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Other Functions
hostName()
Returns the name of the host on which this function was executed. If the function executes on a remote server (distributed processing), the remote server name is returned. If the function executes in the context of a distributed table, it generates a normal column with values relevant to each shard. Otherwise it produces a constant value.
getMacro
Returns a named value from the macros section of the server configuration.
Syntax
getMacro(name);
Arguments
name
— Macro name to retrieve from the<macros>
section. String.
Returned value
- Value of the specified macro.
Type: String.
Example
Example <macros>
section in the server configuration file:
<macros>
<test>Value</test>
</macros>
Query:
SELECT getMacro('test');
Result:
┌─getMacro('test')─┐
│ Value │
└──────────────────┘
The same value can be retrieved as follows:
SELECT * FROM system.macros
WHERE macro = 'test';
┌─macro─┬─substitution─┐
│ test │ Value │
└───────┴──────────────┘
FQDN
Returns the fully qualified domain name of the ClickHouse server.
Syntax
fqdn();
This function is case-insensitive.
Returned value
- String with the fully qualified domain name.
Type: String
.
Example
SELECT FQDN();
Result:
┌─FQDN()──────────────────────────┐
│ clickhouse.ru-central1.internal │
└─────────────────────────────────┘
basename
Extracts the tail of a string following its last slash or backslash. This function if often used to extract the filename from a path.
basename(expr)
Arguments
expr
— A value of type String. Backslashes must be escaped.
Returned Value
A string that contains:
- The tail of the input string after its last slash or backslash. If the input string ends with a slash or backslash (e.g.
/
orc:\
), the function returns an empty string. - The original string if there are no slashes or backslashes.
Example
Query:
SELECT 'some/long/path/to/file' AS a, basename(a)
Result:
┌─a──────────────────────┬─basename('some\\long\\path\\to\\file')─┐
│ some\long\path\to\file │ file │
└────────────────────────┴────────────────────────────────────────┘
Query:
SELECT 'some\\long\\path\\to\\file' AS a, basename(a)
Result:
┌─a──────────────────────┬─basename('some\\long\\path\\to\\file')─┐
│ some\long\path\to\file │ file │
└────────────────────────┴────────────────────────────────────────┘
Query:
SELECT 'some-file-name' AS a, basename(a)
Result:
┌─a──────────────┬─basename('some-file-name')─┐
│ some-file-name │ some-file-name │
└────────────────┴────────────────────────────┘
visibleWidth(x)
Calculates the approximate width when outputting values to the console in text format (tab-separated). This function is used by the system to implement Pretty formats.
NULL
is represented as a string corresponding to NULL
in Pretty
formats.
SELECT visibleWidth(NULL)
┌─visibleWidth(NULL)─┐
│ 4 │
└────────────────────┘
toTypeName(x)
Returns the type name of the passed argument.
If NULL
is passed, then the function returns type Nullable(Nothing)
, which corresponds to ClickHouse's internal NULL
representation.
blockSize()
In ClickHouse, queries are processed in blocks (chunks). This function returns the size (row count) of the block the function is called on.
byteSize
Returns an estimation of uncompressed byte size of its arguments in memory.
Syntax
byteSize(argument [, ...])
Arguments
argument
— Value.
Returned value
- Estimation of byte size of the arguments in memory.
Type: UInt64.
Examples
For String arguments, the function returns the string length + 9 (terminating zero + length).
Query:
SELECT byteSize('string');
Result:
┌─byteSize('string')─┐
│ 15 │
└────────────────────┘
Query:
CREATE TABLE test
(
`key` Int32,
`u8` UInt8,
`u16` UInt16,
`u32` UInt32,
`u64` UInt64,
`i8` Int8,
`i16` Int16,
`i32` Int32,
`i64` Int64,
`f32` Float32,
`f64` Float64
)
ENGINE = MergeTree
ORDER BY key;
INSERT INTO test VALUES(1, 8, 16, 32, 64, -8, -16, -32, -64, 32.32, 64.64);
SELECT key, byteSize(u8) AS `byteSize(UInt8)`, byteSize(u16) AS `byteSize(UInt16)`, byteSize(u32) AS `byteSize(UInt32)`, byteSize(u64) AS `byteSize(UInt64)`, byteSize(i8) AS `byteSize(Int8)`, byteSize(i16) AS `byteSize(Int16)`, byteSize(i32) AS `byteSize(Int32)`, byteSize(i64) AS `byteSize(Int64)`, byteSize(f32) AS `byteSize(Float32)`, byteSize(f64) AS `byteSize(Float64)` FROM test ORDER BY key ASC FORMAT Vertical;
Result:
Row 1:
──────
key: 1
byteSize(UInt8): 1
byteSize(UInt16): 2
byteSize(UInt32): 4
byteSize(UInt64): 8
byteSize(Int8): 1
byteSize(Int16): 2
byteSize(Int32): 4
byteSize(Int64): 8
byteSize(Float32): 4
byteSize(Float64): 8
If the function has multiple arguments, the function accumulates their byte sizes.
Query:
SELECT byteSize(NULL, 1, 0.3, '');
Result:
┌─byteSize(NULL, 1, 0.3, '')─┐
│ 19 │
└────────────────────────────┘
materialize(x)
Turns a constant into a full column containing a single value. Full columns and constants are represented differently in memory. Functions usually execute different code for normal and constant arguments, although the result should typically be the same. This function can be used to debug this behavior.
ignore(…)
Accepts any arguments, including NULL
and does nothing. Always returns 0.
The argument is internally still evaluated. Useful e.g. for benchmarks.
sleep(seconds)
Sleeps ‘seconds’ seconds for each data block. The sleep time can be specified as integer or as floating-point number.
sleepEachRow(seconds)
Sleeps ‘seconds’ seconds for each row. The sleep time can be specified as integer or as floating-point number.
currentDatabase()
Returns the name of the current database.
Useful in table engine parameters of CREATE TABLE
queries where you need to specify the database.
currentUser()
Returns the name of the current user. In case of a distributed query, the name of the user who initiated the query is returned.
SELECT currentUser();
Alias: user()
, USER()
.
Returned values
- The name of the current user.
- In distributed queries, the login of the user who initiated the query.
Type: String
.
Example
SELECT currentUser();
Result:
┌─currentUser()─┐
│ default │
└───────────────┘
isConstant
Returns whether the argument is a constant expression.
A constant expression is an expression whose result is known during query analysis, i.e. before execution. For example, expressions over literals are constant expressions.
This function is mostly intended for development, debugging and demonstration.
Syntax
isConstant(x)
Arguments
x
— Expression to check.
