509 lines
15 KiB
Plaintext
509 lines
15 KiB
Plaintext
[[query-dsl-multi-match-query]]
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=== Multi Match Query
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The `multi_match` query builds on the <<query-dsl-match-query,`match` query>>
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to allow multi-field queries:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"multi_match" : {
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"query": "this is a test", <1>
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"fields": [ "subject", "message" ] <2>
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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<1> The query string.
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<2> The fields to be queried.
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[float]
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==== `fields` and per-field boosting
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Fields can be specified with wildcards, eg:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"multi_match" : {
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"query": "Will Smith",
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"fields": [ "title", "*_name" ] <1>
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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<1> Query the `title`, `first_name` and `last_name` fields.
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Individual fields can be boosted with the caret (`^`) notation:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"multi_match" : {
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"query" : "this is a test",
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"fields" : [ "subject^3", "message" ] <1>
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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<1> The `subject` field is three times as important as the `message` field.
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[[multi-match-types]]
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[float]
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==== Types of `multi_match` query:
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The way the `multi_match` query is executed internally depends on the `type`
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parameter, which can be set to:
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[horizontal]
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`best_fields`:: (*default*) Finds documents which match any field, but
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uses the `_score` from the best field. See <<type-best-fields>>.
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`most_fields`:: Finds documents which match any field and combines
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the `_score` from each field. See <<type-most-fields>>.
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`cross_fields`:: Treats fields with the same `analyzer` as though they
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were one big field. Looks for each word in *any*
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field. See <<type-cross-fields>>.
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`phrase`:: Runs a `match_phrase` query on each field and combines
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the `_score` from each field. See <<type-phrase>>.
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`phrase_prefix`:: Runs a `match_phrase_prefix` query on each field and
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combines the `_score` from each field. See <<type-phrase>>.
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[[type-best-fields]]
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==== `best_fields`
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The `best_fields` type is most useful when you are searching for multiple
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words best found in the same field. For instance ``brown fox'' in a single
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field is more meaningful than ``brown'' in one field and ``fox'' in the other.
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The `best_fields` type generates a <<query-dsl-match-query,`match` query>> for
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each field and wraps them in a <<query-dsl-dis-max-query,`dis_max`>> query, to
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find the single best matching field. For instance, this query:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"multi_match" : {
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"query": "brown fox",
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"type": "best_fields",
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"fields": [ "subject", "message" ],
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"tie_breaker": 0.3
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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would be executed as:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"dis_max": {
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"queries": [
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{ "match": { "subject": "brown fox" }},
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{ "match": { "message": "brown fox" }}
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],
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"tie_breaker": 0.3
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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Normally the `best_fields` type uses the score of the *single* best matching
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field, but if `tie_breaker` is specified, then it calculates the score as
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follows:
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* the score from the best matching field
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* plus `tie_breaker * _score` for all other matching fields
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Also, accepts `analyzer`, `boost`, `operator`, `minimum_should_match`,
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`fuzziness`, `lenient`, `prefix_length`, `max_expansions`, `rewrite`, `zero_terms_query`
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and `cutoff_frequency`, as explained in <<query-dsl-match-query, match query>>.
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[IMPORTANT]
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[[operator-min]]
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.`operator` and `minimum_should_match`
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===================================================
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The `best_fields` and `most_fields` types are _field-centric_ -- they generate
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a `match` query *per field*. This means that the `operator` and
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`minimum_should_match` parameters are applied to each field individually,
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which is probably not what you want.
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Take this query for example:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"multi_match" : {
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"query": "Will Smith",
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"type": "best_fields",
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"fields": [ "first_name", "last_name" ],
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"operator": "and" <1>
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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<1> All terms must be present.
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This query is executed as:
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(+first_name:will +first_name:smith)
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| (+last_name:will +last_name:smith)
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In other words, *all terms* must be present *in a single field* for a document
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to match.
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See <<type-cross-fields>> for a better solution.
