- Functions for working with arrays
- empty
- notEmpty
- length
- emptyArrayUInt8, emptyArrayUInt16, emptyArrayUInt32, emptyArrayUInt64
- emptyArrayInt8, emptyArrayInt16, emptyArrayInt32, emptyArrayInt64
- emptyArrayFloat32, emptyArrayFloat64
- emptyArrayDate, emptyArrayDateTime
- emptyArrayString
- emptyArrayToSingle
- range(end), range(start, end [, step])
- array(x1, …), operator [x1, …]
- arrayConcat
- arrayElement(arr, n), operator arr[n]
- has(arr, elem)
- hasAll
- hasAny
- indexOf(arr, x)
- countEqual(arr, x)
- arrayEnumerate(arr)
- arrayEnumerateUniq(arr, …)
- arrayPopBack
- arrayPopFront
- arrayPushBack
- arrayPushFront
- arrayResize
- arraySlice
- arraySort([func,] arr, …)
- arrayReverseSort([func,] arr, …)
- arrayUniq(arr, …)
- arrayJoin(arr)
- arrayDifference
- arrayDistinct
- arrayEnumerateDense(arr)
- arrayIntersect(arr)
- arrayReduce(agg_func, arr1, …)
- arrayReverse(arr)
- reverse(arr)
- arrayFlatten
- arrayCompact
- arrayZip
Functions for working with arrays
empty
Returns 1 for an empty array, or 0 for a non-empty array.
The result type is UInt8.
The function also works for strings.
notEmpty
Returns 0 for an empty array, or 1 for a non-empty array.
The result type is UInt8.
The function also works for strings.
length
Returns the number of items in the array.
The result type is UInt64.
The function also works for strings.
emptyArrayUInt8, emptyArrayUInt16, emptyArrayUInt32, emptyArrayUInt64
emptyArrayInt8, emptyArrayInt16, emptyArrayInt32, emptyArrayInt64
emptyArrayFloat32, emptyArrayFloat64
emptyArrayDate, emptyArrayDateTime
emptyArrayString
Accepts zero arguments and returns an empty array of the appropriate type.
emptyArrayToSingle
Accepts an empty array and returns a one-element array that is equal to the default value.
range(end), range(start, end [, step])
Returns an array of numbers from start to end-1 by step.
If the argument start
is not specified, defaults to 0.
If the argument step
is not specified, defaults to 1.
It behaviors almost like pythonic range
. But the difference is that all the arguments type must be UInt
numbers.
Just in case, an exception is thrown if arrays with a total length of more than 100,000,000 elements are created in a data block.
array(x1, …), operator [x1, …]
Creates an array from the function arguments.
The arguments must be constants and have types that have the smallest common type. At least one argument must be passed, because otherwise it isn’t clear which type of array to create. That is, you can’t use this function to create an empty array (to do that, use the ‘emptyArray*‘ function described above).
Returns an ‘Array(T)’ type result, where ‘T’ is the smallest common type out of the passed arguments.
arrayConcat
Combines arrays passed as arguments.
arrayConcat(arrays)
Parameters
arrays
– Arbitrary number of arguments of Array type.
Example
SELECT arrayConcat([1, 2], [3, 4], [5, 6]) AS res
┌─res───────────┐
│ [1,2,3,4,5,6] │
└───────────────┘
arrayElement(arr, n), operator arr[n]
Get the element with the index n
from the array arr
. n
must be any integer type.
Indexes in an array begin from one.
Negative indexes are supported. In this case, it selects the corresponding element numbered from the end. For example, arr[-1]
is the last item in the array.
If the index falls outside of the bounds of an array, it returns some default value (0 for numbers, an empty string for strings, etc.), except for the case with a non-constant array and a constant index 0 (in this case there will be an error Array indices are 1-based
).
has(arr, elem)
Checks whether the ‘arr’ array has the ‘elem’ element.
Returns 0 if the the element is not in the array, or 1 if it is.
NULL
is processed as a value.
