Other Parsers

In addition to the main query parsers discussed earlier, there are several other query parsers that can be used instead of or in conjunction with the main parsers for specific purposes.

This section details the other parsers, and gives examples for how they might be used.

Many of these parsers are expressed the same way as Local Parameters in Queries.

Block Join Query Parsers

There are two query parsers that support block joins. These parsers allow indexing and searching for relational content that has been indexed as Nested Documents.

The example usage of the query parsers below assumes these two documents and each of their child documents have been indexed:

<add>
  <doc>
  <field name="id">1</field>
  <field name="title">Solr has block join support</field>
  <field name="content_type">parentDocument</field>
    <doc>
      <field name="id">2</field>
      <field name="comments">SolrCloud supports it too!</field>
    </doc>
  </doc>
  <doc>
    <field name="id">3</field>
    <field name="title">New Lucene and Solr release</field>
    <field name="content_type">parentDocument</field>
    <doc>
      <field name="id">4</field>
      <field name="comments">Lots of new features</field>
    </doc>
  </doc>
</add>

Block Join Children Query Parser

This parser takes a query that matches some parent documents and returns their children.

The syntax for this parser is: q={!child of=<allParents>}<someParents>.

The parameter allParents is a filter that matches only parent documents; here you would define the field and value that you used to identify all parent documents.

The parameter someParents identifies a query that will match some of the parent documents. The output is the children.

Using the example documents above, we can construct a query such as q={!child of="content_type:parentDocument"}title:lucene&wt=xml. We only get one document in response:

<result name="response" numFound="1" start="0">
  <doc>
    <str name="id">4</str>
    <str name="comments">Lots of new features</str>
  </doc>
</result>

The query for someParents should match only parent documents passed by allParents or you may get an exception:

Parent query must not match any docs besides parent filter. Combine them as must (+) and must-not (-) clauses to find a problem doc.

You can search for q=+(someParents) -(allParents) to find a cause if you encounter this error.

Filtering and Tagging

{!child} also supports filters and excludeTags local parameters like the following:

{!child of=<allParents> filters=$parentfq excludeTags=certain}<someParents>&parentfq=BRAND:Foo&parentfq=NAME:Bar&parentfq={!tag=certain}CATEGORY:Baz

This is equivalent to:

{!child of=<allParents>}+<someParents> +BRAND:Foo +NAME:Bar

Notice "$" syntax in filters for referencing queries; comma-separated tags excludeTags allows to exclude certain queries by tagging. Overall the idea is similar to excluding fq in facets. Note, that filtering is applied to the subordinate clause (<someParents>), and the intersection result is joined to the children.

All Children Syntax

When subordinate clause (<someParents>) is omitted, it’s parsed as a segmented and cached filter for children documents. More precisely, q={!child of=<allParents>} is equivalent to q=*:* -<allParents>.

Block Join Parent Query Parser

This parser takes a query that matches child documents and returns their parents.

The syntax for this parser is similar: q={!parent which=<allParents>}<someChildren>.

The parameter allParents is a filter that matches only parent documents; here you would define the field and value that you used to identify all parent documents.

The parameter someChildren is a query that matches some or all of the child documents.

The query for someChildren should match only child documents or you may get an exception:

Child query must not match same docs with parent filter. Combine them as must clauses (+) to find a problem doc.

You can search for q=+(parentFilter) +(someChildren) to find a cause.

Again using the example documents above, we can construct a query such as q={!parent which="content_type:parentDocument"}comments:SolrCloud&wt=xml. We get this document in response:

<result name="response" numFound="1" start="0">
  <doc>
    <str name="id">1</str>
    <arr name="title"><str>Solr has block join support</str></arr>
    <arr name="content_type"><str>parentDocument</str></arr>
  </doc>
</result>
Using which

A common mistake is to try to filter parents with a which filter, as in this bad example:

q={!parent which="title:join"}comments:SolrCloud

Instead, you should use a sibling mandatory clause as a filter:

q= +title:join +{!parent which="content_type:parentDocument"}comments:SolrCloud

Filtering and Tagging

The {!parent} query supports filters and excludeTags local parameters like the following:

{!parent which=<allParents> filters=$childfq excludeTags=certain}<someChildren>&
childfq=COLOR:Red&
childfq=SIZE:XL&
childfq={!tag=certain}PRINT:Hatched

This is equivalent to:

{!parent which=<allParents>}+<someChildren> +COLOR:Red +SIZE:XL

Notice the "$" syntax in filters for referencing queries. Comma-separated tags in excludeTags allow excluding certain queries by tagging. Overall the idea is similar to excluding fq in facets. Note that filtering is applied to the subordinate clause (<someChildren>) first, and the intersection result is joined to the parents.

