Hive语法和UDF手册 – NPE空指针异常

说明：翻译自https://cwiki.apache.org/confluence/display/hive/languagemanual+udf。根据自己的理解，补充了一些内容。

最后更新日期：2024年06月17日

所有 Hive 关键字都不区分大小写，包括 Hive 运算符和函数的名称。

在 Beeline 或 CLI中，使用以下命令显示最新文档：

SHOW FUNCTIONS;
DESCRIBE FUNCTION <function_name>;
DESCRIBE FUNCTION EXTENDED <function_name>;

当 UDF 嵌套在 UDF 或函数中时，表达式缓存的 Bug

当 hive.cache.expr.evaluation 设置为 true（默认值）时，如果 UDF 嵌套在另一个 UDF 或 Hive 函数中，则可能会产生错误的结果。此错误影响版本 0.12.0、0.13.0 和 0.13.1。版本 0.14.0 修复了此错误 (HIVE-7314)。

该问题与 UDF 的 getDisplayString 方法实现有关，如 Hive 用户邮件列表中所述。

内置的运算符

运算符优先级

示例	运算符	描述
A[B] , A.identifier	bracket_op([]), dot(.)	数组元素选择，结构体元素
-A	unary(+), unary(-), unary(~)	一元前缀运算符
A IS [NOT] (NULL\|TRUE\|FALSE)	IS NULL,IS NOT NULL, …	一元后缀
A ^ B	bitwise xor(^)	按位异或
A * B	star(*), divide(/), mod(%), div(DIV)	乘法
A + B	plus(+), minus(-)	加法
A \|\| B	string concatenate(\|\|)	字符串连接
A & B	bitwise and(&)	按位与
A \| B	bitwise or(\|)	按位或

关系运算符

以下运算符比较两个操作数，生成 TRUE 或 FALSE 值。

运算符	操作数类型	描述
A = B	基本类型	如果表达式 A 等于表达式 B，则为 TRUE，否则为 FALSE。
A == B	基本类型	同 =。
A <=> B	基本类型	对于非空操作数，使用 EQUAL(=) 运算符返回相同的结果，但如果两个操作数都为 NULL，则返回 TRUE，如果其中一个为 NULL，则返回 FALSE。（从版本 0.9.0 开始。）
A <> B	基本类型	如果 A 或 B 为 NULL，则为 NULL；如果表达式 A 不等于表达式 B，则为 TRUE，否则为 FALSE。
A != B	基本类型	同 <>。
A < B	基本类型	NULL if A or B is NULL, TRUE if expression A is less than expression B, otherwise FALSE.
A <= B	基本类型	NULL if A or B is NULL, TRUE if expression A is less than or equal to expression B, otherwise FALSE.
A > B	基本类型	NULL if A or B is NULL, TRUE if expression A is greater than expression B, otherwise FALSE.
A >= B	基本类型	NULL if A or B is NULL, TRUE if expression A is greater than or equal to expression B, otherwise FALSE.
A [NOT] BETWEEN B AND C	基本类型	NULL if A, B or C is NULL, TRUE if A is greater than or equal to B AND A less than or equal to C, otherwise FALSE. This can be inverted by using the NOT keyword. (As of version 0.9.0.)
A IS NULL	所有	TRUE if expression A evaluates to NULL, otherwise FALSE.
A IS NOT NULL	所有	FALSE if expression A evaluates to NULL, otherwise TRUE.
A IS [NOT] (TRUE\|FALSE)	Boolean	Evaluates to TRUE only if A mets the condition. (since:3.0.0 ) Note: NULL is UNKNOWN, and because of that (UNKNOWN IS TRUE) and (UNKNOWN IS FALSE) both evaluates to FALSE.
A [NOT] LIKE B	strings	NULL if A or B is NULL, TRUE if string A matches the SQL simple regular expression B, otherwise FALSE. The comparison is done character by character. The _ character in B matches any character in A (similar to . in posix regular expressions) while the % character in B matches an arbitrary number of characters in A (similar to .* in posix regular expressions). For example, ‘foobar’ like ‘foo’ evaluates to FALSE whereas ‘foobar’ like ‘foo_ _ _’ evaluates to TRUE and so does ‘foobar’ like ‘foo%’.
A RLIKE B	strings	NULL if A or B is NULL, TRUE if any (possibly empty) substring of A matches the Java regular expression B, otherwise FALSE. For example, ‘foobar’ RLIKE ‘foo’ evaluates to TRUE and so does ‘foobar’ RLIKE ‘^f.*r$’.
A REGEXP B	strings	Same as RLIKE.

算数运算

以下运算符支持对操作数进行各种常见的算术运算。所有运算符均返回数字类型；如果任何操作数为 NULL，则结果也为 NULL。

Operator	Operand types	Description
A + B	All number types	Gives the result of adding A and B. The type of the result is the same as the common parent(in the type hierarchy) of the types of the operands. For example since every integer is a float, therefore float is a containing type of integer so the + operator on a float and an int will result in a float.
A – B	All number types	Gives the result of subtracting B from A. The type of the result is the same as the common parent(in the type hierarchy) of the types of the operands.
A * B	All number types	Gives the result of multiplying A and B. The type of the result is the same as the common parent(in the type hierarchy) of the types of the operands. Note that if the multiplication causing overflow, you will have to cast one of the operators to a type higher in the type hierarchy.
A / B	All number types	Gives the result of dividing A by B. The result is a double type in most cases. When A and B are both integers, the result is a double type except when the hive.compat configuration parameter is set to “0.13” or “latest” in which case the result is a decimal type.
A DIV B	Integer types	Gives the integer part resulting from dividing A by B. E.g 17 div 3 results in 5.
A % B	All number types	Gives the reminder resulting from dividing A by B. The type of the result is the same as the common parent(in the type hierarchy) of the types of the operands.
A & B	All number types	Gives the result of bitwise AND of A and B. The type of the result is the same as the common parent(in the type hierarchy) of the types of the operands.
A \| B	All number types	Gives the result of bitwise OR of A and B. The type of the result is the same as the common parent(in the type hierarchy) of the types of the operands.
A ^ B	All number types	Gives the result of bitwise XOR of A and B. The type of the result is the same as the common parent(in the type hierarchy) of the types of the operands.
~A	All number types	Gives the result of bitwise NOT of A. The type of the result is the same as the type of A.

逻辑运算符

以下运算符支持创建逻辑表达式。它们均返回布尔值 TRUE、FALSE 或 NULL，具体取决于操作数的布尔值。NULL 表现为“未知”标志，因此如果结果取决于未知的状态，则结果本身也是未知的。

Operator	Operand types	Description
A AND B	boolean	TRUE if both A and B are TRUE, otherwise FALSE. NULL if A or B is NULL.
A OR B	boolean	TRUE if either A or B or both are TRUE, FALSE OR NULL is NULL, otherwise FALSE.
NOT A	boolean	TRUE if A is FALSE or NULL if A is NULL. Otherwise FALSE.
! A	boolean	Same as NOT A.
A IN (val1, val2, …)	boolean	TRUE if A is equal to any of the values. As of Hive 0.13 subqueries are supported in IN statements.
A NOT IN (val1, val2, …)	boolean	TRUE if A is not equal to any of the values. As of Hive 0.13 subqueries are supported in NOT IN statements.
[NOT] EXISTS (subquery)		TRUE if the the subquery returns at least one row. Supported as of Hive 0.13.

