Working with inverted indexes

Create an inverted index

POST /_db/{database-name}/_api/index
Creates an inverted index for the collection collection-name, if it does not already exist. The call expects an object containing the index details.
Path Parameters
  • The name of the database.

Query Parameters
  • The collection name.

HTTP Headers
    Request Body application/json object
    • The name of an Analyzer to use by default. This Analyzer is applied to the values of the indexed fields for which you don’t define Analyzers explicitly.

      Default: identity

    • Enable this option to always cache the field normalization values in memory for all fields by default. This can improve the performance of scoring and ranking queries. Otherwise, these values are memory-mapped and it is up to the operating system to load them from disk into memory and to evict them from memory.

      Normalization values are computed for fields which are processed with Analyzers that have the "norm" feature enabled. These values are used to score fairer if the same tokens occur repeatedly, to emphasize these documents less.

      You can also enable this option to always cache auxiliary data used for querying fields that are indexed with Geo Analyzers in memory for all fields by default. This can improve the performance of geo-spatial queries.

      Default: false

      This property is available in the Enterprise Edition only.

      See the --arangosearch.columns-cache-limit startup option to control the memory consumption of this cache. You can reduce the memory usage of the column cache in cluster deployments by only using the cache for leader shards, see the --arangosearch.columns-cache-only-leader startup option (introduced in v3.10.6).

    • Wait at least this many commits between removing unused files in the ArangoSearch data directory (default: 2, to disable use: 0). For the case where the consolidation policies merge segments often (i.e. a lot of commit+consolidate), a lower value causes a lot of disk space to be wasted. For the case where the consolidation policies rarely merge segments (i.e. few inserts/deletes), a higher value impacts performance without any added benefits.

      Background: With every “commit” or “consolidate” operation, a new state of the inverted index’ internal data structures is created on disk. Old states/snapshots are released once there are no longer any users remaining. However, the files for the released states/snapshots are left on disk, and only removed by “cleanup” operation.

    • Wait at least this many milliseconds between committing inverted index data store changes and making documents visible to queries (default: 1000, to disable use: 0). For the case where there are a lot of inserts/updates, a higher value causes the index not to account for them and memory usage continues to grow until the commit. A lower value impacts performance, including the case where there are no or only a few inserts/updates because of synchronous locking, and it wastes disk space for each commit call.

      Background: For data retrieval, ArangoSearch follows the concept of “eventually-consistent”, i.e. eventually all the data in ArangoDB will be matched by corresponding query expressions. The concept of ArangoSearch “commit” operations is introduced to control the upper-bound on the time until document addition/removals are actually reflected by corresponding query expressions. Once a “commit” operation is complete, all documents added/removed prior to the start of the “commit” operation will be reflected by queries invoked in subsequent ArangoDB transactions, in-progress ArangoDB transactions will still continue to return a repeatable-read state.

    • Wait at least this many milliseconds between applying consolidationPolicy to consolidate the inverted index data store and possibly release space on the filesystem (default: 1000, to disable use: 0). For the case where there are a lot of data modification operations, a higher value could potentially have the data store consume more space and file handles. For the case where there are a few data modification operations, a lower value impacts performance due to no segment candidates being available for consolidation.

      Background: For data modification, ArangoSearch follows the concept of a “versioned data store”. Thus old versions of data may be removed once there are no longer any users of the old data. The frequency of the cleanup and compaction operations are governed by consolidationIntervalMsec and the candidates for compaction are selected via consolidationPolicy.

    • The consolidation policy to apply for selecting which segments should be merged (default: {}).

      Background: With each ArangoDB transaction that inserts documents, one or more ArangoSearch-internal segments get created. Similarly, for removed documents, the segments that contain such documents have these documents marked as ‘deleted’. Over time, this approach causes a lot of small and sparse segments to be created. A “consolidation” operation selects one or more segments and copies all of their valid documents into a single new segment, thereby allowing the search algorithm to perform more optimally and for extra file handles to be released once old segments are no longer used.

      • Filter out consolidation candidates with a score less than this. Default: 0

      • Defines the value (in bytes) to treat all smaller segments as equal for consolidation selection. Default: 2097152

      • The maximum allowed size of all consolidated segments in bytes. Default: 5368709120

      • The maximum number of segments that are evaluated as candidates for consolidation. Default: 10

      • The minimum number of segments that are evaluated as candidates for consolidation. Default: 1

      • The segment candidates for the “consolidation” operation are selected based upon several possible configurable formulas as defined by their types. The supported types are:

        • "tier" (default): consolidate based on segment byte size and live document count as dictated by the customization attributes.

    • A list of Analyzer features. You can set this option to overwrite what features are enabled for the default analyzer. Possible features:

      • "frequency"
      • "norm"
      • "position"
      • "offset"

      Default: the features as defined by the Analyzer itself.

    • An array of attribute paths. You can use strings to index the fields with the default options, or objects to specify options for the fields (with the attribute path in the name property), or a mix of both.