SELECT has([1, 2, NULL], NULL)
┌─has([1, 2, NULL], NULL)─┐
│ 1 │
└─────────────────────────┘
hasAll
Checks whether one array is a subset of another.
hasAll(set, subset)
Parameters
set
– Array of any type with a set of elements.subset
– Array of any type with elements that should be tested to be a subset ofset
.
Return values
1
, ifset
contains all of the elements fromsubset
.0
, otherwise.
Peculiar properties
- An empty array is a subset of any array.
Null
processed as a value.- Order of values in both of arrays doesn’t matter.
Examples
SELECT hasAll([], [])
returns 1.
SELECT hasAll([1, Null], [Null])
returns 1.
SELECT hasAll([1.0, 2, 3, 4], [1, 3])
returns 1.
SELECT hasAll(['a', 'b'], ['a'])
returns 1.
SELECT hasAll([1], ['a'])
returns 0.
SELECT hasAll([[1, 2], [3, 4]], [[1, 2], [3, 5]])
returns 0.
hasAny
Checks whether two arrays have intersection by some elements.
hasAny(array1, array2)
Parameters
array1
– Array of any type with a set of elements.array2
– Array of any type with a set of elements.
Return values
1
, ifarray1
andarray2
have one similar element at least.0
, otherwise.
Peculiar properties
Null
processed as a value.- Order of values in both of arrays doesn’t matter.
Examples
SELECT hasAny([1], [])
returns 0
.
SELECT hasAny([Null], [Null, 1])
returns 1
.
SELECT hasAny([-128, 1., 512], [1])
returns 1
.
SELECT hasAny([[1, 2], [3, 4]], ['a', 'c'])
returns 0
.
SELECT hasAll([[1, 2], [3, 4]], [[1, 2], [1, 2]])
returns 1
.
indexOf(arr, x)
Returns the index of the first ‘x’ element (starting from 1) if it is in the array, or 0 if it is not.
Example:
SELECT indexOf([1, 3, NULL, NULL], NULL)
┌─indexOf([1, 3, NULL, NULL], NULL)─┐
│ 3 │
└───────────────────────────────────┘
Elements set to NULL
are handled as normal values.
countEqual(arr, x)
Returns the number of elements in the array equal to x. Equivalent to arrayCount (elem -> elem = x, arr).
NULL
elements are handled as separate values.
Example:
SELECT countEqual([1, 2, NULL, NULL], NULL)
┌─countEqual([1, 2, NULL, NULL], NULL)─┐
│ 2 │
└──────────────────────────────────────┘
arrayEnumerate(arr)
Returns the array [1, 2, 3, …, length (arr) ]
This function is normally used with ARRAY JOIN. It allows counting something just once for each array after applying ARRAY JOIN. Example:
SELECT
count() AS Reaches,
countIf(num = 1) AS Hits
FROM test.hits
ARRAY JOIN
GoalsReached,
arrayEnumerate(GoalsReached) AS num
WHERE CounterID = 160656
LIMIT 10
┌─Reaches─┬──Hits─┐
│ 95606 │ 31406 │
└─────────┴───────┘
In this example, Reaches is the number of conversions (the strings received after applying ARRAY JOIN), and Hits is the number of pageviews (strings before ARRAY JOIN). In this particular case, you can get the same result in an easier way:
SELECT
sum(length(GoalsReached)) AS Reaches,
count() AS Hits
FROM test.hits
WHERE (CounterID = 160656) AND notEmpty(GoalsReached)
┌─Reaches─┬──Hits─┐
│ 95606 │ 31406 │
└─────────┴───────┘
This function can also be used in higher-order functions. For example, you can use it to get array indexes for elements that match a condition.
arrayEnumerateUniq(arr, …)
Returns an array the same size as the source array, indicating for each element what its position is among elements with the same value.
For example: arrayEnumerateUniq([10, 20, 10, 30]) = [1, 1, 2, 1].
This function is useful when using ARRAY JOIN and aggregation of array elements.