Returned values
1
ifx
is constant.0
ifx
is non-constant.
Type: UInt8.
Examples
Query:
SELECT isConstant(x + 1) FROM (SELECT 43 AS x)
Result:
┌─isConstant(plus(x, 1))─┐
│ 1 │
└────────────────────────┘
Query:
WITH 3.14 AS pi SELECT isConstant(cos(pi))
Result:
┌─isConstant(cos(pi))─┐
│ 1 │
└─────────────────────┘
Query:
SELECT isConstant(number) FROM numbers(1)
Result:
┌─isConstant(number)─┐
│ 0 │
└────────────────────┘
isFinite(x)
Returns 1 if the Float32 or Float64 argument not infinite and not a NaN, otherwise this function returns 0.
isInfinite(x)
Returns 1 if the Float32 or Float64 argument is infinite, otherwise this function returns 0. Note that 0 is returned for a NaN.
ifNotFinite
Checks whether a floating point value is finite.
Syntax
ifNotFinite(x,y)
Arguments
Returned value
x
ifx
is finite.y
ifx
is not finite.
Example
Query:
SELECT 1/0 as infimum, ifNotFinite(infimum,42)
Result:
┌─infimum─┬─ifNotFinite(divide(1, 0), 42)─┐
│ inf │ 42 │
└─────────┴───────────────────────────────┘
You can get similar result by using the ternary operator: isFinite(x) ? x : y
.
isNaN(x)
Returns 1 if the Float32 and Float64 argument is NaN, otherwise this function 0.
hasColumnInTable([‘hostname’[, ‘username’[, ‘password’]],] ‘database’, ‘table’, ‘column’)
Given the database name, the table name, and the column name as constant strings, returns 1 if the given column exists, otherwise 0. If parameter hostname
is given, the check is performed on a remote server.
If the table does not exist, an exception is thrown.
For elements in a nested data structure, the function checks for the existence of a column. For the nested data structure itself, the function returns 0.
bar
Builds a bar chart.
bar(x, min, max, width)
draws a band with width proportional to (x - min)
and equal to width
characters when x = max
.
Arguments
x
— Size to display.min, max
— Integer constants. The value must fit inInt64
.width
— Constant, positive integer, can be fractional.
The band is drawn with accuracy to one eighth of a symbol.
Example:
SELECT
toHour(EventTime) AS h,
count() AS c,
bar(c, 0, 600000, 20) AS bar
FROM test.hits
GROUP BY h
ORDER BY h ASC
┌──h─┬──────c─┬─bar────────────────┐
│ 0 │ 292907 │ █████████▋ │
│ 1 │ 180563 │ ██████ │
│ 2 │ 114861 │ ███▋ │
│ 3 │ 85069 │ ██▋ │
│ 4 │ 68543 │ ██▎ │
│ 5 │ 78116 │ ██▌ │
│ 6 │ 113474 │ ███▋ │
│ 7 │ 170678 │ █████▋ │
│ 8 │ 278380 │ █████████▎ │
│ 9 │ 391053 │ █████████████ │
│ 10 │ 457681 │ ███████████████▎ │
│ 11 │ 493667 │ ████████████████▍ │
│ 12 │ 509641 │ ████████████████▊ │
│ 13 │ 522947 │ █████████████████▍ │
│ 14 │ 539954 │ █████████████████▊ │
│ 15 │ 528460 │ █████████████████▌ │
│ 16 │ 539201 │ █████████████████▊ │
│ 17 │ 523539 │ █████████████████▍ │
│ 18 │ 506467 │ ████████████████▊ │
│ 19 │ 520915 │ █████████████████▎ │
│ 20 │ 521665 │ █████████████████▍ │
│ 21 │ 542078 │ ██████████████████ │
│ 22 │ 493642 │ ████████████████▍ │
│ 23 │ 400397 │ █████████████▎ │
└────┴────────┴────────────────────┘
transform
Transforms a value according to the explicitly defined mapping of some elements to other ones. There are two variations of this function:
transform(x, array_from, array_to, default)
x
– What to transform.
array_from
– Constant array of values to convert.
array_to
– Constant array of values to convert the values in ‘from’ to.
default
– Which value to use if ‘x’ is not equal to any of the values in ‘from’.
array_from
and array_to
must have equally many elements.
Signature:
For x
equal to one of the elements in array_from
, the function returns the corresponding element in array_to
, i.e. the one at the same array index. Otherwise, it returns default
. If multiple matching elements exist array_from
, an arbitrary corresponding element from array_to
is returned.
transform(T, Array(T), Array(U), U) -> U
T
and U
can be numeric, string, or Date or DateTime types.
The same letter (T or U) means that types must be mutually compatible and not necessarily equal.
For example, the first argument could have type Int64
, while the second argument could have type Array(UInt16)
.
Example:
SELECT
transform(SearchEngineID, [2, 3], ['Yandex', 'Google'], 'Other') AS title,
count() AS c
FROM test.hits
WHERE SearchEngineID != 0
GROUP BY title
ORDER BY c DESC
┌─title─────┬──────c─┐
│ Yandex │ 498635 │
│ Google │ 229872 │
│ Other │ 104472 │
└───────────┴────────┘
transform(x, array_from, array_to)
Similar to the other variation but has no ‘default’ argument. In case no match can be found, x
is returned.
Example:
SELECT
transform(domain(Referer), ['yandex.ru', 'google.ru', 'vkontakte.ru'], ['www.yandex', 'example.com', 'vk.com']) AS s,
count() AS c
FROM test.hits
GROUP BY domain(Referer)
ORDER BY count() DESC
LIMIT 10
┌─s──────────────┬───────c─┐
│ │ 2906259 │
│ www.yandex │ 867767 │
│ ███████.ru │ 313599 │
│ mail.yandex.ru │ 107147 │
│ ██████.ru │ 100355 │
│ █████████.ru │ 65040 │
│ news.yandex.ru │ 64515 │
│ ██████.net │ 59141 │
│ example.com │ 57316 │
└────────────────┴─────────┘
formatReadableDecimalSize(x)
Given a size (number of bytes), this function returns a readable, rounded size with suffix (KB, MB, etc.) as string.
Example:
SELECT
arrayJoin([1, 1024, 1024*1024, 192851925]) AS filesize_bytes,
formatReadableDecimalSize(filesize_bytes) AS filesize
┌─filesize_bytes─┬─filesize───┐
│ 1 │ 1.00 B │
│ 1024 │ 1.02 KB │
│ 1048576 │ 1.05 MB │
│ 192851925 │ 192.85 MB │
└────────────────┴────────────┘
formatReadableSize(x)
Given a size (number of bytes), this function returns a readable, rounded size with suffix (KiB, MiB, etc.) as string.
