32 KiB
slug | sidebar_position | sidebar_label |
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/en/sql-reference/aggregate-functions/parametric-functions | 38 | Parametric |
Parametric Aggregate Functions
Some aggregate functions can accept not only argument columns (used for compression), but a set of parameters – constants for initialization. The syntax is two pairs of brackets instead of one. The first is for parameters, and the second is for arguments.
histogram
Calculates an adaptive histogram. It does not guarantee precise results.
histogram(number_of_bins)(values)
The functions uses A Streaming Parallel Decision Tree Algorithm. The borders of histogram bins are adjusted as new data enters a function. In common case, the widths of bins are not equal.
Arguments
values
— Expression resulting in input values.
Parameters
number_of_bins
— Upper limit for the number of bins in the histogram. The function automatically calculates the number of bins. It tries to reach the specified number of bins, but if it fails, it uses fewer bins.
Returned values
-
Array of Tuples of the following format:
``` [(lower_1, upper_1, height_1), ... (lower_N, upper_N, height_N)] ``` - `lower` — Lower bound of the bin. - `upper` — Upper bound of the bin. - `height` — Calculated height of the bin.
Example
SELECT histogram(5)(number + 1)
FROM (
SELECT *
FROM system.numbers
LIMIT 20
)
┌─histogram(5)(plus(number, 1))───────────────────────────────────────────┐
│ [(1,4.5,4),(4.5,8.5,4),(8.5,12.75,4.125),(12.75,17,4.625),(17,20,3.25)] │
└─────────────────────────────────────────────────────────────────────────┘
You can visualize a histogram with the bar function, for example:
WITH histogram(5)(rand() % 100) AS hist
SELECT
arrayJoin(hist).3 AS height,
bar(height, 0, 6, 5) AS bar
FROM
(
SELECT *
FROM system.numbers
LIMIT 20
)
┌─height─┬─bar───┐
│ 2.125 │ █▋ │
│ 3.25 │ ██▌ │
│ 5.625 │ ████▏ │
│ 5.625 │ ████▏ │
│ 3.375 │ ██▌ │
└────────┴───────┘
In this case, you should remember that you do not know the histogram bin borders.
sequenceMatch
Checks whether the sequence contains an event chain that matches the pattern.
Syntax
sequenceMatch(pattern)(timestamp, cond1, cond2, ...)
:::note Events that occur at the same second may lay in the sequence in an undefined order affecting the result. :::
Arguments
-
timestamp
— Column considered to contain time data. Typical data types areDate
andDateTime
. You can also use any of the supported UInt data types. -
cond1
,cond2
— Conditions that describe the chain of events. Data type:UInt8
. You can pass up to 32 condition arguments. The function takes only the events described in these conditions into account. If the sequence contains data that isn’t described in a condition, the function skips them.
Parameters
pattern
— Pattern string. See Pattern syntax.
Returned values
- 1, if the pattern is matched.
- 0, if the pattern isn’t matched.
Type: UInt8
.
Pattern syntax
-
(?N)
— Matches the condition argument at positionN
. Conditions are numbered in the[1, 32]
range. For example,(?1)
matches the argument passed to thecond1
parameter. -
.*
— Matches any number of events. You do not need conditional arguments to match this element of the pattern. -
(?t operator value)
— Sets the time in seconds that should separate two events. For example, pattern(?1)(?t>1800)(?2)
matches events that occur more than 1800 seconds from each other. An arbitrary number of any events can lay between these events. You can use the>=
,>
,<
,<=
,==
operators.
Examples
Consider data in the t
table:
┌─time─┬─number─┐
│ 1 │ 1 │
│ 2 │ 3 │
│ 3 │ 2 │
└──────┴────────┘
Perform the query:
SELECT sequenceMatch('(?1)(?2)')(time, number = 1, number = 2) FROM t
┌─sequenceMatch('(?1)(?2)')(time, equals(number, 1), equals(number, 2))─┐
│ 1 │
└───────────────────────────────────────────────────────────────────────┘
The function found the event chain where number 2 follows number 1. It skipped number 3 between them, because the number is not described as an event. If we want to take this number into account when searching for the event chain given in the example, we should make a condition for it.
