cartesianProduct
The cartesianProduct
function turns a single tuple with a multi-valued field (ie. an array) into multiple tuples, one for each value in the array field. That is, given a single tuple containing an array of N values for fieldA, the cartesianProduct
function will output N tuples, each with one value from the original tuple’s array. In essence, you can flatten arrays for further processing.
For example, using cartesianProduct
you can turn this tuple
{
"fieldA": "foo",
"fieldB": ["bar","baz","bat"]
}
into the following 3 tuples
{
"fieldA": "foo",
"fieldB": "bar"
}
{
"fieldA": "foo",
"fieldB": "baz"
}
{
"fieldA": "foo",
"fieldB": "bat"
}
cartesianProduct Parameters
-
incoming stream
: (Mandatory) A single incoming stream. -
fieldName or evaluator
: (Mandatory) Name of field to flatten values for, or evaluator whose result should be flattened. -
productSort='fieldName ASC|DESC'
: (Optional) Sort order of the newly generated tuples.
cartesianProduct Syntax
cartesianProduct(
<stream>,
<fieldName | evaluator> [as newFieldName],
productSort='fieldName ASC|DESC'
)
cartesianProduct Examples
The following examples show different outputs for this source tuple
{
"fieldA": "valueA",
"fieldB": ["valueB1","valueB2"],
"fieldC": [1,2,3]
}
Single Field, No Sorting
cartesianProduct(
search(collection1, q='*:*', fl='fieldA, fieldB, fieldC', sort='fieldA ASC'),
fieldB
)
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": [1,2,3]
}
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": [1,2,3]
}
Single Evaluator, No Sorting
cartesianProduct(
search(collection1, q='*:*', fl='fieldA, fieldB, fieldC', sort='fieldA ASC'),
sequence(3,4,5) as fieldE
)
{
"fieldA": "valueA",
"fieldB": ["valueB1","valueB2"],
"fieldC": [1,2,3],
"fieldE": 4
}
{
"fieldA": "valueA",
"fieldB": ["valueB1","valueB2"],
"fieldC": [1,2,3],
"fieldE": 9
}
{
"fieldA": "valueA",
"fieldB": ["valueB1","valueB2"],
"fieldC": [1,2,3],
"fieldE": 14
}
Single Field, Sorted by Value
cartesianProduct(
search(collection1, q='*:*', fl='fieldA, fieldB, fieldC', sort='fieldA ASC'),
fieldB,
productSort="fieldB DESC"
)
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": [1,2,3]
}
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": [1,2,3]
}
Single Evaluator, Sorted by Evaluator Values
cartesianProduct(
search(collection1, q='*:*', fl='fieldA, fieldB, fieldC', sort='fieldA ASC'),
sequence(3,4,5) as fieldE,
productSort='newFieldE DESC'
)
{
"fieldA": "valueA",
"fieldB": ["valueB1","valueB2"],
"fieldC": [1,2,3],
"fieldE": 14
}
{
"fieldA": "valueA",
"fieldB": ["valueB1","valueB2"],
"fieldC": [1,2,3],
"fieldE": 9
}
{
"fieldA": "valueA",
"fieldB": ["valueB1","valueB2"],
"fieldC": [1,2,3],
"fieldE": 4
}
Renamed Single Field, Sorted by Value
cartesianProduct(
search(collection1, q='*:*', fl='fieldA, fieldB, fieldC', sort='fieldA ASC'),
fieldB as newFieldB,
productSort="fieldB DESC"
)
{
"fieldA": "valueA",
"fieldB": ["valueB1","valueB2"],
"fieldC": [1,2,3]
"newFieldB": "valueB2",
}
{
"fieldA": "valueA",
"fieldB": ["valueB1","valueB2"],
"fieldC": [1,2,3]
"newFieldB": "valueB1",
}
Multiple Fields, No Sorting
cartesianProduct(
search(collection1, q='*:*', fl='fieldA, fieldB, fieldC', sort='fieldA ASC'),
fieldB,
fieldC
)
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": 1
}
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": 2
}
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": 3
}
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": 1
}
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": 2
}
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": 3
}
Multiple Fields, Sorted by Single Field
cartesianProduct(
search(collection1, q='*:*', fl='fieldA, fieldB, fieldC', sort='fieldA ASC'),
fieldB,
fieldC,
productSort="fieldC ASC"
)
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": 1
}
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": 1
}
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": 2
}
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": 2
}
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": 3
}
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": 3
}
Multiple Fields, Sorted by Multiple Fields
cartesianProduct(
search(collection1, q='*:*', fl='fieldA, fieldB, fieldC', sort='fieldA ASC'),
fieldB,
fieldC,
productSort="fieldC ASC, fieldB DESC"
)
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": 1
}
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": 1
}
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": 2
}
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": 2
}
{
"fieldA": "valueA",
"fieldB": "valueB2",
"fieldC": 3
}
{
"fieldA": "valueA",
"fieldB": "valueB1",
"fieldC": 3
}
Field and Evaluator, No Sorting
cartesianProduct(
search(collection1, q='*:*', fl='fieldA, fieldB, fieldC', sort='fieldA ASC'),
sequence(3,4,5) as fieldE,
fieldB
)
{
"fieldA": "valueA",
"fieldB": valueB1,
"fieldC": [1,2,3],
"fieldE": 4
}
{
"fieldA": "valueA",
"fieldB": valueB2,
"fieldC": [1,2,3],
"fieldE": 4
}
{
"fieldA": "valueA",
"fieldB": valueB1,
"fieldC": [1,2,3],
"fieldE": 9
}
{
"fieldA": "valueA",
"fieldB": valueB2,
"fieldC": [1,2,3],
"fieldE": 9
}
{
"fieldA": "valueA",
"fieldB": valueB1,
"fieldC": [1,2,3],
"fieldE": 14
}
{
"fieldA": "valueA",
"fieldB": valueB2,
"fieldC": [1,2,3],
"fieldE": 14
}
As you can see in the examples above, the cartesianProduct
function does support flattening tuples across multiple fields and/or evaluators.