字符串运算符

Operator	Operand types	Description
A \|\| B	strings	连接操作数 – concat(A,B) 的简写。从 Hive 2.2.0 开始受支持。

复杂类型构造函数

以下函数构造复杂类型的实例。

Constructor Function	Operands	Description
map	(key1, value1, key2, value2, …)	使用给定的键创建一个Map
struct	(val1, val2, val3, …)	使用给定的字段值创建结构体。结构体字段名称为 col1、col2、…
named_struct	(name1, val1, name2, val2, …)	使用给定的字段名称和值创建一个结构体。（Hive 0.8.0。）
array	(val1, val2, …)	创建一个数组 [val1, val2, …]
create_union	(tag, val1, val2, …)	创建一个具有标签参数指向的值的联合类型。

复杂类型的运算符

以下运算符提供访问复杂类型中的元素的机制。

运算符	操作数类型	描述
A[n]	A 是数组，n 是整数	返回数组 A 中的第 n 个元素。第一个元素的索引为 0。例如，如果 A 是一个由 [‘foo’, ‘bar’] 组成的数组，则 A[0] 返回 ‘foo’ 而 A[1] 返回 ‘bar’。
M[key]	M 是 Map<K, V> 类型，key的类型为K	返回与映射中的键对应的值。例如，如果 M 是一个由 {‘f’ -> ‘foo’, ‘b’ -> ‘bar’, ‘all’ -> ‘foobar’} 组成的映射，则 M[‘all’] 返回 ‘foobar’。
S.x	S 是结构	返回 S 的 x 字段。例如对于结构 foobar {int foo, int bar}，foobar.foo 返回存储在结构体的 foo 字段中的整数。

内置函数

数学函数

Hive 支持以下内置数学函数；当参数为 NULL 时，大多数函数返回 NULL：

Return Type	Name (Signature)	Description
DOUBLE	round(DOUBLE a)	返回 a 的四舍五入的 BIGINT 值。
DOUBLE	round(DOUBLE a, INT d)	返回四舍五入到小数点后 d 位的结果。
DOUBLE	bround(DOUBLE a)	使用 HALF_EVEN 舍入模式（从 Hive 1.3.0、2.0.0 开始）返回舍入后的 BIGINT 值。也称为高斯舍入或银行家舍入。示例：bround(2.5) = 2，bround(3.5) = 4。
DOUBLE	bround(DOUBLE a, INT d)	Returns `a` rounded to `d` decimal places using HALF_EVEN rounding mode (as of Hive 1.3.0, 2.0.0). Example: bround(8.25, 1) = 8.2, bround(8.35, 1) = 8.4.
BIGINT	floor(DOUBLE a)	Returns the maximum `BIGINT` value that is equal to or less than `a`.
BIGINT	ceil(DOUBLE a), ceiling(DOUBLE a)	Returns the minimum BIGINT value that is equal to or greater than `a`.
DOUBLE	rand(), rand(INT seed)	Returns a random number (that changes from row to row) that is distributed uniformly from 0 to 1. Specifying the seed will make sure the generated random number sequence is deterministic.
DOUBLE	exp(DOUBLE a), exp(DECIMAL a)	Returns `e^a` where `e` is the base of the natural logarithm. Decimal version added in Hive 0.13.0.
DOUBLE	ln(DOUBLE a), ln(DECIMAL a)	Returns the natural logarithm of the argument `a`. Decimal version added in Hive 0.13.0.
DOUBLE	log10(DOUBLE a), log10(DECIMAL a)	Returns the base-10 logarithm of the argument `a`. Decimal version added in Hive 0.13.0.
DOUBLE	log2(DOUBLE a), log2(DECIMAL a)	Returns the base-2 logarithm of the argument `a`. Decimal version added in Hive 0.13.0.
DOUBLE	log(DOUBLE base, DOUBLE a)log(DECIMAL base, DECIMAL a)	Returns the base-`base` logarithm of the argument `a`. Decimal versions added in Hive 0.13.0.
DOUBLE	pow(DOUBLE a, DOUBLE p), power(DOUBLE a, DOUBLE p)	Returns `a^p`.
DOUBLE	sqrt(DOUBLE a), sqrt(DECIMAL a)	Returns the square root of `a`. Decimal version added in Hive 0.13.0.
STRING	bin(BIGINT a)	返回二进制 (see http://dev.mysql.com/doc/refman/5.0/en/string-functions.html#function_bin).
STRING	hex(BIGINT a) hex(STRING a) hex(BINARY a)	如果参数是 INT 或二进制，hex 将以十六进制格式的字符串返回该数字。否则，如果数字是字符串，它会将每个字符转换为其十六进制表示形式并返回结果字符串。(See http://dev.mysql.com/doc/refman/5.0/en/string-functions.html#function_hex, `BINARY` version as of Hive 0.12.0.)
BINARY	unhex(STRING a)	十六进制的逆转换。将每个字符解释为十六进制数，并转换为数字的字节表示形式。（自 Hive 0.12.0 开始的 BINARY 版本，用于返回字符串。）
STRING	conv(BIGINT num, INT from_base, INT to_base), conv(STRING num, INT from_base, INT to_base)	Converts a number from a given base to another (see http://dev.mysql.com/doc/refman/5.0/en/mathematical-functions.html#function_conv).
DOUBLE	abs(DOUBLE a)	Returns the absolute value.
INT or DOUBLE	pmod(INT a, INT b), pmod(DOUBLE a, DOUBLE b)	返回 `a mod b` 的正值.
DOUBLE	sin(DOUBLE a), sin(DECIMAL a)	Returns the sine of `a` (`a` is in radians). Decimal version added in Hive 0.13.0.
DOUBLE	asin(DOUBLE a), asin(DECIMAL a)	Returns the arc sin of `a` if -1<=a<=1 or NULL otherwise. Decimal version added in Hive 0.13.0.
DOUBLE	cos(DOUBLE a), cos(DECIMAL a)	Returns the cosine of `a` (`a` is in radians). Decimal version added in Hive 0.13.0.
DOUBLE	acos(DOUBLE a), acos(DECIMAL a)	Returns the arccosine of `a` if -1<=a<=1 or NULL otherwise. Decimal version added in Hive 0.13.0.
DOUBLE	tan(DOUBLE a), tan(DECIMAL a)	Returns the tangent of `a` (`a` is in radians). Decimal version added in Hive 0.13.0.
DOUBLE	atan(DOUBLE a), atan(DECIMAL a)	Returns the arctangent of `a`. Decimal version added in Hive 0.13.0.
DOUBLE	degrees(DOUBLE a), degrees(DECIMAL a)	Converts value of `a` from radians to degrees. Decimal version added in Hive 0.13.0.
DOUBLE	radians(DOUBLE a), radians(DOUBLE a)	Converts value of `a` from degrees to radians. Decimal version added in Hive 0.13.0.
INT or DOUBLE	positive(INT a), positive(DOUBLE a)	Returns `a`.
INT or DOUBLE	negative(INT a), negative(DOUBLE a)	Returns `-a`.
DOUBLE or INT	sign(DOUBLE a), sign(DECIMAL a)	Returns the sign of `a` as ‘1.0’ (if `a` is positive) or ‘-1.0’ (if `a` is negative), ‘0.0’ otherwise. The decimal version returns INT instead of DOUBLE. Decimal version added in Hive 0.13.0.
DOUBLE	e()	Returns the value of `e`.
DOUBLE	pi()	Returns the value of `pi`.
BIGINT	factorial(INT a)	Returns the factorial of `a` (as of Hive 1.2.0). Valid `a` is [0..20].
DOUBLE	cbrt(DOUBLE a)	Returns the cube root of `a` double value (as of Hive 1.2.0).
INTBIGINT	shiftleft(TINYINT\|SMALLINT\|INT a, INT b)shiftleft(BIGINT a, INT b)	按位左移（从 Hive 1.2.0 开始）。将 a b 位置向左移动。对于 tinyint、smallint 和 int a 返回 int。对于 bigint a 返回 bigint。
INTBIGINT	shiftright(TINYINT\|SMALLINT\|INT a, INT b)shiftright(BIGINT a, INT b)	按位右移（从 Hive 1.2.0 开始）。将 a b 位置向右移动。对于 tinyint、smallint 和 int a 返回 int。对于 bigint a 返回 bigint。
INTBIGINT	shiftrightunsigned(TINYINT\|SMALLINT\|INT a, INT b),shiftrightunsigned(BIGINT a, INT b)	按位无符号右移（从 Hive 1.2.0 开始）。将 a b 位置向右移动。对于 tinyint、smallint 和 int a 返回 int。对于 bigint a 返回 bigint。
T	greatest(T v1, T v2, …)	返回值列表中的最大值（从 Hive 1.1.0 开始）。当一个或多个参数为 NULL 时，固定为返回 NULL，并且放宽严格类型限制，与“>”运算符一致（从 Hive 2.0.0 开始）。
T	least(T v1, T v2, …)	返回值列表中的最小值（从 Hive 1.1.0 开始）。当一个或多个参数为 NULL 时，固定返回 NULL，并且放宽严格类型限制，与“<”运算符一致（从 Hive 2.0.0 开始）。
INT	width_bucket(NUMERIC expr, NUMERIC min_value, NUMERIC max_value, INT num_buckets)	通过将 expr 映射到第 i 个大小相等的 bucket 中，返回 0 到 num_buckets+1 之间的整数。Buckets 是通过将 [min_value, max_value] 分成大小相等的区域而形成的。如果 expr < min_value，则返回 1，如果 expr > max_value，则返回 num_buckets+1。See https://docs.oracle.com/cd/B19306_01/server.102/b14200/functions214.htm (从 Hive 3.0.0 开始)