      • The name of an Analyzer to use for this field.

        Default: the value defined by the top-level analyzer option.

      • Enable this option to always cache the field normalization values in memory for this specific field. This can improve the performance of scoring and ranking queries. Otherwise, these values are memory-mapped and it is up to the operating system to load them from disk into memory and to evict them from memory.

        Normalization values are computed for fields which are processed with Analyzers that have the "norm" feature enabled. These values are used to score fairer if the same tokens occur repeatedly, to emphasize these documents less.

        You can also enable this option to always cache auxiliary data used for querying fields that are indexed with Geo Analyzers in memory for this specific field. This can improve the performance of geo-spatial queries.

        Default: the value defined by the top-level cache option.

        This property is available in the Enterprise Edition only.

        See the --arangosearch.columns-cache-limit startup option to control the memory consumption of this cache. You can reduce the memory usage of the column cache in cluster deployments by only using the cache for leader shards, see the --arangosearch.columns-cache-only-leader startup option (introduced in v3.10.6).

      • A list of Analyzer features to use for this field. You can set this option to overwrite what features are enabled for the analyzer. Possible features:

        • "frequency"
        • "norm"
        • "position"
        • "offset"

        Default: the features as defined by the Analyzer itself, or inherited from the top-level features option if the analyzer option adjacent to this option is not set.

      • This option only applies if you use the inverted index in a search-alias Views.

        If set to true, then all sub-attributes of this field are indexed, excluding any sub-attributes that are configured separately by other elements in the fields array (and their sub-attributes). The analyzer and features properties apply to the sub-attributes.

        If set to false, then sub-attributes are ignored.

        Default: the value defined by the top-level includeAllFields option.

      • An attribute path. The . character denotes sub-attributes. You can expand one array attribute with [*].

      • Index the specified sub-objects that are stored in an array. Other than with the fields property, the values get indexed in a way that lets you query for co-occurring values. For example, you can search the sub-objects and all the conditions need to be met by a single sub-object instead of across all of them.

        This property is available in the Enterprise Edition only.

        • The name of an Analyzer to use for this field. Default: the value defined by the parent field, or the top-level analyzer option.

        • Enable this option to always cache the field normalization values in memory for this specific nested field. This can improve the performance of scoring and ranking queries. Otherwise, these values are memory-mapped and it is up to the operating system to load them from disk into memory and to evict them from memory.

          Normalization values are computed for fields which are processed with Analyzers that have the "norm" feature enabled. These values are used to score fairer if the same tokens occur repeatedly, to emphasize these documents less.

          You can also enable this option to always cache auxiliary data used for querying fields that are indexed with Geo Analyzers in memory for this specific nested field. This can improve the performance of geo-spatial queries.

          Default: the value defined by the top-level cache option.

          This property is available in the Enterprise Edition only.

          See the --arangosearch.columns-cache-limit startup option to control the memory consumption of this cache. You can reduce the memory usage of the column cache in cluster deployments by only using the cache for leader shards, see the --arangosearch.columns-cache-only-leader startup option (introduced in v3.10.6).

        • A list of Analyzer features to use for this field. You can set this option to overwrite what features are enabled for the analyzer. Possible features:

          • "frequency"
          • "norm"
          • "position"
          • "offset"

          Default: the features as defined by the Analyzer itself, or inherited from the parent field’s or top-level features option if no analyzer option is set at a deeper level, closer to this option.

        • An attribute path. The . character denotes sub-attributes.

        • You can recursively index sub-objects. See the above description of the nested option.

        • This option only applies if you use the inverted index in a search-alias Views.

          You can set the option to true to get the same behavior as with arangosearch Views regarding the indexing of array values for this field. If enabled, both, array and primitive values (strings, numbers, etc.) are accepted. Every element of an array is indexed according to the trackListPositions option.

          If set to false, it depends on the attribute path. If it explicitly expands an array ([*]), then the elements are indexed separately. Otherwise, the array is indexed as a whole, but only geopoint and aql Analyzers accept array inputs. You cannot use an array expansion if searchField is enabled.

          Default: the value defined by the top-level searchField option.

      • This option only applies if you use the inverted index in a search-alias Views.

        You can set the option to true to get the same behavior as with arangosearch Views regarding the indexing of array values for this field. If enabled, both, array and primitive values (strings, numbers, etc.) are accepted. Every element of an array is indexed according to the trackListPositions option.

        If set to false, it depends on the attribute path. If it explicitly expands an array ([*]), then the elements are indexed separately. Otherwise, the array is indexed as a whole, but only geopoint and aql Analyzers accept array inputs. You cannot use an array expansion if searchField is enabled.

        Default: the value defined by the top-level searchField option.

      • This option only applies if you use the inverted index in a search-alias Views, and searchField needs to be true.

        If set to true, then track the value position in arrays for array values. For example, when querying a document like { attr: [ "valueX", "valueY", "valueZ" ] }, you need to specify the array element, e.g. doc.attr[1] == "valueY".