Example:
SELECT
arrayJoin([1, 1024, 1024*1024, 192851925]) AS filesize_bytes,
formatReadableSize(filesize_bytes) AS filesize
┌─filesize_bytes─┬─filesize───┐
│ 1 │ 1.00 B │
│ 1024 │ 1.00 KiB │
│ 1048576 │ 1.00 MiB │
│ 192851925 │ 183.92 MiB │
└────────────────┴────────────┘
formatReadableQuantity(x)
Given a number, this function returns a rounded number with suffix (thousand, million, billion, etc.) as string.
Example:
SELECT
arrayJoin([1024, 1234 * 1000, (4567 * 1000) * 1000, 98765432101234]) AS number,
formatReadableQuantity(number) AS number_for_humans
┌─────────number─┬─number_for_humans─┐
│ 1024 │ 1.02 thousand │
│ 1234000 │ 1.23 million │
│ 4567000000 │ 4.57 billion │
│ 98765432101234 │ 98.77 trillion │
└────────────────┴───────────────────┘
formatReadableTimeDelta
Given a time interval (delta) in seconds, this function returns a time delta with year/month/day/hour/minute/second as string.
Syntax
formatReadableTimeDelta(column[, maximum_unit])
Arguments
column
— A column with a numeric time delta.maximum_unit
— Optional. Maximum unit to show. Acceptable valuesseconds
,minutes
,hours
,days
,months
,years
.
Example:
SELECT
arrayJoin([100, 12345, 432546534]) AS elapsed,
formatReadableTimeDelta(elapsed) AS time_delta
┌────elapsed─┬─time_delta ─────────────────────────────────────────────────────┐
│ 100 │ 1 minute and 40 seconds │
│ 12345 │ 3 hours, 25 minutes and 45 seconds │
│ 432546534 │ 13 years, 8 months, 17 days, 7 hours, 48 minutes and 54 seconds │
└────────────┴─────────────────────────────────────────────────────────────────┘
SELECT
arrayJoin([100, 12345, 432546534]) AS elapsed,
formatReadableTimeDelta(elapsed, 'minutes') AS time_delta
┌────elapsed─┬─time_delta ─────────────────────────────────────────────────────┐
│ 100 │ 1 minute and 40 seconds │
│ 12345 │ 205 minutes and 45 seconds │
│ 432546534 │ 7209108 minutes and 54 seconds │
└────────────┴─────────────────────────────────────────────────────────────────┘
parseTimeDelta
Parse a sequence of numbers followed by something resembling a time unit.
Syntax
parseTimeDelta(timestr)
Arguments
timestr
— A sequence of numbers followed by something resembling a time unit.
Returned value
- A floating-point number with the number of seconds.
Example
SELECT parseTimeDelta('11s+22min')
┌─parseTimeDelta('11s+22min')─┐
│ 1331 │
└─────────────────────────────┘
SELECT parseTimeDelta('1yr2mo')
┌─parseTimeDelta('1yr2mo')─┐
│ 36806400 │
└──────────────────────────┘
least(a, b)
Returns the smaller value of a and b.
greatest(a, b)
Returns the larger value of a and b.
uptime()
Returns the server’s uptime in seconds. If executed in the context of a distributed table, this function generates a normal column with values relevant to each shard. Otherwise it produces a constant value.
version()
Returns the server version as a string. If executed in the context of a distributed table, this function generates a normal column with values relevant to each shard. Otherwise it produces a constant value.
buildId()
Returns the build ID generated by a compiler for the running ClickHouse server binary. If executed in the context of a distributed table, this function generates a normal column with values relevant to each shard. Otherwise it produces a constant value.
blockNumber()
Returns the sequence number of the data block where the row is located.
rowNumberInBlock()
Returns the ordinal number of the row in the data block. Different data blocks are always recalculated.
rowNumberInAllBlocks()
Returns the ordinal number of the row in the data block. This function only considers the affected data blocks.
neighbor
The window function that provides access to a row at a specified offset before or after the current row of a given column.
Syntax
neighbor(column, offset[, default_value])
The result of the function depends on the affected data blocks and the order of data in the block.
:::note Only returns neighbor inside the currently processed data block. :::
The order of rows during calculation of neighbor()
can differ from the order of rows returned to the user.
To prevent that you can create a subquery with ORDER BY and call the function from outside the subquery.
Arguments
column
— A column name or scalar expression.offset
— The number of rows to look before or ahead of the current row incolumn
. Int64.default_value
— Optional. The returned value if offset is beyond the block boundaries. Type of data blocks affected.
Returned values
- Value of
column
withoffset
distance from current row, ifoffset
is not outside the block boundaries. - The default value of
column
ordefault_value
(if given), ifoffset
is outside the block boundaries.
Type: type of data blocks affected or default value type.
Example
Query:
SELECT number, neighbor(number, 2) FROM system.numbers LIMIT 10;
Result:
┌─number─┬─neighbor(number, 2)─┐
│ 0 │ 2 │
│ 1 │ 3 │
│ 2 │ 4 │
│ 3 │ 5 │
│ 4 │ 6 │
│ 5 │ 7 │
│ 6 │ 8 │
│ 7 │ 9 │
│ 8 │ 0 │
│ 9 │ 0 │
└────────┴─────────────────────┘
Query:
SELECT number, neighbor(number, 2, 999) FROM system.numbers LIMIT 10;
Result:
┌─number─┬─neighbor(number, 2, 999)─┐
│ 0 │ 2 │
│ 1 │ 3 │
│ 2 │ 4 │
│ 3 │ 5 │
│ 4 │ 6 │
│ 5 │ 7 │
│ 6 │ 8 │
│ 7 │ 9 │
│ 8 │ 999 │
│ 9 │ 999 │
└────────┴──────────────────────────┘
This function can be used to compute year-over-year metric value:
Query:
WITH toDate('2018-01-01') AS start_date
SELECT
toStartOfMonth(start_date + (number * 32)) AS month,
toInt32(month) % 100 AS money,
neighbor(money, -12) AS prev_year,
round(prev_year / money, 2) AS year_over_year
FROM numbers(16)
Result:
┌──────month─┬─money─┬─prev_year─┬─year_over_year─┐
│ 2018-01-01 │ 32 │ 0 │ 0 │
│ 2018-02-01 │ 63 │ 0 │ 0 │
│ 2018-03-01 │ 91 │ 0 │ 0 │
│ 2018-04-01 │ 22 │ 0 │ 0 │
│ 2018-05-01 │ 52 │ 0 │ 0 │
│ 2018-06-01 │ 83 │ 0 │ 0 │
│ 2018-07-01 │ 13 │ 0 │ 0 │
│ 2018-08-01 │ 44 │ 0 │ 0 │
│ 2018-09-01 │ 75 │ 0 │ 0 │
│ 2018-10-01 │ 5 │ 0 │ 0 │
│ 2018-11-01 │ 36 │ 0 │ 0 │
│ 2018-12-01 │ 66 │ 0 │ 0 │
│ 2019-01-01 │ 97 │ 32 │ 0.33 │
│ 2019-02-01 │ 28 │ 63 │ 2.25 │
│ 2019-03-01 │ 56 │ 91 │ 1.62 │
│ 2019-04-01 │ 87 │ 22 │ 0.25 │
└────────────┴───────┴───────────┴────────────────┘
runningDifference(x)
Calculates the difference between two consecutive row values in the data block. Returns 0 for the first row, and for subsequent rows the difference to the previous row.