Scoring with the Block Join Parent Query Parser

You can optionally use the score local parameter to return scores of the subordinate query. The values to use for this parameter define the type of aggregation, which are avg (average), max (maximum), min (minimum), total (sum). Implicit default is none which returns 0.0.

All Parents Syntax

When subordinate clause (<someChildren>) is omitted, it’s parsed as a segmented and cached filter for all parent documents, or more precisely q={!parent which=<allParents>} is equivalent to q=<allParents>.

Boolean Query Parser

The BoolQParser creates a Lucene BooleanQuery which is a boolean combination of other queries. Sub-queries along with their typed occurrences indicate how documents will be matched and scored.

Parameters

must
A list of queries that must appear in matching documents and contribute to the score.
must_not
A list of queries that must not appear in matching documents.
should
A list of queries should appear in matching documents. For a BooleanQuery with no must queries, one or more should queries must match a document for the BooleanQuery to match.
filter
A list of queries that must appear in matching documents. However, unlike must, the score of filter queries is ignored.

Examples

{!bool must=foo must=bar}
{!bool filter=foo should=bar}

Boost Query Parser

BoostQParser extends the QParserPlugin and creates a boosted query from the input value. The main value is the query to be boosted. Parameter b is the function query to use as the boost. The query to be boosted may be of any type.

Boost Query Parser Examples

Creates a query "foo" which is boosted (scores are multiplied) by the function query log(popularity):

{!boost b=log(popularity)}foo

Creates a query "foo" which is boosted by the date boosting function referenced in ReciprocalFloatFunction:

{!boost b=recip(ms(NOW,mydatefield),3.16e-11,1,1)}foo

Collapsing Query Parser

The CollapsingQParser is really a post filter that provides more performant field collapsing than Solr’s standard approach when the number of distinct groups in the result set is high.

This parser collapses the result set to a single document per group before it forwards the result set to the rest of the search components. So all downstream components (faceting, highlighting, etc.) will work with the collapsed result set.

Details about using the CollapsingQParser can be found in the section Collapse and Expand Results.

Complex Phrase Query Parser

The ComplexPhraseQParser provides support for wildcards, ORs, etc., inside phrase queries using Lucene’s ComplexPhraseQueryParser.

Under the covers, this query parser makes use of the Span group of queries, e.g., spanNear, spanOr, etc., and is subject to the same limitations as that family or parsers.

Parameters

inOrder
Set to true to force phrase queries to match terms in the order specified. The default is true.
df
The default search field.

Examples

{!complexphrase inOrder=true}name:"Jo* Smith"
{!complexphrase inOrder=false}name:"(john jon jonathan~) peters*"

A mix of ordered and unordered complex phrase queries:

+_query_:"{!complexphrase inOrder=true}manu:\"a* c*\"" +_query_:"{!complexphrase inOrder=false df=name}\"bla* pla*\""

Complex Phrase Parser Limitations

Performance is sensitive to the number of unique terms that are associated with a pattern. For instance, searching for "a*" will form a large OR clause (technically a SpanOr with many terms) for all of the terms in your index for the indicated field that start with the single letter 'a'. It may be prudent to restrict wildcards to at least two or preferably three letters as a prefix. Allowing very short prefixes may result in to many low-quality documents being returned.

Notice that it also supports leading wildcards "*a" as well with consequent performance implications. Applying ReversedWildcardFilterFactory in index-time analysis is usually a good idea.

MaxBooleanClauses with Complex Phrase Parser

You may need to increase MaxBooleanClauses in solrconfig.xml as a result of the term expansion above:

<maxBooleanClauses>4096</maxBooleanClauses>

This property is described in more detail in the section Query Sizing and Warming.

Stopwords with Complex Phrase Parser

It is recommended not to use stopword elimination with this query parser.

Lets say we add the terms the, up, and to to stopwords.txt for your collection, and index a document containing the text "Stores up to 15,000 songs, 25,00 photos, or 150 yours of video" in a field named "features".