classify
The classify
function classifies tuples using a logistic regression text classification model. It was designed specifically to work with models trained using the train function. The classify
function uses the model function to retrieve a stored model and then scores a stream of tuples using the model. The tuples read by the classifier must contain a text field that can be used for classification. The classify function uses a Lucene analyzer to extract the features from the text so the model can be applied. By default the classify
function looks for the analyzer using the name of text field in the tuple. If the Solr schema on the worker node does not contain this field, the analyzer can be looked up in another field by specifying the analyzerField
parameter.
Each tuple that is classified is assigned two scores:
-
probability_d* : A float between 0 and 1 which describes the probability that the tuple belongs to the class. This is useful in the classification use case.
-
score_d* : The score of the document that has not be squashed between 0 and 1. The score may be positive or negative. The higher the score the better the document fits the class. This un-squashed score will be useful in query re-ranking and recommendation use cases. This score is particularly useful when multiple high ranking documents have a probability_d score of 1, which won’t provide a meaningful ranking between documents.
classify Parameters
-
model expression
: (Mandatory) Retrieves the stored logistic regression model. -
field
: (Mandatory) The field in the tuples to apply the classifier to. By default the analyzer for this field in the schema will be used extract the features. -
analyzerField
: (Optional) Specifies a different field to find the analyzer from in the schema.
classify Syntax
classify(model(modelCollection,
id="model1",
cacheMillis=5000),
search(contentCollection,
q="id:(a b c)",
fl="text_t, id",
sort="id asc"),
field="text_t")
In the example above the classify expression
is retrieving the model using the model
function. It is then classifying tuples returned by the search
function. The text_t
field is used for the text classification and the analyzer for the text_t
field in the Solr schema is used to analyze the text and extract the features.
commit
The commit
function wraps a single stream (A) and given a collection and batch size will send commit messages to the collection when the batch size is fulfilled or the end of stream is reached. A commit stream is used most frequently with an update stream and as such the commit will take into account possible summary tuples coming from the update stream. All tuples coming into the commit stream will be returned out of the commit stream - no tuples will be dropped and no tuples will be added.
commit Parameters
-
collection
: The collection to send commit messages to (required) -
batchSize
: The commit batch size, sends commit message when batch size is hit. If not provided (or provided as value 0) then a commit is only sent at the end of the incoming stream. -
waitFlush
: The value passed directly to the commit handler (true/false, default: false) -
waitSearcher
: The value passed directly to the commit handler (true/false, default: false) -
softCommit
: The value passed directly to the commit handler (true/false, default: false) -
StreamExpression for StreamA
(required)
commit Syntax
commit(
destinationCollection,
batchSize=2,
update(
destinationCollection,
batchSize=5,
search(collection1, q=*:*, fl="id,a_s,a_i,a_f,s_multi,i_multi", sort="a_f asc, a_i asc")
)
)
complement
The complement
function wraps two streams (A and B) and emits tuples from A which do not exist in B. The tuples are emitted in the order in which they appear in stream A. Both streams must be sorted by the fields being used to determine equality (using the on
parameter).
complement Parameters
-
StreamExpression for StreamA
-
StreamExpression for StreamB
-
on
: Fields to be used for checking equality of tuples between A and B. Can be of the formaton="fieldName"
,on="fieldNameInLeft=fieldNameInRight"
, oron="fieldName, otherFieldName=rightOtherFieldName"
.
complement Syntax
complement(
search(collection1, q=a_s:(setA || setAB), fl="id,a_s,a_i", sort="a_i asc, a_s asc"),
search(collection1, q=a_s:(setB || setAB), fl="id,a_s,a_i", sort="a_i asc"),
on="a_i"
)
complement(
search(collection1, q=a_s:(setA || setAB), fl="id,a_s,a_i", sort="a_i asc, a_s asc"),
search(collection1, q=a_s:(setB || setAB), fl="id,a_s,a_i", sort="a_i asc, a_s asc"),
on="a_i,a_s"
)
daemon
The daemon
function wraps another function and runs it at intervals using an internal thread. The daemon
function can be used to provide both continuous push and pull streaming.
