Ordering During Aggregation#

Some aggregate functions such as array_agg() produce different results depending on the order of input values. This ordering can be specified by writing an ORDER BY Clause within the aggregate function:

array_agg(x ORDER BY y DESC)
array_agg(x ORDER BY x, y, z)

Filtering During Aggregation#

The FILTER keyword can be used to remove rows from aggregation processing with a condition expressed using a WHERE clause. This is evaluated for each row before it is used in the aggregation and is supported for all aggregate functions.

aggregate_function(...) FILTER (WHERE <condition>)

A common and very useful example is to use FILTER to remove nulls from consideration when using array_agg:

SELECT array_agg(name) FILTER (WHERE name IS NOT NULL)
FROM region;

As another example, imagine you want to add a condition on the count for Iris flowers, modifying the following query:

SELECT species,
       count(*) AS count
FROM iris
GROUP BY species;

species    | count
-----------+-------
setosa     |   50
virginica  |   50
versicolor |   50

If you just use a normal WHERE statement you loose information:

SELECT species,
    count(*) AS count
FROM iris
WHERE petal_length_cm > 4
GROUP BY species;

species    | count
-----------+-------
virginica  |   50
versicolor |   34

Using a filter you retain all information:

SELECT species,
       count(*) FILTER (where petal_length_cm > 4) AS count
FROM iris
GROUP BY species;

species    | count
-----------+-------
virginica  |   50
setosa     |    0
versicolor |   34

General Aggregate Functions#

arbitrary(x) → [same as input]#

Returns an arbitrary non-null value of x, if one exists.

array_agg(x) → array<[same as input]>#

Returns an array created from the input x elements.

avg(x) → double#

Returns the average (arithmetic mean) of all input values.

avg(time interval type) → time interval type

Returns the average interval length of all input values.

bool_and(boolean) → boolean#

Returns TRUE if every input value is TRUE, otherwise FALSE.

bool_or(boolean) → boolean#

Returns TRUE if any input value is TRUE, otherwise FALSE.

checksum(x) → varbinary#

Returns an order-insensitive checksum of the given values.

count(*) → bigint#

Returns the number of input rows.

count(x) → bigint

Returns the number of non-null input values.

count_if(x) → bigint#

Returns the number of TRUE input values. This function is equivalent to count(CASE WHEN x THEN 1 END).

every(boolean) → boolean#

This is an alias for bool_and().

geometric_mean(x) → double#

Returns the geometric mean of all input values.

max_by(x, y) → [same as x]#

Returns the value of x associated with the maximum value of y over all input values.

max_by(x, y, n) → array<[same as x]>

Returns n values of x associated with the n largest of all input values of y in descending order of y.

min_by(x, y) → [same as x]#

Returns the value of x associated with the minimum value of y over all input values.

min_by(x, y, n) → array<[same as x]>

Returns n values of x associated with the n smallest of all input values of y in ascending order of y.

max(x) → [same as input]#

Returns the maximum value of all input values.

max(x, n) → array<[same as x]>

Returns n largest values of all input values of x.

min(x) → [same as input]#

Returns the minimum value of all input values.

min(x, n) → array<[same as x]>

Returns n smallest values of all input values of x.

sum(x) → [same as input]#

Returns the sum of all input values.

Bitwise Aggregate Functions#

bitwise_and_agg(x) → bigint#

Returns the bitwise AND of all input values in 2’s complement representation.

bitwise_or_agg(x) → bigint#

Returns the bitwise OR of all input values in 2’s complement representation.

Map Aggregate Functions#

histogram(x) -> map(K, bigint)#

Returns a map containing the count of the number of times each input value occurs.

map_agg(key, value) -> map(K, V)#

Returns a map created from the input key / value pairs.

map_union(x(K, V)) -> map(K, V)#

Returns the union of all the input maps. If a key is found in multiple input maps, that key’s value in the resulting map comes from an arbitrary input map.

multimap_agg(key, value) -> map(K, array(V))#

Returns a multimap created from the input key / value pairs. Each key can be associated with multiple values.

Approximate Aggregate Functions#

approx_distinct(x) → bigint#

Returns the approximate number of distinct input values. This function provides an approximation of count(DISTINCT x). Zero is returned if all input values are null.

This function should produce a standard error of 2.3%, which is the standard deviation of the (approximately normal) error distribution over all possible sets. It does not guarantee an upper bound on the error for any specific input set.

approx_distinct(x, e) → bigint

Returns the approximate number of distinct input values. This function provides an approximation of count(DISTINCT x). Zero is returned if all input values are null.