While the query below does not use this parser:

 q=features:"Stores up to 15,000"

the document is returned. The next query that does use the Complex Phrase Query Parser, as in this query:

 q=features:"sto* up to 15*"&defType=complexphrase

does not return that document because SpanNearQuery has no good way to handle stopwords in a way analogous to PhraseQuery. If you must remove stopwords for your use case, use a custom filter factory or perhaps a customized synonyms filter that reduces given stopwords to some impossible token.

Escaping with Complex Phrase Parser

Special care has to be given when escaping: clauses between double quotes (usually whole query) is parsed twice, these parts have to be escaped as twice, e.g., "foo\\: bar\\^".

Field Query Parser

The FieldQParser extends the QParserPlugin and creates a field query from the input value, applying text analysis and constructing a phrase query if appropriate. The parameter f is the field to be queried.

Example:

{!field f=myfield}Foo Bar

This example creates a phrase query with "foo" followed by "bar" (assuming the analyzer for myfield is a text field with an analyzer that splits on whitespace and lowercase terms). This is generally equivalent to the Lucene query parser expression myfield:"Foo Bar".

Filters Query Parser

The syntax is:

q={!filters param=$fqs excludeTags=sample}field:text&
fqs=COLOR:Red&
fqs=SIZE:XL&
fqs={!tag=sample}BRAND:Foo

which is equivalent to:

q=+field:text +COLOR:Red +SIZE:XL

param local parameter uses "$" syntax to refer to a few queries, where excludeTags may omit some of them.

Function Query Parser

The FunctionQParser extends the QParserPlugin and creates a function query from the input value. This is only one way to use function queries in Solr; for another, more integrated, approach, see the section on Function Queries.

Example:

{!func}log(foo)

Function Range Query Parser

The FunctionRangeQParser extends the QParserPlugin and creates a range query over a function. This is also referred to as frange, as seen in the examples below.

Parameters

l
The lower bound. This parameter is optional.
u
The upper bound. This parameter is optional.
incl
Include the lower bound. This parameter is optional. The default is true.
incu
Include the upper bound. This parameter is optional. The default is true.

Examples

{!frange l=1000 u=50000}myfield
 fq={!frange l=0 u=2.2} sum(user_ranking,editor_ranking)

Both of these examples restrict the results by a range of values found in a declared field or a function query. In the second example, we’re doing a sum calculation, and then defining only values between 0 and 2.2 should be returned to the user.

For more information about range queries over functions, see Yonik Seeley’s introductory blog post Ranges over Functions in Solr 1.4.

Graph Query Parser

The graph query parser does a breadth first, cyclic aware, graph traversal of all documents that are "reachable" from a starting set of root documents identified by a wrapped query.

The graph is built according to linkages between documents based on the terms found in from and to fields that you specify as part of the query.

Supported field types are point fields with docValues enabled, or string fields with indexed=true or docValues=true.

For string fields which are indexed=false and docValues=true, please refer to the javadocs for DocValuesTermsQuery for it’s performance characteristics so indexed=true will perform better for most use-cases.

Graph Query Parameters

to
The field name of matching documents to inspect to identify outgoing edges for graph traversal. Defaults to edge_ids.
from
The field name to of candidate documents to inspect to identify incoming graph edges. Defaults to node_id.
traversalFilter
An optional query that can be supplied to limit the scope of documents that are traversed.
maxDepth
Integer specifying how deep the breadth first search of the graph should go beginning with the initial query. Defaults to -1 (unlimited).
returnRoot
Boolean to indicate if the documents that matched the original query (to define the starting points for graph) should be included in the final results. Defaults to true.
returnOnlyLeaf
Boolean that indicates if the results of the query should be filtered so that only documents with no outgoing edges are returned. Defaults to false.
useAutn
Boolean that indicates if an Automatons should be compiled for each iteration of the breadth first search, which may be faster for some graphs. Defaults to false.

Graph Query Limitations

The graph parser only works in single node Solr installations, or with SolrCloud collections that use exactly 1 shard.