Continuous Push Streaming
With continuous push streaming the daemon
function wraps another function and is then sent to the /stream
handler for execution. The /stream
handler recognizes the daemon
function and keeps it resident in memory, so it can run its internal function at intervals.
In order to facilitate the pushing of tuples, the daemon
function must wrap another stream decorator that pushes the tuples somewhere. One example of this is the update
function, which wraps a stream and sends the tuples to another SolrCloud collection for indexing.
daemon Syntax
daemon(id="uniqueId",
runInterval="1000",
terminate="true",
update(destinationCollection,
batchSize=100,
topic(checkpointCollection,
topicCollection,
q="topic query",
fl="id, title, abstract, text",
id="topicId",
initialCheckpoint=0)
)
)
The sample code above shows a daemon
function wrapping an update
function, which is wrapping a topic
function. When this expression is sent to the /stream
handler, the /stream
hander sees the daemon
function and keeps it in memory where it will run at intervals. In this particular example, the daemon
function will run the update
function every second. The update
function is wrapping a topic
function, which will stream tuples that match the topic
function query in batches. Each subsequent call to the topic will return the next batch of tuples for the topic. The update
function will send all the tuples matching the topic to another collection to be indexed. The terminate
parameter tells the daemon to terminate when the topic
function stops sending tuples.
The effect of this is to push documents that match a specific query into another collection. Custom push functions can be plugged in that push documents out of Solr and into other systems, such as Kafka or an email system.
Push streaming can also be used for continuous background aggregation scenarios where aggregates are rolled up in the background at intervals and pushed to other Solr collections. Another use case is continuous background machine learning model optimization, where the optimized model is pushed to another Solr collection where it can be integrated into queries.
The /stream
handler supports a small set commands for listing and controlling daemon functions:
http://localhost:8983/collection/stream?action=list
This command will provide a listing of the current daemon’s running on the specific node along with there current state.
http://localhost:8983/collection/stream?action=stop&id=daemonId
This command will stop a specific daemon function but leave it resident in memory.
http://localhost:8983/collection/stream?action=start&id=daemonId
This command will start a specific daemon function that has been stopped.
http://localhost:8983/collection/stream?action=kill&id=daemonId
This command will stop a specific daemon function and remove it from memory.
Continuous Pull Streaming
The DaemonStream java class (part of the SolrJ libraries) can also be embedded in a java application to provide continuous pull streaming. Sample code:
StreamContext context = new StreamContext()
SolrClientCache cache = new SolrClientCache();
context.setSolrClientCache(cache);
Map topicQueryParams = new HashMap();
topicQueryParams.put("q","hello"); // The query for the topic
topicQueryparams.put("rows", "500"); // How many rows to fetch during each run
topicQueryparams.put("fl", "id", "title"); // The field list to return with the documents
TopicStream topicStream = new TopicStream(zkHost, // Host address for the zookeeper service housing the collections
"checkpoints", // The collection to store the topic checkpoints
"topicData", // The collection to query for the topic records
"topicId", // The id of the topic
-1, // checkpoint every X tuples, if set -1 it will checkpoint after each run.
topicQueryParams); // The query parameters for the TopicStream
DaemonStream daemonStream = new DaemonStream(topicStream, // The underlying stream to run.
"daemonId", // The id of the daemon
1000, // The interval at which to run the internal stream
500); // The internal queue size for the daemon stream. Tuples will be placed in the queue
// as they are read by the internal internal thread.
// Calling read() on the daemon stream reads records from the internal queue.
daemonStream.setStreamContext(context);
daemonStream.open();
//Read until it's time to shutdown the DaemonStream. You can define the shutdown criteria.
while(!shutdown()) {
Tuple tuple = daemonStream.read() // This will block until tuples become available from the underlying stream (TopicStream)
// The EOF tuple (signaling the end of the stream) will never occur until the DaemonStream has been shutdown.
//Do something with the tuples
}
// Shutdown the DaemonStream.
daemonStream.shutdown();
//Read the DaemonStream until the EOF Tuple is found.
//This allows the underlying stream to perform an orderly shutdown.
while(true) {
Tuple tuple = daemonStream.read();
if(tuple.EOF) {
break;
} else {
//Do something with the tuples.
}
}
//Finally close the stream
daemonStream.close();
eval
The eval
function allows for use cases where new streaming expressions are generated on the fly and then evaluated.
The eval
function wraps a streaming expression and reads a single tuple from the underlying stream.