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===================================================
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[[type-most-fields]]
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==== `most_fields`
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The `most_fields` type is most useful when querying multiple fields that
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contain the same text analyzed in different ways. For instance, the main
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field may contain synonyms, stemming and terms without diacritics. A second
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field may contain the original terms, and a third field might contain
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shingles. By combining scores from all three fields we can match as many
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documents as possible with the main field, but use the second and third fields
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to push the most similar results to the top of the list.
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This query:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"multi_match" : {
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"query": "quick brown fox",
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"type": "most_fields",
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"fields": [ "title", "title.original", "title.shingles" ]
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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would be executed as:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"bool": {
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"should": [
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{ "match": { "title": "quick brown fox" }},
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{ "match": { "title.original": "quick brown fox" }},
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{ "match": { "title.shingles": "quick brown fox" }}
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]
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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The score from each `match` clause is added together, then divided by the
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number of `match` clauses.
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Also, accepts `analyzer`, `boost`, `operator`, `minimum_should_match`,
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`fuzziness`, `lenient`, `prefix_length`, `max_expansions`, `rewrite`, `zero_terms_query`
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and `cutoff_frequency`, as explained in <<query-dsl-match-query,match query>>, but
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*see <<operator-min>>*.
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[[type-phrase]]
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==== `phrase` and `phrase_prefix`
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The `phrase` and `phrase_prefix` types behave just like <<type-best-fields>>,
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but they use a `match_phrase` or `match_phrase_prefix` query instead of a
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`match` query.
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This query:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"multi_match" : {
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"query": "quick brown f",
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"type": "phrase_prefix",
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"fields": [ "subject", "message" ]
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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would be executed as:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"dis_max": {
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"queries": [
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{ "match_phrase_prefix": { "subject": "quick brown f" }},
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{ "match_phrase_prefix": { "message": "quick brown f" }}
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]
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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Also, accepts `analyzer`, `boost`, `lenient`, `slop` and `zero_terms_query` as explained
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in <<query-dsl-match-query>>. Type `phrase_prefix` additionally accepts
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`max_expansions`.
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[IMPORTANT]
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[[phrase-fuzziness]]
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.`phrase`, `phrase_prefix` and `fuzziness`
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===================================================
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The `fuzziness` parameter cannot be used with the `phrase` or `phrase_prefix` type.
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===================================================
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[[type-cross-fields]]
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==== `cross_fields`
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The `cross_fields` type is particularly useful with structured documents where
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multiple fields *should* match. For instance, when querying the `first_name`
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and `last_name` fields for ``Will Smith'', the best match is likely to have
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``Will'' in one field and ``Smith'' in the other.
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****
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This sounds like a job for <<type-most-fields>> but there are two problems
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with that approach. The first problem is that `operator` and
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`minimum_should_match` are applied per-field, instead of per-term (see
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<<operator-min,explanation above>>).
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The second problem is to do with relevance: the different term frequencies in
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the `first_name` and `last_name` fields can produce unexpected results.
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For instance, imagine we have two people: ``Will Smith'' and ``Smith Jones''.
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``Smith'' as a last name is very common (and so is of low importance) but
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``Smith'' as a first name is very uncommon (and so is of great importance).
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If we do a search for ``Will Smith'', the ``Smith Jones'' document will
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probably appear above the better matching ``Will Smith'' because the score of
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`first_name:smith` has trumped the combined scores of `first_name:will` plus
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`last_name:smith`.
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****
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One way of dealing with these types of queries is simply to index the
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`first_name` and `last_name` fields into a single `full_name` field. Of
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course, this can only be done at index time.
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The `cross_field` type tries to solve these problems at query time by taking a
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_term-centric_ approach. It first analyzes the query string into individual
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terms, then looks for each term in any of the fields, as though they were one
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big field.
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A query like:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"multi_match" : {
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"query": "Will Smith",
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"type": "cross_fields",
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"fields": [ "first_name", "last_name" ],
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"operator": "and"
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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is executed as:
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+(first_name:will last_name:will)
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+(first_name:smith last_name:smith)
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In other words, *all terms* must be present *in at least one field* for a
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document to match. (Compare this to
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<<operator-min,the logic used for `best_fields` and `most_fields`>>.)
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That solves one of the two problems. The problem of differing term frequencies
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is solved by _blending_ the term frequencies for all fields in order to even
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out the differences.