SELECT sequenceMatch('(?1)(?2)')(time, number = 1, number = 2, number = 3) FROM t
┌─sequenceMatch('(?1)(?2)')(time, equals(number, 1), equals(number, 2), equals(number, 3))─┐
│ 0 │
└──────────────────────────────────────────────────────────────────────────────────────────┘
In this case, the function couldn’t find the event chain matching the pattern, because the event for number 3 occurred between 1 and 2. If in the same case we checked the condition for number 4, the sequence would match the pattern.
SELECT sequenceMatch('(?1)(?2)')(time, number = 1, number = 2, number = 4) FROM t
┌─sequenceMatch('(?1)(?2)')(time, equals(number, 1), equals(number, 2), equals(number, 4))─┐
│ 1 │
└──────────────────────────────────────────────────────────────────────────────────────────┘
See Also
sequenceCount
Counts the number of event chains that matched the pattern. The function searches event chains that do not overlap. It starts to search for the next chain after the current chain is matched.
:::note Events that occur at the same second may lay in the sequence in an undefined order affecting the result. :::
Syntax
sequenceCount(pattern)(timestamp, cond1, cond2, ...)
Arguments
-
timestamp
— Column considered to contain time data. Typical data types areDate
andDateTime
. You can also use any of the supported UInt data types. -
cond1
,cond2
— Conditions that describe the chain of events. Data type:UInt8
. You can pass up to 32 condition arguments. The function takes only the events described in these conditions into account. If the sequence contains data that isn’t described in a condition, the function skips them.
Parameters
pattern
— Pattern string. See Pattern syntax.
Returned values
- Number of non-overlapping event chains that are matched.
Type: UInt64
.
Example
Consider data in the t
table:
┌─time─┬─number─┐
│ 1 │ 1 │
│ 2 │ 3 │
│ 3 │ 2 │
│ 4 │ 1 │
│ 5 │ 3 │
│ 6 │ 2 │
└──────┴────────┘
Count how many times the number 2 occurs after the number 1 with any amount of other numbers between them:
SELECT sequenceCount('(?1).*(?2)')(time, number = 1, number = 2) FROM t
┌─sequenceCount('(?1).*(?2)')(time, equals(number, 1), equals(number, 2))─┐
│ 2 │
└─────────────────────────────────────────────────────────────────────────┘
See Also
windowFunnel
Searches for event chains in a sliding time window and calculates the maximum number of events that occurred from the chain.
The function works according to the algorithm:
-
The function searches for data that triggers the first condition in the chain and sets the event counter to 1. This is the moment when the sliding window starts.
-
If events from the chain occur sequentially within the window, the counter is incremented. If the sequence of events is disrupted, the counter isn’t incremented.
-
If the data has multiple event chains at varying points of completion, the function will only output the size of the longest chain.
Syntax
windowFunnel(window, [mode, [mode, ... ]])(timestamp, cond1, cond2, ..., condN)
Arguments
timestamp
— Name of the column containing the timestamp. Data types supported: Date, DateTime and other unsigned integer types (note that even though timestamp supports theUInt64
type, it’s value can’t exceed the Int64 maximum, which is 2^63 - 1).cond
— Conditions or data describing the chain of events. UInt8.
Parameters
window
— Length of the sliding window, it is the time interval between the first and the last condition. The unit ofwindow
depends on thetimestamp
itself and varies. Determined using the expressiontimestamp of cond1 <= timestamp of cond2 <= ... <= timestamp of condN <= timestamp of cond1 + window
.mode
— It is an optional argument. One or more modes can be set.'strict_deduplication'
— If the same condition holds for the sequence of events, then such repeating event interrupts further processing. Note: it may work unexpectedly if several conditions hold for the same event.'strict_order'
— Don't allow interventions of other events. E.g. in the case ofA->B->D->C
, it stops findingA->B->C
at theD
and the max event level is 2.'strict_increase'
— Apply conditions only to events with strictly increasing timestamps.
Returned value
The maximum number of consecutive triggered conditions from the chain within the sliding time window. All the chains in the selection are analyzed.
Type: Integer
.
Example
Determine if a set period of time is enough for the user to select a phone and purchase it twice in the online store.