The eval
function then retrieves a string Streaming Expressions from the expr_s
field of the tuple.
The eval
function then compiles the string Streaming Expression and emits the tuples.
eval Parameters
-
StreamExpression
: (Mandatory) The stream which provides the streaming expression to be evaluated.
eval Syntax
eval(expr)
In the example above the eval
expression reads the first tuple from the underlying expression. It then compiles and
executes the string Streaming Expression in the epxr_s field.
executor
The executor
function wraps a stream source that contains streaming expressions, and executes the expressions in parallel. The executor
function looks for the expression in the expr_s
field in each tuple. The executor
function has an internal thread pool that runs tasks that compile and run expressions in parallel on the same worker node. This function can also be parallelized across worker nodes by wrapping it in the parallel
function to provide parallel execution of expressions across a cluster.
The executor
function does not do anything specific with the output of the expressions that it runs. Therefore the expressions that are executed must contain the logic for pushing tuples to their destination. The update function can be included in the expression being executed to send the tuples to a SolrCloud collection for storage.
This model allows for asynchronous execution of jobs where the output is stored in a SolrCloud collection where it can be accessed as the job progresses.
executor Parameters
-
threads
: (Optional) The number of threads in the executors thread pool for executing expressions. -
StreamExpression
: (Mandatory) The stream source which contains the Streaming Expressions to execute.
executor Syntax
daemon(id="myDaemon",
terminate="true",
executor(threads=10,
topic(checkpointCollection
storedExpressions,
q="*:*",
fl="id, expr_s",
initialCheckPoint=0,
id="myTopic")))
In the example above a daemon wraps an executor, which wraps a topic that is returning tuples with expressions to execute. When sent to the stream handler, the daemon will call the executor at intervals which will cause the executor to read from the topic and execute the expressions found in the expr_s
field. The daemon will repeatedly call the executor until all the tuples that match the topic have been iterated, then it will terminate. This is the approach for executing batches of streaming expressions from a topic
queue.
fetch
The fetch
function iterates a stream and fetches additional fields and adds them to the tuples. The fetch
function fetches in batches to limit the number of calls back to Solr. Tuples streamed from the fetch
function will contain the original fields and the additional fields that were fetched. The fetch
function supports one-to-one fetches. Many-to-one fetches, where the stream source contains duplicate keys, will also work, but one-to-many fetches are currently not supported by this function.
fetch Parameters
-
Collection
: (Mandatory) The collection to fetch the fields from. -
StreamExpression
: (Mandatory) The stream source for the fetch function. -
fl
: (Mandatory) The fields to be fetched. -
on
: Fields to be used for checking equality of tuples between stream source and fetched records. Formatted ason="fieldNameInTuple=fieldNameInCollection"
. -
batchSize
: (Optional) The batch fetch size.
fetch Syntax
fetch(addresses,
search(people, q="*:*", fl="username, firstName, lastName", sort="username asc"),
fl="streetAddress, city, state, country, zip",
on="username=userId")
The example above fetches addresses for users by matching the username in the tuple with the userId field in the addresses collection.
having
The having
expression wraps a stream and applies a boolean operation to each tuple. It emits only tuples for which the boolean operation returns true.
having Parameters
-
StreamExpression
: (Mandatory) The stream source for the having function. -
booleanEvaluator
: (Madatory) The following boolean operations are supported:eq
(equals),gt
(greater than),lt
(less than),gteq
(greater than or equal to),lteq
(less than or equal to),and
,or
,eor
(exclusive or), andnot
. Boolean evaluators can be nested with other evaluators to form complex boolean logic.
The comparison evaluators compare the value in a specific field with a value, whether a string, number, or boolean. For example: eq(field1, 10)
, returns true
if field1
is equal to 10.
having Syntax
having(rollup(over=a_s,
sum(a_i),
search(collection1,
q=*:*,
fl="id,a_s,a_i,a_f",
sort="a_s asc")),
and(gt(sum(a_i), 100), lt(sum(a_i), 110)))
In this example, the having
expression iterates the aggregated tuples from the rollup
expression and emits all tuples where the field sum(a_i)
is greater then 100 and less then 110.
leftOuterJoin
The leftOuterJoin
function wraps two streams, Left and Right, and emits tuples from Left. If there is a tuple in Right equal (as defined by on
) then the values in that tuple will be included in the emitted tuple. An equal tuple in Right need not exist for the Left tuple to be emitted. This supports one-to-one, one-to-many, many-to-one, and many-to-many left outer join scenarios. The tuples are emitted in the order in which they appear in the Left stream. Both streams must be sorted by the fields being used to determine equality (using the on
parameter). If both tuples contain a field of the same name then the value from the Right stream will be used in the emitted tuple.