:::note Only returns differences inside the currently processed data block. :::
The result of the function depends on the affected data blocks and the order of data in the block.
The order of rows during calculation of runningDifference()
can differ from the order of rows returned to the user.
To prevent that you can create a subquery with ORDER BY and call the function from outside the subquery.
Example:
SELECT
EventID,
EventTime,
runningDifference(EventTime) AS delta
FROM
(
SELECT
EventID,
EventTime
FROM events
WHERE EventDate = '2016-11-24'
ORDER BY EventTime ASC
LIMIT 5
)
┌─EventID─┬───────────EventTime─┬─delta─┐
│ 1106 │ 2016-11-24 00:00:04 │ 0 │
│ 1107 │ 2016-11-24 00:00:05 │ 1 │
│ 1108 │ 2016-11-24 00:00:05 │ 0 │
│ 1109 │ 2016-11-24 00:00:09 │ 4 │
│ 1110 │ 2016-11-24 00:00:10 │ 1 │
└─────────┴─────────────────────┴───────┘
Please note that the block size affects the result. The internal state of runningDifference
state is reset for each new block.
SELECT
number,
runningDifference(number + 1) AS diff
FROM numbers(100000)
WHERE diff != 1
┌─number─┬─diff─┐
│ 0 │ 0 │
└────────┴──────┘
┌─number─┬─diff─┐
│ 65536 │ 0 │
└────────┴──────┘
set max_block_size=100000 -- default value is 65536!
SELECT
number,
runningDifference(number + 1) AS diff
FROM numbers(100000)
WHERE diff != 1
┌─number─┬─diff─┐
│ 0 │ 0 │
└────────┴──────┘
runningDifferenceStartingWithFirstValue
Same as runningDifference, but returns the value of the first row as the value on the first row.
runningConcurrency
Calculates the number of concurrent events. Each event has a start time and an end time. The start time is included in the event, while the end time is excluded. Columns with a start time and an end time must be of the same data type. The function calculates the total number of active (concurrent) events for each event start time.
:::tip Events must be ordered by the start time in ascending order. If this requirement is violated the function raises an exception. Every data block is processed separately. If events from different data blocks overlap then they can not be processed correctly. :::
Syntax
runningConcurrency(start, end)
Arguments
start
— A column with the start time of events. Date, DateTime, or DateTime64.end
— A column with the end time of events. Date, DateTime, or DateTime64.
Returned values
- The number of concurrent events at each event start time.
Type: UInt32
Example
Consider the table:
┌──────start─┬────────end─┐
│ 2021-03-03 │ 2021-03-11 │
│ 2021-03-06 │ 2021-03-12 │
│ 2021-03-07 │ 2021-03-08 │
│ 2021-03-11 │ 2021-03-12 │
└────────────┴────────────┘
Query:
SELECT start, runningConcurrency(start, end) FROM example_table;
Result:
┌──────start─┬─runningConcurrency(start, end)─┐
│ 2021-03-03 │ 1 │
│ 2021-03-06 │ 2 │
│ 2021-03-07 │ 3 │
│ 2021-03-11 │ 2 │
└────────────┴────────────────────────────────┘
MACNumToString(num)
Interprets a UInt64 number as a MAC address in big endian format. Returns the corresponding MAC address in format AA:BB:CC:DD:EE:FF (colon-separated numbers in hexadecimal form) as string.
MACStringToNum(s)
The inverse function of MACNumToString. If the MAC address has an invalid format, it returns 0.
MACStringToOUI(s)
Given a MAC address in format AA:BB:CC:DD:EE:FF (colon-separated numbers in hexadecimal form), returns the first three octets as a UInt64 number. If the MAC address has an invalid format, it returns 0.
getSizeOfEnumType
Returns the number of fields in Enum.
An exception is thrown if the type is not Enum
.
getSizeOfEnumType(value)
Arguments:
value
— Value of typeEnum
.
Returned values
- The number of fields with
Enum
input values.
Example
SELECT getSizeOfEnumType( CAST('a' AS Enum8('a' = 1, 'b' = 2) ) ) AS x
┌─x─┐
│ 2 │
└───┘
blockSerializedSize
Returns the size on disk without considering compression.
blockSerializedSize(value[, value[, ...]])
Arguments
value
— Any value.
Returned values
- The number of bytes that will be written to disk for block of values without compression.
Example
Query:
SELECT blockSerializedSize(maxState(1)) as x
Result:
┌─x─┐
│ 2 │
└───┘
toColumnTypeName
Returns the internal name of the data type that represents the value.
toColumnTypeName(value)
Arguments:
value
— Any type of value.
Returned values
- The internal data type name used to represent
value
.
Example
Difference between toTypeName ' and ' toColumnTypeName
:
SELECT toTypeName(CAST('2018-01-01 01:02:03' AS DateTime))
Result:
┌─toTypeName(CAST('2018-01-01 01:02:03', 'DateTime'))─┐
│ DateTime │
└─────────────────────────────────────────────────────┘
Query:
SELECT toColumnTypeName(CAST('2018-01-01 01:02:03' AS DateTime))
Result:
┌─toColumnTypeName(CAST('2018-01-01 01:02:03', 'DateTime'))─┐
│ Const(UInt32) │
└───────────────────────────────────────────────────────────┘
The example shows that the DateTime
data type is internally stored as Const(UInt32)
.
dumpColumnStructure
Outputs a detailed description of data structures in RAM
dumpColumnStructure(value)
Arguments:
value
— Any type of value.
Returned values
- A description of the column structure used for representing
value
.