This function should produce a standard error of no more than e, which is the standard deviation of the (approximately normal) error distribution over all possible sets. It does not guarantee an upper bound on the error for any specific input set. The current implementation of this function requires that e be in the range of [0.0040625, 0.26000].

approx_percentile(x, percentage) → [same as x]#

Returns the approximate percentile for all input values of x at the given percentage. The value of percentage must be between zero and one and must be constant for all input rows.

approx_percentile(x, percentages) → array<[same as x]>

Returns the approximate percentile for all input values of x at each of the specified percentages. Each element of the percentages array must be between zero and one, and the array must be constant for all input rows.

approx_percentile(x, w, percentage) → [same as x]

Returns the approximate weighed percentile for all input values of x using the per-item weight w at the percentage p. Weights must be strictly positive. Integer-value weights can be thought of as a replication count for the value x in the percentile set. The value of p must be between zero and one and must be constant for all input rows.

approx_percentile(x, w, percentage, accuracy) → [same as x]

Returns the approximate weighed percentile for all input values of x using the per-item weight w at the percentage p, with a maximum rank error of accuracy. Weights must be strictly positive. Integer-value weights can be thought of as a replication count for the value x in the percentile set. The value of p must be between zero and one and must be constant for all input rows. accuracy must be a value greater than zero and less than one, and it must be constant for all input rows.

approx_percentile(x, w, percentages) → array<[same as x]>

Returns the approximate weighed percentile for all input values of x using the per-item weight w at each of the given percentages specified in the array. Weights must be strictly positive. Integer-value weights can be thought of as a replication count for the value x in the percentile set. Each element of the array must be between zero and one, and the array must be constant for all input rows.

approx_set(x) → HyperLogLog

See HyperLogLog Functions.

merge(x) → HyperLogLog

See HyperLogLog Functions.

merge(qdigest(T)) -> qdigest(T)

See Quantile Digest Functions.

qdigest_agg(x) → qdigest<[same as x]>

See Quantile Digest Functions.

qdigest_agg(x, w) → qdigest<[same as x]>

See Quantile Digest Functions.

qdigest_agg(x, w, accuracy) → qdigest<[same as x]>

See Quantile Digest Functions.

numeric_histogram(buckets, value, weight) → map<double, double>#

Computes an approximate histogram with up to buckets number of buckets for all values with a per-item weight of weight. The algorithm is based loosely on:

Yael Ben-Haim and Elad Tom-Tov, "A streaming parallel decision tree algorithm",
J. Machine Learning Research 11 (2010), pp. 849--872.

buckets must be a bigint. value and weight must be numeric.

numeric_histogram(buckets, value) → map<double, double>

Computes an approximate histogram with up to buckets number of buckets for all values. This function is equivalent to the variant of numeric_histogram() that takes a weight, with a per-item weight of 1.

Statistical Aggregate Functions#

corr(y, x) → double#

Returns correlation coefficient of input values.

covar_pop(y, x) → double#

Returns the population covariance of input values.

covar_samp(y, x) → double#

Returns the sample covariance of input values.

kurtosis(x) → double#

Returns the excess kurtosis of all input values. Unbiased estimate using the following expression:

kurtosis(x) = n(n+1)/((n-1)(n-2)(n-3))sum[(x_i-mean)^4]/stddev(x)^4-3(n-1)^2/((n-2)(n-3))

regr_intercept(y, x) → double#

Returns linear regression intercept of input values. y is the dependent value. x is the independent value.

regr_slope(y, x) → double#

Returns linear regression slope of input values. y is the dependent value. x is the independent value.

skewness(x) → double#

Returns the skewness of all input values.

stddev(x) → double#

This is an alias for stddev_samp().

stddev_pop(x) → double#

Returns the population standard deviation of all input values.

stddev_samp(x) → double#

Returns the sample standard deviation of all input values.

variance(x) → double#

This is an alias for var_samp().

var_pop(x) → double#

Returns the population variance of all input values.

var_samp(x) → double#

Returns the sample variance of all input values.

Lambda Aggregate Functions#

reduce_agg(inputValue T, initialState S, inputFunction(S, T, S), combineFunction(S, S, S)) → S#

Reduces all input values into a single value. inputFunction will be invoked for each non-null input value. In addition to taking the input value, inputFunction takes the current state, initially initialState, and returns the new state. combineFunction will be invoked to combine two states into a new state. The final state is returned:

SELECT id, reduce_agg(value, 0, (a, b) -> a + b, (a, b) -> a + b)
FROM (
    VALUES
        (1, 3),
        (1, 4),
        (1, 5),
        (2, 6),
        (2, 7)
) AS t(id, value)
GROUP BY id;
-- (1, 12)
-- (2, 13)

SELECT id, reduce_agg(value, 1, (a, b) -> a * b, (a, b) -> a * b)
FROM (
    VALUES
        (1, 3),
        (1, 4),
        (1, 5),
        (2, 6),
        (2, 7)
) AS t(id, value)
GROUP BY id;
-- (1, 60)
-- (2, 42)

The state type must be a boolean, integer, floating-point, or date/time/interval.