You can wrap the incoming streams with a select
function to be specific about which field values are included in the emitted tuple.
leftOuterJoin Parameters
-
StreamExpression for StreamLeft
-
StreamExpression for StreamRight
-
on
: Fields to be used for checking equality of tuples between Left and Right. Can be of the formaton="fieldName"
,on="fieldNameInLeft=fieldNameInRight"
, oron="fieldName, otherFieldName=rightOtherFieldName"
.
leftOuterJoin Syntax
leftOuterJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
search(pets, q=type:cat, fl="personId,petName", sort="personId asc"),
on="personId"
)
leftOuterJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
search(pets, q=type:cat, fl="ownerId,petName", sort="ownerId asc"),
on="personId=ownerId"
)
leftOuterJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
select(
search(pets, q=type:cat, fl="ownerId,name", sort="ownerId asc"),
ownerId,
name as petName
),
on="personId=ownerId"
)
hashJoin
The hashJoin
function wraps two streams, Left and Right, and for every tuple in Left which exists in Right will emit a tuple containing the fields of both tuples. This supports one-to-one, one-to-many, many-to-one, and many-to-many inner join scenarios. The tuples are emitted in the order in which they appear in the Left stream. The order of the streams does not matter. If both tuples contain a field of the same name then the value from the Right stream will be used in the emitted tuple.
You can wrap the incoming streams with a select
function to be specific about which field values are included in the emitted tuple.
The hashJoin function can be used when the tuples of Left and Right cannot be put in the same order. Because the tuples are out of order this stream functions by reading all values from the Right stream during the open operation and will store all tuples in memory. The result of this is a memory footprint equal to the size of the Right stream.
hashJoin Parameters
-
StreamExpression for StreamLeft
-
hashed=StreamExpression for StreamRight
-
on
: Fields to be used for checking equality of tuples between Left and Right. Can be of the formaton="fieldName"
,on="fieldNameInLeft=fieldNameInRight"
, oron="fieldName, otherFieldName=rightOtherFieldName"
.
hashJoin Syntax
hashJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
hashed=search(pets, q=type:cat, fl="personId,petName", sort="personId asc"),
on="personId"
)
hashJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
hashed=search(pets, q=type:cat, fl="ownerId,petName", sort="ownerId asc"),
on="personId=ownerId"
)
hashJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
hashed=select(
search(pets, q=type:cat, fl="ownerId,name", sort="ownerId asc"),
ownerId,
name as petName
),
on="personId=ownerId"
)
innerJoin
Wraps two streams, Left and Right. For every tuple in Left which exists in Right a tuple containing the fields of both tuples will be emitted. This supports one-to-one, one-to-many, many-to-one, and many-to-many inner join scenarios. The tuples are emitted in the order in which they appear in the Left stream. Both streams must be sorted by the fields being used to determine equality (the 'on' parameter). If both tuples contain a field of the same name then the value from the Right stream will be used in the emitted tuple. You can wrap the incoming streams with a select(…)
expression to be specific about which field values are included in the emitted tuple.
innerJoin Parameters
-
StreamExpression for StreamLeft
-
StreamExpression for StreamRight
-
on
: Fields to be used for checking equality of tuples between Left and Right. Can be of the formaton="fieldName"
,on="fieldNameInLeft=fieldNameInRight"
, oron="fieldName, otherFieldName=rightOtherFieldName"
.
innerJoin Syntax
innerJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
search(pets, q=type:cat, fl="personId,petName", sort="personId asc"),
on="personId"
)
innerJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
search(pets, q=type:cat, fl="ownerId,petName", sort="ownerId asc"),
on="personId=ownerId"
)
innerJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
select(
search(pets, q=type:cat, fl="ownerId,name", sort="ownerId asc"),
ownerId,
name as petName
),
on="personId=ownerId"
)
intersect
The intersect
function wraps two streams, A and B, and emits tuples from A which DO exist in B. The tuples are emitted in the order in which they appear in stream A. Both streams must be sorted by the fields being used to determine equality (the on
parameter). Only tuples from A are emitted.
intersect Parameters
-
StreamExpression for StreamA
-
StreamExpression for StreamB
-
on
: Fields to be used for checking equality of tuples between A and B. Can be of the formaton="fieldName"
,on="fieldNameInLeft=fieldNameInRight"
, oron="fieldName, otherFieldName=rightOtherFieldName"
.
intersect Syntax
intersect(
search(collection1, q=a_s:(setA || setAB), fl="id,a_s,a_i", sort="a_i asc, a_s asc"),
search(collection1, q=a_s:(setB || setAB), fl="id,a_s,a_i", sort="a_i asc"),
on="a_i"
)
intersect(
search(collection1, q=a_s:(setA || setAB), fl="id,a_s,a_i", sort="a_i asc, a_s asc"),
search(collection1, q=a_s:(setB || setAB), fl="id,a_s,a_i", sort="a_i asc, a_s asc"),
on="a_i,a_s"
)
merge
The merge
function merges two or more streaming expressions and maintains the ordering of the underlying streams. Because the order is maintained, the sorts of the underlying streams must line up with the on parameter provided to the merge function.
