas() self.assertTrue( self.spark._jvm.OnSuccessCall.isCalled(), "The callback from the query execution listener should be called after 'toPandas'") class SparkSessionTests(PySparkTestCase): # This test is separate because it's closely related with session's start and stop. # See SPARK-23228. def test_set_jvm_default_session(self): spark = SparkSession.builder.getOrCreate() try: self.assertTrue(spark._jvm.SparkSession.getDefaultSession().isDefined()) finally: spark.stop() self.assertTrue(spark._jvm.SparkSession.getDefaultSession().isEmpty()) def test_jvm_default_session_already_set(self): # Here, we assume there is the default session already set in JVM. jsession = self.sc._jvm.SparkSession(self.sc._jsc.sc()) self.sc._jvm.SparkSession.setDefaultSession(jsession) spark = SparkSession.builder.getOrCreate() try: self.assertTrue(spark._jvm.SparkSession.getDefaultSession().isDefined()) # The session should be the same with the exiting one. self.assertTrue(jsession.equals(spark._jvm.SparkSession.getDefaultSession().get())) finally: spark.stop() class UDFInitializationTests(unittest.TestCase): def tearDown(self): if SparkSession._instantiatedSession is not None: SparkSession._instantiatedSession.stop() if SparkContext._active_spark_context is not None: SparkContext._active_spark_context.stop() def test_udf_init_shouldnt_initialize_context(self): from pyspark.sql.functions import UserDefinedFunction UserDefinedFunction(lambda x: x, StringType()) self.assertIsNone( SparkContext._active_spark_context, "SparkContext shouldn't be initialized when UserDefinedFunction is created." ) self.assertIsNone( SparkSession._instantiatedSession, "SparkSession shouldn't be initialized when UserDefinedFunction is created." ) class HiveContextSQLTests(ReusedPySparkTestCase): @classmethod def setUpClass(cls): ReusedPySparkTestCase.setUpClass() cls.tempdir = tempfile.NamedTemporaryFile(delete=False) cls.hive_available = True try: cls.sc._jvm.org.apache.hadoop.hive.conf.HiveConf() except py4j.protocol.Py4JError: cls.hive_available = False except TypeError: cls.hive_available = False os.unlink(cls.tempdir.name) if cls.hive_available: cls.spark = HiveContext._createForTesting(cls.sc) cls.testData = [Row(key=i, value=str(i)) for i in range(100)] cls.df = cls.sc.parallelize(cls.testData).toDF() def setUp(self): if not self.hive_available: self.skipTest("Hive is not available.") @classmethod def tearDownClass(cls): ReusedPySparkTestCase.tearDownClass() shutil.rmtree(cls.tempdir.name, ignore_errors=True) def test_save_and_load_table(self): df = self.df tmpPath = tempfile.mkdtemp() shutil.rmtree(tmpPath) df.write.saveAsTable("savedJsonTable", "json", "append", path=tmpPath) actual = self.spark.createExternalTable("externalJsonTable", tmpPath, "json") self.assertEqual(sorted(df.collect()), sorted(self.spark.sql("SELECT * FROM savedJsonTable").collect())) self.assertEqual(sorted(df.collect()), sorted(self.spark.sql("SELECT * FROM externalJsonTable").collect())) self.assertEqual(sorted(df.collect()), sorted(actual.collect())) self.spark.sql("DROP TABLE externalJsonTable") df.write.saveAsTable("savedJsonTable", "json", "overwrite", path=tmpPath) schema = StructType([StructField("value", StringType(), True)]) actual = self.spark.createExternalTable("externalJsonTable", source="json", schema=schema, path=tmpPath, noUse="this options will not be used") self.assertEqual(sorted(df.collect()), sorted(self.spark.sql("SELECT * FROM savedJsonTable").collect())) self.assertEqual(sorted(df.select("value").collect()), sorted(self.spark.sql("SELECT * FROM externalJsonTable").collect())) self.assertEqual(sorted(df.select("value").collect()), sorted(actual.collect())) self.spark.sql("DROP TABLE savedJsonTable") self.spark.sql("DROP TABLE externalJsonTable") defaultDataSourceName = self.spark.getConf("spark.sql.sources.default", "org.apache.spark.sql.parquet") self.spark.sql("SET spark.sql.sources.default=org.apache.spark.sql.json") df.write.saveAsTable("savedJsonTable", path=tmpPath, mode="overwrite") actual = self.spark.createExternalTable("externalJsonTable", path=tmpPath) self.assertEqual(sorted(df.collect()), sorted(self.spark.sql("SELECT * FROM savedJsonTable").collect())) self.assertEqual(sorted(df.collect()), sorted(self.spark.sql("SELECT * FROM externalJsonTable").collect())) self.assertEqual(sorted(df.collect()), sorted(actual.collect())) self.spark.sql("DROP TABLE savedJsonTable") self.spark.sql("DROP TABLE externalJsonTable") self.spark.sql("SET spark.sql.sources.default=" + defaultDataSourceName) shutil.rmtree(tmpPath) def test_window_functions(self): df = self.spark.createDataFrame([(1, "1"), (2, "2"), (1, "2"), (1, "2")], ["key", "value"]) w = Window.partitionBy("value").orderBy("key") from pyspark.sql import functions as F sel = df.select(df.value, df.key, F.max("key").over(w.rowsBetween(0, 1)), F.min("key").over(w.rowsBetween(0, 1)), F.count("key").over(w.rowsBetween(float('-inf'), float('inf'))), F.row_number().over(w), F.rank().over(w), F.dense_rank().over(w), F.ntile(2).over(w)) rs = sorted(sel.collect()) expected = [ ("1", 1, 1, 1, 1, 1, 1, 1, 1), ("2", 1, 1, 1, 3, 1, 1, 1, 1), ("2", 1, 2, 1, 3, 2, 1, 1, 1), ("2", 2, 2, 2, 3, 3, 3, 2, 2) ] for r, ex in zip(rs, expected): self.assertEqual(tuple(r), ex[:len(r)]) def test_window_functions_without_partitionBy(self): df = self.spark.createDataFrame([(1, "1"), (2, "2"), (1, "2"), (1, "2")], ["key", "value"]) w = Window.orderBy("key", df.value) from pyspark.sql import functions as F sel = df.select(df.value, df.key, F.max("key").over(w.rowsBetween(0, 1)), F.min("key").over(w.rowsBetween(0, 1)), F.count("key").over(w.rowsBetween(float('-inf'), float('inf'))), F.row_number().over(w), F.rank().over(w), F.dense_rank().over(w), F.ntile(2).over(w)) rs = sorted(sel.collect()) expected = [ ("1", 1, 1, 1, 4, 1, 1, 1, 1), ("2", 1, 1, 1, 4, 2, 2, 2, 1), ("2", 1, 2, 1, 4, 3, 2, 2, 2), ("2", 2, 2, 2, 4, 4, 4, 3, 2) ] for r, ex in zip(rs, expected): self.assertEqual(tuple(r), ex[:len(r)]) def test_window_functions_cumulative_sum(self): df = self.spark.createDataFrame([("one", 1), ("two", 2)], ["key", "value"]) from pyspark.sql import functions as F # Test cumulative sum sel = df.select( df.key, F.sum(df.value).over(Window.rowsBetween(Window.unboundedPreceding, 0))) rs = sorted(sel.collect()) expected = [("one", 1), ("two", 3)] for r, ex in zip(rs, expected): self.assertEqual(tuple(r), ex[:len(r)]) # Test boundary values less than JVM's Long.MinValue and make sure we don't overflow sel = df.select( df.key, F.sum(df.value).over(Window.rowsBetween(Window.unboundedPreceding - 1, 0))) rs = sorted(sel.collect()) expected = [("one", 1), ("two", 3)] for r, ex in zip(rs, expected): self.assertEqual(tuple(r), ex[:len(r)]) # Test boundary values greater than JVM's Long.MaxValue and make sure we don't overflow frame_end = Window.unboundedFollowing + 1 sel = df.select( df.key, F.sum(df.value).over(Window.rowsBetween(Window.currentRow, frame_end))) rs = sorted(sel.collect()) expected = [("one", 3), ("two", 2)] for r, ex in zip(rs, expected): self.assertEqual(tuple(r), ex[:len(r)]) def test_collect_functions(self): df = self.spark.createDataFrame([(1, "1"), (2, "2"), (1, "2"), (1, "2")], ["key", "value"]) from pyspark.sql import functions self.assertEqual( sorted(df.select(functions.collect_set(df.key).alias('r')).collect()[0].r), [1, 2]) self.assertEqual( sorted(df.select(functions.collect_list(df.key).alias('r')).collect()[0].r), [1, 1, 1, 2]) self.assertEqual( sorted(df.select(functions.collect_set(df.value).alias('r')).collect()[0].r), ["1", "2"]) self.assertEqual( sorted(df.select(functions.collect_list(df.value).alias('r')).collect()[0].r), ["1", "2", "2", "2"]) def test_limit_and_take(self): df = self.spark.range(1, 1000, numPartitions=10) def assert_runs_only_one_job_stage_and_task(job_group_name, f): tracker = self.sc.statusTracker() self.sc.setJobGroup(job_group_name, description="") f() jobs = tracker.getJobIdsForGroup(job_group_name) self.assertEqual(1, len(jobs)) stages = tracker.getJobInfo(jobs[0]).stageIds self.assertEqual(1, len(stages)) self.assertEqual(1, tracker.getStageInfo(stages[0]).numTasks) # Regression test for SPARK-10731: take should delegate to Scala implementation assert_runs_only_one_job_stage_and_task("take", lambda: df.take(1)) # Regression test for SPARK-17514: limit(n).collect() should the perform same as take(n) assert_runs_only_one_job_stage_and_task("collect_limit", lambda: df.limit(1).collect()) def test_datetime_functions(self): from pyspark.sql import functions from datetime import date, datetime df = self.spark.range(1).selectExpr("'2017-01-22' as dateCol") parse_result = df.select(functions.to_date(functions.col("dateCol"))).first() self.assertEquals(date(2017, 1, 22), parse_result['to_date(`dateCol`)']) @unittest.skipIf(sys.version_info < (3, 3), "Unittest < 3.3 doesn't support mocking") def test_unbounded_frames(self): from unittest.mock import patch from pyspark.sql import functions as F from pyspark.sql import window import importlib df = self.spark.range(0, 3) def rows_frame_match(): return "ROWS BETWEEN UNBOUNDED PRECEDING AND UNBOUNDED FOLLOWING" in df.select( F.count("*").over(window.Window.rowsBetween(-sys.maxsize, sys.maxsize)) ).columns[0] def range_frame_match(): return "RANGE BETWEEN UNBOUNDED PRECEDING AND UNBOUNDED FOLLOWING" in df.select( F.count("*").over(window.Window.rangeBetween(-sys.maxsize, sys.maxsize)) ).columns[0] with patch("sys.maxsize", 2 ** 31 - 1): importlib.reload(window) self.assertTrue(rows_frame_match()) self.assertTrue(range_frame_match()) with patch("sys.maxsize", 2 ** 63 - 1): importlib.reload(window) self.assertTrue(rows_frame_match()) self.assertTrue(range_frame_match()) with patch("sys.maxsize", 2 ** 127 - 1): importlib.reload(window) self.assertTrue(rows_frame_match()) self.assertTrue(range_frame_match()) importlib.reload(window) class DataTypeVerificationTests(unittest.TestCase): def test_verify_type_exception_msg(self): self.assertRaisesRegexp( ValueError, "test_name", lambda: _make_type_verifier(StringType(), nullable=False, name="test_name")(None)) schema = StructType([StructField('a', StructType([StructField('b', IntegerType())]))]) self.assertRaisesRegexp( TypeError, "field b in field a", lambda: _make_type_verifier(schema)([["data"]])) def test_verify_type_ok_nullable(self): obj = None types = [IntegerType(), FloatType(), StringType(), StructType([])] for data_type in types: try: _make_type_verifier(data_type, nullable=True)(obj) except Exception: self.fail("verify_type(%s, %s, nullable=True)" % (obj, data_type)) def test_verify_type_not_nullable(self): import array import datetime import decimal schema = StructType([ StructField('s', StringType(), nullable=False), StructField('i', IntegerType(), nullable=True)]) class MyObj: def __init__(self, **kwargs): for k, v in kwargs.items(): setattr(self, k, v) # obj, data_type success_spec = [ # String ("", StringType()), (u"", StringType()), (1, StringType()), (1.0, StringType()), ([], StringType()), ({}, StringType()), # UDT (ExamplePoint(1.0, 2.0), ExamplePointUDT()), # Boolean (True, BooleanType()), # Byte (-(2**7), ByteType()), (2**7 - 1, ByteType()), # Short (-(2**15), ShortType()), (2**15 - 1, ShortType()), # Integer (-(2**31), IntegerType()), (2**31 - 1, IntegerType()), # Long (2**64, LongType()), # Float & Double (1.0, FloatType()), (1.0, DoubleType()), # Decimal (decimal.Decimal("1.0"), DecimalType()), # Binary (bytearray([1, 2]), BinaryType()), # Date/Timestamp (datetime.date(2000, 1, 2), DateType()), (datetime.datetime(2000, 1, 2, 3, 4), DateType()), (datetime.datetime(2000, 1, 2, 3, 4), TimestampType()), # Array ([], ArrayType(IntegerType())), (["1", None], ArrayType(StringType(), containsNull=True)), ([1, 2], ArrayType(IntegerType())), ((1, 2), ArrayType(IntegerType())), (array.array('h', [1, 2]), ArrayType(IntegerType())), # Map ({}, MapType(StringType(), IntegerType())), ({"a": 1}, MapType(StringType(), IntegerType())), ({"a": None}, MapType(StringType(), IntegerType(), valueContainsNull=True)), # Struct ({"s": "a", "i": 1}, schema), ({"s": "a", "i": None}, schema), ({"s": "a"}, schema), ({"s": "a", "f": 1.0}, schema), (Row(s="a", i=1), schema), (Row(s="a", i=None), schema), (Row(s="a", i=1, f=1.0), schema), (["a", 