Graph Query Examples

To understand how the graph parser works, consider the following Directed Cyclic Graph, containing 8 nodes (A to H) and 9 edges (1 to 9):

image

One way to model this graph as Solr documents, would be to create one document per node, with mutivalued fields identifying the incoming and outgoing edges for each node:

curl -H 'Content-Type: application/json' 'http://localhost:8983/solr/my_graph/update?commit=true' --data-binary '[
  {"id":"A","foo":  7, "out_edge":["1","9"],  "in_edge":["4","2"]  },
  {"id":"B","foo": 12, "out_edge":["3","6"],  "in_edge":["1"]      },
  {"id":"C","foo": 10, "out_edge":["5","2"],  "in_edge":["9"]      },
  {"id":"D","foo": 20, "out_edge":["4","7"],  "in_edge":["3","5"]  },
  {"id":"E","foo": 17, "out_edge":[],         "in_edge":["6"]      },
  {"id":"F","foo": 11, "out_edge":[],         "in_edge":["7"]      },
  {"id":"G","foo":  7, "out_edge":["8"],      "in_edge":[]         },
  {"id":"H","foo": 10, "out_edge":[],         "in_edge":["8"]      }
]'

With the model shown above, the following query demonstrates a simple traversal of all nodes reachable from node A:

http://localhost:8983/solr/my_graph/query?fl=id&q={!graph+from=in_edge+to=out_edge}id:A
"response":{"numFound":6,"start":0,"docs":[
   { "id":"A" },
   { "id":"B" },
   { "id":"C" },
   { "id":"D" },
   { "id":"E" },
   { "id":"F" } ]
}

We can also use the traversalFilter to limit the graph traversal to only nodes with maximum value of 15 in the foo field. In this case that means D, E, and F are excluded – F has a value of foo=11, but it is unreachable because the traversal skipped D:

http://localhost:8983/solr/my_graph/query?fl=id&q={!graph+from=in_edge+to=out_edge+traversalFilter='foo:[*+TO+15]'}id:A
...
"response":{"numFound":3,"start":0,"docs":[
   { "id":"A" },
   { "id":"B" },
   { "id":"C" } ]
}

The examples shown so far have all used a query for a single document ("id:A") as the root node for the graph traversal, but any query can be used to identify multiple documents to use as root nodes. The next example demonstrates using the maxDepth parameter to find all nodes that are at most one edge away from an root node with a value in the foo field less then or equal to 10:

http://localhost:8983/solr/my_graph/query?fl=id&q={!graph+from=in_edge+to=out_edge+maxDepth=1}foo:[*+TO+10]
...
"response":{"numFound":6,"start":0,"docs":[
   { "id":"A" },
   { "id":"B" },
   { "id":"C" },
   { "id":"D" },
   { "id":"G" },
   { "id":"H" } ]
}

Simplified Models

The Document & Field modeling used in the above examples enumerated all of the outgoing and income edges for each node explicitly, to help demonstrate exactly how the "from" and "to" parameters work, and to give you an idea of what is possible. With multiple sets of fields like these for identifying incoming and outgoing edges, it’s possible to model many independent Directed Graphs that contain some or all of the documents in your collection.

But in many cases it can also be possible to drastically simplify the model used.

For example, the same graph shown in the diagram above can be modeled by Solr Documents that represent each node and know only the ids of the nodes they link to, without knowing anything about the incoming links:

curl -H 'Content-Type: application/json' 'http://localhost:8983/solr/alt_graph/update?commit=true' --data-binary '[
  {"id":"A","foo":  7, "out_edge":["B","C"] },
  {"id":"B","foo": 12, "out_edge":["E","D"] },
  {"id":"C","foo": 10, "out_edge":["A","D"] },
  {"id":"D","foo": 20, "out_edge":["A","F"] },
  {"id":"E","foo": 17, "out_edge":[]        },
  {"id":"F","foo": 11, "out_edge":[]        },
  {"id":"G","foo":  7, "out_edge":["H"]     },
  {"id":"H","foo": 10, "out_edge":[]        }
  ]'

With this alternative document model, all of the same queries demonstrated above can still be executed, simply by changing the “from” parameter to replace the “in_edge” field with the “id” field:

http://localhost:8983/solr/alt_graph/query?fl=id&q={!graph+from=id+to=out_edge+maxDepth=1}foo:[*+TO+10]
...
"response":{"numFound":6,"start":0,"docs":[
   { "id":"A" },
   { "id":"B" },
   { "id":"C" },
   { "id":"D" },
   { "id":"G" },
   { "id":"H" } ]
}

Join Query Parser

JoinQParser extends the QParserPlugin. It allows normalizing relationships between documents with a join operation. This is different from the concept of a join in a relational database because no information is being truly joined. An appropriate SQL analogy would be an "inner query".