Example
SELECT dumpColumnStructure(CAST('2018-01-01 01:02:03', 'DateTime'))
┌─dumpColumnStructure(CAST('2018-01-01 01:02:03', 'DateTime'))─┐
│ DateTime, Const(size = 1, UInt32(size = 1)) │
└──────────────────────────────────────────────────────────────┘
defaultValueOfArgumentType
Returns the default value for the given data type.
Does not include default values for custom columns set by the user.
defaultValueOfArgumentType(expression)
Arguments:
expression
— Arbitrary type of value or an expression that results in a value of an arbitrary type.
Returned values
0
for numbers.- Empty string for strings.
ᴺᵁᴸᴸ
for Nullable.
Example
Query:
SELECT defaultValueOfArgumentType( CAST(1 AS Int8) )
Result:
┌─defaultValueOfArgumentType(CAST(1, 'Int8'))─┐
│ 0 │
└─────────────────────────────────────────────┘
Query:
SELECT defaultValueOfArgumentType( CAST(1 AS Nullable(Int8) ) )
Result:
┌─defaultValueOfArgumentType(CAST(1, 'Nullable(Int8)'))─┐
│ ᴺᵁᴸᴸ │
└───────────────────────────────────────────────────────┘
defaultValueOfTypeName
Returns the default value for the given type name.
Does not include default values for custom columns set by the user.
defaultValueOfTypeName(type)
Arguments:
type
— A string representing a type name.
Returned values
0
for numbers.- Empty string for strings.
ᴺᵁᴸᴸ
for Nullable.
Example
Query:
SELECT defaultValueOfTypeName('Int8')
Result:
┌─defaultValueOfTypeName('Int8')─┐
│ 0 │
└────────────────────────────────┘
Query:
SELECT defaultValueOfTypeName('Nullable(Int8)')
Result:
┌─defaultValueOfTypeName('Nullable(Int8)')─┐
│ ᴺᵁᴸᴸ │
└──────────────────────────────────────────┘
indexHint
This function is intended for debugging and introspection. It ignores its argument and always returns 1. The arguments are not evaluated.
But during index analysis, the argument of this function is assumed to be not wrapped in indexHint
. This allows to select data in index ranges by the corresponding condition but without further filtering by this condition. The index in ClickHouse is sparse and using indexHint
will yield more data than specifying the same condition directly.
Syntax
SELECT * FROM table WHERE indexHint(<expression>)
Returned value
Type: Uint8.
Example
Here is the example of test data from the table ontime.
Table:
SELECT count() FROM ontime
┌─count()─┐
│ 4276457 │
└─────────┘
The table has indexes on the fields (FlightDate, (Year, FlightDate))
.
Create a query which does not use the index:
SELECT FlightDate AS k, count() FROM ontime GROUP BY k ORDER BY k
ClickHouse processed the entire table (Processed 4.28 million rows
).
Result:
┌──────────k─┬─count()─┐
│ 2017-01-01 │ 13970 │
│ 2017-01-02 │ 15882 │
........................
│ 2017-09-28 │ 16411 │
│ 2017-09-29 │ 16384 │
│ 2017-09-30 │ 12520 │
└────────────┴─────────┘
To apply the index, select a specific date:
SELECT FlightDate AS k, count() FROM ontime WHERE k = '2017-09-15' GROUP BY k ORDER BY k
ClickHouse now uses the index to process a significantly smaller number of rows (Processed 32.74 thousand rows
).
Result:
┌──────────k─┬─count()─┐
│ 2017-09-15 │ 16428 │
└────────────┴─────────┘
Now wrap the expression k = '2017-09-15'
in function indexHint
:
Query:
SELECT
FlightDate AS k,
count()
FROM ontime
WHERE indexHint(k = '2017-09-15')
GROUP BY k
ORDER BY k ASC
ClickHouse used the index the same way as previously (Processed 32.74 thousand rows
).
The expression k = '2017-09-15'
was not used when generating the result.
In example, the indexHint
function allows to see adjacent dates.
Result:
┌──────────k─┬─count()─┐
│ 2017-09-14 │ 7071 │
│ 2017-09-15 │ 16428 │
│ 2017-09-16 │ 1077 │
│ 2017-09-30 │ 8167 │
└────────────┴─────────┘
replicate
Creates an array with a single value.
Used for the internal implementation of arrayJoin.
SELECT replicate(x, arr);
Arguments:
arr
— An array.x
— The value to fill the result array with.
Returned value
An array of the lame length as arr
filled with value x
.
Type: Array
.
Example
Query:
SELECT replicate(1, ['a', 'b', 'c'])
Result:
┌─replicate(1, ['a', 'b', 'c'])─┐
│ [1,1,1] │
└───────────────────────────────┘
filesystemAvailable
Returns the amount of free space in the filesystem hosting the database persistence. The returned value is always smaller than total free space (filesystemFree) because some space is reserved for the operating system.
Syntax
filesystemAvailable()
Returned value
- The amount of remaining space available in bytes.
Type: UInt64.
Example
Query:
SELECT formatReadableSize(filesystemAvailable()) AS "Available space";
Result:
┌─Available space─┐
│ 30.75 GiB │
└─────────────────┘
filesystemFree
Returns the total amount of the free space on the filesystem hosting the database persistence. See also filesystemAvailable
Syntax
filesystemFree()
Returned value
- The amount of free space in bytes.
Type: UInt64.
Example
Query:
SELECT formatReadableSize(filesystemFree()) AS "Free space";
Result:
┌─Free space─┐
│ 32.39 GiB │
└────────────┘
filesystemCapacity
Returns the capacity of the filesystem in bytes. Needs the path to the data directory to be configured.
Syntax
filesystemCapacity()
Returned value
- Capacity of the filesystem in bytes.
Type: UInt64.
Example
Query:
SELECT formatReadableSize(filesystemCapacity()) AS "Capacity";
Result:
┌─Capacity──┐
│ 39.32 GiB │
└───────────┘
initializeAggregation
Calculates the result of an aggregate function based on a single value. This function can be used to initialize aggregate functions with combinator -State. You can create states of aggregate functions and insert them to columns of type AggregateFunction or use initialized aggregates as default values.
Syntax
initializeAggregation (aggregate_function, arg1, arg2, ..., argN)
Arguments
aggregate_function
— Name of the aggregation function to initialize. String.arg
— Arguments of aggregate function.
Returned value(s)
- Result of aggregation for every row passed to the function.
The return type is the same as the return type of function, that initializeAgregation
takes as first argument.