1], schema), (["a", None], schema), (("a", 1), schema), (MyObj(s="a", i=1), schema), (MyObj(s="a", i=None), schema), (MyObj(s="a"), schema), ] # obj, data_type, exception class failure_spec = [ # String (match anything but None) (None, StringType(), ValueError), # UDT (ExamplePoint(1.0, 2.0), PythonOnlyUDT(), ValueError), # Boolean (1, BooleanType(), TypeError), ("True", BooleanType(), TypeError), ([1], BooleanType(), TypeError), # Byte (-(2**7) - 1, ByteType(), ValueError), (2**7, ByteType(), ValueError), ("1", ByteType(), TypeError), (1.0, ByteType(), TypeError), # Short (-(2**15) - 1, ShortType(), ValueError), (2**15, ShortType(), ValueError), # Integer (-(2**31) - 1, IntegerType(), ValueError), (2**31, IntegerType(), ValueError), # Float & Double (1, FloatType(), TypeError), (1, DoubleType(), TypeError), # Decimal (1.0, DecimalType(), TypeError), (1, DecimalType(), TypeError), ("1.0", DecimalType(), TypeError), # Binary (1, BinaryType(), TypeError), # Date/Timestamp ("2000-01-02", DateType(), TypeError), (946811040, TimestampType(), TypeError), # Array (["1", None], ArrayType(StringType(), containsNull=False), ValueError), ([1, "2"], ArrayType(IntegerType()), TypeError), # Map ({"a": 1}, MapType(IntegerType(), IntegerType()), TypeError), ({"a": "1"}, MapType(StringType(), IntegerType()), TypeError), ({"a": None}, MapType(StringType(), IntegerType(), valueContainsNull=False), ValueError), # Struct ({"s": "a", "i": "1"}, schema, TypeError), (Row(s="a"), schema, ValueError), # Row can't have missing field (Row(s="a", i="1"), schema, TypeError), (["a"], schema, ValueError), (["a", "1"], schema, TypeError), (MyObj(s="a", i="1"), schema, TypeError), (MyObj(s=None, i="1"), schema, ValueError), ] # Check success cases for obj, data_type in success_spec: try: _make_type_verifier(data_type, nullable=False)(obj) except Exception: self.fail("verify_type(%s, %s, nullable=False)" % (obj, data_type)) # Check failure cases for obj, data_type, exp in failure_spec: msg = "verify_type(%s, %s, nullable=False) == %s" % (obj, data_type, exp) with self.assertRaises(exp, msg=msg): _make_type_verifier(data_type, nullable=False)(obj) @unittest.skipIf( not _have_pandas or not _have_pyarrow, _pandas_requirement_message or _pyarrow_requirement_message) class ArrowTests(ReusedSQLTestCase): @classmethod def setUpClass(cls): from datetime import date, datetime from decimal import Decimal from distutils.version import LooseVersion import pyarrow as pa super(ArrowTests, cls).setUpClass() cls.warnings_lock = threading.Lock() # Synchronize default timezone between Python and Java cls.tz_prev = os.environ.get("TZ", None) # save current tz if set tz = "America/Los_Angeles" os.environ["TZ"] = tz time.tzset() cls.spark.conf.set("spark.sql.session.timeZone", tz) cls.spark.conf.set("spark.sql.execution.arrow.enabled", "true") # Disable fallback by default to easily detect the failures. cls.spark.conf.set("spark.sql.execution.arrow.fallback.enabled", "false") cls.schema = StructType([ StructField("1_str_t", StringType(), True), StructField("2_int_t", IntegerType(), True), StructField("3_long_t", LongType(), True), StructField("4_float_t", FloatType(), True), StructField("5_double_t", DoubleType(), True), StructField("6_decimal_t", DecimalType(38, 18), True), StructField("7_date_t", DateType(), True), StructField("8_timestamp_t", TimestampType(), True)]) cls.data = [(u"a", 1, 10, 0.2, 2.0, Decimal("2.0"), date(1969, 1, 1), datetime(1969, 1, 1, 1, 1, 1)), (u"b", 2, 20, 0.4, 4.0, Decimal("4.0"), date(2012, 2, 2), datetime(2012, 2, 2, 2, 2, 2)), (u"c", 3, 30, 0.8, 6.0, Decimal("6.0"), date(2100, 3, 3), datetime(2100, 3, 3, 3, 3, 3))] # TODO: remove version check once minimum pyarrow version is 0.10.0 if LooseVersion("0.10.0") <= LooseVersion(pa.__version__): cls.schema.add(StructField("9_binary_t", BinaryType(), True)) cls.data[0] = cls.data[0] + (bytearray(b"a"),) cls.data[1] = cls.data[1] + (bytearray(b"bb"),) cls.data[2] = cls.data[2] + (bytearray(b"ccc"),) @classmethod def tearDownClass(cls): del os.environ["TZ"] if cls.tz_prev is not None: os.environ["TZ"] = cls.tz_prev time.tzset() super(ArrowTests, cls).tearDownClass() def create_pandas_data_frame(self): import pandas as pd import numpy as np data_dict = {} for j, name in enumerate(self.schema.names): data_dict[name] = [self.data[i][j] for i in range(len(self.data))] # need to convert these to numpy types first data_dict["2_int_t"] = np.int32(data_dict["2_int_t"]) data_dict["4_float_t"] = np.float32(data_dict["4_float_t"]) return pd.DataFrame(data=data_dict) def test_toPandas_fallback_enabled(self): import pandas as pd with self.sql_conf({"spark.sql.execution.arrow.fallback.enabled": True}): schema = StructType([StructField("map", MapType(StringType(), IntegerType()), True)]) df = self.spark.createDataFrame([({u'a': 1},)], schema=schema) with QuietTest(self.sc): with self.warnings_lock: with warnings.catch_warnings(record=True) as warns: # we want the warnings to appear even if this test is run from a subclass warnings.simplefilter("always") pdf = df.toPandas() # Catch and check the last UserWarning. user_warns = [ warn.message for warn in warns if isinstance(warn.message, UserWarning)] self.assertTrue(len(user_warns) > 0) self.assertTrue( "Attempting non-optimization" in _exception_message(user_warns[-1])) self.assertPandasEqual(pdf, pd.DataFrame({u'map': [{u'a': 1}]})) def test_toPandas_fallback_disabled(self): from distutils.version import LooseVersion import pyarrow as pa schema = StructType([StructField("map", MapType(StringType(), IntegerType()), True)]) df = self.spark.createDataFrame([(None,)], schema=schema) with QuietTest(self.sc): with self.warnings_lock: with self.assertRaisesRegexp(Exception, 'Unsupported type'): df.toPandas() # TODO: remove BinaryType check once minimum pyarrow version is 0.10.0 if LooseVersion(pa.__version__) < LooseVersion("0.10.0"): schema = StructType([StructField("binary", BinaryType(), True)]) df = self.spark.createDataFrame([(None,)], schema=schema) with QuietTest(self.sc): with self.assertRaisesRegexp(Exception, 'Unsupported type.*BinaryType'): df.toPandas() def test_null_conversion(self): df_null = self.spark.createDataFrame([tuple([None for _ in range(len(self.data[0]))])] + self.data) pdf = df_null.toPandas() null_counts = pdf.isnull().sum().tolist() self.assertTrue(all([c == 1 for c in null_counts])) def _toPandas_arrow_toggle(self, df): with self.sql_conf({"spark.sql.execution.arrow.enabled": False}): pdf = df.toPandas() pdf_arrow = df.toPandas() return pdf, pdf_arrow def test_toPandas_arrow_toggle(self): df = self.spark.createDataFrame(self.data, schema=self.schema) pdf, pdf_arrow = self._toPandas_arrow_toggle(df) expected = self.create_pandas_data_frame() self.assertPandasEqual(expected, pdf) self.assertPandasEqual(expected, pdf_arrow) def test_toPandas_respect_session_timezone(self): df = self.spark.createDataFrame(self.data, schema=self.schema) timezone = "America/New_York" with self.sql_conf({ "spark.sql.execution.pandas.respectSessionTimeZone": False, "spark.sql.session.timeZone": timezone}): pdf_la, pdf_arrow_la = self._toPandas_arrow_toggle(df) self.assertPandasEqual(pdf_arrow_la, pdf_la) with self.sql_conf({ "spark.sql.execution.pandas.respectSessionTimeZone": True, "spark.sql.session.timeZone": timezone}): pdf_ny, pdf_arrow_ny = self._toPandas_arrow_toggle(df) self.assertPandasEqual(pdf_arrow_ny, pdf_ny) self.assertFalse(pdf_ny.equals(pdf_la)) from pyspark.sql.types import _check_series_convert_timestamps_local_tz pdf_la_corrected = pdf_la.copy() for field in self.schema: if isinstance(field.dataType, TimestampType): pdf_la_corrected[field.name] = _check_series_convert_timestamps_local_tz( pdf_la_corrected[field.name], timezone) self.assertPandasEqual(pdf_ny, pdf_la_corrected) def test_pandas_round_trip(self): pdf = self.create_pandas_data_frame() df = self.spark.createDataFrame(self.data, schema=self.schema) pdf_arrow = df.toPandas() self.assertPandasEqual(pdf_arrow, pdf) def test_filtered_frame(self): df = self.spark.range(3).toDF("i") pdf = df.filter("i < 0").toPandas() self.assertEqual(len(pdf.columns), 1) self.assertEqual(pdf.columns[0], "i") self.assertTrue(pdf.empty) def _createDataFrame_toggle(self, pdf, schema=None): with self.sql_conf({"spark.sql.execution.arrow.enabled": False}): df_no_arrow = self.spark.createDataFrame(pdf, schema=schema) df_arrow = self.spark.createDataFrame(pdf, schema=schema) return df_no_arrow, df_arrow def test_createDataFrame_toggle(self): pdf = self.create_pandas_data_frame() df_no_arrow, df_arrow = self._createDataFrame_toggle(pdf, schema=self.schema) self.assertEquals(df_no_arrow.collect(), df_arrow.collect()) def test_createDataFrame_respect_session_timezone(self): from datetime import timedelta pdf = self.create_pandas_data_frame() timezone = "America/New_York" with self.sql_conf({ "spark.sql.execution.pandas.respectSessionTimeZone": False, "spark.sql.session.timeZone": timezone}): df_no_arrow_la, df_arrow_la = self._createDataFrame_toggle(pdf, schema=self.schema) result_la = df_no_arrow_la.collect() result_arrow_la = df_arrow_la.collect() self.assertEqual(result_la, result_arrow_la) with self.sql_conf({ "spark.sql.execution.pandas.respectSessionTimeZone": True, "spark.sql.session.timeZone": timezone}): df_no_arrow_ny, df_arrow_ny = self._createDataFrame_toggle(pdf, schema=self.schema) result_ny = df_no_arrow_ny.collect() result_arrow_ny = df_arrow_ny.collect() self.assertEqual(result_ny, result_arrow_ny) self.assertNotEqual(result_ny, result_la) # Correct result_la by adjusting 3 hours difference between Los Angeles and New York result_la_corrected = [Row(**{k: v - timedelta(hours=3) if k == '8_timestamp_t' else v for k, v in row.asDict().items()}) for row in result_la] self.assertEqual(result_ny, result_la_corrected) def test_createDataFrame_with_schema(self): pdf = self.create_pandas_data_frame() df = self.spark.createDataFrame(pdf, schema=self.schema) self.assertEquals(self.schema, df.schema) pdf_arrow = df.toPandas() self.assertPandasEqual(pdf_arrow, pdf) def test_createDataFrame_with_incorrect_schema(self): pdf = self.create_pandas_data_frame() fields = list(self.schema) fields[0], fields[7] = fields[7], fields[0] # swap str with timestamp wrong_schema = StructType(fields) with QuietTest(self.sc): with self.assertRaisesRegexp(Exception, ".*No cast.*string.*timestamp.*"): self.spark.createDataFrame(pdf, schema=wrong_schema) def test_createDataFrame_with_names(self): pdf = self.create_pandas_data_frame() new_names = list(map(str, range(len(self.schema.fieldNames())))) # Test that schema as a list of column names gets applied df = self.spark.createDataFrame(pdf, schema=list(new_names)) self.assertEquals(df.schema.fieldNames(), new_names) # Test that schema as tuple of column names gets applied df = self.spark.createDataFrame(pdf, schema=tuple(new_names)) self.assertEquals(df.schema.fieldNames(), new_names) def test_createDataFrame_column_name_encoding(self): import pandas as pd pdf = pd.DataFrame({u'a': [1]}) columns = self.spark.createDataFrame(pdf).columns self.assertTrue(isinstance(columns[0], str)) self.assertEquals(columns[0], 'a') columns = self.spark.createDataFrame(pdf, [u'b']).columns self.assertTrue(isinstance(columns[0], str)) self.assertEquals(columns[0], 'b') def test_createDataFrame_with_single_data_type(self): import pandas as pd with QuietTest(self.sc): with self.assertRaisesRegexp(ValueError, ".*IntegerType.*not supported.