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In practice, `first_name:smith` will be treated as though it has the same
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frequencies as `last_name:smith`, plus one. This will make matches on
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`first_name` and `last_name` have comparable scores, with a tiny advantage
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for `last_name` since it is the most likely field that contains `smith`.
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Note that `cross_fields` is usually only useful on short string fields
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that all have a `boost` of `1`. Otherwise boosts, term freqs and length
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normalization contribute to the score in such a way that the blending of term
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statistics is not meaningful anymore.
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If you run the above query through the <<search-validate>>, it returns this
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explanation:
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+blended("will", fields: [first_name, last_name])
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+blended("smith", fields: [first_name, last_name])
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Also, accepts `analyzer`, `boost`, `operator`, `minimum_should_match`,
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`lenient`, `zero_terms_query` and `cutoff_frequency`, as explained in
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<<query-dsl-match-query, match query>>.
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===== `cross_field` and analysis
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The `cross_field` type can only work in term-centric mode on fields that have
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the same analyzer. Fields with the same analyzer are grouped together as in
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the example above. If there are multiple groups, they are combined with a
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`bool` query.
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For instance, if we have a `first` and `last` field which have
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the same analyzer, plus a `first.edge` and `last.edge` which
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both use an `edge_ngram` analyzer, this query:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"multi_match" : {
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"query": "Jon",
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"type": "cross_fields",
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"fields": [
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"first", "first.edge",
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"last", "last.edge"
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]
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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would be executed as:
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blended("jon", fields: [first, last])
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| (
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blended("j", fields: [first.edge, last.edge])
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blended("jo", fields: [first.edge, last.edge])
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blended("jon", fields: [first.edge, last.edge])
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)
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In other words, `first` and `last` would be grouped together and
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treated as a single field, and `first.edge` and `last.edge` would be
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grouped together and treated as a single field.
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Having multiple groups is fine, but when combined with `operator` or
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`minimum_should_match`, it can suffer from the <<operator-min,same problem>>
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as `most_fields` or `best_fields`.
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You can easily rewrite this query yourself as two separate `cross_fields`
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queries combined with a `bool` query, and apply the `minimum_should_match`
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parameter to just one of them:
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"bool": {
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"should": [
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{
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"multi_match" : {
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"query": "Will Smith",
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"type": "cross_fields",
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"fields": [ "first", "last" ],
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"minimum_should_match": "50%" <1>
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}
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},
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{
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"multi_match" : {
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"query": "Will Smith",
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"type": "cross_fields",
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"fields": [ "*.edge" ]
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}
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}
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]
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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<1> Either `will` or `smith` must be present in either of the `first`
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or `last` fields
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You can force all fields into the same group by specifying the `analyzer`
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parameter in the query.
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[source,js]
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--------------------------------------------------
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GET /_search
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{
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"query": {
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"multi_match" : {
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"query": "Jon",
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"type": "cross_fields",
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"analyzer": "standard", <1>
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"fields": [ "first", "last", "*.edge" ]
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}
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}
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}
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--------------------------------------------------
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// CONSOLE
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<1> Use the `standard` analyzer for all fields.
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which will be executed as:
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blended("will", fields: [first, first.edge, last.edge, last])
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blended("smith", fields: [first, first.edge, last.edge, last])
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===== `tie_breaker`
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By default, each per-term `blended` query will use the best score returned by
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any field in a group, then these scores are added together to give the final
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score. The `tie_breaker` parameter can change the default behaviour of the
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per-term `blended` queries. It accepts:
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[horizontal]
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`0.0`:: Take the single best score out of (eg) `first_name:will`
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and `last_name:will` (*default*)
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`1.0`:: Add together the scores for (eg) `first_name:will` and
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`last_name:will`
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`0.0 < n < 1.0`:: Take the single best score plus +tie_breaker+ multiplied
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by each of the scores from other matching fields.
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[IMPORTANT]
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[[crossfields-fuzziness]]
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|
.`cross_fields` and `fuzziness`
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===================================================
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The `fuzziness` parameter cannot be used with the `cross_fields` type.
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===================================================
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