Example:
SELECT
Goals.ID AS GoalID,
sum(Sign) AS Reaches,
sumIf(Sign, num = 1) AS Visits
FROM test.visits
ARRAY JOIN
Goals,
arrayEnumerateUniq(Goals.ID) AS num
WHERE CounterID = 160656
GROUP BY GoalID
ORDER BY Reaches DESC
LIMIT 10
┌──GoalID─┬─Reaches─┬─Visits─┐
│ 53225 │ 3214 │ 1097 │
│ 2825062 │ 3188 │ 1097 │
│ 56600 │ 2803 │ 488 │
│ 1989037 │ 2401 │ 365 │
│ 2830064 │ 2396 │ 910 │
│ 1113562 │ 2372 │ 373 │
│ 3270895 │ 2262 │ 812 │
│ 1084657 │ 2262 │ 345 │
│ 56599 │ 2260 │ 799 │
│ 3271094 │ 2256 │ 812 │
└─────────┴─────────┴────────┘
In this example, each goal ID has a calculation of the number of conversions (each element in the Goals nested data structure is a goal that was reached, which we refer to as a conversion) and the number of sessions. Without ARRAY JOIN, we would have counted the number of sessions as sum(Sign). But in this particular case, the rows were multiplied by the nested Goals structure, so in order to count each session one time after this, we apply a condition to the value of the arrayEnumerateUniq(Goals.ID) function.
The arrayEnumerateUniq function can take multiple arrays of the same size as arguments. In this case, uniqueness is considered for tuples of elements in the same positions in all the arrays.
SELECT arrayEnumerateUniq([1, 1, 1, 2, 2, 2], [1, 1, 2, 1, 1, 2]) AS res
┌─res───────────┐
│ [1,2,1,1,2,1] │
└───────────────┘
This is necessary when using ARRAY JOIN with a nested data structure and further aggregation across multiple elements in this structure.
arrayPopBack
Removes the last item from the array.
arrayPopBack(array)
Parameters
array
– Array.
Example
SELECT arrayPopBack([1, 2, 3]) AS res
┌─res───┐
│ [1,2] │
└───────┘
arrayPopFront
Removes the first item from the array.
arrayPopFront(array)
Parameters
array
– Array.
Example
SELECT arrayPopFront([1, 2, 3]) AS res
┌─res───┐
│ [2,3] │
└───────┘
arrayPushBack
Adds one item to the end of the array.
arrayPushBack(array, single_value)
Parameters
array
– Array.single_value
– A single value. Only numbers can be added to an array with numbers, and only strings can be added to an array of strings. When adding numbers, ClickHouse automatically sets thesingle_value
type for the data type of the array. For more information about the types of data in ClickHouse, see “Data types“. Can beNULL
. The function adds aNULL
element to an array, and the type of array elements converts toNullable
.
Example
SELECT arrayPushBack(['a'], 'b') AS res
┌─res───────┐
│ ['a','b'] │
└───────────┘
arrayPushFront
Adds one element to the beginning of the array.
arrayPushFront(array, single_value)
Parameters
array
– Array.single_value
– A single value. Only numbers can be added to an array with numbers, and only strings can be added to an array of strings. When adding numbers, ClickHouse automatically sets thesingle_value
type for the data type of the array. For more information about the types of data in ClickHouse, see “Data types“. Can beNULL
. The function adds aNULL
element to an array, and the type of array elements converts toNullable
.
Example
SELECT arrayPushFront(['b'], 'a') AS res
┌─res───────┐
│ ['a','b'] │
└───────────┘
arrayResize
Changes the length of the array.
arrayResize(array, size[, extender])
Parameters:
array
— Array.size
— Required length of the array.- If
size
is less than the original size of the array, the array is truncated from the right.
- If
- If
size
is larger than the initial size of the array, the array is extended to the right withextender
values or default values for the data type of the array items. extender
— Value for extending an array. Can beNULL
.
Returned value:
An array of length size
.
Examples of calls
SELECT arrayResize([1], 3)
┌─arrayResize([1], 3)─┐
│ [1,0,0] │
└─────────────────────┘
SELECT arrayResize([1], 3, NULL)
┌─arrayResize([1], 3, NULL)─┐
│ [1,NULL,NULL] │
└───────────────────────────┘
arraySlice
Returns a slice of the array.
arraySlice(array, offset[, length])
Parameters
array
– Array of data.offset
– Indent from the edge of the array. A positive value indicates an offset on the left, and a negative value is an indent on the right. Numbering of the array items begins with 1.length
- The length of the required slice. If you specify a negative value, the function returns an open slice[offset, array_length - length)
. If you omit the value, the function returns the slice[offset, the_end_of_array]
.