*"): self.spark.createDataFrame(pd.DataFrame({"a": [1]}), schema="int") def test_createDataFrame_does_not_modify_input(self): import pandas as pd # Some series get converted for Spark to consume, this makes sure input is unchanged pdf = self.create_pandas_data_frame() # Use a nanosecond value to make sure it is not truncated pdf.ix[0, '8_timestamp_t'] = pd.Timestamp(1) # Integers with nulls will get NaNs filled with 0 and will be casted pdf.ix[1, '2_int_t'] = None pdf_copy = pdf.copy(deep=True) self.spark.createDataFrame(pdf, schema=self.schema) self.assertTrue(pdf.equals(pdf_copy)) def test_schema_conversion_roundtrip(self): from pyspark.sql.types import from_arrow_schema, to_arrow_schema arrow_schema = to_arrow_schema(self.schema) schema_rt = from_arrow_schema(arrow_schema) self.assertEquals(self.schema, schema_rt) def test_createDataFrame_with_array_type(self): import pandas as pd pdf = pd.DataFrame({"a": [[1, 2], [3, 4]], "b": [[u"x", u"y"], [u"y", u"z"]]}) df, df_arrow = self._createDataFrame_toggle(pdf) result = df.collect() result_arrow = df_arrow.collect() expected = [tuple(list(e) for e in rec) for rec in pdf.to_records(index=False)] for r in range(len(expected)): for e in range(len(expected[r])): self.assertTrue(expected[r][e] == result_arrow[r][e] and result[r][e] == result_arrow[r][e]) def test_toPandas_with_array_type(self): expected = [([1, 2], [u"x", u"y"]), ([3, 4], [u"y", u"z"])] array_schema = StructType([StructField("a", ArrayType(IntegerType())), StructField("b", ArrayType(StringType()))]) df = self.spark.createDataFrame(expected, schema=array_schema) pdf, pdf_arrow = self._toPandas_arrow_toggle(df) result = [tuple(list(e) for e in rec) for rec in pdf.to_records(index=False)] result_arrow = [tuple(list(e) for e in rec) for rec in pdf_arrow.to_records(index=False)] for r in range(len(expected)): for e in range(len(expected[r])): self.assertTrue(expected[r][e] == result_arrow[r][e] and result[r][e] == result_arrow[r][e]) def test_createDataFrame_with_int_col_names(self): import numpy as np import pandas as pd pdf = pd.DataFrame(np.random.rand(4, 2)) df, df_arrow = self._createDataFrame_toggle(pdf) pdf_col_names = [str(c) for c in pdf.columns] self.assertEqual(pdf_col_names, df.columns) self.assertEqual(pdf_col_names, df_arrow.columns) def test_createDataFrame_fallback_enabled(self): import pandas as pd with QuietTest(self.sc): with self.sql_conf({"spark.sql.execution.arrow.fallback.enabled": True}): with warnings.catch_warnings(record=True) as warns: # we want the warnings to appear even if this test is run from a subclass warnings.simplefilter("always") df = self.spark.createDataFrame( pd.DataFrame([[{u'a': 1}]]), "a: map") # Catch and check the last UserWarning. user_warns = [ warn.message for warn in warns if isinstance(warn.message, UserWarning)] self.assertTrue(len(user_warns) > 0) self.assertTrue( "Attempting non-optimization" in _exception_message(user_warns[-1])) self.assertEqual(df.collect(), [Row(a={u'a': 1})]) def test_createDataFrame_fallback_disabled(self): from distutils.version import LooseVersion import pandas as pd import pyarrow as pa with QuietTest(self.sc): with self.assertRaisesRegexp(TypeError, 'Unsupported type'): self.spark.createDataFrame( pd.DataFrame([[{u'a': 1}]]), "a: map") # TODO: remove BinaryType check once minimum pyarrow version is 0.10.0 if LooseVersion(pa.__version__) < LooseVersion("0.10.0"): with QuietTest(self.sc): with self.assertRaisesRegexp(TypeError, 'Unsupported type.*BinaryType'): self.spark.createDataFrame( pd.DataFrame([[{'a': b'aaa'}]]), "a: binary") # Regression test for SPARK-23314 def test_timestamp_dst(self): import pandas as pd # Daylight saving time for Los Angeles for 2015 is Sun, Nov 1 at 2:00 am dt = [datetime.datetime(2015, 11, 1, 0, 30), datetime.datetime(2015, 11, 1, 1, 30), datetime.datetime(2015, 11, 1, 2, 30)] pdf = pd.DataFrame({'time': dt}) df_from_python = self.spark.createDataFrame(dt, 'timestamp').toDF('time') df_from_pandas = self.spark.createDataFrame(pdf) self.assertPandasEqual(pdf, df_from_python.toPandas()) self.assertPandasEqual(pdf, df_from_pandas.toPandas()) class EncryptionArrowTests(ArrowTests): @classmethod def conf(cls): return super(EncryptionArrowTests, cls).conf().set("spark.io.encryption.enabled", "true") @unittest.skipIf( not _have_pandas or not _have_pyarrow, _pandas_requirement_message or _pyarrow_requirement_message) class PandasUDFTests(ReusedSQLTestCase): def test_pandas_udf_basic(self): from pyspark.rdd import PythonEvalType from pyspark.sql.functions import pandas_udf, PandasUDFType udf = pandas_udf(lambda x: x, DoubleType()) self.assertEqual(udf.returnType, DoubleType()) self.assertEqual(udf.evalType, PythonEvalType.SQL_SCALAR_PANDAS_UDF) udf = pandas_udf(lambda x: x, DoubleType(), PandasUDFType.SCALAR) self.assertEqual(udf.returnType, DoubleType()) self.assertEqual(udf.evalType, PythonEvalType.SQL_SCALAR_PANDAS_UDF) udf = pandas_udf(lambda x: x, 'double', PandasUDFType.SCALAR) self.assertEqual(udf.returnType, DoubleType()) self.assertEqual(udf.evalType, PythonEvalType.SQL_SCALAR_PANDAS_UDF) udf = pandas_udf(lambda x: x, StructType([StructField("v", DoubleType())]), PandasUDFType.GROUPED_MAP) self.assertEqual(udf.returnType, StructType([StructField("v", DoubleType())])) self.assertEqual(udf.evalType, PythonEvalType.SQL_GROUPED_MAP_PANDAS_UDF) udf = pandas_udf(lambda x: x, 'v double', PandasUDFType.GROUPED_MAP) self.assertEqual(udf.returnType, StructType([StructField("v", DoubleType())])) self.assertEqual(udf.evalType, PythonEvalType.SQL_GROUPED_MAP_PANDAS_UDF) udf = pandas_udf(lambda x: x, 'v double', functionType=PandasUDFType.GROUPED_MAP) self.assertEqual(udf.returnType, StructType([StructField("v", DoubleType())])) self.assertEqual(udf.evalType, PythonEvalType.SQL_GROUPED_MAP_PANDAS_UDF) udf = pandas_udf(lambda x: x, returnType='v double', functionType=PandasUDFType.GROUPED_MAP) self.assertEqual(udf.returnType, StructType([StructField("v", DoubleType())])) self.assertEqual(udf.evalType, PythonEvalType.SQL_GROUPED_MAP_PANDAS_UDF) def test_pandas_udf_decorator(self): from pyspark.rdd import PythonEvalType from pyspark.sql.functions import pandas_udf, PandasUDFType from pyspark.sql.types import StructType, StructField, DoubleType @pandas_udf(DoubleType()) def foo(x): return x self.assertEqual(foo.returnType, DoubleType()) self.assertEqual(foo.evalType, PythonEvalType.SQL_SCALAR_PANDAS_UDF) @pandas_udf(returnType=DoubleType()) def foo(x): return x self.assertEqual(foo.returnType, DoubleType()) self.assertEqual(foo.evalType, PythonEvalType.SQL_SCALAR_PANDAS_UDF) schema = StructType([StructField("v", DoubleType())]) @pandas_udf(schema, PandasUDFType.GROUPED_MAP) def foo(x): return x self.assertEqual(foo.returnType, schema) self.assertEqual(foo.evalType, PythonEvalType.SQL_GROUPED_MAP_PANDAS_UDF) @pandas_udf('v double', PandasUDFType.GROUPED_MAP) def foo(x): return x self.assertEqual(foo.returnType, schema) self.assertEqual(foo.evalType, PythonEvalType.SQL_GROUPED_MAP_PANDAS_UDF) @pandas_udf(schema, functionType=PandasUDFType.GROUPED_MAP) def foo(x): return x self.assertEqual(foo.returnType, schema) self.assertEqual(foo.evalType, PythonEvalType.SQL_GROUPED_MAP_PANDAS_UDF) @pandas_udf(returnType='double', functionType=PandasUDFType.SCALAR) def foo(x): return x self.assertEqual(foo.returnType, DoubleType()) self.assertEqual(foo.evalType, PythonEvalType.SQL_SCALAR_PANDAS_UDF) @pandas_udf(returnType=schema, functionType=PandasUDFType.GROUPED_MAP) def foo(x): return x self.assertEqual(foo.returnType, schema) self.assertEqual(foo.evalType, PythonEvalType.SQL_GROUPED_MAP_PANDAS_UDF) def test_udf_wrong_arg(self): from pyspark.sql.functions import pandas_udf, PandasUDFType with QuietTest(self.sc): with self.assertRaises(ParseException): @pandas_udf('blah') def foo(x): return x with self.assertRaisesRegexp(ValueError, 'Invalid returnType.*None'): @pandas_udf(functionType=PandasUDFType.SCALAR) def foo(x): return x with self.assertRaisesRegexp(ValueError, 'Invalid functionType'): @pandas_udf('double', 100) def foo(x): return x with self.assertRaisesRegexp(ValueError, '0-arg pandas_udfs.*not.*supported'): pandas_udf(lambda: 1, LongType(), PandasUDFType.SCALAR) with self.assertRaisesRegexp(ValueError, '0-arg pandas_udfs.*not.*supported'): @pandas_udf(LongType(), PandasUDFType.SCALAR) def zero_with_type(): return 1 with self.assertRaisesRegexp(TypeError, 'Invalid returnType'): @pandas_udf(returnType=PandasUDFType.GROUPED_MAP) def foo(df): return df with self.assertRaisesRegexp(TypeError, 'Invalid returnType'): @pandas_udf(returnType='double', functionType=PandasUDFType.GROUPED_MAP) def foo(df): return df with self.assertRaisesRegexp(ValueError, 'Invalid function'): @pandas_udf(returnType='k int, v double', functionType=PandasUDFType.GROUPED_MAP) def foo(k, v, w): return k def test_stopiteration_in_udf(self): from pyspark.sql.functions import udf, pandas_udf, PandasUDFType from py4j.protocol import Py4JJavaError def foo(x): raise StopIteration() def foofoo(x, y): raise StopIteration() exc_message = "Caught StopIteration thrown from user's code; failing the task" df = self.spark.range(0, 100) # plain udf (test for SPARK-23754) self.assertRaisesRegexp( Py4JJavaError, exc_message, df.withColumn('v', udf(foo)('id')).collect ) # pandas scalar udf self.assertRaisesRegexp( Py4JJavaError, exc_message, df.withColumn( 'v', pandas_udf(foo, 'double', PandasUDFType.SCALAR)('id') ).collect ) # pandas grouped map self.assertRaisesRegexp( Py4JJavaError, exc_message, df.groupBy('id').apply( pandas_udf(foo, df.schema, PandasUDFType.GROUPED_MAP) ).collect ) self.assertRaisesRegexp( Py4JJavaError, exc_message, df.groupBy('id').apply( pandas_udf(foofoo, df.schema, PandasUDFType.GROUPED_MAP) ).collect ) # pandas grouped agg self.assertRaisesRegexp( Py4JJavaError, exc_message, df.groupBy('id').agg( pandas_udf(foo, 'double', PandasUDFType.GROUPED_AGG)('id') ).collect ) @unittest.skipIf( not _have_pandas or not _have_pyarrow, _pandas_requirement_message or _pyarrow_requirement_message) class ScalarPandasUDFTests(ReusedSQLTestCase): @classmethod def setUpClass(cls): ReusedSQLTestCase.setUpClass() # Synchronize default timezone between Python and Java cls.tz_prev = os.environ.get("TZ", None) # save current tz if set tz = "America/Los_Angeles" os.environ["TZ"] = tz time.tzset() cls.sc.environment["TZ"] = tz cls.spark.conf.set("spark.sql.session.timeZone", tz) @classmethod def tearDownClass(cls): del os.environ["TZ"] if cls.tz_prev is not None: os.environ["TZ"] = cls.tz_prev time.tzset() ReusedSQLTestCase.tearDownClass() @property def nondeterministic_vectorized_udf(self): from pyspark.sql.functions import pandas_udf @pandas_udf('double') def random_udf(v): import pandas as pd import numpy as np return pd.Series(np.random.random(len(v))) random_udf = random_udf.asNondeterministic() return random_udf def test_pandas_udf_tokenize(self): from pyspark.sql.functions import pandas_udf tokenize = pandas_udf(lambda s: s.apply(lambda str: str.split(' ')), ArrayType(StringType())) self.assertEqual(tokenize.returnType, ArrayType(StringType())) df = self.spark.createDataFrame([("hi boo",), ("bye boo",)], ["vals"]) result = df.select(tokenize("vals").alias("hi")) self.assertEqual([Row(hi=[u'hi', u'boo']), Row(hi=[u'bye', u'boo'])], result.collect()) def test_pandas_udf_nested_arrays(self): from pyspark.sql.functions import pandas_udf tokenize = pandas_udf(lambda s: s.apply(lambda str: [str.split(' ')]), ArrayType(ArrayType(StringType()))) self.assertEqual(tokenize.returnType, ArrayType(ArrayType(StringType()))) df = self.spark.createDataFrame([("hi boo",), ("bye boo",)], ["vals"]) result = df.select(tokenize("vals").alias("hi")) self.assertEqual([Row(hi=[[u'hi', u'boo']]), Row(hi=[[u'bye', u'boo']])], result.collect()) def test_vectorized_udf_basic(self): from pyspark.sql.functions import pandas_udf, col, array df = self.spark.range(10).select( col('id').cast('string').alias('str'), col('id').cast('int').alias('int'), col('id').alias('long'), col('id').cast('float').alias('float'), col('id').cast('double').alias('double'), col('id').cast('decimal').alias('decimal'), col('id').cast('boolean').alias('bool'), array(col('id')).alias('array_long')) f = lambda x: x str_f = pandas_udf(f, StringType()) int_f = pandas_udf(f, IntegerType()) long_f = pandas_udf(f, LongType()) float_f = pandas_udf(f, FloatType()) double_f = pandas_udf(f, DoubleType()) decimal_f = pandas_udf(f, DecimalType()) bool_f = pandas_udf(f, BooleanType()) array_long_f = pandas_udf(f, ArrayType(LongType())) res = df.select(str_f(col('str')), int_f(col('int')), long_f(col('long')), float_f(col('float')), double_f(col('double')), decimal_f('decimal'), bool_f(col('bool')), array_long_f('array_long')) self.assertEquals(df.collect(), res.collect()) def test_register_nondeterministic_vectorized_udf_basic(self): from pyspark.sql.functions import pandas_udf from pyspark.rdd import