Examples:

Find all products containing the word "ipod", join them against manufacturer docs and return the list of manufacturers:

{!join from=manu_id_s to=id}ipod

Find all manufacturer docs named "belkin", join them against product docs, and filter the list to only products with a price less than $12:

q  = {!join from=id to=manu_id_s}compName_s:Belkin
fq = price:[* TO 12]

The join operation is done on a term basis, so the "from" and "to" fields must use compatible field types. For example: joining between a StrField and a IntPointField will not work, likewise joining between a StrField and a TextField that uses LowerCaseFilterFactory will only work for values that are already lower cased in the string field.

Join Parser Scoring

You can optionally use the score parameter to return scores of the subordinate query. The values to use for this parameter define the type of aggregation, which are avg (average), max (maximum), min (minimum) total, or none.

Score parameter and single value numerics

Specifying score local parameter switches the join algorithm. This might have performance implication on large indices, but it’s more important that this algorithm won’t work for single value numeric field starting from 7.0. Users are encouraged to change field types to string and rebuild indexes during migration.

Joining Across Collections

You can also specify a fromIndex parameter to join with a field from another core or collection. If running in SolrCloud mode, then the collection specified in the fromIndex parameter must have a single shard and a replica on all Solr nodes where the collection you’re joining to has a replica.

Let’s consider an example where you want to use a Solr join query to filter movies by directors that have won an Oscar. Specifically, imagine we have two collections with the following fields:

movies: id, title, director_id, …​

movie_directors: id, name, has_oscar, …​

To filter movies by directors that have won an Oscar using a Solr join on the movie_directors collection, you can send the following filter query to the movies collection:

fq={!join from=id fromIndex=movie_directors to=director_id}has_oscar:true

Notice that the query criteria of the filter (has_oscar:true) is based on a field in the collection specified using fromIndex. Keep in mind that you cannot return fields from the fromIndex collection using join queries, you can only use the fields for filtering results in the "to" collection (movies).

Next, let’s understand how these collections need to be deployed in your cluster. Imagine the movies collection is deployed to a four node SolrCloud cluster and has two shards with a replication factor of two. Specifically, the movies collection has replicas on the following four nodes:

node 1: movies_shard1_replica1

node 2: movies_shard1_replica2

node 3: movies_shard2_replica1

node 4: movies_shard2_replica2

To use the movie_directors collection in Solr join queries with the movies collection, it needs to have a replica on each of the four nodes. In other words, movie_directors must have one shard and replication factor of four:

node 1: movie_directors_shard1_replica1

node 2: movie_directors_shard1_replica2

node 3: movie_directors_shard1_replica3

node 4: movie_directors_shard1_replica4

At query time, the JoinQParser will access the local replica of the movie_directors collection to perform the join. If a local replica is not available or active, then the query will fail. At this point, it should be clear that since you’re limited to a single shard and the data must be replicated across all nodes where it is needed, this approach works better with smaller data sets where there is a one-to-many relationship between the from collection and the to collection. Moreover, if you add a replica to the to collection, then you also need to add a replica for the from collection.

For more information about join queries, see the Solr Wiki page on Joins. Erick Erickson has also written a blog post about join performance titled Solr and Joins.

Lucene Query Parser

The LuceneQParser extends the QParserPlugin by parsing Solr’s variant on the Lucene QueryParser syntax. This is effectively the same query parser that is used in Lucene. It uses the operators q.op, the default operator ("OR" or "AND") and df, the default field name.

Example:

{!lucene q.op=AND df=text}myfield:foo +bar -baz

For more information about the syntax for the Lucene Query Parser, see the Classic QueryParser javadocs.

Learning To Rank Query Parser

The LTRQParserPlugin is a special purpose parser for reranking the top results of a simple query using a more complex ranking query which is based on a machine learnt model.

Example:

{!ltr model=myModel reRankDocs=100}

Details about using the LTRQParserPlugin can be found in the Learning To Rank section.

Max Score Query Parser

The MaxScoreQParser extends the LuceneQParser but returns the Max score from the clauses. It does this by wrapping all SHOULD clauses in a DisjunctionMaxQuery with tie=1.0. Any MUST or PROHIBITED clauses are passed through as-is. Non-boolean queries, e.g., NumericRange falls-through to the LuceneQParser parser behavior.

Example:

{!maxscore tie=0.01}C OR (D AND E)

More Like This Query Parser

MLTQParser enables retrieving documents that are similar to a given document. It uses Lucene’s existing MoreLikeThis logic and also works in SolrCloud mode. The document identifier used here is the unique id value and not the Lucene internal document id. The list of returned documents excludes the queried document.