Example
SELECT arraySlice([1, 2, NULL, 4, 5], 2, 3) AS res
┌─res────────┐
│ [2,NULL,4] │
└────────────┘
Array elements set to NULL
are handled as normal values.
arraySort([func,] arr, …)
Sorts the elements of the arr
array in ascending order. If the func
function is specified, sorting order is determined by the result of the func
function applied to the elements of the array. If func
accepts multiple arguments, the arraySort
function is passed several arrays that the arguments of func
will correspond to. Detailed examples are shown at the end of arraySort
description.
Example of integer values sorting:
SELECT arraySort([1, 3, 3, 0]);
┌─arraySort([1, 3, 3, 0])─┐
│ [0,1,3,3] │
└─────────────────────────┘
Example of string values sorting:
SELECT arraySort(['hello', 'world', '!']);
┌─arraySort(['hello', 'world', '!'])─┐
│ ['!','hello','world'] │
└────────────────────────────────────┘
Consider the following sorting order for the NULL
, NaN
and Inf
values:
SELECT arraySort([1, nan, 2, NULL, 3, nan, -4, NULL, inf, -inf]);
┌─arraySort([1, nan, 2, NULL, 3, nan, -4, NULL, inf, -inf])─┐
│ [-inf,-4,1,2,3,inf,nan,nan,NULL,NULL] │
└───────────────────────────────────────────────────────────┘
-Inf
values are first in the array.NULL
values are last in the array.NaN
values are right beforeNULL
.Inf
values are right beforeNaN
.
Note that arraySort
is a higher-order function. You can pass a lambda function to it as the first argument. In this case, sorting order is determined by the result of the lambda function applied to the elements of the array.
Let’s consider the following example:
SELECT arraySort((x) -> -x, [1, 2, 3]) as res;
┌─res─────┐
│ [3,2,1] │
└─────────┘
For each element of the source array, the lambda function returns the sorting key, that is, [1 –> -1, 2 –> -2, 3 –> -3]. Since the arraySort
function sorts the keys in ascending order, the result is [3, 2, 1]. Thus, the (x) –> -x
lambda function sets the descending order in a sorting.
The lambda function can accept multiple arguments. In this case, you need to pass the arraySort
function several arrays of identical length that the arguments of lambda function will correspond to. The resulting array will consist of elements from the first input array; elements from the next input array(s) specify the sorting keys. For example:
SELECT arraySort((x, y) -> y, ['hello', 'world'], [2, 1]) as res;
┌─res────────────────┐
│ ['world', 'hello'] │
└────────────────────┘
Here, the elements that are passed in the second array ([2, 1]) define a sorting key for the corresponding element from the source array ([‘hello’, ‘world’]), that is, [‘hello’ –> 2, ‘world’ –> 1]. Since the lambda function doesn’t use x
, actual values of the source array don’t affect the order in the result. So, ‘hello’ will be the second element in the result, and ‘world’ will be the first.
Other examples are shown below.
SELECT arraySort((x, y) -> y, [0, 1, 2], ['c', 'b', 'a']) as res;
┌─res─────┐
│ [2,1,0] │
└─────────┘
SELECT arraySort((x, y) -> -y, [0, 1, 2], [1, 2, 3]) as res;
┌─res─────┐
│ [2,1,0] │
└─────────┘
Note
To improve sorting efficiency, the Schwartzian transform is used.
arrayReverseSort([func,] arr, …)
Sorts the elements of the arr
array in descending order. If the func
function is specified, arr
is sorted according to the result of the func
function applied to the elements of the array, and then the sorted array is reversed. If func
accepts multiple arguments, the arrayReverseSort
function is passed several arrays that the arguments of func
will correspond to. Detailed examples are shown at the end of arrayReverseSort
description.