Example
Query:
SELECT uniqMerge(state) FROM (SELECT initializeAggregation('uniqState', number % 3) AS state FROM numbers(10000));
Result:
┌─uniqMerge(state)─┐
│ 3 │
└──────────────────┘
Query:
SELECT finalizeAggregation(state), toTypeName(state) FROM (SELECT initializeAggregation('sumState', number % 3) AS state FROM numbers(5));
Result:
┌─finalizeAggregation(state)─┬─toTypeName(state)─────────────┐
│ 0 │ AggregateFunction(sum, UInt8) │
│ 1 │ AggregateFunction(sum, UInt8) │
│ 2 │ AggregateFunction(sum, UInt8) │
│ 0 │ AggregateFunction(sum, UInt8) │
│ 1 │ AggregateFunction(sum, UInt8) │
└────────────────────────────┴───────────────────────────────┘
Example with AggregatingMergeTree
table engine and AggregateFunction
column:
CREATE TABLE metrics
(
key UInt64,
value AggregateFunction(sum, UInt64) DEFAULT initializeAggregation('sumState', toUInt64(0))
)
ENGINE = AggregatingMergeTree
ORDER BY key
INSERT INTO metrics VALUES (0, initializeAggregation('sumState', toUInt64(42)))
See Also
finalizeAggregation
Given a state of aggregate function, this function returns the result of aggregation (or finalized state when using a -State combinator).
Syntax
finalizeAggregation(state)
Arguments
state
— State of aggregation. AggregateFunction.
Returned value(s)
- Value/values that was aggregated.
Type: Value of any types that was aggregated.
Examples
Query:
SELECT finalizeAggregation(( SELECT countState(number) FROM numbers(10)));
Result:
┌─finalizeAggregation(_subquery16)─┐
│ 10 │
└──────────────────────────────────┘
Query:
SELECT finalizeAggregation(( SELECT sumState(number) FROM numbers(10)));
Result:
┌─finalizeAggregation(_subquery20)─┐
│ 45 │
└──────────────────────────────────┘
Note that NULL
values are ignored.
Query:
SELECT finalizeAggregation(arrayReduce('anyState', [NULL, 2, 3]));
Result:
┌─finalizeAggregation(arrayReduce('anyState', [NULL, 2, 3]))─┐
│ 2 │
└────────────────────────────────────────────────────────────┘
Combined example:
Query:
WITH initializeAggregation('sumState', number) AS one_row_sum_state
SELECT
number,
finalizeAggregation(one_row_sum_state) AS one_row_sum,
runningAccumulate(one_row_sum_state) AS cumulative_sum
FROM numbers(10);
Result:
┌─number─┬─one_row_sum─┬─cumulative_sum─┐
│ 0 │ 0 │ 0 │
│ 1 │ 1 │ 1 │
│ 2 │ 2 │ 3 │
│ 3 │ 3 │ 6 │
│ 4 │ 4 │ 10 │
│ 5 │ 5 │ 15 │
│ 6 │ 6 │ 21 │
│ 7 │ 7 │ 28 │
│ 8 │ 8 │ 36 │
│ 9 │ 9 │ 45 │
└────────┴─────────────┴────────────────┘
See Also
runningAccumulate
Accumulates the states of an aggregate function for each row of a data block.
:::note The state is reset for each new block of data. :::
Syntax
runningAccumulate(agg_state[, grouping]);
Arguments
agg_state
— State of the aggregate function. AggregateFunction.grouping
— Grouping key. Optional. The state of the function is reset if thegrouping
value is changed. It can be any of the supported data types for which the equality operator is defined.
Returned value
- Each resulting row contains a result of the aggregate function, accumulated for all the input rows from 0 to the current position.
runningAccumulate
resets states for each new data block or when thegrouping
value changes.
Type depends on the aggregate function used.
Examples
Consider how you can use runningAccumulate
to find the cumulative sum of numbers without and with grouping.
Query:
SELECT k, runningAccumulate(sum_k) AS res FROM (SELECT number as k, sumState(k) AS sum_k FROM numbers(10) GROUP BY k ORDER BY k);
Result:
┌─k─┬─res─┐
│ 0 │ 0 │
│ 1 │ 1 │
│ 2 │ 3 │
│ 3 │ 6 │
│ 4 │ 10 │
│ 5 │ 15 │
│ 6 │ 21 │
│ 7 │ 28 │
│ 8 │ 36 │
│ 9 │ 45 │
└───┴─────┘
The subquery generates sumState
for every number from 0
to 9
. sumState
returns the state of the sum function that contains the sum of a single number.
The whole query does the following:
- For the first row,
runningAccumulate
takessumState(0)
and returns0
. - For the second row, the function merges
sumState(0)
andsumState(1)
resulting insumState(0 + 1)
, and returns1
as a result. - For the third row, the function merges
sumState(0 + 1)
andsumState(2)
resulting insumState(0 + 1 + 2)
, and returns3
as a result. - The actions are repeated until the block ends.
The following example shows the groupping
parameter usage:
Query:
SELECT
grouping,
item,
runningAccumulate(state, grouping) AS res
FROM
(
SELECT
toInt8(number / 4) AS grouping,
number AS item,
sumState(number) AS state
FROM numbers(15)
GROUP BY item
ORDER BY item ASC
);
Result:
┌─grouping─┬─item─┬─res─┐
│ 0 │ 0 │ 0 │
│ 0 │ 1 │ 1 │
│ 0 │ 2 │ 3 │
│ 0 │ 3 │ 6 │
│ 1 │ 4 │ 4 │
│ 1 │ 5 │ 9 │
│ 1 │ 6 │ 15 │
│ 1 │ 7 │ 22 │
│ 2 │ 8 │ 8 │
│ 2 │ 9 │ 17 │
│ 2 │ 10 │ 27 │
│ 2 │ 11 │ 38 │
│ 3 │ 12 │ 12 │
│ 3 │ 13 │ 25 │
│ 3 │ 14 │ 39 │
└──────────┴──────┴─────┘
As you can see, runningAccumulate
merges states for each group of rows separately.
joinGet
The function lets you extract data from the table the same way as from a dictionary.
Gets the data from Join tables using the specified join key.
Only supports tables created with the ENGINE = Join(ANY, LEFT, <join_keys>)
statement.
Syntax
joinGet(join_storage_table_name, `value_column`, join_keys)
Arguments
join_storage_table_name
— an identifier indicating where the search is performed. The identifier is searched in the default database (see settingdefault_database
in the config file). To override the default database, useUSE db_name
or specify the database and the table through the separatordb_name.db_table
as in the example.value_column
— name of the column of the table that contains required data.join_keys
— list of keys.
Returned value
Returns a list of values corresponded to list of keys.