This query parser takes the following parameters:

qf
Specifies the fields to use for similarity.
mintf
Specifies the Minimum Term Frequency, the frequency below which terms will be ignored in the source document.
mindf
Specifies the Minimum Document Frequency, the frequency at which words will be ignored when they do not occur in at least this many documents.
maxdf
Specifies the Maximum Document Frequency, the frequency at which words will be ignored when they occur in more than this many documents.
minwl
Sets the minimum word length below which words will be ignored.
maxwl
Sets the maximum word length above which words will be ignored.
maxqt
Sets the maximum number of query terms that will be included in any generated query.
maxntp
Sets the maximum number of tokens to parse in each example document field that is not stored with TermVector support.
boost
Specifies if the query will be boosted by the interesting term relevance. It can be either "true" or "false".

Examples

Find documents like the document with id=1 and using the name field for similarity.

{!mlt qf=name}1

Adding more constraints to what qualifies as similar using mintf and mindf.

{!mlt qf=name mintf=2 mindf=3}1

Nested Query Parser

The NestedParser extends the QParserPlugin and creates a nested query, with the ability for that query to redefine its type via local parameters. This is useful in specifying defaults in configuration and letting clients indirectly reference them.

Example:

{!query defType=func v=$q1}

If the q1 parameter is price, then the query would be a function query on the price field. If the q1 parameter is \{!lucene}inStock:true}} then a term query is created from the Lucene syntax string that matches documents with inStock=true. These parameters would be defined in solrconfig.xml, in the defaults section:

<lst name="defaults">
  <str name="q1">{!lucene}inStock:true</str>
</lst>

For more information about the possibilities of nested queries, see Yonik Seeley’s blog post Nested Queries in Solr.

Payload Query Parsers

These query parsers utilize payloads encoded on terms during indexing.

The main query, for both of these parsers, is parsed straightforwardly from the field type’s query analysis into a SpanQuery. The generated SpanQuery will be either a SpanTermQuery or an ordered, zero slop SpanNearQuery, depending on how many tokens are emitted. Payloads can be encoded on terms using either the DelimitedPayloadTokenFilter or the NumericPayloadTokenFilter. The payload using parsers are:

  • PayloadScoreQParser
  • PayloadCheckQParser

Payload Score Parser

PayloadScoreQParser incorporates each matching term’s numeric (integer or float) payloads into the scores.

This parser accepts the following parameters:

f
The field to use. This parameter is required.
func
The payload function. The options are: min, max, average, or sum. This parameter is required.
operator
A search operator. The options are or and phrase, which is the default. This defines if the search query should be an OR query or a phrase query.
includeSpanScore
If true, multiples the computed payload factor by the score of the original query. If false, the default, the computed payload factor is the score.

Examples

{!payload_score f=my_field_dpf v=some_term func=max}
{!payload_score f=payload_field func=sum operator=or}A B C

Payload Check Parser

PayloadCheckQParser only matches when the matching terms also have the specified payloads.

This parser accepts the following parameters:

f
The field to use (required).
payloads

A space-separated list of payloads that must match the query terms (required)

Each specified payload will be encoded using the encoder determined from the field type and encoded accordingly for matching.

DelimitedPayloadTokenFilter 'identity' encoded payloads also work here, as well as float and integer encoded ones.

Example

{!payload_check f=words_dps payloads="VERB NOUN"}searching stuff

Prefix Query Parser

PrefixQParser extends the QParserPlugin by creating a prefix query from the input value. Currently no analysis or value transformation is done to create this prefix query.

The parameter is f, the field. The string after the prefix declaration is treated as a wildcard query.

Example:

{!prefix f=myfield}foo

This would be generally equivalent to the Lucene query parser expression myfield:foo*.

Raw Query Parser

RawQParser extends the QParserPlugin by creating a term query from the input value without any text analysis or transformation. This is useful in debugging, or when raw terms are returned from the terms component (this is not the default).

The only parameter is f, which defines the field to search.

Example:

{!raw f=myfield}Foo Bar

This example constructs the query: TermQuery(Term("myfield","Foo Bar")).

For easy filter construction to drill down in faceting, the TermQParserPlugin is recommended.

For full analysis on all fields, including text fields, you may want to use the FieldQParserPlugin.