Example of integer values sorting:
SELECT arrayReverseSort([1, 3, 3, 0]);
┌─arrayReverseSort([1, 3, 3, 0])─┐
│ [3,3,1,0] │
└────────────────────────────────┘
Example of string values sorting:
SELECT arrayReverseSort(['hello', 'world', '!']);
┌─arrayReverseSort(['hello', 'world', '!'])─┐
│ ['world','hello','!'] │
└───────────────────────────────────────────┘
Consider the following sorting order for the NULL
, NaN
and Inf
values:
SELECT arrayReverseSort([1, nan, 2, NULL, 3, nan, -4, NULL, inf, -inf]) as res;
┌─res───────────────────────────────────┐
│ [inf,3,2,1,-4,-inf,nan,nan,NULL,NULL] │
└───────────────────────────────────────┘
Inf
values are first in the array.NULL
values are last in the array.NaN
values are right beforeNULL
.-Inf
values are right beforeNaN
.
Note that the arrayReverseSort
is a higher-order function. You can pass a lambda function to it as the first argument. Example is shown below.
SELECT arrayReverseSort((x) -> -x, [1, 2, 3]) as res;
┌─res─────┐
│ [1,2,3] │
└─────────┘
The array is sorted in the following way:
- At first, the source array ([1, 2, 3]) is sorted according to the result of the lambda function applied to the elements of the array. The result is an array [3, 2, 1].
- Array that is obtained on the previous step, is reversed. So, the final result is [1, 2, 3].
The lambda function can accept multiple arguments. In this case, you need to pass the arrayReverseSort
function several arrays of identical length that the arguments of lambda function will correspond to. The resulting array will consist of elements from the first input array; elements from the next input array(s) specify the sorting keys. For example:
SELECT arrayReverseSort((x, y) -> y, ['hello', 'world'], [2, 1]) as res;
┌─res───────────────┐
│ ['hello','world'] │
└───────────────────┘
In this example, the array is sorted in the following way:
- At first, the source array ([‘hello’, ‘world’]) is sorted according to the result of the lambda function applied to the elements of the arrays. The elements that are passed in the second array ([2, 1]), define the sorting keys for corresponding elements from the source array. The result is an array [‘world’, ‘hello’].
- Array that was sorted on the previous step, is reversed. So, the final result is [‘hello’, ‘world’].
Other examples are shown below.
SELECT arrayReverseSort((x, y) -> y, [4, 3, 5], ['a', 'b', 'c']) AS res;
┌─res─────┐
│ [5,3,4] │
└─────────┘
SELECT arrayReverseSort((x, y) -> -y, [4, 3, 5], [1, 2, 3]) AS res;
┌─res─────┐
│ [4,3,5] │
└─────────┘
arrayUniq(arr, …)
If one argument is passed, it counts the number of different elements in the array.
If multiple arguments are passed, it counts the number of different tuples of elements at corresponding positions in multiple arrays.
If you want to get a list of unique items in an array, you can use arrayReduce(‘groupUniqArray’, arr).
arrayJoin(arr)
A special function. See the section “ArrayJoin function”.
arrayDifference
Calculates the difference between adjacent array elements. Returns an array where the first element will be 0, the second is the difference between a[1] - a[0]
, etc. The type of elements in the resulting array is determined by the type inference rules for subtraction (e.g. UInt8
- UInt8
= Int16
).
Syntax
arrayDifference(array)
Parameters
array
– Array.
Returned values
Returns an array of differences between adjacent elements.
Example
Query:
SELECT arrayDifference([1, 2, 3, 4])
Result:
┌─arrayDifference([1, 2, 3, 4])─┐
│ [0,1,1,1] │
└───────────────────────────────┘
Example of the overflow due to result type Int64:
Query:
SELECT arrayDifference([0, 10000000000000000000])
Result:
┌─arrayDifference([0, 10000000000000000000])─┐
│ [0,-8446744073709551616] │
└────────────────────────────────────────────┘
arrayDistinct
Takes an array, returns an array containing the distinct elements only.
Syntax
arrayDistinct(array)
Parameters
array
– Array.
Returned values
Returns an array containing the distinct elements.