十进制数据类型的数学函数和运算符

Version

The decimal datatype was introduced in Hive 0.11.0 (HIVE-2693).

All regular arithmetic operators (such as +, -, *, /) and relevant mathematical UDFs (Floor, Ceil, Round, and many more) have been updated to handle decimal types. For a list of supported UDFs, see Mathematical UDFs in Hive Data Types.

Collection Functions

The following built-in collection functions are supported in Hive:

Return Type	Name(Signature)	Description
int	size(Map<K.V>)	map元素数目
int	size(Array<T>)	数组元素数目
array<K>	map_keys(Map<K.V>)	返回map的key数组。
array<V>	map_values(Map<K.V>)	返回map的value数组。
boolean	array_contains(Array<T>, value)	如果数组包含值value，则返回 TRUE。
array<t>	sort_array(Array<T>)	根据数组元素的自然顺序对输入数组进行升序排序并返回（从 0.9.0 版本开始）。

类型转换函数

Hive 支持以下类型转换函数：

返回类型	函数签名	描述
binary	binary(string\|binary)	将字符串或binary数据转换成二进制数据
<type>	cast(expr as <type>)	将表达式 expr 的结果转换为目标类型<type> 。例如，cast(‘1’ as BIGINT) 将字符串 ‘1’ 转换为其整数表示。如果转换不成功，则返回 null。如果 cast(expr as boolean)，Hive 对非空字符串返回 true。

Date Functions

The following built-in date functions are supported in Hive:

Return Type	Name(Signature)	Description
string	from_unixtime(bigint unixtime[, string pattern])	Converts a number of seconds since epoch (1970-01-01 00:00:00 UTC) to a string representing the timestamp of that moment in the current time zone(using config “hive.local.time.zone”) using the specified pattern. If the pattern is missing the default is used (‘uuuu-MM-dd HH:mm:ss’ or yyyy-MM-dd HH:mm:ss’). Example: from_unixtime(0)=1970-01-01 00:00:00 (hive.local.time.zone=Etc/GMT)As of Hive 4.0.0 (HIVE-25576), the “hive.datetime.formatter” property can be used to control the underlying formatter implementation, and as a consequence the accepted patterns and their behavior. Prior versions always used https://docs.oracle.com/javase/8/docs/api/java/text/SimpleDateFormat.html as the underlying formatter.
bigint	unix_timestamp()	Gets current Unix timestamp in seconds. This function is not deterministic and its value is not fixed for the scope of a query execution, therefore prevents proper optimization of queries – this has been deprecated since 2.0 in favour of CURRENT_TIMESTAMP constant.
bigint	unix_timestamp(string date)	Converts a datetime string to unix time (seconds since epoch) using the default pattern(s). The default accepted patterns depend on the underlying formatter implementation. The datetime string does not contain a timezone so the conversion uses the local time zone as specified by “hive.local.time.zone” property. Returns null when the conversion fails. Example: unix_timestamp(‘2009-03-20 11:30:01’) = 1237573801As of Hive 4.0.0 (HIVE-25576), the “hive.datetime.formatter” property can be used to control the underlying formatter implementation, and as a consequence the accepted patterns and their behavior. Prior versions always used https://docs.oracle.com/javase/8/docs/api/java/text/SimpleDateFormat.html as the underlying formatter.
bigint	unix_timestamp(string date, string pattern)	Converts a datetime string to unix time (seconds since epoch) using the specified pattern. The accepted patterns and their behavior depend on the underlying formatter implementation. Returns null when the conversion fails. Example: unix_timestamp(‘2009-03-20’, ‘uuuu-MM-dd’) = 1237532400As of Hive 4.0.0 (HIVE-25576), the “hive.datetime.formatter” property can be used to control the underlying formatter implementation, and as a consequence the accepted patterns and their behavior. Prior versions always used https://docs.oracle.com/javase/8/docs/api/java/text/SimpleDateFormat.html as the underlying formatter.
pre 2.1.0: string2.1.0 on: date	to_date(string timestamp)	Returns the date part of a timestamp string (pre-Hive 2.1.0): to_date(“1970-01-01 00:00:00”) = “1970-01-01”. As of Hive 2.1.0, returns a date object.Prior to Hive 2.1.0 (HIVE-13248) the return type was a String because no Date type existed when the method was created.
int	year(string date)	Returns the year part of a date or a timestamp string: year(“1970-01-01 00:00:00”) = 1970, year(“1970-01-01”) = 1970.
int	quarter(date/timestamp/string)	Returns the quarter of the year for a date, timestamp, or string in the range 1 to 4 (as of Hive 1.3.0). Example: quarter(‘2015-04-08’) = 2.
int	month(string date)	Returns the month part of a date or a timestamp string: month(“1970-11-01 00:00:00”) = 11, month(“1970-11-01”) = 11.
int	day(string date) dayofmonth(date)	Returns the day part of a date or a timestamp string: day(“1970-11-01 00:00:00”) = 1, day(“1970-11-01”) = 1.
int	hour(string date)	Returns the hour of the timestamp: hour(‘2009-07-30 12:58:59′) = 12, hour(’12:58:59’) = 12.
int	minute(string date)	Returns the minute of the timestamp.
int	second(string date)	Returns the second of the timestamp.
int	weekofyear(string date)	Returns the week number of a timestamp string: weekofyear(“1970-11-01 00:00:00”) = 44, weekofyear(“1970-11-01”) = 44.
int	extract(field FROM source)	Retrieve fields such as days or hours from source (as of Hive 2.2.0). Source must be a date, timestamp, interval or a string that can be converted into either a date or timestamp. Supported fields include: day, dayofweek, hour, minute, month, quarter, second, week and year.Examples:select extract(month from “2016-10-20”) results in 10.select extract(hour from “2016-10-20 05:06:07”) results in 5.select extract(dayofweek from “2016-10-20 05:06:07”) results in 5.select extract(month from interval ‘1-3’ year to month) results in 3.select extract(minute from interval ‘3 12:20:30’ day to second) results in 20.
int	datediff(string enddate, string startdate)	Returns the number of days from startdate to enddate: datediff(‘2009-03-01’, ‘2009-02-27’) = 2.
pre 2.1.0: string2.1.0 on: date	date_add(date/timestamp/string startdate, tinyint/smallint/int days)	Adds a number of days to startdate: date_add(‘2008-12-31’, 1) = ‘2009-01-01’.Prior to Hive 2.1.0 (HIVE-13248) the return type was a String because no Date type existed when the method was created.
pre 2.1.0: string2.1.0 on: date	date_sub(date/timestamp/string startdate, tinyint/smallint/int days)	Subtracts a number of days to startdate: date_sub(‘2008-12-31’, 1) = ‘2008-12-30’.Prior to Hive 2.1.0 (HIVE-13248) the return type was a String because no Date type existed when the method was created.
timestamp	from_utc_timestamp({any primitive type} ts, string timezone)	Converts a timestamp* in UTC to a given timezone (as of Hive 0.8.0).* timestamp is a primitive type, including timestamp/date, tinyint/smallint/int/bigint, float/double and decimal. Fractional values are considered as seconds. Integer values are considered as milliseconds. For example, from_utc_timestamp(2592000.0,’PST’), from_utc_timestamp(2592000000,’PST’) and from_utc_timestamp(timestamp ‘1970-01-30 16:00:00′,’PST’) all return the timestamp 1970-01-30 08:00:00.
timestamp	to_utc_timestamp({any primitive type} ts, string timezone)	Converts a timestamp* in a given timezone to UTC (as of Hive 0.8.0).* timestamp is a primitive type, including timestamp/date, tinyint/smallint/int/bigint, float/double and decimal.Fractional values are considered as seconds. Integer values are considered as milliseconds. For example, to_utc_timestamp(2592000.0,’PST’), to_utc_timestamp(2592000000,’PST’) and to_utc_timestamp(timestamp ‘1970-01-30 16:00:00′,’PST’) all return the timestamp 1970-01-31 00:00:00.
date	current_date	Returns the current date at the start of query evaluation (as of Hive 1.2.0). All calls of current_date within the same query return the same value.
timestamp	current_timestamp	Returns the current timestamp at the start of query evaluation (as of Hive 1.2.0). All calls of current_timestamp within the same query return the same value.
string	add_months(string start_date, int num_months, output_date_format)	Returns the date that is num_months after start_date (as of Hive 1.1.0). start_date is a string, date or timestamp. num_months is an integer. If start_date is the last day of the month or if the resulting month has fewer days than the day component of start_date, then the result is the last day of the resulting month. Otherwise, the result has the same day component as start_date. The default output format is ‘yyyy-MM-dd’.Before Hive 4.0.0, the time part of the date is ignored.As of Hive 4.0.0, add_months supports an optional argument output_date_format, which accepts a String that represents a valid date format for the output. This allows to retain the time format in the output.For example :add_months(‘2009-08-31’, 1) returns ‘2009-09-30’. add_months(‘2017-12-31 14:15:16’, 2, ‘YYYY-MM-dd HH:mm:ss’) returns ‘2018-02-28 14:15:16’.
string	last_day(string date)	Returns the last day of the month which the date belongs to (as of Hive 1.1.0). date is a string in the format ‘yyyy-MM-dd HH:mm:ss’ or ‘yyyy-MM-dd’. The time part of date is ignored.
string	next_day(string start_date, string day_of_week)	Returns the first date which is later than start_date and named as day_of_week (as of Hive 1.2.0). start_date is a string/date/timestamp. day_of_week is 2 letters, 3 letters or full name of the day of the week (e.g. Mo, tue, FRIDAY). The time part of start_date is ignored. Example: next_day(‘2015-01-14’, ‘TU’) = 2015-01-20.
string	trunc(string date, string format)	Returns date truncated to the unit specified by the format (as of Hive 1.2.0). Supported formats: MONTH/MON/MM, YEAR/YYYY/YY. Example: trunc(‘2015-03-17’, ‘MM’) = 2015-03-01.
double	months_between(date1, date2)	Returns number of months between dates date1 and date2 (as of Hive 1.2.0). If date1 is later than date2, then the result is positive. If date1 is earlier than date2, then the result is negative. If date1 and date2 are either the same days of the month or both last days of months, then the result is always an integer. Otherwise the UDF calculates the fractional portion of the result based on a 31-day month and considers the difference in time components date1 and date2. date1 and date2 type can be date, timestamp or string in the format ‘yyyy-MM-dd’ or ‘yyyy-MM-dd HH:mm:ss’. The result is rounded to 8 decimal places. Example: months_between(‘1997-02-28 10:30:00’, ‘1996-10-30’) = 3.94959677
string	date_format(date/timestamp/string ts, string pattern)	Converts a date/timestamp/string to a value of string using the specified pattern (as of Hive 1.2.0). The accepted patterns and their behavior depend on the underlying formatter implementation. The pattern argument should be constant. Example: date_format(‘2015-04-08’, ‘y’) = ‘2015’.date_format can be used to implement other UDFs, e.g.:dayname(date) is date_format(date, ‘EEEE’)dayofyear(date) is date_format(date, ‘D’)As of Hive 4.0.0 ( HIVE-27673 – Configurable datetime formatter for date_format CLOSED ), the “hive.datetime.formatter” property can be used to control the underlying formatter implementation, and as a consequence the accepted patterns and their behavior. Prior versions always used https://docs.oracle.com/javase/8/docs/api/java/text/SimpleDateFormat.html as the underlying formatter.

Conditional Functions

Return Type	Name(Signature)	Description
T	if(boolean testCondition, T valueTrue, T valueFalseOrNull)	Returns valueTrue when testCondition is true, returns valueFalseOrNull otherwise.
boolean	isnull( a )	Returns true if a is NULL and false otherwise.
boolean	isnotnull ( a )	Returns true if a is not NULL and false otherwise.
T	nvl(T value, T default_value)	Returns default value if value is null else returns value (as of HIve 0.11).
T	COALESCE(T v1, T v2, …)	Returns the first v that is not NULL, or NULL if all v’s are NULL.
T	CASE a WHEN b THEN c [WHEN d THEN e]* [ELSE f] END	When a = b, returns c; when a = d, returns e; else returns f.
T	CASE WHEN a THEN b [WHEN c THEN d]* [ELSE e] END	When a = true, returns b; when c = true, returns d; else returns e.
T	nullif( a, b )	Returns NULL if a=b; otherwise returns a (as of Hive 2.3.0).Shorthand for: CASE WHEN a = b then NULL else a
void	assert_true(boolean condition)	Throw an exception if ‘condition’ is not true, otherwise return null (as of Hive 0.8.0). For example, select assert_true (2<1).

String Functions

The following built-in String functions are supported in Hive:

Return Type	Name(Signature)	Description
int	ascii(string str)	Returns the numeric value of the first character of str.
string	base64(binary bin)	Converts the argument from binary to a base 64 string (as of Hive 0.12.0).
int	character_length(string str)	Returns the number of UTF-8 characters contained in str (as of Hive 2.2.0). The function char_length is shorthand for this function.
string	chr(bigint\|double A)	Returns the ASCII character having the binary equivalent to A (as of Hive 1.3.0 and 2.1.0). If A is larger than 256 the result is equivalent to chr(A % 256). Example: select chr(88); returns “X”.
string	concat(string\|binary A, string\|binary B…)	Returns the string or bytes resulting from concatenating the strings or bytes passed in as parameters in order. For example, concat(‘foo’, ‘bar’) results in ‘foobar’. Note that this function can take any number of input strings.
array<struct<string,double>>	context_ngrams(array<array<string>>, array<string>, int K, int pf)	Returns the top-k contextual N-grams from a set of tokenized sentences, given a string of “context”. See StatisticsAndDataMining for more information.
string	concat_ws(string SEP, string A, string B…)	Like concat() above, but with custom separator SEP.
string	concat_ws(string SEP, array<string>)	Like concat_ws() above, but taking an array of strings. (as of Hive 0.9.0)
string	decode(binary bin, string charset)	Decodes the first argument into a String using the provided character set (one of ‘US-ASCII’, ‘ISO-8859-1’, ‘UTF-8’, ‘UTF-16BE’, ‘UTF-16LE’, ‘UTF-16’). If either argument is null, the result will also be null. (As of Hive 0.12.0.)
string	elt(N int,str1 string,str2 string,str3 string,…)	Return string at index number. For example elt(2,’hello’,’world’) returns ‘world’. Returns NULL if N is less than 1 or greater than the number of arguments.(see https://dev.mysql.com/doc/refman/5.7/en/string-functions.html#function_elt)
binary	encode(string src, string charset)	Encodes the first argument into a BINARY using the provided character set (one of ‘US-ASCII’, ‘ISO-8859-1’, ‘UTF-8’, ‘UTF-16BE’, ‘UTF-16LE’, ‘UTF-16’). If either argument is null, the result will also be null. (As of Hive 0.12.0.)
int	field(val T,val1 T,val2 T,val3 T,…)	Returns the index of val in the val1,val2,val3,… list or 0 if not found. For example field(‘world’,’say’,’hello’,’world’) returns 3. All primitive types are supported, arguments are compared using str.equals(x). If val is NULL, the return value is 0.(see https://dev.mysql.com/doc/refman/5.7/en/string-functions.html#function_field)
int	find_in_set(string str, string strList)	Returns the first occurance of str in strList where strList is a comma-delimited string. Returns null if either argument is null. Returns 0 if the first argument contains any commas. For example, find_in_set(‘ab’, ‘abc,b,ab,c,def’) returns 3.
string	format_number(number x, int d)	Formats the number X to a format like ‘#,###,###.##’, rounded to D decimal places, and returns the result as a string. If D is 0, the result has no decimal point or fractional part. (As of Hive 0.10.0; bug with float types fixed in Hive 0.14.0, decimal type support added in Hive 0.14.0)
string	get_json_object(string json_string, string path)	Extracts json object from a json string based on json path specified, and returns json string of the extracted json object. It will return null if the input json string is invalid. *NOTE: The json path can only have the characters [0-9a-z_], i.e., no upper-case or special characters. Also, the keys cannot start with numbers.*** This is due to restrictions on Hive column names.
boolean	in_file(string str, string filename)	Returns true if the string str appears as an entire line in filename.
int	instr(string str, string substr)	Returns the position of the first occurrence of `substr` in `str`. Returns `null` if either of the arguments are `null` and returns `0` if `substr` could not be found in `str`. Be aware that this is not zero based. The first character in `str` has index 1.
int	length(string A)	Returns the length of the string.
int	locate(string substr, string str[, int pos])	Returns the position of the first occurrence of substr in str after position pos.
string	lower(string A) lcase(string A)	Returns the string resulting from converting all characters of B to lower case. For example, lower(‘fOoBaR’) results in ‘foobar’.
string	lpad(string str, int len, string pad)	Returns str, left-padded with pad to a length of len. If str is longer than len, the return value is shortened to len characters. In case of empty pad string, the return value is null.
string	ltrim(string A)	Returns the string resulting from trimming spaces from the beginning(left hand side) of A. For example, ltrim(‘ foobar ‘) results in ‘foobar ‘.
array<struct<string,double>>	ngrams(array<array<string>>, int N, int K, int pf)	Returns the top-k N-grams from a set of tokenized sentences, such as those returned by the sentences() UDAF. See StatisticsAndDataMining for more information.
int	octet_length(string str)	Returns the number of octets required to hold the string str in UTF-8 encoding (since Hive 2.2.0). Note that octet_length(str) can be larger than character_length(str).
string	parse_url(string urlString, string partToExtract [, string keyToExtract])	Returns the specified part from the URL. Valid values for partToExtract include HOST, PATH, QUERY, REF, PROTOCOL, AUTHORITY, FILE, and USERINFO. For example, parse_url(‘http://facebook.com/path1/p.php?k1=v1&k2=v2#Ref1’, ‘HOST’) returns ‘facebook.com’. Also a value of a particular key in QUERY can be extracted by providing the key as the third argument, for example, parse_url(‘http://facebook.com/path1/p.php?k1=v1&k2=v2#Ref1’, ‘QUERY’, ‘k1’) returns ‘v1’.
string	printf(String format, Obj… args)	Returns the input formatted according do printf-style format strings (as of Hive 0.9.0).
string	quote(String text)	Returns the quoted string (Includes escape character for any single quotes HIVE-4.0.0)InputOutputNULLNULLDONT’DONT’DON’T’DON\’T’
string	regexp_extract(string subject, string pattern, int index)	返回使用正则表达式提取的字符串。例如，regexp_extract(‘foothebar’, ‘foo(.*?)(bar)’, 2) 返回“bar”。请注意，使用预定义字符类时需要小心：正则表达式中一个反斜杠要替换成两个反斜杠，例如使用’\s’作为第二个参数将匹配字母 s；’\\s’才会匹配空格，等等。’index’ 参数是 Java 正则表达式 Matcher group() 方法索引，0表示整个字符串，大于0的整数i表示匹配第i个括号。请参阅文档 docs/api/java/util/regex/Matcher.html
string	regexp_replace(string INITIAL_STRING, string PATTERN, string REPLACEMENT)	返回用 REPLACEMENT 替换 INITIAL_STRING 中与 PATTERN 中定义的 java 正则表达式语法匹配的所有子字符串后得到的字符串。例如，regexp_replace(“foobar”, “oo\|ar”, “”) 返回”fb”。请注意，使用预定义字符类时需要小心：正则表达式中一个反斜杠要替换成两个反斜杠，例如使用’\s’作为第二个参数将匹配字母 s；’\\s’才会匹配空格，等等。
string	repeat(string str, int n)	Repeats str n times.
string	replace(string A, string OLD, string NEW)	Returns the string A with all non-overlapping occurrences of OLD replaced with NEW (as of Hive 1.3.0 and 2.1.0). Example: select replace(“ababab”, “abab”, “Z”); returns “Zab”.
string	reverse(string A)	Returns the reversed string.
string	rpad(string str, int len, string pad)	Returns str, right-padded with pad to a length of len. If str is longer than len, the return value is shortened to len characters. In case of empty pad string, the return value is null.
string	rtrim(string A)	Returns the string resulting from trimming spaces from the end(right hand side) of A. For example, rtrim(‘ foobar ‘) results in ‘ foobar’.
array<array<string>>	sentences(string str, string lang, string locale)	Tokenizes a string of natural language text into words and sentences, where each sentence is broken at the appropriate sentence boundary and returned as an array of words. The ‘lang’ and ‘locale’ are optional arguments. For example, sentences(‘Hello there! How are you?’) returns ( (“Hello”, “there”), (“How”, “are”, “you”) ).
string	space(int n)	Returns a string of n spaces.
array	split(string str, string pat)	Splits str around pat (pat is a regular expression).
map<string,string>	str_to_map(text[, delimiter1, delimiter2])	Splits text into key-value pairs using two delimiters. Delimiter1 separates text into K-V pairs, and Delimiter2 splits each K-V pair. Default delimiters are ‘,’ for delimiter1 and ‘:’ for delimiter2.
string	substr(string\|binary A, int start) substring(string\|binary A, int start)	Returns the substring or slice of the byte array of A starting from start position till the end of string A. For example, substr(‘foobar’, 4) results in ‘bar’ (see [http://dev.mysql.com/doc/refman/5.0/en/string-functions.html#function_substr]).
string	substr(string\|binary A, int start, int len) substring(string\|binary A, int start, int len)	Returns the substring or slice of the byte array of A starting from start position with length len. For example, substr(‘foobar’, 4, 1) results in ‘b’ (see [http://dev.mysql.com/doc/refman/5.0/en/string-functions.html#function_substr]).
string	substring_index(string A, string delim, int count)	Returns the substring from string A before count occurrences of the delimiter delim (as of Hive 1.3.0). If count is positive, everything to the left of the final delimiter (counting from the left) is returned. If count is negative, everything to the right of the final delimiter (counting from the right) is returned. Substring_index performs a case-sensitive match when searching for delim. Example: substring_index(‘www.apache.org’, ‘.’, 2) = ‘www.apache’.
string	translate(string\|char\|varchar input, string\|char\|varchar from, string\|char\|varchar to)	Translates the input string by replacing the characters present in the `from` string with the corresponding characters in the `to` string. This is similar to the `translate` function in PostgreSQL. If any of the parameters to this UDF are NULL, the result is NULL as well. (Available as of Hive 0.10.0, for string types)Char/varchar support added as of Hive 0.14.0.
string	trim(string A)	Returns the string resulting from trimming spaces from both ends of A. For example, trim(‘ foobar ‘) results in ‘foobar’
binary	unbase64(string str)	Converts the argument from a base 64 string to BINARY. (As of Hive 0.12.0.)
string	upper(string A) ucase(string A)	Returns the string resulting from converting all characters of A to upper case. For example, upper(‘fOoBaR’) results in ‘FOOBAR’.
string	initcap(string A)	Returns string, with the first letter of each word in uppercase, all other letters in lowercase. Words are delimited by whitespace. (As of Hive 1.1.0.)
int	levenshtein(string A, string B)	Returns the Levenshtein distance between two strings (as of Hive 1.2.0). For example, levenshtein(‘kitten’, ‘sitting’) results in 3.
string	soundex(string A)	Returns soundex code of the string (as of Hive 1.2.0). For example, soundex(‘Miller’) results in M460.