merge Parameters
-
StreamExpression A
-
StreamExpression B
-
Optional StreamExpression C,D,….Z
-
on
: Sort criteria for performing the merge. Of the formfieldName order
where order isasc
ordesc
. Multiple fields can be provided in the formfieldA order, fieldB order
.
merge Syntax
# Merging two stream expressions together
merge(
search(collection1,
q="id:(0 3 4)",
fl="id,a_s,a_i,a_f",
sort="a_f asc"),
search(collection1,
q="id:(1)",
fl="id,a_s,a_i,a_f",
sort="a_f asc"),
on="a_f asc")
# Merging four stream expressions together. Notice that while the sorts of each stream are not identical they are
# comparable. That is to say the first N fields in each stream's sort matches the N fields in the merge's on clause.
merge(
search(collection1,
q="id:(0 3 4)",
fl="id,fieldA,fieldB,fieldC",
sort="fieldA asc, fieldB desc"),
search(collection1,
q="id:(1)",
fl="id,fieldA",
sort="fieldA asc"),
search(collection2,
q="id:(10 11 13)",
fl="id,fieldA,fieldC",
sort="fieldA asc"),
search(collection3,
q="id:(987)",
fl="id,fieldA,fieldC",
sort="fieldA asc"),
on="fieldA asc")
null
The null expression is a useful utility function for understanding bottlenecks when performing parallel relational algebra (joins, intersections, rollups etc.). The null function reads all the tuples from an underlying stream and returns a single tuple with the count and processing time. Because the null stream adds minimal overhead of it’s own, it can be used to isolate the performance of Solr’s /export handler. If the /export handlers performance is not the bottleneck, then the bottleneck is likely occurring in the workers where the stream decorators are running.
The null expression can be wrapped by the parallel function and sent to worker nodes. In this scenario each worker will return one tuple with the count of tuples processed on the worker and the timing information for that worker. This gives valuable information such as:
-
As more workers are added does the performance of the /export handler improve or not.
-
Are tuples being evenly distributed across the workers, or is the hash partitioning sending more documents to a single worker.
-
Are all workers processing data at the same speed, or is one of the workers the source of the bottleneck.
null Parameters
-
StreamExpression
: (Mandatory) The expression read by the null function.
null Syntax
parallel(workerCollection,
null(search(collection1, q=*:*, fl="id,a_s,a_i,a_f", sort="a_s desc", qt="/export", partitionKeys="a_s")),
workers="20",
zkHost="localhost:9983",
sort="a_s desc")
The expression above shows a parallel function wrapping a null function. This will cause the null function to be run in parallel across 20 worker nodes. Each worker will return a single tuple with number of tuples processed and time it took to iterate the tuples.
outerHashJoin
The outerHashJoin
function wraps two streams, Left and Right, and emits tuples from Left. If there is a tuple in Right equal (as defined by the on
parameter) then the values in that tuple will be included in the emitted tuple. An equal tuple in Right need not exist for the Left tuple to be emitted. This supports one-to-one, one-to-many, many-to-one, and many-to-many left outer join scenarios. The tuples are emitted in the order in which they appear in the Left stream. The order of the streams does not matter. If both tuples contain a field of the same name then the value from the Right stream will be used in the emitted tuple.
You can wrap the incoming streams with a select
function to be specific about which field values are included in the emitted tuple.
The outerHashJoin stream can be used when the tuples of Left and Right cannot be put in the same order. Because the tuples are out of order, this stream functions by reading all values from the Right stream during the open operation and will store all tuples in memory. The result of this is a memory footprint equal to the size of the Right stream.
outerHashJoin Parameters
-
StreamExpression for StreamLeft
-
hashed=StreamExpression for StreamRight
-
on
: Fields to be used for checking equality of tuples between Left and Right. Can be of the formaton="fieldName"
,on="fieldNameInLeft=fieldNameInRight"
, oron="fieldName, otherFieldName=rightOtherFieldName"
.
outerHashJoin Syntax
outerHashJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
hashed=search(pets, q=type:cat, fl="personId,petName", sort="personId asc"),
on="personId"
)
outerHashJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
hashed=search(pets, q=type:cat, fl="ownerId,petName", sort="ownerId asc"),
on="personId=ownerId"
)
outerHashJoin(
search(people, q=*:*, fl="personId,name", sort="personId asc"),
hashed=select(
search(pets, q=type:cat, fl="ownerId,name", sort="ownerId asc"),
ownerId,
name as petName
),
on="personId=ownerId"
)
parallel
The parallel
function wraps a streaming expression and sends it to N worker nodes to be processed in parallel.