Set the following chain of events:
- The user logged in to their account on the store (
eventID = 1003
). - The user searches for a phone (
eventID = 1007, product = 'phone'
). - The user placed an order (
eventID = 1009
). - The user made the order again (
eventID = 1010
).
Input table:
┌─event_date─┬─user_id─┬───────────timestamp─┬─eventID─┬─product─┐
│ 2019-01-28 │ 1 │ 2019-01-29 10:00:00 │ 1003 │ phone │
└────────────┴─────────┴─────────────────────┴─────────┴─────────┘
┌─event_date─┬─user_id─┬───────────timestamp─┬─eventID─┬─product─┐
│ 2019-01-31 │ 1 │ 2019-01-31 09:00:00 │ 1007 │ phone │
└────────────┴─────────┴─────────────────────┴─────────┴─────────┘
┌─event_date─┬─user_id─┬───────────timestamp─┬─eventID─┬─product─┐
│ 2019-01-30 │ 1 │ 2019-01-30 08:00:00 │ 1009 │ phone │
└────────────┴─────────┴─────────────────────┴─────────┴─────────┘
┌─event_date─┬─user_id─┬───────────timestamp─┬─eventID─┬─product─┐
│ 2019-02-01 │ 1 │ 2019-02-01 08:00:00 │ 1010 │ phone │
└────────────┴─────────┴─────────────────────┴─────────┴─────────┘
Find out how far the user user_id
could get through the chain in a period in January-February of 2019.
Query:
SELECT
level,
count() AS c
FROM
(
SELECT
user_id,
windowFunnel(6048000000000000)(timestamp, eventID = 1003, eventID = 1009, eventID = 1007, eventID = 1010) AS level
FROM trend
WHERE (event_date >= '2019-01-01') AND (event_date <= '2019-02-02')
GROUP BY user_id
)
GROUP BY level
ORDER BY level ASC;
Result:
┌─level─┬─c─┐
│ 4 │ 1 │
└───────┴───┘
retention
The function takes as arguments a set of conditions from 1 to 32 arguments of type UInt8
that indicate whether a certain condition was met for the event.
Any condition can be specified as an argument (as in WHERE).
The conditions, except the first, apply in pairs: the result of the second will be true if the first and second are true, of the third if the first and third are true, etc.
Syntax
retention(cond1, cond2, ..., cond32);
Arguments
cond
— An expression that returns aUInt8
result (1 or 0).
Returned value
The array of 1 or 0.
- 1 — Condition was met for the event.
- 0 — Condition wasn’t met for the event.
Type: UInt8
.
Example
Let’s consider an example of calculating the retention
function to determine site traffic.
1. Create a table to illustrate an example.
CREATE TABLE retention_test(date Date, uid Int32) ENGINE = Memory;
INSERT INTO retention_test SELECT '2020-01-01', number FROM numbers(5);
INSERT INTO retention_test SELECT '2020-01-02', number FROM numbers(10);
INSERT INTO retention_test SELECT '2020-01-03', number FROM numbers(15);
Input table:
Query:
SELECT * FROM retention_test
Result:
┌───────date─┬─uid─┐
│ 2020-01-01 │ 0 │
│ 2020-01-01 │ 1 │
│ 2020-01-01 │ 2 │
│ 2020-01-01 │ 3 │
│ 2020-01-01 │ 4 │
└────────────┴─────┘
┌───────date─┬─uid─┐
│ 2020-01-02 │ 0 │
│ 2020-01-02 │ 1 │
│ 2020-01-02 │ 2 │
│ 2020-01-02 │ 3 │
│ 2020-01-02 │ 4 │
│ 2020-01-02 │ 5 │
│ 2020-01-02 │ 6 │
│ 2020-01-02 │ 7 │
│ 2020-01-02 │ 8 │
│ 2020-01-02 │ 9 │
└────────────┴─────┘
┌───────date─┬─uid─┐
│ 2020-01-03 │ 0 │
│ 2020-01-03 │ 1 │
│ 2020-01-03 │ 2 │
│ 2020-01-03 │ 3 │
│ 2020-01-03 │ 4 │
│ 2020-01-03 │ 5 │
│ 2020-01-03 │ 6 │
│ 2020-01-03 │ 7 │
│ 2020-01-03 │ 8 │
│ 2020-01-03 │ 9 │
│ 2020-01-03 │ 10 │
│ 2020-01-03 │ 11 │
│ 2020-01-03 │ 12 │
│ 2020-01-03 │ 13 │
│ 2020-01-03 │ 14 │
└────────────┴─────┘
2. Group users by unique ID uid
using the retention
function.