Data Masking Functions

The following built-in data masking functions are supported in Hive:

Return Type	Name(Signature)	Description
string	mask(string str[, string upper[, string lower[, string number]]])	Returns a masked version of str (as of Hive 2.1.0). By default, upper case letters are converted to “X”, lower case letters are converted to “x” and numbers are converted to “n”. For example mask(“abcd-EFGH-8765-4321”) results in xxxx-XXXX-nnnn-nnnn. You can override the characters used in the mask by supplying additional arguments: the second argument controls the mask character for upper case letters, the third argument for lower case letters and the fourth argument for numbers. For example, mask(“abcd-EFGH-8765-4321”, “U”, “l”, “#”) results in llll-UUUU-####-####.
string	mask_first_n(string str[, int n])	Returns a masked version of str with the first n values masked (as of Hive 2.1.0). Upper case letters are converted to “X”, lower case letters are converted to “x” and numbers are converted to “n”. For example, mask_first_n(“1234-5678-8765-4321”, 4) results in nnnn-5678-8765-4321.
string	mask_last_n(string str[, int n])	Returns a masked version of str with the last n values masked (as of Hive 2.1.0). Upper case letters are converted to “X”, lower case letters are converted to “x” and numbers are converted to “n”. For example, mask_last_n(“1234-5678-8765-4321”, 4) results in 1234-5678-8765-nnnn.
string	mask_show_first_n(string str[, int n])	Returns a masked version of str, showing the first n characters unmasked (as of Hive 2.1.0). Upper case letters are converted to “X”, lower case letters are converted to “x” and numbers are converted to “n”. For example, mask_show_first_n(“1234-5678-8765-4321”, 4) results in 1234-nnnn-nnnn-nnnn.
string	mask_show_last_n(string str[, int n])	Returns a masked version of str, showing the last n characters unmasked (as of Hive 2.1.0). Upper case letters are converted to “X”, lower case letters are converted to “x” and numbers are converted to “n”. For example, mask_show_last_n(“1234-5678-8765-4321”, 4) results in nnnn-nnnn-nnnn-4321.
string	mask_hash(string\|char\|varchar str)	Returns a hashed value based on str (as of Hive 2.1.0). The hash is consistent and can be used to join masked values together across tables. This function returns null for non-string types.

Misc. Functions

Return Type	Name(Signature)	Description
varies	java_method(class, method[, arg1[, arg2..]])	Synonym for `reflect`. (As of Hive 0.9.0.)
varies	reflect(class, method[, arg1[, arg2..]])	Calls a Java method by matching the argument signature, using reflection. (As of Hive 0.7.0.) See Reflect (Generic) UDF for examples.
int	hash(a1[, a2…])	Returns a hash value of the arguments. (As of Hive 0.4.)
string	current_user()	Returns current user name from the configured authenticator manager (as of Hive 1.2.0). Could be the same as the user provided when connecting, but with some authentication managers (for example HadoopDefaultAuthenticator) it could be different.
string	logged_in_user()	Returns current user name from the session state (as of Hive 2.2.0). This is the username provided when connecting to Hive.
string	current_database()	Returns current database name (as of Hive 0.13.0).
string	md5(string/binary)	Calculates an MD5 128-bit checksum for the string or binary (as of Hive 1.3.0). The value is returned as a string of 32 hex digits, or NULL if the argument was NULL. Example: md5(‘ABC’) = ‘902fbdd2b1df0c4f70b4a5d23525e932’.
string	sha1(string/binary)sha(string/binary)	Calculates the SHA-1 digest for string or binary and returns the value as a hex string (as of Hive 1.3.0). Example: sha1(‘ABC’) = ‘3c01bdbb26f358bab27f267924aa2c9a03fcfdb8’.
bigint	crc32(string/binary)	Computes a cyclic redundancy check value for string or binary argument and returns bigint value (as of Hive 1.3.0). Example: crc32(‘ABC’) = 2743272264.
string	sha2(string/binary, int)	Calculates the SHA-2 family of hash functions (SHA-224, SHA-256, SHA-384, and SHA-512) (as of Hive 1.3.0). The first argument is the string or binary to be hashed. The second argument indicates the desired bit length of the result, which must have a value of 224, 256, 384, 512, or 0 (which is equivalent to 256). SHA-224 is supported starting from Java 8. If either argument is NULL or the hash length is not one of the permitted values, the return value is NULL. Example: sha2(‘ABC’, 256) = ‘b5d4045c3f466fa91fe2cc6abe79232a1a57cdf104f7a26e716e0a1e2789df78’.
binary	aes_encrypt(input string/binary, key string/binary)	Encrypt input using AES (as of Hive 1.3.0). Key lengths of 128, 192 or 256 bits can be used. 192 and 256 bits keys can be used if Java Cryptography Extension (JCE) Unlimited Strength Jurisdiction Policy Files are installed. If either argument is NULL or the key length is not one of the permitted values, the return value is NULL. Example: base64(aes_encrypt(‘ABC’, ‘1234567890123456’)) = ‘y6Ss+zCYObpCbgfWfyNWTw==’.
binary	aes_decrypt(input binary, key string/binary)	Decrypt input using AES (as of Hive 1.3.0). Key lengths of 128, 192 or 256 bits can be used. 192 and 256 bits keys can be used if Java Cryptography Extension (JCE) Unlimited Strength Jurisdiction Policy Files are installed. If either argument is NULL or the key length is not one of the permitted values, the return value is NULL. Example: aes_decrypt(unbase64(‘y6Ss+zCYObpCbgfWfyNWTw==’), ‘1234567890123456’) = ‘ABC’.
string	version()	Returns the Hive version (as of Hive 2.1.0). The string contains 2 fields, the first being a build number and the second being a build hash. Example: “select version();” might return “2.1.0.2.5.0.0-1245 r027527b9c5ce1a3d7d0b6d2e6de2378fb0c39232”. Actual results will depend on your build.
bigint	surrogate_key([write_id_bits, task_id_bits])	Automatically generate numerical Ids for rows as you enter data into a table. Can only be used as default value for acid or insert-only tables.

xpath

The following functions are described in LanguageManual XPathUDF:

xpath, xpath_short, xpath_int, xpath_long, xpath_float, xpath_double, xpath_number, xpath_string

get_json_object

A limited version of JSONPath is supported:

$ : Root object
. : Child operator
[] : Subscript operator for array
* : Wildcard for []