If certain does not exist in source table then 0
or null
will be returned based on join_use_nulls setting.
More info about join_use_nulls
in Join operation.
Example
Input table:
CREATE DATABASE db_test
CREATE TABLE db_test.id_val(`id` UInt32, `val` UInt32) ENGINE = Join(ANY, LEFT, id) SETTINGS join_use_nulls = 1
INSERT INTO db_test.id_val VALUES (1,11)(2,12)(4,13)
┌─id─┬─val─┐
│ 4 │ 13 │
│ 2 │ 12 │
│ 1 │ 11 │
└────┴─────┘
Query:
SELECT joinGet(db_test.id_val, 'val', toUInt32(number)) from numbers(4) SETTINGS join_use_nulls = 1
Result:
┌─joinGet(db_test.id_val, 'val', toUInt32(number))─┐
│ 0 │
│ 11 │
│ 12 │
│ 0 │
└──────────────────────────────────────────────────┘
catboostEvaluate(path_to_model, feature_1, feature_2, …, feature_n)
:::note This function is not available in ClickHouse Cloud. :::
Evaluate an external catboost model. CatBoost is an open-source gradient boosting library developed by Yandex for machine learning. Accepts a path to a catboost model and model arguments (features). Returns Float64.
SELECT feat1, ..., feat_n, catboostEvaluate('/path/to/model.bin', feat_1, ..., feat_n) AS prediction
FROM data_table
Prerequisites
- Build the catboost evaluation library
Before evaluating catboost models, the libcatboostmodel.<so|dylib>
library must be made available. See CatBoost documentation how to compile it.
Next, specify the path to libcatboostmodel.<so|dylib>
in the clickhouse configuration:
<clickhouse>
...
<catboost_lib_path>/path/to/libcatboostmodel.so</catboost_lib_path>
...
</clickhouse>
For security and isolation reasons, the model evaluation does not run in the server process but in the clickhouse-library-bridge process.
At the first execution of catboostEvaluate()
, the server starts the library bridge process if it is not running already. Both processes
communicate using a HTTP interface. By default, port 9012
is used. A different port can be specified as follows - this is useful if port
9012
is already assigned to a different service.
<library_bridge>
<port>9019</port>
</library_bridge>
- Train a catboost model using libcatboost
See Training and applying models for how to train catboost models from a training data set.
throwIf(x[, message[, error_code]])
Throw an exception if argument x
is true.
Arguments
x
- the condition to check.message
- a constant string providing a custom error message. Optional.error_code
- A constant integer providing a custom error code. Optional.
To use the error_code
argument, configuration parameter allow_custom_error_code_in_throwif
must be enabled.
Example
SELECT throwIf(number = 3, 'Too many') FROM numbers(10);
Result:
↙ Progress: 0.00 rows, 0.00 B (0.00 rows/s., 0.00 B/s.) Received exception from server (version 19.14.1):
Code: 395. DB::Exception: Received from localhost:9000. DB::Exception: Too many.
identity
Returns its argument. Intended for debugging and testing. Allows to cancel using index, and get the query performance of a full scan. When the query is analyzed for possible use of an index, the analyzer ignores everything in identity
functions. Also disables constant folding.
Syntax
identity(x)
Example
Query:
SELECT identity(42);
Result:
┌─identity(42)─┐
│ 42 │
└──────────────┘
getSetting
Returns the current value of a custom setting.
Syntax
getSetting('custom_setting');
Parameter
custom_setting
— The setting name. String.
Returned value
- The setting's current value.
Example
SET custom_a = 123;
SELECT getSetting('custom_a');
Result:
123
See Also
isDecimalOverflow
Checks whether the Decimal value is outside its precision or outside the specified precision.
Syntax
isDecimalOverflow(d, [p])
Arguments
d
— value. Decimal.p
— precision. Optional. If omitted, the initial precision of the first argument is used. This parameter can be helpful to migrate data from/to another database or file. UInt8.
Returned values
1
— Decimal value has more digits then allowed by its precision,0
— Decimal value satisfies the specified precision.
Example
Query:
SELECT isDecimalOverflow(toDecimal32(1000000000, 0), 9),
isDecimalOverflow(toDecimal32(1000000000, 0)),
isDecimalOverflow(toDecimal32(-1000000000, 0), 9),
isDecimalOverflow(toDecimal32(-1000000000, 0));
Result:
1 1 1 1
countDigits
Returns number of decimal digits need to represent a value.
Syntax
countDigits(x)
Arguments
Returned value
Number of digits.
Type: UInt8.
:::note
For Decimal
values takes into account their scales: calculates result over underlying integer type which is (value * scale)
. For example: countDigits(42) = 2
, countDigits(42.000) = 5
, countDigits(0.04200) = 4
. I.e. you may check decimal overflow for Decimal64
with countDecimal(x) > 18
. It's a slow variant of isDecimalOverflow.
:::
Example
Query:
SELECT countDigits(toDecimal32(1, 9)), countDigits(toDecimal32(-1, 9)),
countDigits(toDecimal64(1, 18)), countDigits(toDecimal64(-1, 18)),
countDigits(toDecimal128(1, 38)), countDigits(toDecimal128(-1, 38));
Result:
10 10 19 19 39 39
errorCodeToName
Returns the textual name of an error code.
Type: LowCardinality(String).
Syntax
errorCodeToName(1)
Result:
UNSUPPORTED_METHOD
tcpPort
Returns native interface TCP port number listened by this server. If executed in the context of a distributed table, this function generates a normal column with values relevant to each shard. Otherwise it produces a constant value.
Syntax
tcpPort()
Arguments
- None.
Returned value
- The TCP port number.
Type: UInt16.
Example
Query:
SELECT tcpPort();
Result:
┌─tcpPort()─┐
│ 9000 │
└───────────┘
See Also
currentProfiles
Returns a list of the current settings profiles for the current user.
The command SET PROFILE could be used to change the current setting profile. If the command SET PROFILE
was not used the function returns the profiles specified at the current user's definition (see CREATE USER).
Syntax
currentProfiles()
Returned value
- List of the current user settings profiles.
enabledProfiles
Returns settings profiles, assigned to the current user both explicitly and implicitly. Explicitly assigned profiles are the same as returned by the currentProfiles function. Implicitly assigned profiles include parent profiles of other assigned profiles, profiles assigned via granted roles, profiles assigned via their own settings, and the main default profile (see the default_profile
section in the main server configuration file).
Syntax
enabledProfiles()
Returned value
- List of the enabled settings profiles.
defaultProfiles
Returns all the profiles specified at the current user's definition (see CREATE USER statement).