PythonEvalType import random random_pandas_udf = pandas_udf( lambda x: random.randint(6, 6) + x, IntegerType()).asNondeterministic() self.assertEqual(random_pandas_udf.deterministic, False) self.assertEqual(random_pandas_udf.evalType, PythonEvalType.SQL_SCALAR_PANDAS_UDF) nondeterministic_pandas_udf = self.spark.catalog.registerFunction( "randomPandasUDF", random_pandas_udf) self.assertEqual(nondeterministic_pandas_udf.deterministic, False) self.assertEqual(nondeterministic_pandas_udf.evalType, PythonEvalType.SQL_SCALAR_PANDAS_UDF) [row] = self.spark.sql("SELECT randomPandasUDF(1)").collect() self.assertEqual(row[0], 7) def test_vectorized_udf_null_boolean(self): from pyspark.sql.functions import pandas_udf, col data = [(True,), (True,), (None,), (False,)] schema = StructType().add("bool", BooleanType()) df = self.spark.createDataFrame(data, schema) bool_f = pandas_udf(lambda x: x, BooleanType()) res = df.select(bool_f(col('bool'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_null_byte(self): from pyspark.sql.functions import pandas_udf, col data = [(None,), (2,), (3,), (4,)] schema = StructType().add("byte", ByteType()) df = self.spark.createDataFrame(data, schema) byte_f = pandas_udf(lambda x: x, ByteType()) res = df.select(byte_f(col('byte'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_null_short(self): from pyspark.sql.functions import pandas_udf, col data = [(None,), (2,), (3,), (4,)] schema = StructType().add("short", ShortType()) df = self.spark.createDataFrame(data, schema) short_f = pandas_udf(lambda x: x, ShortType()) res = df.select(short_f(col('short'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_null_int(self): from pyspark.sql.functions import pandas_udf, col data = [(None,), (2,), (3,), (4,)] schema = StructType().add("int", IntegerType()) df = self.spark.createDataFrame(data, schema) int_f = pandas_udf(lambda x: x, IntegerType()) res = df.select(int_f(col('int'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_null_long(self): from pyspark.sql.functions import pandas_udf, col data = [(None,), (2,), (3,), (4,)] schema = StructType().add("long", LongType()) df = self.spark.createDataFrame(data, schema) long_f = pandas_udf(lambda x: x, LongType()) res = df.select(long_f(col('long'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_null_float(self): from pyspark.sql.functions import pandas_udf, col data = [(3.0,), (5.0,), (-1.0,), (None,)] schema = StructType().add("float", FloatType()) df = self.spark.createDataFrame(data, schema) float_f = pandas_udf(lambda x: x, FloatType()) res = df.select(float_f(col('float'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_null_double(self): from pyspark.sql.functions import pandas_udf, col data = [(3.0,), (5.0,), (-1.0,), (None,)] schema = StructType().add("double", DoubleType()) df = self.spark.createDataFrame(data, schema) double_f = pandas_udf(lambda x: x, DoubleType()) res = df.select(double_f(col('double'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_null_decimal(self): from decimal import Decimal from pyspark.sql.functions import pandas_udf, col data = [(Decimal(3.0),), (Decimal(5.0),), (Decimal(-1.0),), (None,)] schema = StructType().add("decimal", DecimalType(38, 18)) df = self.spark.createDataFrame(data, schema) decimal_f = pandas_udf(lambda x: x, DecimalType(38, 18)) res = df.select(decimal_f(col('decimal'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_null_string(self): from pyspark.sql.functions import pandas_udf, col data = [("foo",), (None,), ("bar",), ("bar",)] schema = StructType().add("str", StringType()) df = self.spark.createDataFrame(data, schema) str_f = pandas_udf(lambda x: x, StringType()) res = df.select(str_f(col('str'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_string_in_udf(self): from pyspark.sql.functions import pandas_udf, col import pandas as pd df = self.spark.range(10) str_f = pandas_udf(lambda x: pd.Series(map(str, x)), StringType()) actual = df.select(str_f(col('id'))) expected = df.select(col('id').cast('string')) self.assertEquals(expected.collect(), actual.collect()) def test_vectorized_udf_datatype_string(self): from pyspark.sql.functions import pandas_udf, col df = self.spark.range(10).select( col('id').cast('string').alias('str'), col('id').cast('int').alias('int'), col('id').alias('long'), col('id').cast('float').alias('float'), col('id').cast('double').alias('double'), col('id').cast('decimal').alias('decimal'), col('id').cast('boolean').alias('bool')) f = lambda x: x str_f = pandas_udf(f, 'string') int_f = pandas_udf(f, 'integer') long_f = pandas_udf(f, 'long') float_f = pandas_udf(f, 'float') double_f = pandas_udf(f, 'double') decimal_f = pandas_udf(f, 'decimal(38, 18)') bool_f = pandas_udf(f, 'boolean') res = df.select(str_f(col('str')), int_f(col('int')), long_f(col('long')), float_f(col('float')), double_f(col('double')), decimal_f('decimal'), bool_f(col('bool'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_null_binary(self): from distutils.version import LooseVersion import pyarrow as pa from pyspark.sql.functions import pandas_udf, col if LooseVersion(pa.__version__) < LooseVersion("0.10.0"): with QuietTest(self.sc): with self.assertRaisesRegexp( NotImplementedError, 'Invalid returnType.*scalar Pandas UDF.*BinaryType'): pandas_udf(lambda x: x, BinaryType()) else: data = [(bytearray(b"a"),), (None,), (bytearray(b"bb"),), (bytearray(b"ccc"),)] schema = StructType().add("binary", BinaryType()) df = self.spark.createDataFrame(data, schema) str_f = pandas_udf(lambda x: x, BinaryType()) res = df.select(str_f(col('binary'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_array_type(self): from pyspark.sql.functions import pandas_udf, col data = [([1, 2],), ([3, 4],)] array_schema = StructType([StructField("array", ArrayType(IntegerType()))]) df = self.spark.createDataFrame(data, schema=array_schema) array_f = pandas_udf(lambda x: x, ArrayType(IntegerType())) result = df.select(array_f(col('array'))) self.assertEquals(df.collect(), result.collect()) def test_vectorized_udf_null_array(self): from pyspark.sql.functions import pandas_udf, col data = [([1, 2],), (None,), (None,), ([3, 4],), (None,)] array_schema = StructType([StructField("array", ArrayType(IntegerType()))]) df = self.spark.createDataFrame(data, schema=array_schema) array_f = pandas_udf(lambda x: x, ArrayType(IntegerType())) result = df.select(array_f(col('array'))) self.assertEquals(df.collect(), result.collect()) def test_vectorized_udf_complex(self): from pyspark.sql.functions import pandas_udf, col, expr df = self.spark.range(10).select( col('id').cast('int').alias('a'), col('id').cast('int').alias('b'), col('id').cast('double').alias('c')) add = pandas_udf(lambda x, y: x + y, IntegerType()) power2 = pandas_udf(lambda x: 2 ** x, IntegerType()) mul = pandas_udf(lambda x, y: x * y, DoubleType()) res = df.select(add(col('a'), col('b')), power2(col('a')), mul(col('b'), col('c'))) expected = df.select(expr('a + b'), expr('power(2, a)'), expr('b * c')) self.assertEquals(expected.collect(), res.collect()) def test_vectorized_udf_exception(self): from pyspark.sql.functions import pandas_udf, col df = self.spark.range(10) raise_exception = pandas_udf(lambda x: x * (1 / 0), LongType()) with QuietTest(self.sc): with self.assertRaisesRegexp(Exception, 'division( or modulo)? by zero'): df.select(raise_exception(col('id'))).collect() def test_vectorized_udf_invalid_length(self): from pyspark.sql.functions import pandas_udf, col import pandas as pd df = self.spark.range(10) raise_exception = pandas_udf(lambda _: pd.Series(1), LongType()) with QuietTest(self.sc): with self.assertRaisesRegexp( Exception, 'Result vector from pandas_udf was not the required length'): df.select(raise_exception(col('id'))).collect() def test_vectorized_udf_chained(self): from pyspark.sql.functions import pandas_udf, col df = self.spark.range(10) f = pandas_udf(lambda x: x + 1, LongType()) g = pandas_udf(lambda x: x - 1, LongType()) res = df.select(g(f(col('id')))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_wrong_return_type(self): from pyspark.sql.functions import pandas_udf, col with QuietTest(self.sc): with self.assertRaisesRegexp( NotImplementedError, 'Invalid returnType.*scalar Pandas UDF.*MapType'): pandas_udf(lambda x: x * 1.0, MapType(LongType(), LongType())) def test_vectorized_udf_return_scalar(self): from pyspark.sql.functions import pandas_udf, col df = self.spark.range(10) f = pandas_udf(lambda x: 1.0, DoubleType()) with QuietTest(self.sc): with self.assertRaisesRegexp(Exception, 'Return.*type.*Series'): df.select(f(col('id'))).collect() def test_vectorized_udf_decorator(self): from pyspark.sql.functions import pandas_udf, col df = self.spark.range(10) @pandas_udf(returnType=LongType()) def identity(x): return x res = df.select(identity(col('id'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_empty_partition(self): from pyspark.sql.functions import pandas_udf, col df = self.spark.createDataFrame(self.sc.parallelize([Row(id=1)], 2)) f = pandas_udf(lambda x: x, LongType()) res = df.select(f(col('id'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_varargs(self): from pyspark.sql.functions import pandas_udf, col df = self.spark.createDataFrame(self.sc.parallelize([Row(id=1)], 2)) f = pandas_udf(lambda *v: v[0], LongType()) res = df.select(f(col('id'))) self.assertEquals(df.collect(), res.collect()) def test_vectorized_udf_unsupported_types(self): from pyspark.sql.functions import pandas_udf with QuietTest(self.sc): with self.assertRaisesRegexp( NotImplementedError, 'Invalid returnType.*scalar Pandas UDF.*MapType'): pandas_udf(lambda x: x, MapType(StringType(), IntegerType())) def test_vectorized_udf_dates(self): from pyspark.sql.functions import pandas_udf, col from datetime import date schema = StructType().add("idx", LongType()).add("date", DateType()) data = [(0, date(1969, 1, 1),), (1, date(2012, 2, 2),), (2, None,), (3, date(2100, 4, 4),)] df = self.spark.createDataFrame(data, schema=schema) date_copy = pandas_udf(lambda t: t, returnType=DateType()) df = df.withColumn("date_copy", date_copy(col("date"))) @pandas_udf(returnType=StringType()) def check_data(idx, date, date_copy): import pandas as pd msgs = [] is_equal = date.isnull() for i in range(len(idx)): if (is_equal[i] and data[idx[i]][1] is None) or \ date[i] == data[idx[i]][1]: msgs.append(None) else: msgs.append( "date values are not equal (date='%s': data[%d][1]='%s')" % (date[i], idx[i], data[idx[i]][1])) return pd.Series(msgs) result = df.withColumn("check_data", check_data(col("idx"), col("date"), col("date_copy"))).collect() self.assertEquals(len(data), len(result)) for i in range(len(result)): self.assertEquals(data[i][1], result[i][1]) # "date" col self.assertEquals(data[i][1], result[i][2]) # "date_copy" col self.assertIsNone(result[i][3]) # "check_data" col def test_vectorized_udf_timestamps(self): from pyspark.sql.functions import pandas_udf, col from datetime import datetime schema = StructType([ StructField("idx", LongType(), True), StructField("timestamp", TimestampType(), True)]) data = [(0, datetime(1969, 1, 1, 1, 1, 1)), (1, datetime(2012, 2, 2, 2, 2, 2)), (2, None), (3, datetime(2100, 3, 3, 3, 3, 3))] df = self.spark.createDataFrame(data, schema=schema) # Check that a timestamp passed through a pandas_udf will not be altered by timezone calc f_timestamp_copy = pandas_udf(lambda t: t, returnType=TimestampType()) df = df.withColumn("timestamp_copy", f_timestamp_copy(col("timestamp"))) @pandas_udf(returnType=StringType()) def check_data(idx, timestamp, timestamp_copy): import pandas as pd msgs = [] is_equal = timestamp.isnull() # use this array to check values are equal for i in range(len(idx)): # Check that timestamps are as expected in the UDF if (is_equal[i] and data[idx[i]][1] is None) or \ timestamp[i].to_pydatetime() == data[idx[i]][1]: msgs.append(None) else: msgs.append( "timestamp values are not equal (timestamp='%s': data[%d][1]='%s')" % (timestamp[i], idx[i], data[idx[i]][1])) return pd.Series(msgs) result = df.withColumn("check_data", check_data(col("idx"), col("timestamp"), col("timestamp_copy"))).collect() # Check that collection values are correct self.assertEquals(len(data), len(result)) for i