Re-Ranking Query Parser

The ReRankQParserPlugin is a special purpose parser for Re-Ranking the top results of a simple query using a more complex ranking query.

Details about using the ReRankQParserPlugin can be found in the Query Re-Ranking section.

Simple Query Parser

The Simple query parser in Solr is based on Lucene’s SimpleQueryParser. This query parser is designed to allow users to enter queries however they want, and it will do its best to interpret the query and return results.

This parser takes the following parameters:

q.operators

Comma-separated list of names of parsing operators to enable. By default, all operations are enabled, and this parameter can be used to effectively disable specific operators as needed, by excluding them from the list. Passing an empty string with this parameter disables all operators.

NameOperatorDescriptionExample query
AND+Specifies ANDtoken1+token2
OR|Specifies ORtoken1|token2
NOT-Specifies NOT-token3
PREFIX*Specifies a prefix queryterm*
PHRASE"Creates a phrase"term1 term2"
PRECEDENCE( )Specifies precedence; tokens inside the parenthesis will be analyzed first. Otherwise, normal order is left to right.token1 + (token2 | token3)
ESCAPE\Put it in front of operators to match them literallyC\\
WHITESPACEspace or [\r\t\n]

Delimits tokens on whitespace. If not enabled, whitespace splitting will not be performed prior to analysis – usually most desirable.

Not splitting whitespace is a unique feature of this parser that enables multi-word synonyms to work. However, it probably actually won’t unless synonyms are configured to normalize instead of expand to all that match a given synonym. Such a configuration requires normalizing synonyms at both index time and query time. Solr’s analysis screen can help here.

term1 term2
FUZZY

~

~N

At the end of terms, specifies a fuzzy query.

"N" is optional and may be either "1" or "2" (the default)

term~1
NEAR~NAt the end of phrases, specifies a NEAR query"term1 term2"~5
q.op
Defines the default operator to use if none is defined by the user. Allowed values are AND and OR. OR is used if none is specified.
qf
A list of query fields and boosts to use when building the query.
df
Defines the default field if none is defined in the Schema, or overrides the default field if it is already defined.

Any errors in syntax are ignored and the query parser will interpret queries as best it can. However, this can lead to odd results in some cases.

Spatial Query Parsers

There are two spatial QParsers in Solr: geofilt and bbox. But there are other ways to query spatially: using the frange parser with a distance function, using the standard (lucene) query parser with the range syntax to pick the corners of a rectangle, or with RPT and BBoxField you can use the standard query parser but use a special syntax within quotes that allows you to pick the spatial predicate.

All these options are documented further in the section Spatial Search.

Surround Query Parser

The SurroundQParser enables the Surround query syntax, which provides proximity search functionality. There are two positional operators: w creates an ordered span query and n creates an unordered one. Both operators take a numeric value to indicate distance between two terms. The default is 1, and the maximum is 99.

Note that the query string is not analyzed in any way.

Example:

{!surround} 3w(foo, bar)

This example finds documents where the terms "foo" and "bar" are no more than 3 terms away from each other (i.e., no more than 2 terms between them).

This query parser will also accept boolean operators (AND, OR, and NOT, in either upper- or lowercase), wildcards, quoting for phrase searches, and boosting. The w and n operators can also be expressed in upper- or lowercase.

The non-unary operators (everything but NOT) support both infix (a AND b AND c) and prefix AND(a, b, c) notation.

Switch Query Parser

SwitchQParser is a QParserPlugin that acts like a "switch" or "case" statement.

The primary input string is trimmed and then prefixed with case. for use as a key to lookup a "switch case" in the parser’s local params. If a matching local param is found the resulting param value will then be parsed as a subquery, and returned as the parse result.

The case local param can be optionally be specified as a switch case to match missing (or blank) input strings. The default local param can optionally be specified as a default case to use if the input string does not match any other switch case local params. If default is not specified, then any input which does not match a switch case local param will result in a syntax error.

In the examples below, the result of each query is "XXX":

{!switch case.foo=XXX case.bar=zzz case.yak=qqq}foo
The extra whitespace between } and bar is trimmed automatically.
{!switch case.foo=qqq case.bar=XXX case.yak=zzz} bar
The result will fallback to the default.
{!switch case.foo=qqq case.bar=zzz default=XXX}asdf
No input uses the value for case instead.
{!switch case=XXX case.bar=zzz case.yak=qqq}

A practical usage of this parser, is in specifying appends filter query (fq) parameters in the configuration of a SearchHandler, to provide a fixed set of filter options for clients using custom parameter names.