Query:
SELECT
uid,
retention(date = '2020-01-01', date = '2020-01-02', date = '2020-01-03') AS r
FROM retention_test
WHERE date IN ('2020-01-01', '2020-01-02', '2020-01-03')
GROUP BY uid
ORDER BY uid ASC
Result:
┌─uid─┬─r───────┐
│ 0 │ [1,1,1] │
│ 1 │ [1,1,1] │
│ 2 │ [1,1,1] │
│ 3 │ [1,1,1] │
│ 4 │ [1,1,1] │
│ 5 │ [0,0,0] │
│ 6 │ [0,0,0] │
│ 7 │ [0,0,0] │
│ 8 │ [0,0,0] │
│ 9 │ [0,0,0] │
│ 10 │ [0,0,0] │
│ 11 │ [0,0,0] │
│ 12 │ [0,0,0] │
│ 13 │ [0,0,0] │
│ 14 │ [0,0,0] │
└─────┴─────────┘
3. Calculate the total number of site visits per day.
Query:
SELECT
sum(r[1]) AS r1,
sum(r[2]) AS r2,
sum(r[3]) AS r3
FROM
(
SELECT
uid,
retention(date = '2020-01-01', date = '2020-01-02', date = '2020-01-03') AS r
FROM retention_test
WHERE date IN ('2020-01-01', '2020-01-02', '2020-01-03')
GROUP BY uid
)
Result:
┌─r1─┬─r2─┬─r3─┐
│ 5 │ 5 │ 5 │
└────┴────┴────┘
Where:
r1
- the number of unique visitors who visited the site during 2020-01-01 (thecond1
condition).r2
- the number of unique visitors who visited the site during a specific time period between 2020-01-01 and 2020-01-02 (cond1
andcond2
conditions).r3
- the number of unique visitors who visited the site during a specific time period on 2020-01-01 and 2020-01-03 (cond1
andcond3
conditions).
uniqUpTo(N)(x)
Calculates the number of different values of the argument up to a specified limit, N
. If the number of different argument values is greater than N
, this function returns N
+ 1, otherwise it calculates the exact value.
Recommended for use with small N
s, up to 10. The maximum value of N
is 100.
For the state of an aggregate function, this function uses the amount of memory equal to 1 + N
* the size of one value of bytes.
When dealing with strings, this function stores a non-cryptographic hash of 8 bytes; the calculation is approximated for strings.
For example, if you had a table that logs every search query made by users on your website. Each row in the table represents a single search query, with columns for the user ID, the search query, and the timestamp of the query. You can use uniqUpTo
to generate a report that shows only the keywords that produced at least 5 unique users.
SELECT SearchPhrase
FROM SearchLog
GROUP BY SearchPhrase
HAVING uniqUpTo(4)(UserID) >= 5
uniqUpTo(4)(UserID)
calculates the number of unique UserID
values for each SearchPhrase
, but it only counts up to 4 unique values. If there are more than 4 unique UserID
values for a SearchPhrase
, the function returns 5 (4 + 1). The HAVING
clause then filters out the SearchPhrase
values for which the number of unique UserID
values is less than 5. This will give you a list of search keywords that were used by at least 5 unique users.
sumMapFiltered
This function behaves the same as sumMap except that it also accepts an array of keys to filter with as a parameter. This can be especially useful when working with a high cardinality of keys.
Syntax
sumMapFiltered(keys_to_keep)(keys, values)
Parameters
Returned Value
- Returns a tuple of two arrays: keys in sorted order, and values summed for the corresponding keys.