Syntax
defaultProfiles()
Returned value
- List of the default settings profiles.
currentRoles
Returns the roles assigned to the current user. The roles can be changed by the SET ROLE statement. If no SET ROLE
statement was not, the function currentRoles
returns the same as defaultRoles
.
Syntax
currentRoles()
Returned value
- A list of the current roles for the current user.
enabledRoles
Returns the names of the current roles and the roles, granted to some of the current roles.
Syntax
enabledRoles()
Returned value
- List of the enabled roles for the current user.
defaultRoles
Returns the roles which are enabled by default for the current user when he logs in. Initially these are all roles granted to the current user (see GRANT), but that can be changed with the SET DEFAULT ROLE statement.
Syntax
defaultRoles()
Returned value
- List of the default roles for the current user.
getServerPort
Returns the server port number. When the port is not used by the server, throws an exception.
Syntax
getServerPort(port_name)
Arguments
-
port_name
— The name of the server port. String. Possible values:- 'tcp_port'
- 'tcp_port_secure'
- 'http_port'
- 'https_port'
- 'interserver_http_port'
- 'interserver_https_port'
- 'mysql_port'
- 'postgresql_port'
- 'grpc_port'
- 'prometheus.port'
Returned value
- The number of the server port.
Type: UInt16.
Example
Query:
SELECT getServerPort('tcp_port');
Result:
┌─getServerPort('tcp_port')─┐
│ 9000 │
└───────────────────────────┘
queryID
Returns the ID of the current query. Other parameters of a query can be extracted from the system.query_log table via query_id
.
In contrast to initialQueryID function, queryID
can return different results on different shards (see the example).
Syntax
queryID()
Returned value
- The ID of the current query.
Type: String
Example
Query:
CREATE TABLE tmp (str String) ENGINE = Log;
INSERT INTO tmp (*) VALUES ('a');
SELECT count(DISTINCT t) FROM (SELECT queryID() AS t FROM remote('127.0.0.{1..3}', currentDatabase(), 'tmp') GROUP BY queryID());
Result:
┌─count()─┐
│ 3 │
└─────────┘
initialQueryID
Returns the ID of the initial current query. Other parameters of a query can be extracted from the system.query_log table via initial_query_id
.
In contrast to queryID function, initialQueryID
returns the same results on different shards (see example).
Syntax
initialQueryID()
Returned value
- The ID of the initial current query.
Type: String
Example
Query:
CREATE TABLE tmp (str String) ENGINE = Log;
INSERT INTO tmp (*) VALUES ('a');
SELECT count(DISTINCT t) FROM (SELECT initialQueryID() AS t FROM remote('127.0.0.{1..3}', currentDatabase(), 'tmp') GROUP BY queryID());
Result:
┌─count()─┐
│ 1 │
└─────────┘
shardNum
Returns the index of a shard which processes a part of data in a distributed query. Indices are started from 1
.
If a query is not distributed then constant value 0
is returned.
Syntax
shardNum()
Returned value
- Shard index or constant
0
.
Type: UInt32.
Example
In the following example a configuration with two shards is used. The query is executed on the system.one table on every shard.
Query:
CREATE TABLE shard_num_example (dummy UInt8)
ENGINE=Distributed(test_cluster_two_shards_localhost, system, one, dummy);
SELECT dummy, shardNum(), shardCount() FROM shard_num_example;
Result:
┌─dummy─┬─shardNum()─┬─shardCount()─┐
│ 0 │ 2 │ 2 │
│ 0 │ 1 │ 2 │
└───────┴────────────┴──────────────┘
See Also
shardCount
Returns the total number of shards for a distributed query.
If a query is not distributed then constant value 0
is returned.
Syntax
shardCount()
Returned value
- Total number of shards or
0
.
Type: UInt32.
See Also
- shardNum() function example also contains
shardCount()
function call.
getOSKernelVersion
Returns a string with the current OS kernel version.
Syntax
getOSKernelVersion()
Arguments
- None.
Returned value
- The current OS kernel version.
Type: String.
Example
Query:
SELECT getOSKernelVersion();
Result:
┌─getOSKernelVersion()────┐
│ Linux 4.15.0-55-generic │
└─────────────────────────┘
zookeeperSessionUptime
Returns the uptime of the current ZooKeeper session in seconds.
Syntax
zookeeperSessionUptime()
Arguments
- None.
Returned value
- Uptime of the current ZooKeeper session in seconds.
Type: UInt32.
Example
Query:
SELECT zookeeperSessionUptime();
Result:
┌─zookeeperSessionUptime()─┐
│ 286 │
└──────────────────────────┘
generateRandomStructure
Generates random table structure in a format column1_name column1_type, column2_name column2_type, ...
.
Syntax
generateRandomStructure([number_of_columns, seed])
Arguments
number_of_columns
— The desired number of columns in the result table structure. If set to 0 orNull
, the number of columns will be random from 1 to 128. Default value:Null
.seed
- Random seed to produce stable results. If seed is not specified or set toNull
, it is randomly generated.
All arguments must be constant.
Returned value
- Randomly generated table structure.
Type: String.
Examples
Query:
SELECT generateRandomStructure()
Result:
┌─generateRandomStructure()─────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┐
│ c1 Decimal32(5), c2 Date, c3 Tuple(LowCardinality(String), Int128, UInt64, UInt16, UInt8, IPv6), c4 Array(UInt128), c5 UInt32, c6 IPv4, c7 Decimal256(64), c8 Decimal128(3), c9 UInt256, c10 UInt64, c11 DateTime │
└───────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┘
Query:
SELECT generateRandomStructure(1)
Result:
┌─generateRandomStructure(1)─┐
│ c1 Map(UInt256, UInt16) │
└────────────────────────────┘
Query:
SELECT generateRandomStructure(NULL, 33)
Result:
┌─generateRandomStructure(NULL, 33)─────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┐
│ c1 DateTime, c2 Enum8('c2V0' = 0, 'c2V1' = 1, 'c2V2' = 2, 'c2V3' = 3), c3 LowCardinality(Nullable(FixedString(30))), c4 Int16, c5 Enum8('c5V0' = 0, 'c5V1' = 1, 'c5V2' = 2, 'c5V3' = 3), c6 Nullable(UInt8), c7 String, c8 Nested(e1 IPv4, e2 UInt8, e3 UInt16, e4 UInt16, e5 Int32, e6 Map(Date, Decimal256(70))) │
└────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┘
Note: the maximum nesting depth of complex types (Array, Tuple, Map, Nested) is limited to 16.
This function can be used together with generateRandom to generate completely random tables.