Using the example configuration below, clients can optionally specify the custom parameters in_stock and shipping to override the default filtering behavior, but are limited to the specific set of legal values (shipping=any|free, in_stock=yes|no|all).

<requestHandler name="/select" class="solr.SearchHandler">
  <lst name="defaults">
    <str name="in_stock">yes</str>
    <str name="shipping">any</str>
  </lst>
  <lst name="appends">
    <str name="fq">{!switch case.all='*:*'
                            case.yes='inStock:true'
                            case.no='inStock:false'
                            v=$in_stock}</str>
    <str name="fq">{!switch case.any='*:*'
                            case.free='shipping_cost:0.0'
                            v=$shipping}</str>
  </lst>
</requestHandler>

Term Query Parser

TermQParser extends the QParserPlugin by creating a single term query from the input value equivalent to readableToIndexed(). This is useful for generating filter queries from the external human readable terms returned by the faceting or terms components. The only parameter is f, for the field.

Example:

{!term f=weight}1.5

For text fields, no analysis is done since raw terms are already returned from the faceting and terms components. To apply analysis to text fields as well, see the Field Query Parser, above.

If no analysis or transformation is desired for any type of field, see the Raw Query Parser, above.

Terms Query Parser

TermsQParser functions similarly to the Term Query Parser but takes in multiple values separated by commas and returns documents matching any of the specified values.

This can be useful for generating filter queries from the external human readable terms returned by the faceting or terms components, and may be more efficient in some cases than using the Standard Query Parser to generate a boolean query since the default implementation method avoids scoring.

This query parser takes the following parameters:

f
The field on which to search. This parameter is required.
separator
Separator to use when parsing the input. If set to " " (a single blank space), will trim additional white space from the input terms. Defaults to a comma (,).
method
The internal query-building implementation: termsFilter, booleanQuery, automaton, or docValuesTermsFilter. Defaults to termsFilter.

Examples

{!terms f=tags}software,apache,solr,lucene
{!terms f=categoryId method=booleanQuery separator=" "}8 6 7 5309

XML Query Parser

The XmlQParserPlugin extends the QParserPlugin and supports the creation of queries from XML. Example:

ParameterValue
defTypexmlparser
q
<BooleanQuery fieldName="description">
   <Clause occurs="must">
      <TermQuery>shirt</TermQuery>
   </Clause>
   <Clause occurs="mustnot">
      <TermQuery>plain</TermQuery>
   </Clause>
   <Clause occurs="should">
      <TermQuery>cotton</TermQuery>
   </Clause>
   <Clause occurs="must">
      <BooleanQuery fieldName="size">
         <Clause occurs="should">
            <TermsQuery>S M L</TermsQuery>
         </Clause>
      </BooleanQuery>
   </Clause>
</BooleanQuery>

The XmlQParser implementation uses the SolrCoreParser class which extends Lucene’s CoreParser class. XML elements are mapped to QueryBuilder classes as follows:

XML elementQueryBuilder class
<BooleanQuery>BooleanQueryBuilder
<BoostingTermQuery>BoostingTermBuilder
<ConstantScoreQuery>ConstantScoreQueryBuilder
<DisjunctionMaxQuery>DisjunctionMaxQueryBuilder
<MatchAllDocsQuery>MatchAllDocsQueryBuilder
<RangeQuery>RangeQueryBuilder
<SpanFirst>SpanFirstBuilder
<SpanNear>SpanNearBuilder
<SpanNot>SpanNotBuilder
<SpanOr>SpanOrBuilder
<SpanOrTerms>SpanOrTermsBuilder
<SpanTerm>SpanTermBuilder
<TermQuery>TermQueryBuilder
<TermsQuery>TermsQueryBuilder
<UserQuery>UserInputQueryBuilder
<LegacyNumericRangeQuery>LegacyNumericRangeQuery(Builder) is deprecated

Customizing XML Query Parser

You can configure your own custom query builders for additional XML elements. The custom builders need to extend the SolrQueryBuilder or the SolrSpanQueryBuilder class. Example solrconfig.xml snippet:

<queryParser name="xmlparser" class="XmlQParserPlugin">
  <str name="MyCustomQuery">com.mycompany.solr.search.MyCustomQueryBuilder</str>
</queryParser>