in range(len(result)): self.assertEquals(data[i][1], result[i][1]) # "timestamp" col self.assertEquals(data[i][1], result[i][2]) # "timestamp_copy" col self.assertIsNone(result[i][3]) # "check_data" col def test_vectorized_udf_return_timestamp_tz(self): from pyspark.sql.functions import pandas_udf, col import pandas as pd df = self.spark.range(10) @pandas_udf(returnType=TimestampType()) def gen_timestamps(id): ts = [pd.Timestamp(i, unit='D', tz='America/Los_Angeles') for i in id] return pd.Series(ts) result = df.withColumn("ts", gen_timestamps(col("id"))).collect() spark_ts_t = TimestampType() for r in result: i, ts = r ts_tz = pd.Timestamp(i, unit='D', tz='America/Los_Angeles').to_pydatetime() expected = spark_ts_t.fromInternal(spark_ts_t.toInternal(ts_tz)) self.assertEquals(expected, ts) def test_vectorized_udf_check_config(self): from pyspark.sql.functions import pandas_udf, col import pandas as pd with self.sql_conf({"spark.sql.execution.arrow.maxRecordsPerBatch": 3}): df = self.spark.range(10, numPartitions=1) @pandas_udf(returnType=LongType()) def check_records_per_batch(x): return pd.Series(x.size).repeat(x.size) result = df.select(check_records_per_batch(col("id"))).collect() for (r,) in result: self.assertTrue(r <= 3) def test_vectorized_udf_timestamps_respect_session_timezone(self): from pyspark.sql.functions import pandas_udf, col from datetime import datetime import pandas as pd schema = StructType([ StructField("idx", LongType(), True), StructField("timestamp", TimestampType(), True)]) data = [(1, datetime(1969, 1, 1, 1, 1, 1)), (2, datetime(2012, 2, 2, 2, 2, 2)), (3, None), (4, datetime(2100, 3, 3, 3, 3, 3))] df = self.spark.createDataFrame(data, schema=schema) f_timestamp_copy = pandas_udf(lambda ts: ts, TimestampType()) internal_value = pandas_udf( lambda ts: ts.apply(lambda ts: ts.value if ts is not pd.NaT else None), LongType()) timezone = "America/New_York" with self.sql_conf({ "spark.sql.execution.pandas.respectSessionTimeZone": False, "spark.sql.session.timeZone": timezone}): df_la = df.withColumn("tscopy", f_timestamp_copy(col("timestamp"))) \ .withColumn("internal_value", internal_value(col("timestamp"))) result_la = df_la.select(col("idx"), col("internal_value")).collect() # Correct result_la by adjusting 3 hours difference between Los Angeles and New York diff = 3 * 60 * 60 * 1000 * 1000 * 1000 result_la_corrected = \ df_la.select(col("idx"), col("tscopy"), col("internal_value") + diff).collect() with self.sql_conf({ "spark.sql.execution.pandas.respectSessionTimeZone": True, "spark.sql.session.timeZone": timezone}): df_ny = df.withColumn("tscopy", f_timestamp_copy(col("timestamp"))) \ .withColumn("internal_value", internal_value(col("timestamp"))) result_ny = df_ny.select(col("idx"), col("tscopy"), col("internal_value")).collect() self.assertNotEqual(result_ny, result_la) self.assertEqual(result_ny, result_la_corrected) def test_nondeterministic_vectorized_udf(self): # Test that nondeterministic UDFs are evaluated only once in chained UDF evaluations from pyspark.sql.functions import udf, pandas_udf, col @pandas_udf('double') def plus_ten(v): return v + 10 random_udf = self.nondeterministic_vectorized_udf df = self.spark.range(10).withColumn('rand', random_udf(col('id'))) result1 = df.withColumn('plus_ten(rand)', plus_ten(df['rand'])).toPandas() self.assertEqual(random_udf.deterministic, False) self.assertTrue(result1['plus_ten(rand)'].equals(result1['rand'] + 10)) def test_nondeterministic_vectorized_udf_in_aggregate(self): from pyspark.sql.functions import pandas_udf, sum df = self.spark.range(10) random_udf = self.nondeterministic_vectorized_udf with QuietTest(self.sc): with self.assertRaisesRegexp(AnalysisException, 'nondeterministic'): df.groupby(df.id).agg(sum(random_udf(df.id))).collect() with self.assertRaisesRegexp(AnalysisException, 'nondeterministic'): df.agg(sum(random_udf(df.id))).collect() def test_register_vectorized_udf_basic(self): from pyspark.rdd import PythonEvalType from pyspark.sql.functions import pandas_udf, col, expr df = self.spark.range(10).select( col('id').cast('int').alias('a'), col('id').cast('int').alias('b')) original_add = pandas_udf(lambda x, y: x + y, IntegerType()) self.assertEqual(original_add.deterministic, True) self.assertEqual(original_add.evalType, PythonEvalType.SQL_SCALAR_PANDAS_UDF) new_add = self.spark.catalog.registerFunction("add1", original_add) res1 = df.select(new_add(col('a'), col('b'))) res2 = self.spark.sql( "SELECT add1(t.a, t.b) FROM (SELECT id as a, id as b FROM range(10)) t") expected = df.select(expr('a + b')) self.assertEquals(expected.collect(), res1.collect()) self.assertEquals(expected.collect(), res2.collect()) # Regression test for SPARK-23314 def test_timestamp_dst(self): from pyspark.sql.functions import pandas_udf # Daylight saving time for Los Angeles for 2015 is Sun, Nov 1 at 2:00 am dt = [datetime.datetime(2015, 11, 1, 0, 30), datetime.datetime(2015, 11, 1, 1, 30), datetime.datetime(2015, 11, 1, 2, 30)] df = self.spark.createDataFrame(dt, 'timestamp').toDF('time') foo_udf = pandas_udf(lambda x: x, 'timestamp') result = df.withColumn('time', foo_udf(df.time)) self.assertEquals(df.collect(), result.collect()) @unittest.skipIf(sys.version_info[:2] < (3, 5), "Type hints are supported from Python 3.5.") def test_type_annotation(self): from pyspark.sql.functions import pandas_udf # Regression test to check if type hints can be used. See SPARK-23569. # Note that it throws an error during compilation in lower Python versions if 'exec' # is not used. Also, note that we explicitly use another dictionary to avoid modifications # in the current 'locals()'. # # Hyukjin: I think it's an ugly way to test issues about syntax specific in # higher versions of Python, which we shouldn't encourage. This was the last resort # I could come up with at that time. _locals = {} exec( "import pandas as pd\ndef noop(col: pd.Series) -> pd.Series: return col", _locals) df = self.spark.range(1).select(pandas_udf(f=_locals['noop'], returnType='bigint')('id')) self.assertEqual(df.first()[0], 0) def test_mixed_udf(self): import pandas as pd from pyspark.sql.functions import col, udf, pandas_udf df = self.spark.range(0, 1).toDF('v') # Test mixture of multiple UDFs and Pandas UDFs. @udf('int') def f1(x): assert type(x) == int return x + 1 @pandas_udf('int') def f2(x): assert type(x) == pd.Series return x + 10 @udf('int') def f3(x): assert type(x) == int return x + 100 @pandas_udf('int') def f4(x): assert type(x) == pd.Series return x + 1000 # Test single expression with chained UDFs df_chained_1 = df.withColumn('f2_f1', f2(f1(df['v']))) df_chained_2 = df.withColumn('f3_f2_f1', f3(f2(f1(df['v'])))) df_chained_3 = df.withColumn('f4_f3_f2_f1', f4(f3(f2(f1(df['v']))))) df_chained_4 = df.withColumn('f4_f2_f1', f4(f2(f1(df['v'])))) df_chained_5 = df.withColumn('f4_f3_f1', f4(f3(f1(df['v'])))) expected_chained_1 = df.withColumn('f2_f1', df['v'] + 11) expected_chained_2 = df.withColumn('f3_f2_f1', df['v'] + 111) expected_chained_3 = df.withColumn('f4_f3_f2_f1', df['v'] + 1111) expected_chained_4 = df.withColumn('f4_f2_f1', df['v'] + 1011) expected_chained_5 = df.withColumn('f4_f3_f1', df['v'] + 1101) self.assertEquals(expected_chained_1.collect(), df_chained_1.collect()) self.assertEquals(expected_chained_2.collect(), df_chained_2.collect()) self.assertEquals(expected_chained_3.collect(), df_chained_3.collect()) self.assertEquals(expected_chained_4.collect(), df_chained_4.collect()) self.assertEquals(expected_chained_5.collect(), df_chained_5.collect()) # Test multiple mixed UDF expressions in a single projection df_multi_1 = df \ .withColumn('f1', f1(col('v'))) \ .withColumn('f2', f2(col('v'))) \ .withColumn('f3', f3(col('v'))) \ .withColumn('f4', f4(col('v'))) \ .withColumn('f2_f1', f2(col('f1'))) \ .withColumn('f3_f1', f3(col('f1'))) \ .withColumn('f4_f1', f4(col('f1'))) \ .withColumn('f3_f2', f3(col('f2'))) \ .withColumn('f4_f2', f4(col('f2'))) \ .withColumn('f4_f3', f4(col('f3'))) \ .withColumn('f3_f2_f1', f3(col('f2_f1'))) \ .withColumn('f4_f2_f1', f4(col('f2_f1'))) \ .withColumn('f4_f3_f1', f4(col('f3_f1'))) \ .withColumn('f4_f3_f2', f4(col('f3_f2'))) \ .withColumn('f4_f3_f2_f1', f4(col('f3_f2_f1'))) # Test mixed udfs in a single expression df_multi_2 = df \ .withColumn('f1', f1(col('v'))) \ .withColumn('f2', f2(col('v'))) \ .withColumn('f3', f3(col('v'))) \ .withColumn('f4', f4(col('v'))) \ .withColumn('f2_f1', f2(f1(col('v')))) \ .withColumn('f3_f1', f3(f1(col('v')))) \ .withColumn('f4_f1', f4(f1(col('v')))) \ .withColumn('f3_f2', f3(f2(col('v')))) \ .withColumn('f4_f2', f4(f2(col('v')))) \ .withColumn('f4_f3', f4(f3(col('v')))) \ .withColumn('f3_f2_f1', f3(f2(f1(col('v'))))) \ .withColumn('f4_f2_f1', f4(f2(f1(col('v'))))) \ .withColumn('f4_f3_f1', f4(f3(f1(col('v'))))) \ .withColumn('f4_f3_f2', f4(f3(f2(col('v'))))) \ .withColumn('f4_f3_f2_f1', f4(f3(f2(f1(col('v')))))) expected = df \ .withColumn('f1', df['v'] + 1) \ .withColumn('f2', df['v'] + 10) \ .withColumn('f3', df['v'] + 100) \ .withColumn('f4', df['v'] + 1000) \ .withColumn('f2_f1', df['v'] + 11) \ .withColumn('f3_f1', df['v'] + 101) \ .withColumn('f4_f1', df['v'] + 1001) \ .withColumn('f3_f2', df['v'] + 110) \ .withColumn('f4_f2', df['v'] + 1010) \ .withColumn('f4_f3', df['v'] + 1100) \ .withColumn('f3_f2_f1', df['v'] + 111) \ .withColumn('f4_f2_f1', df['v'] + 1011) \ .withColumn('f4_f3_f1', df['v'] + 1101) \ .withColumn('f4_f3_f2', df['v'] + 1110) \ .withColumn('f4_f3_f2_f1', df['v'] + 1111) self.assertEquals(expected.collect(), df_multi_1.collect()) self.assertEquals(expected.collect(), df_multi_2.collect()) def test_mixed_udf_and_sql(self): import pandas as pd from pyspark.sql import Column from pyspark.sql.functions import udf, pandas_udf df = self.spark.range(0, 1).toDF('v') # Test mixture of UDFs, Pandas UDFs and SQL expression. @udf('int') def f1(x): assert type(x) == int return x + 1 def f2(x): assert type(x) == Column return x + 10 @pandas_udf('int') def f3(x): assert type(x) == pd.Series return x + 100 df1 = df.withColumn('f1', f1(df['v'])) \ .withColumn('f2', f2(df['v'])) \ .withColumn('f3', f3(df['v'])) \ .withColumn('f1_f2', f1(f2(df['v']))) \ .withColumn('f1_f3', f1(f3(df['v']))) \ .withColumn('f2_f1', f2(f1(df['v']))) \ .withColumn('f2_f3', f2(f3(df['v']))) \ .withColumn('f3_f1', f3(f1(df['v']))) \ .withColumn('f3_f2', f3(f2(df['v']))) \ .withColumn('f1_f2_f3', f1(f2(f3(df['v'])))) \ .withColumn('f1_f3_f2', f1(f3(f2(df['v'])))) \ .withColumn('f2_f1_f3', f2(f1(f3(df['v'])))) \ .withColumn('f2_f3_f1', f2(f3(f1(df['v'])))) \ .withColumn('f3_f1_f2', f3(f1(f2(df['v'])))) \ .withColumn('f3_f2_f1', f3(f2(f1(df['v'])))) expected = df.withColumn('f1', df['v'] + 1) \ .withColumn('f2', df['v'] + 10) \ .withColumn('f3', df['v'] + 100) \ .withColumn('f1_f2', df['v'] + 11) \ .withColumn('f1_f3', df['v'] + 101) \ .withColumn('f2_f1', df['v'] + 11) \ .withColumn('f2_f3', df['v'] + 110) \ .withColumn('f3_f1', df['v'] + 101) \ .withColumn('f3_f2', df['v'] + 110) \ .withColumn('f1_f2_f3', df['v'] + 111) \ .withColumn('f1_f3_f2', df['v'] + 111) \ .withColumn('f2_f1_f3', df['v'] + 111) \ .withColumn('f2_f3_f1', df['v'] + 111) \ .withColumn('f3_f1_f2', df['v'] + 111) \ .withColumn('f3_f2_f1', df['v'] + 111) self.assertEquals(expected.collect(), df1.collect()) # SPARK-24721 @unittest.skipIf(not _test_compiled, _test_not_compiled_message) def test_datasource_with_udf(self): # Same as SQLTests.test_datasource_with_udf, but with Pandas UDF # This needs to a separate test because Arrow dependency is optional import pandas as pd import numpy as np from pyspark.sql.functions import pandas_udf, lit, col path = tempfile.mkdtemp() shutil.rmtree(path) try: self.spark.range(1).write.mode("overwrite").format('csv').save(path) filesource_df = self.spark.read.option('inferSchema', True).csv(path).toDF('i') datasource_df = self.spark.read \ .format("org.apache.spark.sql.sources.SimpleScanSource") \ .option('from', 0).option('to', 1).load().toDF('i') datasource_v2_df = self.spark.read \ .format("org.apache.spark.sql.sources.v2.SimpleDataSourceV2") \ .load().toDF('i', 'j') c1 = pandas_udf(lambda x: x + 1, 'int')(lit(1)) c2 = pandas_udf(lambda x: x + 1, 'int')(col('i')) f1 = pandas_udf(lambda x: pd.Series(np.repeat(False, len(x))), 'boolean')(lit(1)) f2 = pandas_udf(lambda x: pd.Series(np.repeat(False, len(x))), 'boolean')(col('i')) for df in [filesource_df, datasource_df, datasource_v2_df]: result = df.withColumn('c', c1) expected = df.withColumn('c', lit(2)) self.assertEquals(expected.collect(), result.collect()) for df in [filesource_df, datasource_df, datasource_v2_df]: result = df.withColumn('c', c2) expected = df.withColumn('c', col('i') + 1) self.assertEquals(expected.collect(), result.collect()) for df in [filesource_df, datasource_df, datasource_v2_df]: for f in [f1, f2]: result = df.filter(f) self.assertEquals(0, result.count()) finally: shutil.rmtree(path) @unittest.skipIf( not _have_pandas or not _have_pyarrow, _pandas_requirement_message or _pyarrow_requirement_message) class GroupedMapPandasUDFTests(ReusedSQLTestCase): @property def data(self): from pyspark.sql.functions import array, explode, col, lit return self.spark.range(10).toDF('id') \ .withColumn("vs", array([lit(i) for i in range(20, 30)])) \ .withColumn("v", explode(col('vs'))).drop('vs') def test_supported_types(self): from decimal import Decimal from distutils.version import LooseVersion import pyarrow as pa from pyspark.sql.functions import pandas_udf, PandasUDFType values = [ 1, 2, 3, 4, 5, 1.1, 2.2, Decimal(1.123), [1, 2, 2], True, 'hello' ] output_fields = [ ('id', IntegerType()), ('byte', ByteType()), ('short', ShortType()), ('int', IntegerType()), ('long', LongType()), ('float', FloatType()), ('double', DoubleType()), ('decim', DecimalType(10, 3)), ('array', ArrayType(IntegerType())), ('bool', BooleanType()), ('str', StringType()) ] # TODO: Add BinaryType to variables above once minimum pyarrow version is 0.10.0 if LooseVersion(pa.