Syntax not supported that’s worth noticing:

: Zero length string as key
.. : Recursive descent
@ : Current object/element
() : Script expression
?() : Filter (script) expression.
[,] : Union operator
[start:end.step] : array slice operator

Example: src_json table is a single column (json), single row table:

+----+ json+----+{"store": {"fruit":\[{"weight":8,"type":"apple"},{"weight":9,"type":"pear"}], "bicycle":{"price":19.95,"color":"red"} }, "email":"amy@only_for_json_udf_test.net", "owner":"amy"}+----+

The fields of the json object can be extracted using these queries:

hive> SELECT get_json_object(src_json.json, '$.owner') FROM src_json;amyhive> SELECT get_json_object(src_json.json, '$.store.fruit\[0]') FROM src_json;{"weight":8,"type":"apple"}hive> SELECT get_json_object(src_json.json, '$.non_exist_key') FROM src_json;NULL

Built-in Aggregate Functions (UDAF)

The following built-in aggregate functions are supported in Hive:

Return Type	Name(Signature)	Description
BIGINT	count(*), count(expr), count(DISTINCT expr[, expr…])	count(*) – Returns the total number of retrieved rows, including rows containing NULL values.count(expr) – Returns the number of rows for which the supplied expression is non-NULL.count(DISTINCT expr[, expr]) – Returns the number of rows for which the supplied expression(s) are unique and non-NULL. Execution of this can be optimized with hive.optimize.distinct.rewrite.
DOUBLE	sum(col), sum(DISTINCT col)	Returns the sum of the elements in the group or the sum of the distinct values of the column in the group.
DOUBLE	avg(col), avg(DISTINCT col)	Returns the average of the elements in the group or the average of the distinct values of the column in the group.
DOUBLE	min(col)	Returns the minimum of the column in the group.
DOUBLE	max(col)	Returns the maximum value of the column in the group.
DOUBLE	variance(col), var_pop(col)	Returns the variance of a numeric column in the group.
DOUBLE	var_samp(col)	Returns the unbiased sample variance of a numeric column in the group.
DOUBLE	stddev_pop(col)	Returns the standard deviation of a numeric column in the group.
DOUBLE	stddev_samp(col)	Returns the unbiased sample standard deviation of a numeric column in the group.
DOUBLE	covar_pop(col1, col2)	Returns the population covariance of a pair of numeric columns in the group.
DOUBLE	covar_samp(col1, col2)	Returns the sample covariance of a pair of a numeric columns in the group.
DOUBLE	corr(col1, col2)	Returns the Pearson coefficient of correlation of a pair of a numeric columns in the group.
DOUBLE	percentile(BIGINT col, p)	Returns the exact p^th percentile of a column in the group (does not work with floating point types). p must be between 0 and 1. NOTE: A true percentile can only be computed for integer values. Use PERCENTILE_APPROX if your input is non-integral.
array<double>	percentile(BIGINT col, array(p₁ [, p₂]…))	Returns the exact percentiles p₁, p₂, … of a column in the group (does not work with floating point types). p_i must be between 0 and 1. NOTE: A true percentile can only be computed for integer values. Use PERCENTILE_APPROX if your input is non-integral.
DOUBLE	percentile_approx(DOUBLE col, p [, B])	Returns an approximate p^th percentile of a numeric column (including floating point types) in the group. The B parameter controls approximation accuracy at the cost of memory. Higher values yield better approximations, and the default is 10,000. When the number of distinct values in col is smaller than B, this gives an exact percentile value.
array<double>	percentile_approx(DOUBLE col, array(p₁ [, p₂]…) [, B])	Same as above, but accepts and returns an array of percentile values instead of a single one.
double	regr_avgx(independent, dependent)	Equivalent to avg(dependent). As of Hive 2.2.0.
double	regr_avgy(independent, dependent)	Equivalent to avg(independent). As of Hive 2.2.0.
double	regr_count(independent, dependent)	Returns the number of non-null pairs used to fit the linear regression line. As of Hive 2.2.0.
double	regr_intercept(independent, dependent)	Returns the y-intercept of the linear regression line, i.e. the value of b in the equation dependent = a * independent + b. As of Hive 2.2.0.
double	regr_r2(independent, dependent)	Returns the coefficient of determination for the regression. As of Hive 2.2.0.
double	regr_slope(independent, dependent)	Returns the slope of the linear regression line, i.e. the value of a in the equation dependent = a * independent + b. As of Hive 2.2.0.
double	regr_sxx(independent, dependent)	Equivalent to regr_count(independent, dependent) * var_pop(dependent). As of Hive 2.2.0.
double	regr_sxy(independent, dependent)	Equivalent to regr_count(independent, dependent) * covar_pop(independent, dependent). As of Hive 2.2.0.
double	regr_syy(independent, dependent)	Equivalent to regr_count(independent, dependent) * var_pop(independent). As of Hive 2.2.0.
array<struct {`'x','y'`}>	histogram_numeric(col, b)	Computes a histogram of a numeric column in the group using b non-uniformly spaced bins. The output is an array of size b of double-valued (x,y) coordinates that represent the bin centers and heights
array	collect_set(col)	Returns a set of objects with duplicate elements eliminated.
array	collect_list(col)	Returns a list of objects with duplicates. (As of Hive 0.13.0.)
INTEGER	ntile(INTEGER x)	Divides an ordered partition into `x` groups called buckets and assigns a bucket number to each row in the partition. This allows easy calculation of tertiles, quartiles, deciles, percentiles and other common summary statistics. (As of Hive 0.11.0.)

Built-in Table-Generating Functions (UDTF)

Normal user-defined functions, such as concat(), take in a single input row and output a single output row. In contrast, table-generating functions transform a single input row to multiple output rows.

Row-set columns types	Name(Signature)	Description
T	explode(ARRAY<T> a)	Explodes an array to multiple rows. Returns a row-set with a single column (col), one row for each element from the array.
T_key,T_value	explode(MAP<T_key,T_value> m)	Explodes a map to multiple rows. Returns a row-set with a two columns (key,value) , one row for each key-value pair from the input map. (As of Hive 0.8.0.).
int,T	posexplode(ARRAY<T> a)	Explodes an array to multiple rows with additional positional column of int type (position of items in the original array, starting with 0). Returns a row-set with two columns (pos,val), one row for each element from the array.
T₁,…,T_n	inline(ARRAY<STRUCT<f₁:T₁,…,f_n:T_n>> a)	Explodes an array of structs to multiple rows. Returns a row-set with N columns (N = number of top level elements in the struct), one row per struct from the array. (As of Hive 0.10.)
T₁,…,T_n/r	stack(int r,T₁V₁,…,T_n/rV_n)	Breaks up n values V₁,…,V_n into r rows. Each row will have n/r columns. r must be constant.

string₁,…,string_n	json_tuple(string jsonStr,string k₁,…,string k_n)	Takes JSON string and a set of n keys, and returns a tuple of n values. This is a more efficient version of the `get_json_object` UDF because it can get multiple keys with just one call.
string ₁,…,string_n	parse_url_tuple(string urlStr,string p₁,…,string p_n)	Takes URL string and a set of n URL parts, and returns a tuple of n values. This is similar to the `parse_url()` UDF but can extract multiple parts at once out of a URL. Valid part names are: HOST, PATH, QUERY, REF, PROTOCOL, AUTHORITY, FILE, USERINFO, QUERY:<KEY>.