Example
Query:
CREATE TABLE sum_map
(
`date` Date,
`timeslot` DateTime,
`statusMap` Nested(status UInt16, requests UInt64)
)
ENGINE = Log
INSERT INTO sum_map VALUES
('2000-01-01', '2000-01-01 00:00:00', [1, 2, 3], [10, 10, 10]),
('2000-01-01', '2000-01-01 00:00:00', [3, 4, 5], [10, 10, 10]),
('2000-01-01', '2000-01-01 00:01:00', [4, 5, 6], [10, 10, 10]),
('2000-01-01', '2000-01-01 00:01:00', [6, 7, 8], [10, 10, 10]);
SELECT sumMapFiltered([1, 4, 8])(statusMap.status, statusMap.requests) FROM sum_map;
Result:
┌─sumMapFiltered([1, 4, 8])(statusMap.status, statusMap.requests)─┐
1. │ ([1,4,8],[10,20,10]) │
└─────────────────────────────────────────────────────────────────┘
sumMapFilteredWithOverflow
This function behaves the same as sumMap except that it also accepts an array of keys to filter with as a parameter. This can be especially useful when working with a high cardinality of keys. It differs from the sumMapFiltered function in that it does summation with overflow - i.e. returns the same data type for the summation as the argument data type.
Syntax
sumMapFilteredWithOverflow(keys_to_keep)(keys, values)
Parameters
Returned Value
- Returns a tuple of two arrays: keys in sorted order, and values summed for the corresponding keys.
Example
In this example we create a table sum_map
, insert some data into it and then use both sumMapFilteredWithOverflow
and sumMapFiltered
and the toTypeName
function for comparison of the result. Where requests
was of type UInt8
in the created table, sumMapFiltered
has promoted the type of the summed values to UInt64
to avoid overflow whereas sumMapFilteredWithOverflow
has kept the type as UInt8
which is not large enough to store the result - i.e. overflow has occurred.
Query:
CREATE TABLE sum_map
(
`date` Date,
`timeslot` DateTime,
`statusMap` Nested(status UInt8, requests UInt8)
)
ENGINE = Log
INSERT INTO sum_map VALUES
('2000-01-01', '2000-01-01 00:00:00', [1, 2, 3], [10, 10, 10]),
('2000-01-01', '2000-01-01 00:00:00', [3, 4, 5], [10, 10, 10]),
('2000-01-01', '2000-01-01 00:01:00', [4, 5, 6], [10, 10, 10]),
('2000-01-01', '2000-01-01 00:01:00', [6, 7, 8], [10, 10, 10]);
SELECT sumMapFilteredWithOverflow([1, 4, 8])(statusMap.status, statusMap.requests) as summap_overflow, toTypeName(summap_overflow) FROM sum_map;
SELECT sumMapFiltered([1, 4, 8])(statusMap.status, statusMap.requests) as summap, toTypeName(summap) FROM sum_map;
Result:
┌─sum──────────────────┬─toTypeName(sum)───────────────────┐
1. │ ([1,4,8],[10,20,10]) │ Tuple(Array(UInt8), Array(UInt8)) │
└──────────────────────┴───────────────────────────────────┘
┌─summap───────────────┬─toTypeName(summap)─────────────────┐
1. │ ([1,4,8],[10,20,10]) │ Tuple(Array(UInt8), Array(UInt64)) │
└──────────────────────┴────────────────────────────────────┘
sequenceNextNode
Returns a value of the next event that matched an event chain.
Experimental function, SET allow_experimental_funnel_functions = 1
to enable it.
Syntax
sequenceNextNode(direction, base)(timestamp, event_column, base_condition, event1, event2, event3, ...)
Parameters
-
direction
— Used to navigate to directions.- forward — Moving forward.
- backward — Moving backward.
-
base
— Used to set the base point.- head — Set the base point to the first event.
- tail — Set the base point to the last event.
- first_match — Set the base point to the first matched
event1
. - last_match — Set the base point to the last matched
event1
.
Arguments
timestamp
— Name of the column containing the timestamp. Data types supported: Date, DateTime and other unsigned integer types.event_column
— Name of the column containing the value of the next event to be returned. Data types supported: String and Nullable(String).base_condition
— Condition that the base point must fulfill.event1
,event2
, ... — Conditions describing the chain of events. UInt8.
Returned values
event_column[next_index]
— If the pattern is matched and next value exists.NULL
- If the pattern isn’t matched or next value doesn't exist.
Type: Nullable(String).
Example
It can be used when events are A->B->C->D->E and you want to know the event following B->C, which is D.