__version__) >= LooseVersion("0.10.0"): values.append(bytearray([0x01, 0x02])) output_fields.append(('bin', BinaryType())) output_schema = StructType([StructField(*x) for x in output_fields]) df = self.spark.createDataFrame([values], schema=output_schema) # Different forms of group map pandas UDF, results of these are the same udf1 = pandas_udf( lambda pdf: pdf.assign( byte=pdf.byte * 2, short=pdf.short * 2, int=pdf.int * 2, long=pdf.long * 2, float=pdf.float * 2, double=pdf.double * 2, decim=pdf.decim * 2, bool=False if pdf.bool else True, str=pdf.str + 'there', array=pdf.array, ), output_schema, PandasUDFType.GROUPED_MAP ) udf2 = pandas_udf( lambda _, pdf: pdf.assign( byte=pdf.byte * 2, short=pdf.short * 2, int=pdf.int * 2, long=pdf.long * 2, float=pdf.float * 2, double=pdf.double * 2, decim=pdf.decim * 2, bool=False if pdf.bool else True, str=pdf.str + 'there', array=pdf.array, ), output_schema, PandasUDFType.GROUPED_MAP ) udf3 = pandas_udf( lambda key, pdf: pdf.assign( id=key[0], byte=pdf.byte * 2, short=pdf.short * 2, int=pdf.int * 2, long=pdf.long * 2, float=pdf.float * 2, double=pdf.double * 2, decim=pdf.decim * 2, bool=False if pdf.bool else True, str=pdf.str + 'there', array=pdf.array, ), output_schema, PandasUDFType.GROUPED_MAP ) result1 = df.groupby('id').apply(udf1).sort('id').toPandas() expected1 = df.toPandas().groupby('id').apply(udf1.func).reset_index(drop=True) result2 = df.groupby('id').apply(udf2).sort('id').toPandas() expected2 = expected1 result3 = df.groupby('id').apply(udf3).sort('id').toPandas() expected3 = expected1 self.assertPandasEqual(expected1, result1) self.assertPandasEqual(expected2, result2) self.assertPandasEqual(expected3, result3) def test_array_type_correct(self): from pyspark.sql.functions import pandas_udf, PandasUDFType, array, col df = self.data.withColumn("arr", array(col("id"))).repartition(1, "id") output_schema = StructType( [StructField('id', LongType()), StructField('v', IntegerType()), StructField('arr', ArrayType(LongType()))]) udf = pandas_udf( lambda pdf: pdf, output_schema, PandasUDFType.GROUPED_MAP ) result = df.groupby('id').apply(udf).sort('id').toPandas() expected = df.toPandas().groupby('id').apply(udf.func).reset_index(drop=True) self.assertPandasEqual(expected, result) def test_register_grouped_map_udf(self): from pyspark.sql.functions import pandas_udf, PandasUDFType foo_udf = pandas_udf(lambda x: x, "id long", PandasUDFType.GROUPED_MAP) with QuietTest(self.sc): with self.assertRaisesRegexp( ValueError, 'f.*SQL_BATCHED_UDF.*SQL_SCALAR_PANDAS_UDF.*SQL_GROUPED_AGG_PANDAS_UDF.*'): self.spark.catalog.registerFunction("foo_udf", foo_udf) def test_decorator(self): from pyspark.sql.functions import pandas_udf, PandasUDFType df = self.data @pandas_udf( 'id long, v int, v1 double, v2 long', PandasUDFType.GROUPED_MAP ) def foo(pdf): return pdf.assign(v1=pdf.v * pdf.id * 1.0, v2=pdf.v + pdf.id) result = df.groupby('id').apply(foo).sort('id').toPandas() expected = df.toPandas().groupby('id').apply(foo.func).reset_index(drop=True) self.assertPandasEqual(expected, result) def test_coerce(self): from pyspark.sql.functions import pandas_udf, PandasUDFType df = self.data foo = pandas_udf( lambda pdf: pdf, 'id long, v double', PandasUDFType.GROUPED_MAP ) result = df.groupby('id').apply(foo).sort('id').toPandas() expected = df.toPandas().groupby('id').apply(foo.func).reset_index(drop=True) expected = expected.assign(v=expected.v.astype('float64')) self.assertPandasEqual(expected, result) def test_complex_groupby(self): from pyspark.sql.functions import pandas_udf, col, PandasUDFType df = self.data @pandas_udf( 'id long, v int, norm double', PandasUDFType.GROUPED_MAP ) def normalize(pdf): v = pdf.v return pdf.assign(norm=(v - v.mean()) / v.std()) result = df.groupby(col('id') % 2 == 0).apply(normalize).sort('id', 'v').toPandas() pdf = df.toPandas() expected = pdf.groupby(pdf['id'] % 2 == 0).apply(normalize.func) expected = expected.sort_values(['id', 'v']).reset_index(drop=True) expected = expected.assign(norm=expected.norm.astype('float64')) self.assertPandasEqual(expected, result) def test_empty_groupby(self): from pyspark.sql.functions import pandas_udf, col, PandasUDFType df = self.data @pandas_udf( 'id long, v int, norm double', PandasUDFType.GROUPED_MAP ) def normalize(pdf): v = pdf.v return pdf.assign(norm=(v - v.mean()) / v.std()) result = df.groupby().apply(normalize).sort('id', 'v').toPandas() pdf = df.toPandas() expected = normalize.func(pdf) expected = expected.sort_values(['id', 'v']).reset_index(drop=True) expected = expected.assign(norm=expected.norm.astype('float64')) self.assertPandasEqual(expected, result) def test_datatype_string(self): from pyspark.sql.functions import pandas_udf, PandasUDFType df = self.data foo_udf = pandas_udf( lambda pdf: pdf.assign(v1=pdf.v * pdf.id * 1.0, v2=pdf.v + pdf.id), 'id long, v int, v1 double, v2 long', PandasUDFType.GROUPED_MAP ) result = df.groupby('id').apply(foo_udf).sort('id').toPandas() expected = df.toPandas().groupby('id').apply(foo_udf.func).reset_index(drop=True) self.assertPandasEqual(expected, result) def test_wrong_return_type(self): from pyspark.sql.functions import pandas_udf, PandasUDFType with QuietTest(self.sc): with self.assertRaisesRegexp( NotImplementedError, 'Invalid returnType.*grouped map Pandas UDF.*MapType'): pandas_udf( lambda pdf: pdf, 'id long, v map', PandasUDFType.GROUPED_MAP) def test_wrong_args(self): from pyspark.sql.functions import udf, pandas_udf, sum, PandasUDFType df = self.data with QuietTest(self.sc): with self.assertRaisesRegexp(ValueError, 'Invalid udf'): df.groupby('id').apply(lambda x: x) with self.assertRaisesRegexp(ValueError, 'Invalid udf'): df.groupby('id').apply(udf(lambda x: x, DoubleType())) with self.assertRaisesRegexp(ValueError, 'Invalid udf'): df.groupby('id').apply(sum(df.v)) with self.assertRaisesRegexp(ValueError, 'Invalid udf'): df.groupby('id').apply(df.v + 1) with self.assertRaisesRegexp(ValueError, 'Invalid function'): df.groupby('id').apply( pandas_udf(lambda: 1, StructType([StructField("d", DoubleType())]))) with self.assertRaisesRegexp(ValueError, 'Invalid udf'): df.groupby('id').apply(pandas_udf(lambda x, y: x, DoubleType())) with self.assertRaisesRegexp(ValueError, 'Invalid udf.*GROUPED_MAP'): df.groupby('id').apply( pandas_udf(lambda x, y: x, DoubleType(), PandasUDFType.SCALAR)) def test_unsupported_types(self): from distutils.version import LooseVersion import pyarrow as pa from pyspark.sql.functions import pandas_udf, PandasUDFType common_err_msg = 'Invalid returnType.*grouped map Pandas UDF.*' unsupported_types = [ StructField('map', MapType(StringType(), IntegerType())), StructField('arr_ts', ArrayType(TimestampType())), StructField('null', NullType()), ] # TODO: Remove this if-statement once minimum pyarrow version is 0.10.0 if LooseVersion(pa.__version__) < LooseVersion("0.10.0"): unsupported_types.append(StructField('bin', BinaryType())) for unsupported_type in unsupported_types: schema = StructType([StructField('id', LongType(), True), unsupported_type]) with QuietTest(self.sc): with self.assertRaisesRegexp(NotImplementedError, common_err_msg): pandas_udf(lambda x: x, schema, PandasUDFType.GROUPED_MAP) # Regression test for SPARK-23314 def test_timestamp_dst(self): from pyspark.sql.functions import pandas_udf, PandasUDFType # Daylight saving time for Los Angeles for 2015 is Sun, Nov 1 at 2:00 am dt = [datetime.datetime(2015, 11, 1, 0, 30), datetime.datetime(2015, 11, 1, 1, 30), datetime.datetime(2015, 11, 1, 2, 30)] df = self.spark.createDataFrame(dt, 'timestamp').toDF('time') foo_udf = pandas_udf(lambda pdf: pdf, 'time timestamp', PandasUDFType.GROUPED_MAP) result = df.groupby('time').apply(foo_udf).sort('time') self.assertPandasEqual(df.toPandas(), result.toPandas()) def test_udf_with_key(self): from pyspark.sql.functions import pandas_udf, col, PandasUDFType df = self.data pdf = df.toPandas() def foo1(key, pdf): import numpy as np assert type(key) == tuple assert type(key[0]) == np.int64 return pdf.assign(v1=key[0], v2=pdf.v * key[0], v3=pdf.v * pdf.id, v4=pdf.v * pdf.id.mean()) def foo2(key, pdf): import numpy as np assert type(key) == tuple assert type(key[0]) == np.int64 assert type(key[1]) == np.int32 return pdf.assign(v1=key[0], v2=key[1], v3=pdf.v * key[0], v4=pdf.v + key[1]) def foo3(key, pdf): assert type(key) == tuple assert len(key) == 0 return pdf.assign(v1=pdf.v * pdf.id) # v2 is int because numpy.int64 * pd.Series results in pd.Series # v3 is long because pd.Series * pd.Series results in pd.Series udf1 = pandas_udf( foo1, 'id long, v int, v1 long, v2 int, v3 long, v4 double', PandasUDFType.GROUPED_MAP) udf2 = pandas_udf( foo2, 'id long, v int, v1 long, v2 int, v3 int, v4 int', PandasUDFType.GROUPED_MAP) udf3 = pandas_udf( foo3, 'id long, v int, v1 long', PandasUDFType.GROUPED_MAP) # Test groupby column result1 = df.groupby('id').apply(udf1).sort('id', 'v').toPandas() expected1 = pdf.groupby('id')\ .apply(lambda x: udf1.func((x.id.iloc[0],), x))\ .sort_values(['id', 'v']).reset_index(drop=True) self.assertPandasEqual(expected1, result1) # Test groupby expression result2 = df.groupby(df.id % 2).apply(udf1).sort('id', 'v').toPandas() expected2 = pdf.groupby(pdf.id % 2)\ .apply(lambda x: udf1.func((x.id.iloc[0] % 2,), x))\ .sort_values(['id', 'v']).reset_index(drop=True) self.assertPandasEqual(expected2, result2) # Test complex groupby result3 = df.groupby(df.id, df.v % 2).apply(udf2).sort('id', 'v').toPandas() expected3 = pdf.groupby([pdf.id, pdf.v % 2])\ .apply(lambda x: udf2.func((x.id.iloc[0], (x.v % 2).iloc[0],), x))\ .sort_values(['id', 'v']).reset_index(drop=True) self.assertPandasEqual(expected3, result3) # Test empty groupby result4 = df.groupby().apply(udf3).sort('id', 'v').toPandas() expected4 = udf3.func((), pdf) self.assertPandasEqual(expected4, result4) def test_column_order(self): from collections import OrderedDict import pandas as pd from pyspark.sql.functions import pandas_udf, PandasUDFType # Helper function to set column names from a list def rename_pdf(pdf, names): pdf.rename(columns={old: new for old, new in zip(pd_result.columns, names)}, inplace=True) df = self.data grouped_df = df.groupby('id') grouped_pdf = df.toPandas().groupby('id') # Function returns a pdf with required column names, but order could be arbitrary using dict def change_col_order(pdf): # Constructing a DataFrame from a dict should result in the same order, # but use from_items to ensure the pdf column