Usage Examples

explode (array)

select explode(array('A','B','C'));select explode(array('A','B','C')) as col;select tf.* from (select 0) t lateral view explode(array('A','B','C')) tf;select tf.* from (select 0) t lateral view explode(array('A','B','C')) tf as col;

explode (map)

select explode(map('A',10,'B',20,'C',30));select explode(map('A',10,'B',20,'C',30)) as (key,value);select tf.* from (select 0) t lateral view explode(map('A',10,'B',20,'C',30)) tf;select tf.* from (select 0) t lateral view explode(map('A',10,'B',20,'C',30)) tf as key,value;

posexplode (array)

select posexplode(array('A','B','C'));select posexplode(array('A','B','C')) as (pos,val);select tf.* from (select 0) t lateral view posexplode(array('A','B','C')) tf;select tf.* from (select 0) t lateral view posexplode(array('A','B','C')) tf as pos,val;

inline (array of structs)

select inline(array(struct('A',10,date '2015-01-01'),struct('B',20,date '2016-02-02')));select inline(array(struct('A',10,date '2015-01-01'),struct('B',20,date '2016-02-02'))) as (col1,col2,col3);select tf.* from (select 0) t lateral view inline(array(struct('A',10,date '2015-01-01'),struct('B',20,date '2016-02-02'))) tf;select tf.* from (select 0) t lateral view inline(array(struct('A',10,date '2015-01-01'),struct('B',20,date '2016-02-02'))) tf as col1,col2,col3;

stack (values)

select stack(2,'A',10,date '2015-01-01','B',20,date '2016-01-01');select stack(2,'A',10,date '2015-01-01','B',20,date '2016-01-01') as (col0,col1,col2);select tf.* from (select 0) t lateral view stack(2,'A',10,date '2015-01-01','B',20,date '2016-01-01') tf;select tf.* from (select 0) t lateral view stack(2,'A',10,date '2015-01-01','B',20,date '2016-01-01') tf as col0,col1,col2;

Using the syntax “SELECT udtf(col) AS colAlias…” has a few limitations:

No other expressions are allowed in SELECT
- SELECT pageid, explode(adid_list) AS myCol… is not supported
UDTF’s can’t be nested
- SELECT explode(explode(adid_list)) AS myCol… is not supported
GROUP BY / CLUSTER BY / DISTRIBUTE BY / SORT BY is not supported
- SELECT explode(adid_list) AS myCol … GROUP BY myCol is not supported

Please see LanguageManual LateralView for an alternative syntax that does not have these limitations.

Also see Writing UDTFs if you want to create a custom UDTF.

explode

explode() takes in an array (or a map) as an input and outputs the elements of the array (map) as separate rows. UDTFs can be used in the SELECT expression list and as a part of LATERAL VIEW.

As an example of using explode() in the SELECT expression list, consider a table named myTable that has a single column (myCol) and two rows:

Array<int> myCol
[100,200,300]
[400,500,600]

Then running the query:

SELECT explode(myCol) AS myNewCol FROM myTable;

will produce:

(int) myNewCol
100
200
300
400
500
600

The usage with Maps is similar:

SELECT explode(myMap) AS (myMapKey, myMapValue) FROM myMapTable;

posexplode

Version

Available as of Hive 0.13.0. See HIVE-4943.

posexplode() is similar to explode but instead of just returning the elements of the array it returns the element as well as its position in the original array.

As an example of using posexplode() in the SELECT expression list, consider a table named myTable that has a single column (myCol) and two rows:

Array<int> myCol
[100,200,300]
[400,500,600]

Then running the query:

SELECT posexplode(myCol) AS pos, myNewCol FROM myTable;

will produce:

(int) pos	(int) myNewCol
1	100
2	200
3	300
1	400
2	500
3	600

json_tuple

A new json_tuple() UDTF is introduced in Hive 0.7. It takes a set of names (keys) and a JSON string, and returns a tuple of values using one function. This is much more efficient than calling GET_JSON_OBJECT to retrieve more than one key from a single JSON string. In any case where a single JSON string would be parsed more than once, your query will be more efficient if you parse it once, which is what JSON_TUPLE is for. As JSON_TUPLE is a UDTF, you will need to use the LATERAL VIEW syntax in order to achieve the same goal.

For example,

select a.timestamp, get_json_object(a.appevents, '$.eventid'), get_json_object(a.appenvets, '$.eventname') from log a;

should be changed to:

select a.timestamp, b.*from log a lateral view json_tuple(a.appevent, 'eventid', 'eventname') b as f1, f2;

parse_url_tuple

The parse_url_tuple() UDTF is similar to parse_url(), but can extract multiple parts of a given URL, returning the data in a tuple. Values for a particular key in QUERY can be extracted by appending a colon and the key to the partToExtract argument, for example, parse_url_tuple(‘http://facebook.com/path1/p.php?k1=v1&k2=v2#Ref1’, ‘QUERY:k1’, ‘QUERY:k2’) returns a tuple with values of ‘v1′,’v2’. This is more efficient than calling parse_url() multiple times. All the input parameters and output column types are string.

SELECT b.*FROM src LATERAL VIEW parse_url_tuple(fullurl, 'HOST', 'PATH', 'QUERY', 'QUERY:id') b as host, path, query, query_id LIMIT 1;

GROUPing and SORTing on f(column)

A typical OLAP pattern is that you have a timestamp column and you want to group by daily or other less granular date windows than by second. So you might want to select concat(year(dt),month(dt)) and then group on that concat(). But if you attempt to GROUP BY or SORT BY a column on which you’ve applied a function and alias, like this:

select f(col) as fc, count(*) from table_name group by fc;

you will get an error:

FAILED: Error in semantic analysis: line 1:69 Invalid Table Alias or Column Reference fc

because you are not able to GROUP BY or SORT BY a column alias on which a function has been applied. There are two workarounds. First, you can reformulate this query with subqueries, which is somewhat complicated:

select sq.fc,col1,col2,...,colN,count(*) from (select f(col) as fc,col1,col2,...,colN from table_name) sq group by sq.fc,col1,col2,...,colN;

Or you can make sure not to use a column alias, which is simpler:

select f(col) as fc, count(*) from table_name group by f(col);

Contact Tim Ellis (tellis) at RiotGames dot com if you would like to discuss this in further detail.

Utility Functions

Function Name	Return Type	Description	To Run
version	String	Provides the Hive version Details (Package built version)	select version();
buildversion	String	Extension of the Version function which includes the checksum	select buildversion();

UDF internals

The context of a UDF’s evaluate method is one row at a time. A simple invocation of a UDF like

SELECT length(string_col) FROM table_name;

would evaluate the length of each of the string_col’s values in the map portion of the job. The side effect of the UDF being evaluated on the map-side is that you can’t control the order of rows which get sent to the mapper. It is the same order in which the file split sent to the mapper gets deserialized. Any reduce side operation (such as SORT BY, ORDER BY, regular JOIN, etc.) would apply to the UDFs output as if it is just another column of the table. This is fine since the context of the UDF’s evaluate method is meant to be one row at a time.

If you would like to control which rows get sent to the same UDF (and possibly in what order), you will have the urge to make the UDF evaluate during the reduce phase. This is achievable by making use of DISTRIBUTE BY, DISTRIBUTE BY + SORT BY, CLUSTER BY. An example query would be:

SELECT reducer_udf(my_col, distribute_col, sort_col) FROM

(SELECT my_col, distribute_col, sort_col FROM table_name DISTRIBUTE BY distribute_col SORT BY distribute_col, sort_col) t

However, one could argue that the very premise of your requirement to control the set of rows sent to the same UDF is to do aggregation in that UDF. In such a case, using a User Defined Aggregate Function (UDAF) is a better choice. You can read more about writing a UDAF here. Alternatively, you can user a custom reduce script to accomplish the same using Hive’s Transform functionality. Both of these options would do aggregations on the reduce side.

Creating Custom UDFs

For information about how to create a custom UDF, see Hive Plugins and Create Function.

select explode(array(‘A’,’B’,’C’));select explode(array(‘A’,’B’,’C’)) as col;select tf.* from (select 0) t lateral view explode(array(‘A’,’B’,’C’)) tf;select tf.* from (select 0) t lateral view explode(array(‘A’,’B’,’C’)) tf as col;

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