Example
Query:
SELECT arrayDistinct([1, 2, 2, 3, 1])
Result:
┌─arrayDistinct([1, 2, 2, 3, 1])─┐
│ [1,2,3] │
└────────────────────────────────┘
arrayEnumerateDense(arr)
Returns an array of the same size as the source array, indicating where each element first appears in the source array.
Example:
SELECT arrayEnumerateDense([10, 20, 10, 30])
┌─arrayEnumerateDense([10, 20, 10, 30])─┐
│ [1,2,1,3] │
└───────────────────────────────────────┘
arrayIntersect(arr)
Takes multiple arrays, returns an array with elements that are present in all source arrays. Elements order in the resulting array is the same as in the first array.
Example:
SELECT
arrayIntersect([1, 2], [1, 3], [2, 3]) AS no_intersect,
arrayIntersect([1, 2], [1, 3], [1, 4]) AS intersect
┌─no_intersect─┬─intersect─┐
│ [] │ [1] │
└──────────────┴───────────┘
arrayReduce(agg_func, arr1, …)
Applies an aggregate function to array elements and returns its result. The name of the aggregation function is passed as a string in single quotes 'max'
, 'sum'
. When using parametric aggregate functions, the parameter is indicated after the function name in parentheses 'uniqUpTo(6)'
.
Example:
SELECT arrayReduce('max', [1, 2, 3])
┌─arrayReduce('max', [1, 2, 3])─┐
│ 3 │
└───────────────────────────────┘
If an aggregate function takes multiple arguments, then this function must be applied to multiple arrays of the same size.
Example:
SELECT arrayReduce('maxIf', [3, 5], [1, 0])
┌─arrayReduce('maxIf', [3, 5], [1, 0])─┐
│ 3 │
└──────────────────────────────────────┘
Example with a parametric aggregate function:
SELECT arrayReduce('uniqUpTo(3)', [1, 2, 3, 4, 5, 6, 7, 8, 9, 10])
┌─arrayReduce('uniqUpTo(3)', [1, 2, 3, 4, 5, 6, 7, 8, 9, 10])─┐
│ 4 │
└─────────────────────────────────────────────────────────────┘
arrayReverse(arr)
Returns an array of the same size as the original array containing the elements in reverse order.
Example:
SELECT arrayReverse([1, 2, 3])
┌─arrayReverse([1, 2, 3])─┐
│ [3,2,1] │
└─────────────────────────┘
reverse(arr)
Synonym for “arrayReverse”
arrayFlatten
Converts an array of arrays to a flat array.
Function:
- Applies to any depth of nested arrays.
- Does not change arrays that are already flat.
The flattened array contains all the elements from all source arrays.
Syntax
flatten(array_of_arrays)
Alias: flatten
.
Parameters
array_of_arrays
— Array of arrays. For example,[[1,2,3], [4,5]]
.
Examples
SELECT flatten([[[1]], [[2], [3]]])
┌─flatten(array(array([1]), array([2], [3])))─┐
│ [1,2,3] │
└─────────────────────────────────────────────┘
arrayCompact
Removes consecutive duplicate elements from an array. The order of result values is determined by the order in the source array.
Syntax
arrayCompact(arr)
Parameters
arr
— The array to inspect.
Returned value
The array without duplicate.
Type: Array
.
Example
Query:
SELECT arrayCompact([1, 1, nan, nan, 2, 3, 3, 3])
Result:
┌─arrayCompact([1, 1, nan, nan, 2, 3, 3, 3])─┐
│ [1,nan,nan,2,3] │
└────────────────────────────────────────────┘
arrayZip
Combine multiple Array type columns into one Array[Tuple(…)] column
Syntax
arrayZip(arr1, arr2, ..., arrN)
Parameters
arr
— Any number of array type columns to combine.
Returned value
The result of Array[Tuple(…)] type after the combination of these arrays
Example
Query:
SELECT arrayZip(['a', 'b', 'c'], ['d', 'e', 'f']);
Result:
┌─arrayZip(['a', 'b', 'c'], ['d', 'e', 'f'])─┐
│ [('a','d'),('b','e'),('c','f')] │
└────────────────────────────────────────────┘