The parallel function requires that the partitionKeys
parameter be provided to the underlying searches. The partitionKeys
parameter will partition the search results (tuples) across the worker nodes. Tuples with the same values in the partitionKeys field will be shuffled to the same worker nodes.
The parallel function maintains the sort order of the tuples returned by the worker nodes, so the sort criteria of the parallel function must match up with the sort order of the tuples returned by the workers.
Worker Collections
The worker nodes can be from the same collection as the data, or they can be a different collection entirely, even one that only exists for parallel streaming expressions. A worker collection can be any SolrCloud collection that has the |
parallel Parameters
-
collection
: Name of the worker collection to send the StreamExpression to. -
StreamExpression
: Expression to send to the worker collection. -
workers
: Number of workers in the worker collection to send the expression to. -
zkHost
: (Optional) The ZooKeeper connect string where the worker collection resides. -
sort
: The sort criteria for ordering tuples returned by the worker nodes.
parallel Syntax
parallel(workerCollection,
reduce(search(collection1, q=*:*, fl="id,a_s,a_i,a_f", sort="a_s desc", partitionKeys="a_s"),
by="a_s",
group(sort="a_f desc", n="4")),
workers="20",
zkHost="localhost:9983",
sort="a_s desc")
The expression above shows a parallel
function wrapping a reduce
function. This will cause the reduce
function to be run in parallel across 20 worker nodes.
priority
The priority
function is a simple priority scheduler for the executor function. The executor
function doesn’t directly have a concept of task prioritization; instead it simply executes tasks in the order that they are read from it’s underlying stream. The priority
function provides the ability to schedule a higher priority task ahead of lower priority tasks that were submitted earlier.
The priority
function wraps two topics that are both emitting tuples that contain streaming expressions to execute. The first topic is considered the higher priority task queue.
Each time the priority
function is called, it checks the higher priority task queue to see if there are any tasks to execute. If tasks are waiting in the higher priority queue then the priority function will emit the higher priority tasks. If there are no high priority tasks to run, the lower priority queue tasks are emitted.
The priority
function will only emit a batch of tasks from one of the queues each time it is called. This ensures that no lower priority tasks are executed until the higher priority queue has no tasks to run.
priority Parameters
-
topic expression
: (Mandatory) the high priority task queue -
topic expression
: (Mandatory) the lower priority task queue
priority Syntax
daemon(id="myDaemon",
executor(threads=10,
priority(topic(checkpointCollection, storedExpressions, q="priority:high", fl="id, expr_s", initialCheckPoint=0,id="highPriorityTasks"),
topic(checkpointCollection, storedExpressions, q="priority:low", fl="id, expr_s", initialCheckPoint=0,id="lowPriorityTasks"))))
In the example above the daemon
function is calling the executor iteratively. Each time it’s called, the executor
function will execute the tasks emitted by the priority
function. The priority
function wraps two topics. The first topic is the higher priority task queue, the second topics is the lower priority topic.
reduce
The reduce
function wraps an internal stream and groups tuples by common fields.
Each tuple group is operated on as a single block by a pluggable reduce operation. The group operation provided with Solr implements distributed grouping functionality. The group operation also serves as an example reduce operation that can be referred to when building custom reduce operations.
The reduce function relies on the sort order of the underlying stream. Accordingly the sort order of the underlying stream must be aligned with the group by field. |
reduce Parameters
-
StreamExpression
: (Mandatory) -
by
: (Mandatory) A comma separated list of fields to group by. -
Reduce Operation
: (Mandatory)
reduce Syntax
reduce(search(collection1, q=*:*, fl="id,a_s,a_i,a_f", sort="a_s asc, a_f asc"),
by="a_s",
group(sort="a_f desc", n="4")
)
rollup
The rollup
function wraps another stream function and rolls up aggregates over bucket fields. The rollup function relies on the sort order of the underlying stream to rollup aggregates one grouping at a time. Accordingly, the sort order of the underlying stream must match the fields in the over
parameter of the rollup function.
The rollup function also needs to process entire result sets in order to perform its aggregations. When the underlying stream is the search
function, the /export
handler can be used to provide full sorted result sets to the rollup function. This sorted approach allows the rollup function to perform aggregations over very high cardinality fields. The disadvantage of this approach is that the tuples must be sorted and streamed across the network to a worker node to be aggregated. For faster aggregation over low to moderate cardinality fields, the facet
function can be used.
rollup Parameters
-
StreamExpression
(Mandatory) -
over
: (Mandatory) A list of fields to group by. -
metrics
: (Mandatory) The list of metrics to compute. Currently supported metrics aresum(col)
,avg(col)
,min(col)
,max(col)
,count(*)
.