The query statement searching the event following A->B:
CREATE TABLE test_flow (
dt DateTime,
id int,
page String)
ENGINE = MergeTree()
PARTITION BY toYYYYMMDD(dt)
ORDER BY id;
INSERT INTO test_flow VALUES (1, 1, 'A') (2, 1, 'B') (3, 1, 'C') (4, 1, 'D') (5, 1, 'E');
SELECT id, sequenceNextNode('forward', 'head')(dt, page, page = 'A', page = 'A', page = 'B') as next_flow FROM test_flow GROUP BY id;
Result:
┌─id─┬─next_flow─┐
│ 1 │ C │
└────┴───────────┘
Behavior for forward
and head
ALTER TABLE test_flow DELETE WHERE 1 = 1 settings mutations_sync = 1;
INSERT INTO test_flow VALUES (1, 1, 'Home') (2, 1, 'Gift') (3, 1, 'Exit');
INSERT INTO test_flow VALUES (1, 2, 'Home') (2, 2, 'Home') (3, 2, 'Gift') (4, 2, 'Basket');
INSERT INTO test_flow VALUES (1, 3, 'Gift') (2, 3, 'Home') (3, 3, 'Gift') (4, 3, 'Basket');
SELECT id, sequenceNextNode('forward', 'head')(dt, page, page = 'Home', page = 'Home', page = 'Gift') FROM test_flow GROUP BY id;
dt id page
1970-01-01 09:00:01 1 Home // Base point, Matched with Home
1970-01-01 09:00:02 1 Gift // Matched with Gift
1970-01-01 09:00:03 1 Exit // The result
1970-01-01 09:00:01 2 Home // Base point, Matched with Home
1970-01-01 09:00:02 2 Home // Unmatched with Gift
1970-01-01 09:00:03 2 Gift
1970-01-01 09:00:04 2 Basket
1970-01-01 09:00:01 3 Gift // Base point, Unmatched with Home
1970-01-01 09:00:02 3 Home
1970-01-01 09:00:03 3 Gift
1970-01-01 09:00:04 3 Basket
Behavior for backward
and tail
SELECT id, sequenceNextNode('backward', 'tail')(dt, page, page = 'Basket', page = 'Basket', page = 'Gift') FROM test_flow GROUP BY id;
dt id page
1970-01-01 09:00:01 1 Home
1970-01-01 09:00:02 1 Gift
1970-01-01 09:00:03 1 Exit // Base point, Unmatched with Basket
1970-01-01 09:00:01 2 Home
1970-01-01 09:00:02 2 Home // The result
1970-01-01 09:00:03 2 Gift // Matched with Gift
1970-01-01 09:00:04 2 Basket // Base point, Matched with Basket
1970-01-01 09:00:01 3 Gift
1970-01-01 09:00:02 3 Home // The result
1970-01-01 09:00:03 3 Gift // Base point, Matched with Gift
1970-01-01 09:00:04 3 Basket // Base point, Matched with Basket
Behavior for forward
and first_match
SELECT id, sequenceNextNode('forward', 'first_match')(dt, page, page = 'Gift', page = 'Gift') FROM test_flow GROUP BY id;
dt id page
1970-01-01 09:00:01 1 Home
1970-01-01 09:00:02 1 Gift // Base point
1970-01-01 09:00:03 1 Exit // The result
1970-01-01 09:00:01 2 Home
1970-01-01 09:00:02 2 Home
1970-01-01 09:00:03 2 Gift // Base point
1970-01-01 09:00:04 2 Basket The result
1970-01-01 09:00:01 3 Gift // Base point
1970-01-01 09:00:02 3 Home // The result
1970-01-01 09:00:03 3 Gift
1970-01-01 09:00:04 3 Basket
SELECT id, sequenceNextNode('forward', 'first_match')(dt, page, page = 'Gift', page = 'Gift', page = 'Home') FROM test_flow GROUP BY id;
dt id page
1970-01-01 09:00:01 1 Home
1970-01-01 09:00:02 1 Gift // Base point
1970-01-01 09:00:03 1 Exit // Unmatched with Home
1970-01-01 09:00:01 2 Home
1970-01-01 09:00:02 2 Home
1970-01-01 09:00:03 2 Gift // Base point
1970-01-01 09:00:04 2 Basket // Unmatched with Home