order is different than schema return pd.DataFrame.from_items([ ('id', pdf.id), ('u', pdf.v * 2), ('v', pdf.v)]) ordered_udf = pandas_udf( change_col_order, 'id long, v int, u int', PandasUDFType.GROUPED_MAP ) # The UDF result should assign columns by name from the pdf result = grouped_df.apply(ordered_udf).sort('id', 'v')\ .select('id', 'u', 'v').toPandas() pd_result = grouped_pdf.apply(change_col_order) expected = pd_result.sort_values(['id', 'v']).reset_index(drop=True) self.assertPandasEqual(expected, result) # Function returns a pdf with positional columns, indexed by range def range_col_order(pdf): # Create a DataFrame with positional columns, fix types to long return pd.DataFrame(list(zip(pdf.id, pdf.v * 3, pdf.v)), dtype='int64') range_udf = pandas_udf( range_col_order, 'id long, u long, v long', PandasUDFType.GROUPED_MAP ) # The UDF result uses positional columns from the pdf result = grouped_df.apply(range_udf).sort('id', 'v') \ .select('id', 'u', 'v').toPandas() pd_result = grouped_pdf.apply(range_col_order) rename_pdf(pd_result, ['id', 'u', 'v']) expected = pd_result.sort_values(['id', 'v']).reset_index(drop=True) self.assertPandasEqual(expected, result) # Function returns a pdf with columns indexed with integers def int_index(pdf): return pd.DataFrame(OrderedDict([(0, pdf.id), (1, pdf.v * 4), (2, pdf.v)])) int_index_udf = pandas_udf( int_index, 'id long, u int, v int', PandasUDFType.GROUPED_MAP ) # The UDF result should assign columns by position of integer index result = grouped_df.apply(int_index_udf).sort('id', 'v') \ .select('id', 'u', 'v').toPandas() pd_result = grouped_pdf.apply(int_index) rename_pdf(pd_result, ['id', 'u', 'v']) expected = pd_result.sort_values(['id', 'v']).reset_index(drop=True) self.assertPandasEqual(expected, result) @pandas_udf('id long, v int', PandasUDFType.GROUPED_MAP) def column_name_typo(pdf): return pd.DataFrame({'iid': pdf.id, 'v': pdf.v}) @pandas_udf('id long, v int', PandasUDFType.GROUPED_MAP) def invalid_positional_types(pdf): return pd.DataFrame([(u'a', 1.2)]) with QuietTest(self.sc): with self.assertRaisesRegexp(Exception, "KeyError: 'id'"): grouped_df.apply(column_name_typo).collect() with self.assertRaisesRegexp(Exception, "No cast implemented"): grouped_df.apply(invalid_positional_types).collect() def test_positional_assignment_conf(self): import pandas as pd from pyspark.sql.functions import pandas_udf, PandasUDFType with self.sql_conf({ "spark.sql.legacy.execution.pandas.groupedMap.assignColumnsByName": False}): @pandas_udf("a string, b float", PandasUDFType.GROUPED_MAP) def foo(_): return pd.DataFrame([('hi', 1)], columns=['x', 'y']) df = self.data result = df.groupBy('id').apply(foo).select('a', 'b').collect() for r in result: self.assertEqual(r.a, 'hi') self.assertEqual(r.b, 1) def test_self_join_with_pandas(self): import pyspark.sql.functions as F @F.pandas_udf('key long, col string', F.PandasUDFType.GROUPED_MAP) def dummy_pandas_udf(df): return df[['key', 'col']] df = self.spark.createDataFrame([Row(key=1, col='A'), Row(key=1, col='B'), Row(key=2, col='C')]) df_with_pandas = df.groupBy('key').apply(dummy_pandas_udf) # this was throwing an AnalysisException before SPARK-24208 res = df_with_pandas.alias('temp0').join(df_with_pandas.alias('temp1'), F.col('temp0.key') == F.col('temp1.key')) self.assertEquals(res.count(), 5) def test_mixed_scalar_udfs_followed_by_grouby_apply(self): import pandas as pd from pyspark.sql.functions import udf, pandas_udf, PandasUDFType df = self.spark.range(0, 10).toDF('v1') df = df.withColumn('v2', udf(lambda x: x + 1, 'int')(df['v1'])) \ .withColumn('v3', pandas_udf(lambda x: x + 2, 'int')(df['v1'])) result = df.groupby() \ .apply(pandas_udf(lambda x: pd.DataFrame([x.sum().sum()]), 'sum int', PandasUDFType.GROUPED_MAP)) self.assertEquals(result.collect()[0]['sum'], 165) @unittest.skipIf( not _have_pandas or not _have_pyarrow, _pandas_requirement_message or _pyarrow_requirement_message) class GroupedAggPandasUDFTests(ReusedSQLTestCase): @property def data(self): from pyspark.sql.functions import array, explode, col, lit return self.spark.range(10).toDF('id') \ .withColumn("vs", array([lit(i * 1.0) + col('id') for i in range(20, 30)])) \ .withColumn("v", explode(col('vs'))) \ .drop('vs') \ .withColumn('w', lit(1.0)) @property def python_plus_one(self): from pyspark.sql.functions import udf @udf('double') def plus_one(v): assert isinstance(v, (int, float)) return v + 1 return plus_one @property def pandas_scalar_plus_two(self): import pandas as pd from pyspark.sql.functions import pandas_udf, PandasUDFType @pandas_udf('double', PandasUDFType.SCALAR) def plus_two(v): assert isinstance(v, pd.Series) return v + 2 return plus_two @property def pandas_agg_mean_udf(self): from pyspark.sql.functions import pandas_udf, PandasUDFType @pandas_udf('double', PandasUDFType.GROUPED_AGG) def avg(v): return v.mean() return avg @property def pandas_agg_sum_udf(self): from pyspark.sql.functions import pandas_udf, PandasUDFType @pandas_udf('double', PandasUDFType.GROUPED_AGG) def sum(v): return v.sum() return sum @property def pandas_agg_weighted_mean_udf(self): import numpy as np from pyspark.sql.functions import pandas_udf, PandasUDFType @pandas_udf('double', PandasUDFType.GROUPED_AGG) def weighted_mean(v, w): return np.average(v, weights=w) return weighted_mean def test_manual(self): from pyspark.sql.functions import pandas_udf, array df = self.data sum_udf = self.pandas_agg_sum_udf mean_udf = self.pandas_agg_mean_udf mean_arr_udf = pandas_udf( self.pandas_agg_mean_udf.func, ArrayType(self.pandas_agg_mean_udf.returnType), self.pandas_agg_mean_udf.evalType) result1 = df.groupby('id').agg( sum_udf(df.v), mean_udf(df.v), mean_arr_udf(array(df.v))).sort('id') expected1 = self.spark.createDataFrame( [[0, 245.0, 24.5, [24.5]], [1, 255.0, 25.5, [25.5]], [2, 265.0, 26.5, [26.5]], [3, 275.0, 27.5, [27.5]], [4, 285.0, 28.5, [28.5]], [5, 295.0, 29.5, [29.5]], [6, 305.0, 30.5, [30.5]], [7, 315.0, 31.5, [31.5]], [8, 325.0, 32.5, [32.5]], [9, 335.0, 33.5, [33.5]]], ['id', 'sum(v)', 'avg(v)', 'avg(array(v))']) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) def test_basic(self): from pyspark.sql.functions import col, lit, sum, mean df = self.data weighted_mean_udf = self.pandas_agg_weighted_mean_udf # Groupby one column and aggregate one UDF with literal result1 = df.groupby('id').agg(weighted_mean_udf(df.v, lit(1.0))).sort('id') expected1 = df.groupby('id').agg(mean(df.v).alias('weighted_mean(v, 1.0)')).sort('id') self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) # Groupby one expression and aggregate one UDF with literal result2 = df.groupby((col('id') + 1)).agg(weighted_mean_udf(df.v, lit(1.0)))\ .sort(df.id + 1) expected2 = df.groupby((col('id') + 1))\ .agg(mean(df.v).alias('weighted_mean(v, 1.0)')).sort(df.id + 1) self.assertPandasEqual(expected2.toPandas(), result2.toPandas()) # Groupby one column and aggregate one UDF without literal result3 = df.groupby('id').agg(weighted_mean_udf(df.v, df.w)).sort('id') expected3 = df.groupby('id').agg(mean(df.v).alias('weighted_mean(v, w)')).sort('id') self.assertPandasEqual(expected3.toPandas(), result3.toPandas()) # Groupby one expression and aggregate one UDF without literal result4 = df.groupby((col('id') + 1).alias('id'))\ .agg(weighted_mean_udf(df.v, df.w))\ .sort('id') expected4 = df.groupby((col('id') + 1).alias('id'))\ .agg(mean(df.v).alias('weighted_mean(v, w)'))\ .sort('id') self.assertPandasEqual(expected4.toPandas(), result4.toPandas()) def test_unsupported_types(self): from pyspark.sql.types import DoubleType, MapType from pyspark.sql.functions import pandas_udf, PandasUDFType with QuietTest(self.sc): with self.assertRaisesRegexp(NotImplementedError, 'not supported'): pandas_udf( lambda x: x, ArrayType(ArrayType(TimestampType())), PandasUDFType.GROUPED_AGG) with QuietTest(self.sc): with self.assertRaisesRegexp(NotImplementedError, 'not supported'): @pandas_udf('mean double, std double', PandasUDFType.GROUPED_AGG) def mean_and_std_udf(v): return v.mean(), v.std() with QuietTest(self.sc): with self.assertRaisesRegexp(NotImplementedError, 'not supported'): @pandas_udf(MapType(DoubleType(), DoubleType()), PandasUDFType.GROUPED_AGG) def mean_and_std_udf(v): return {v.mean(): v.std()} def test_alias(self): from pyspark.sql.functions import mean df = self.data mean_udf = self.pandas_agg_mean_udf result1 = df.groupby('id').agg(mean_udf(df.v).alias('mean_alias')) expected1 = df.groupby('id').agg(mean(df.v).alias('mean_alias')) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) def test_mixed_sql(self): """ Test mixing group aggregate pandas UDF with sql expression. """ from pyspark.sql.functions import sum, mean df = self.data sum_udf = self.pandas_agg_sum_udf # Mix group aggregate pandas UDF with sql expression result1 = (df.groupby('id') .agg(sum_udf(df.v) + 1) .sort('id')) expected1 = (df.groupby('id') .agg(sum(df.v) + 1) .sort('id')) # Mix group aggregate pandas UDF with sql expression (order swapped) result2 = (df.groupby('id') .agg(sum_udf(df.v + 1)) .sort('id')) expected2 = (df.groupby('id') .agg(sum(df.v + 1)) .sort('id')) # Wrap group aggregate pandas UDF with two sql expressions result3 = (df.groupby('id') .agg(sum_udf(df.v + 1) + 2) .sort('id')) expected3 = (df.groupby('id') .agg(sum(df.v + 1) + 2) .sort('id')) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) self.assertPandasEqual(expected2.toPandas(), result2.toPandas()) self.assertPandasEqual(expected3.toPandas(), result3.toPandas()) def test_mixed_udfs(self): """ Test mixing group aggregate pandas UDF with python UDF and scalar pandas UDF. """ from pyspark.sql.functions import sum, mean df = self.data plus_one = self.python_plus_one plus_two = self.pandas_scalar_plus_two sum_udf = self.pandas_agg_sum_udf # Mix group aggregate pandas UDF and python UDF result1 = (df.groupby('id') .agg(plus_one(sum_udf(df.v))) .sort('id')) expected1 = (df.groupby('id') .agg(plus_one(sum(df.v))) .sort('id')) # Mix group aggregate pandas UDF and python UDF (order swapped) result2 = (df.groupby('id') .agg(sum_udf(plus_one(df.v))) .sort('id')) expected2 = (df.groupby('id') .agg(sum(plus_one(df.v))) .sort('id')) # Mix group aggregate pandas UDF and scalar pandas UDF result3 = (df.groupby('id') .agg(sum_udf(plus_two(df.v))) .sort('id')) expected3 = (df.groupby('id') .agg(sum(plus_two(df.v))) .sort('id')) # Mix group aggregate pandas UDF and scalar pandas UDF (order swapped) result4 = (df.groupby('id') .agg(plus_two(sum_udf(df.v))) .sort('id')) expected4 = (df.groupby('id') .agg(plus_two(sum(df.v))) .sort('id')) # Wrap group aggregate pandas UDF with two python UDFs and use python UDF in groupby result5 = (df.groupby(plus_one(df.id)) .agg(plus_one(sum_udf(plus_one(df.v)))) .sort('plus_one(id)')) expected5 = (df.groupby(plus_one(df.id)) .agg(plus_one(sum(plus_one(df.v)))) .sort('plus_one(id)')) # Wrap group aggregate pandas UDF with two scala pandas UDF and user scala pandas UDF in # groupby result6 = (df.groupby(plus_two(df.id)) .agg(plus_two(sum_udf(plus_two(df.v)))) .sort('plus_two(id)')) expected6 = (df.groupby(plus_two(df.id)) .agg(plus_two(sum(plus_two(df.v)))) .sort('plus_two(id)')) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) self.assertPandasEqual(expected2.toPandas(), result2.toPandas()) self.assertPandasEqual(expected3.toPandas(), result3.toPandas()) self.assertPandasEqual(expected4.toPandas(), result4.toPandas()) self.assertPandasEqual(expected5.toPandas(), result5.toPandas()) self.assertPandasEqual(expected6.toPandas(), result6.toPandas()) def test_multiple_udfs(self): """ Test multiple group aggregate pandas UDFs in one agg function. """ from pyspark.sql.functions import col, lit, sum, mean df = self.data mean_udf = self.pandas_agg_mean_udf sum_udf = self.pandas_agg_sum_udf weighted_mean_udf = self.pandas_agg_weighted_mean_udf result1 = (df.groupBy('id') .agg(mean_udf(df.v), sum_udf(df.v), weighted_mean_udf(df.v, df.w)) .sort('id') .toPandas()) expected1 = (df.groupBy('id') .agg(mean(df.v), sum(df.v), mean(df.v).alias('weighted_mean(v, w)')) .sort('id') .toPandas()) self.assertPandasEqual(expected1, result1) def test_complex_groupby(self): from pyspark.sql.functions import lit, sum df = self.data sum_udf = self.pandas_agg_sum_udf plus_one = self.python_plus_one plus_two = self.pandas_scalar_plus_two # groupby one expression result1 = df.groupby(df.v % 2).agg(sum_udf(df.v)) expected1 = df.groupby(df.v % 2).agg(sum(df.v)) # empty groupby result2 = df.groupby().agg(sum_udf(df.v)) expected2 = df.groupby().agg(sum(df.v)) # groupby one column and one sql expression result3 = df.groupby(df.id, df.v % 2).agg(sum_udf(df.v)).orderBy(df.id, df.v % 2) expected3 = df.groupby(df.id, df.v % 2).agg(sum(df.v)).orderBy(df.id, df.v % 2) # groupby one python UDF result4 = df.groupby(plus_one(df.id)).agg(sum_udf(df.v)) expected4 = df.groupby(plus_one(df.id)).agg(sum(df.v)) # groupby one scalar pandas UDF result5 = df.groupby(plus_two(df.id)).agg(sum_udf(df.v)) expected5 = df.groupby(plus_two(df.id)).agg(sum(df.v)) # groupby one expression and one python UDF result6 = df.groupby(df.v % 2, plus_one(df.id)).agg(sum_udf(df.v)) expected6 = df.groupby(df.v % 2, plus_one(df.id)).agg(sum(df.v)) # groupby one expression and one scalar pandas UDF result7 = df.groupby(df.v % 2, plus_two(df.id)).agg(sum_udf(df.v)).sort('sum(v)') expected7 = df.groupby(df.v % 2, plus_two(df.id)).agg(sum(df.v)).sort('sum(v)') self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) self.assertPandasEqual(expected2.toPandas(), result2.toPandas()) self.assertPandasEqual(expected3.toPandas(), result3.toPandas()) self.assertPandasEqual(expected4.toPandas(), result4.toPandas()) self.assertPandasEqual(expected5.toPandas(), result5.toPandas()) self.assertPandasEqual(expected6.toPandas(), result6.toPandas()) self.assertPandasEqual(expected7.toPandas(), result7.toPandas()) def test_complex_expressions(self): from pyspark.sql.functions import col, sum df = self.data plus_one = self.python_plus_one plus_two = self.pandas_scalar_plus_two sum_udf = self.pandas_agg_sum_udf # Test complex expressions with sql expression, python UDF and # group aggregate pandas UDF result1 = (df.withColumn('v1', plus_one(df.v)) .withColumn('v2', df.v + 2) .groupby(df.id, df.v % 2) .agg(sum_udf(col('v')), sum_udf(col('v1') + 3), sum_udf(col('v2')) + 5, plus_one(sum_udf(col('v1'))), sum_udf(plus_one(col('v2')))) .sort('id') .toPandas()) expected1 = (df.withColumn('v1', df.v + 1) .withColumn('v2', df.v + 2) .groupby(df.id, df.v % 2) .agg(sum(col('v')), sum(col('v1') + 3), sum(col('v2')) + 5, plus_one(sum(col('v1'))), sum(plus_one(col('v2')))) .sort('id') .toPandas()) # Test complex expressions with sql expression, scala pandas UDF and # group aggregate pandas UDF result2 = (df.withColumn('v1', plus_one(df.v)) .withColumn('v2', df.v + 2) .groupby(df.id, df.v % 2) .agg(sum_udf(col('v')), sum_udf(col('v1') + 3), sum_udf(col('v2')) + 5, plus_two(sum_udf(col('v1'))), sum_udf(plus_two(col('v2')))) .sort('id') .toPandas()) expected2 = (df.withColumn('v1', df.v + 1) .withColumn('v2', df.v + 2) .groupby(df.id, df.v % 2) .agg(sum(col('v')), sum(col('v1') + 3), sum(col('v2')) + 5, plus_two(sum(col('v1'))), sum(plus_two(col('v2')))) .sort('id') .toPandas()) # Test sequential groupby aggregate result3 = (df.groupby('id') .agg(sum_udf(df.v).alias('v')) .groupby('id') .agg(sum_udf(col('v'))) .sort('id') .toPandas()) expected3 = (df.groupby('id') .agg(sum(df.v).alias('v')) .groupby('id') .agg(sum(col('v'))) .sort('id') .toPandas()) self.assertPandasEqual(expected1, result1) self.assertPandasEqual(expected2, result2) self.assertPandasEqual(expected3, result3) def test_retain_group_columns(self): from pyspark.sql.functions import sum, lit, col with self.sql_conf({"spark.sql.retainGroupColumns": False}): df = self.data sum_udf = self.pandas_agg_sum_udf result1 = df.groupby(df.id).agg(sum_udf(df.v)) expected1 = df.groupby(df.id).agg(sum(df.v)) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) def test_array_type(self): from pyspark.sql.functions import pandas_udf, PandasUDFType df = self.data array_udf = pandas_udf(lambda x: [1.0, 2.0], 'array', PandasUDFType.GROUPED_AGG) result1 = df.groupby('id').agg(array_udf(df['v']).alias('v2')) self.assertEquals(result1.first()['v2'], [1.0, 2.0]) def test_invalid_args(self): from pyspark.sql.functions import mean df = self.data plus_one = self.python_plus_one mean_udf = self.pandas_agg_mean_udf with QuietTest(self.sc): with self.assertRaisesRegexp( AnalysisException, 'nor.*aggregate function'): df.groupby(df.id).agg(plus_one(df.v)).collect() with QuietTest(self.sc): with self.assertRaisesRegexp( AnalysisException, 'aggregate function.*argument.*aggregate function'): df.groupby(df.id).agg(mean_udf(mean_udf(df.v))).collect() with QuietTest(self.sc): with self.assertRaisesRegexp( AnalysisException, 'mixture.*aggregate function.*group aggregate pandas UDF'): df.groupby(df.id).agg(mean_udf(df.v), mean(df.v)).collect() def test_register_vectorized_udf_basic(self): from pyspark.sql.functions import pandas_udf from pyspark.rdd import PythonEvalType sum_pandas_udf = pandas_udf( lambda v: v.sum(), "integer", PythonEvalType.SQL_GROUPED_AGG_PANDAS_UDF) self.assertEqual(sum_pandas_udf.evalType, PythonEvalType.SQL_GROUPED_AGG_PANDAS_UDF) group_agg_pandas_udf = self.spark.udf.register("sum_pandas_udf", sum_pandas_udf) self.assertEqual(group_agg_pandas_udf.evalType, PythonEvalType.SQL_GROUPED_AGG_PANDAS_UDF) q = "SELECT sum_pandas_udf(v1) FROM VALUES (3, 0), (2, 0), (1, 1) tbl(v1, v2) GROUP BY v2" actual = sorted(map(lambda r: r[0], self.spark.sql(q).collect())) expected = [1, 5] self.assertEqual(actual, expected) @unittest.skipIf( not _have_pandas or not _have_pyarrow, _pandas_requirement_message or _pyarrow_requirement_message) class WindowPandasUDFTests(ReusedSQLTestCase): @property def data(self): from pyspark.sql.functions import array, explode, col, lit return self.spark.range(10).toDF('id') \ .withColumn("vs", array([lit(i * 1.0) + col('id') for i in range(20, 30)])) \ .withColumn("v", explode(col('vs'))) \ .drop('vs') \ .withColumn('w', lit(1.0)) @property def python_plus_one(self): from pyspark.sql.functions import udf return udf(lambda v: v + 1, 'double') @property def pandas_scalar_time_two(self): from pyspark.sql.functions import pandas_udf, PandasUDFType return pandas_udf(lambda v: v * 2, 'double') @property def pandas_agg_mean_udf(self): from pyspark.sql.functions import pandas_udf, PandasUDFType @pandas_udf('double', PandasUDFType.GROUPED_AGG) def avg(v): return v.mean() return avg @property def pandas_agg_max_udf(self): from pyspark.sql.functions import pandas_udf, PandasUDFType @pandas_udf('double', PandasUDFType.GROUPED_AGG) def max(v): return v.max() return max @property def pandas_agg_min_udf(self): from pyspark.sql.functions import pandas_udf, PandasUDFType @pandas_udf('double', PandasUDFType.GROUPED_AGG) def min(v): return v.min() return min @property def unbounded_window(self): return Window.partitionBy('id') \ .rowsBetween(Window.unboundedPreceding, Window.unboundedFollowing) @property def ordered_window(self): return Window.partitionBy('id').orderBy('v') @property def unpartitioned_window(self): return Window.partitionBy() def test_simple(self): from pyspark.sql.functions import pandas_udf, PandasUDFType, percent_rank, mean, max df = self.data w = self.unbounded_window mean_udf = self.pandas_agg_mean_udf result1 = df.withColumn('mean_v', mean_udf(df['v']).over(w)) expected1 = df.withColumn('mean_v', mean(df['v']).over(w)) result2 = df.select(mean_udf(df['v']).over(w)) expected2 = df.select(mean(df['v']).over(w)) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) self.assertPandasEqual(expected2.toPandas(), result2.toPandas()) def test_multiple_udfs(self): from pyspark.sql.functions import max, min, mean df = self.data w = self.unbounded_window result1 = df.withColumn('mean_v', self.pandas_agg_mean_udf(df['v']).over(w)) \ .withColumn('max_v', self.pandas_agg_max_udf(df['v']).over(w)) \ .withColumn('min_w', self.pandas_agg_min_udf(df['w']).over(w)) expected1 = df.withColumn('mean_v', mean(df['v']).over(w)) \ .withColumn('max_v', max(df['v']).over(w)) \ .withColumn('min_w', min(df['w']).over(w)) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) def test_replace_existing(self): from pyspark.sql.functions import mean df = self.data w = self.unbounded_window result1 = df.withColumn('v', self.pandas_agg_mean_udf(df['v']).over(w)) expected1 = df.withColumn('v', mean(df['v']).over(w)) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) def test_mixed_sql(self): from pyspark.sql.functions import mean df = self.data w = self.unbounded_window mean_udf = self.pandas_agg_mean_udf result1 = df.withColumn('v', mean_udf(df['v'] * 2).over(w) + 1) expected1 = df.withColumn('v', mean(df['v'] * 2).over(w) + 1) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) def test_mixed_udf(self): from pyspark.sql.functions import mean df = self.data w = self.unbounded_window plus_one = self.python_plus_one time_two = self.pandas_scalar_time_two mean_udf = self.pandas_agg_mean_udf result1 = df.withColumn( 'v2', plus_one(mean_udf(plus_one(df['v'])).over(w))) expected1 = df.withColumn( 'v2', plus_one(mean(plus_one(df['v'])).over(w))) result2 = df.withColumn( 'v2', time_two(mean_udf(time_two(df['v'])).over(w))) expected2 = df.withColumn( 'v2', time_two(mean(time_two(df['v'])).over(w))) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) self.assertPandasEqual(expected2.toPandas(), result2.toPandas()) def test_without_partitionBy(self): from pyspark.sql.functions import mean df = self.data w = self.unpartitioned_window mean_udf = self.pandas_agg_mean_udf result1 = df.withColumn('v2', mean_udf(df['v']).over(w)) expected1 = df.withColumn('v2', mean(df['v']).over(w)) result2 = df.select(mean_udf(df['v']).over(w)) expected2 = df.select(mean(df['v']).over(w)) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) self.assertPandasEqual(expected2.toPandas(), result2.toPandas()) def test_mixed_sql_and_udf(self): from pyspark.sql.functions import max, min, rank, col df = self.data w = self.unbounded_window ow = self.ordered_window max_udf = self.pandas_agg_max_udf min_udf = self.pandas_agg_min_udf result1 = df.withColumn('v_diff', max_udf(df['v']).over(w) - min_udf(df['v']).over(w)) expected1 = df.withColumn('v_diff', max(df['v']).over(w) - min(df['v']).over(w)) # Test mixing sql window function and window udf in the same expression result2 = df.withColumn('v_diff', max_udf(df['v']).over(w) - min(df['v']).over(w)) expected2 = expected1 # Test chaining sql aggregate function and udf result3 = df.withColumn('max_v', max_udf(df['v']).over(w)) \ .withColumn('min_v', min(df['v']).over(w)) \ .withColumn('v_diff', col('max_v') - col('min_v')) \ .drop('max_v', 'min_v') expected3 = expected1 # Test mixing sql window function and udf result4 = df.withColumn('max_v', max_udf(df['v']).over(w)) \ .withColumn('rank', rank().over(ow)) expected4 = df.withColumn('max_v', max(df['v']).over(w)) \ .withColumn('rank', rank().over(ow)) self.assertPandasEqual(expected1.toPandas(), result1.toPandas()) self.assertPandasEqual(expected2.toPandas(), result2.toPandas()) self.assertPandasEqual(expected3.toPandas(), result3.toPandas()) self.assertPandasEqual(expected4.toPandas(), result4.toPandas()) def test_array_type(self): from pyspark.sql.functions import pandas_udf, PandasUDFType df = self.data w = self.unbounded_window array_udf = pandas_udf(lambda x: [1.0, 2.0], 'array', PandasUDFType.GROUPED_AGG) result1 = df.withColumn('v2', array_udf(df['v']).over(w)) self.assertEquals(result1.first()['v2'], [1.0, 2.0]) def test_invalid_args(self): from pyspark.sql.functions import mean, pandas_udf, PandasUDFType df = self.data w = self.unbounded_window ow = self.ordered_window mean_udf = self.pandas_agg_mean_udf with QuietTest(self.sc): with self.assertRaisesRegexp( AnalysisException, '.*not supported within a window function'): foo_udf = pandas_udf(lambda x: x, 'v double', PandasUDFType.GROUPED_MAP) df.withColumn('v2', foo_udf(df['v']).over(w)) with QuietTest(self.sc): with self.assertRaisesRegexp( AnalysisException, '.*Only unbounded window frame is supported.*'): df.withColumn('mean_v', mean_udf(df['v']).over(ow)) if __name__ == "__main__": from pyspark.sql.tests import * if xmlrunner: unittest.main(testRunner=xmlrunner.XMLTestRunner(output='target/test-reports'), verbosity=2) else: unittest.main(verbosity=2)