rollup Syntax
rollup(
search(collection1, q=*:*, fl="a_s,a_i,a_f", qt="/export", sort="a_s asc"),
over="a_s",
sum(a_i),
sum(a_f),
min(a_i),
min(a_f),
max(a_i),
max(a_f),
avg(a_i),
avg(a_f),
count(*)
)
The example about shows the rollup function wrapping the search function. Notice that search function is using the /export
handler to provide the entire result set to the rollup stream. Also notice that the search function’s sort param matches up with the rollup’s over
parameter. This allows the rollup function to rollup the over the a_s
field, one group at a time.
scoreNodes
See section in graph traversal.
select
The select
function wraps a streaming expression and outputs tuples containing a subset or modified set of fields from the incoming tuples. The list of fields included in the output tuple can contain aliases to effectively rename fields. The select
stream supports both operations and evaluators. One can provide a list of operations and evaluators to perform on any fields, such as replace, add, if
, etc….
select Parameters
-
StreamExpression
-
fieldName
: name of field to include in the output tuple (can include multiple of these), such asoutputTuple[fieldName] = inputTuple[fieldName]
-
fieldName as aliasFieldName
: aliased field name to include in the output tuple (can include multiple of these), such asoutputTuple[aliasFieldName] = incomingTuple[fieldName]
-
replace(fieldName, value, withValue=replacementValue)
: ifincomingTuple[fieldName] == value
thenoutgoingTuple[fieldName]
will be set toreplacementValue
.value
can be the string "null" to replace a null value with some other value. -
replace(fieldName, value, withField=otherFieldName)
: ifincomingTuple[fieldName] == value
thenoutgoingTuple[fieldName]
will be set to the value ofincomingTuple[otherFieldName]
.value
can be the string "null" to replace a null value with some other value.
select Syntax
// output tuples with fields teamName, wins, losses, and winPercentages where a null value for wins or losses is translated to the value of 0
select(
search(collection1, fl="id,teamName_s,wins,losses", q="*:*", sort="id asc"),
teamName_s as teamName,
wins,
losses,
replace(wins,null,withValue=0),
replace(losses,null,withValue=0),
if(eq(0,wins), 0, div(add(wins,losses), wins)) as winPercentage
)
sort
The sort
function wraps a streaming expression and re-orders the tuples. The sort function emits all incoming tuples in the new sort order. The sort function reads all tuples from the incoming stream, re-orders them using an algorithm with O(nlog(n))
performance characteristics, where n is the total number of tuples in the incoming stream, and then outputs the tuples in the new sort order. Because all tuples are read into memory, the memory consumption of this function grows linearly with the number of tuples in the incoming stream.
sort Parameters
-
StreamExpression
-
by
: Sort criteria for re-ordering the tuples
sort Syntax
The expression below finds dog owners and orders the results by owner and pet name. Notice that it uses an efficient innerJoin by first ordering by the person/owner id and then re-orders the final output by the owner and pet names.
sort(
innerJoin(
search(people, q=*:*, fl="id,name", sort="id asc"),
search(pets, q=type:dog, fl="owner,petName", sort="owner asc"),
on="id=owner"
),
by="name asc, petName asc"
)
top
The top
function wraps a streaming expression and re-orders the tuples. The top function emits only the top N tuples in the new sort order. The top function re-orders the underlying stream so the sort criteria does not have to match up with the underlying stream.
top Parameters
-
n
: Number of top tuples to return. -
StreamExpression
-
sort
: Sort criteria for selecting the top N tuples.
top Syntax
The expression below finds the top 3 results of the underlying search. Notice that it reverses the sort order. The top function re-orders the results of the underlying stream.
top(n=3,
search(collection1,
q="*:*",
qt="/export",
fl="id,a_s,a_i,a_f",
sort="a_f desc, a_i desc"),
sort="a_f asc, a_i asc")
unique
The unique
function wraps a streaming expression and emits a unique stream of tuples based on the over
parameter. The unique function relies on the sort order of the underlying stream. The over
parameter must match up with the sort order of the underlying stream.
The unique function implements a non-co-located unique algorithm. This means that records with the same unique over
field do not need to be co-located on the same shard. When executed in the parallel, the partitionKeys
parameter must be the same as the unique over
field so that records with the same keys will be shuffled to the same worker.
unique Parameters
-
StreamExpression
-
over
: The unique criteria.
unique Syntax
unique(
search(collection1,
q="*:*",
qt="/export",
fl="id,a_s,a_i,a_f",
sort="a_f asc, a_i asc"),
over="a_f")
update
The update
function wraps another functions and sends the tuples to a SolrCloud collection for indexing.
update Parameters
-
destinationCollection
: (Mandatory) The collection where the tuples will indexed. -
batchSize
: (Mandatory) The indexing batch size. -
StreamExpression
: (Mandatory)
update Syntax
update(destinationCollection,
batchSize=500,
search(collection1,
q=*:*,
fl="id,a_s,a_i,a_f,s_multi,i_multi",
sort="a_f asc, a_i asc"))
The example above sends the tuples returned by the search
function to the destinationCollection
to be indexed.
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