1970-01-01 09:00:01 3 Gift // Base point
1970-01-01 09:00:02 3 Home // Matched with Home
1970-01-01 09:00:03 3 Gift // The result
1970-01-01 09:00:04 3 Basket
Behavior for backward
and last_match
SELECT id, sequenceNextNode('backward', 'last_match')(dt, page, page = 'Gift', page = 'Gift') FROM test_flow GROUP BY id;
dt id page
1970-01-01 09:00:01 1 Home // The result
1970-01-01 09:00:02 1 Gift // Base point
1970-01-01 09:00:03 1 Exit
1970-01-01 09:00:01 2 Home
1970-01-01 09:00:02 2 Home // The result
1970-01-01 09:00:03 2 Gift // Base point
1970-01-01 09:00:04 2 Basket
1970-01-01 09:00:01 3 Gift
1970-01-01 09:00:02 3 Home // The result
1970-01-01 09:00:03 3 Gift // Base point
1970-01-01 09:00:04 3 Basket
SELECT id, sequenceNextNode('backward', 'last_match')(dt, page, page = 'Gift', page = 'Gift', page = 'Home') FROM test_flow GROUP BY id;
dt id page
1970-01-01 09:00:01 1 Home // Matched with Home, the result is null
1970-01-01 09:00:02 1 Gift // Base point
1970-01-01 09:00:03 1 Exit
1970-01-01 09:00:01 2 Home // The result
1970-01-01 09:00:02 2 Home // Matched with Home
1970-01-01 09:00:03 2 Gift // Base point
1970-01-01 09:00:04 2 Basket
1970-01-01 09:00:01 3 Gift // The result
1970-01-01 09:00:02 3 Home // Matched with Home
1970-01-01 09:00:03 3 Gift // Base point
1970-01-01 09:00:04 3 Basket
Behavior for base_condition
CREATE TABLE test_flow_basecond
(
`dt` DateTime,
`id` int,
`page` String,
`ref` String
)
ENGINE = MergeTree
PARTITION BY toYYYYMMDD(dt)
ORDER BY id;
INSERT INTO test_flow_basecond VALUES (1, 1, 'A', 'ref4') (2, 1, 'A', 'ref3') (3, 1, 'B', 'ref2') (4, 1, 'B', 'ref1');
SELECT id, sequenceNextNode('forward', 'head')(dt, page, ref = 'ref1', page = 'A') FROM test_flow_basecond GROUP BY id;
dt id page ref
1970-01-01 09:00:01 1 A ref4 // The head can not be base point because the ref column of the head unmatched with 'ref1'.
1970-01-01 09:00:02 1 A ref3
1970-01-01 09:00:03 1 B ref2
1970-01-01 09:00:04 1 B ref1
SELECT id, sequenceNextNode('backward', 'tail')(dt, page, ref = 'ref4', page = 'B') FROM test_flow_basecond GROUP BY id;
dt id page ref
1970-01-01 09:00:01 1 A ref4
1970-01-01 09:00:02 1 A ref3
1970-01-01 09:00:03 1 B ref2
1970-01-01 09:00:04 1 B ref1 // The tail can not be base point because the ref column of the tail unmatched with 'ref4'.
SELECT id, sequenceNextNode('forward', 'first_match')(dt, page, ref = 'ref3', page = 'A') FROM test_flow_basecond GROUP BY id;
dt id page ref
1970-01-01 09:00:01 1 A ref4 // This row can not be base point because the ref column unmatched with 'ref3'.
1970-01-01 09:00:02 1 A ref3 // Base point
1970-01-01 09:00:03 1 B ref2 // The result
1970-01-01 09:00:04 1 B ref1
SELECT id, sequenceNextNode('backward', 'last_match')(dt, page, ref = 'ref2', page = 'B') FROM test_flow_basecond GROUP BY id;
dt id page ref
1970-01-01 09:00:01 1 A ref4
1970-01-01 09:00:02 1 A ref3 // The result
1970-01-01 09:00:03 1 B ref2 // Base point
1970-01-01 09:00:04 1 B ref1 // This row can not be base point because the ref column unmatched with 'ref2'.