        If set to false, all values in an array are treated as equal alternatives. You don’t specify an array element in queries, e.g. doc.attr == "valueY", and all elements are searched for a match.

        Default: the value defined by the top-level trackListPositions option.

    • This attribute can be set to true to create the index in the background, not write-locking the underlying collection for as long as if the index is built in the foreground. The default value is false.

    • This option only applies if you use the inverted index in a search-alias Views.

      If set to true, then all document attributes are indexed, excluding any sub-attributes that are configured in the fields array (and their sub-attributes). The analyzer and features properties apply to the sub-attributes.

      Default: false

      Using includeAllFields for a lot of attributes in combination with complex Analyzers may significantly slow down the indexing process.

    • An easy-to-remember name for the index to look it up or refer to it in index hints. Index names are subject to the same character restrictions as collection names. If omitted, a name is auto-generated so that it is unique with respect to the collection, e.g. idx_832910498.

    • This option only applies if you use the inverted index in a search-alias Views.

      An array of strings defining sort expressions that you want to optimize. This is also known as WAND optimization (introduced in v3.12.0).

      If you query a View with the SEARCH operation in combination with a SORT and LIMIT operation, search results can be retrieved faster if the SORT expression matches one of the optimized expressions.

      Only sorting by highest rank is supported, that is, sorting by the result of a scoring function in descending order (DESC). Use @doc in the expression where you would normally pass the document variable emitted by the SEARCH operation to the scoring function.

      You can define up to 64 expressions per View.

      Example: ["BM25(@doc) DESC", "TFIDF(@doc, true) DESC"]

      Default: []

      This property is available in the Enterprise Edition only.

    • The number of threads to use for indexing the fields. Default: 2

    • Enable this option to always cache the primary key column in memory. This can improve the performance of queries that return many documents. Otherwise, these values are memory-mapped and it is up to the operating system to load them from disk into memory and to evict them from memory.

      Default: false

      See the --arangosearch.columns-cache-limit startup option to control the memory consumption of this cache. You can reduce the memory usage of the column cache in cluster deployments by only using the cache for leader shards, see the --arangosearch.columns-cache-only-leader startup option (introduced in v3.10.6).

    • You can define a primary sort order to enable an AQL optimization. If a query iterates over all documents of a collection, wants to sort them by attribute values, and the (left-most) fields to sort by, as well as their sorting direction, match with the primarySort definition, then the SORT operation is optimized away.

      • Enable this option to always cache the primary sort columns in memory. This can improve the performance of queries that utilize the primary sort order. Otherwise, these values are memory-mapped and it is up to the operating system to load them from disk into memory and to evict them from memory.

        Default: false

        This property is available in the Enterprise Edition only.

        See the --arangosearch.columns-cache-limit startup option to control the memory consumption of this cache. You can reduce the memory usage of the column cache in cluster deployments by only using the cache for leader shards, see the --arangosearch.columns-cache-only-leader startup option (introduced in v3.10.6).

      • Defines how to compress the primary sort data. Possible values:

        • "lz4" (default): use LZ4 fast compression.
        • "none": disable compression to trade space for speed.

      • An array of the fields to sort the index by and the direction to sort each field in.

        • The sorting direction. Possible values:

          • "asc for ascending
          • "desc" for descending

        • An attribute path. The . character denotes sub-attributes.

    • This option only applies if you use the inverted index in a search-alias Views.

      You can set the option to true to get the same behavior as with arangosearch Views regarding the indexing of array values as the default. If enabled, both, array and primitive values (strings, numbers, etc.) are accepted. Every element of an array is indexed according to the trackListPositions option.

      If set to false, it depends on the attribute path. If it explicitly expands an array ([*]), then the elements are indexed separately. Otherwise, the array is indexed as a whole, but only geopoint and aql Analyzers accept array inputs. You cannot use an array expansion if searchField is enabled.

      Default: false

    • The optional storedValues attribute can contain an array of objects with paths to additional attributes to store in the index. These additional attributes cannot be used for index lookups or for sorting, but they can be used for projections. This allows an index to fully cover more queries and avoid extra document lookups.

      You may use the following shorthand notations on index creation instead of an array of objects. The default compression and cache settings are used in this case:

      • An array of strings, like ["attr1", "attr2"], to place each attribute into a separate column of the index (introduced in v3.10.3).

      • An array of arrays of strings, like [["attr1", "attr2"]], to place the attributes into a single column of the index, or [["attr1"], ["attr2"]] to place each attribute into a separate column. You can also mix it with the full form:

        [
          ["attr1"],
          ["attr2", "attr3"],
          { "fields": ["attr4", "attr5"], "cache": true }
        ]
        

      • Enable this option to always cache stored values in memory. This can improve the query performance if stored values are involved. Otherwise, these values are memory-mapped and it is up to the operating system to load them from disk into memory and to evict them from memory.

        Default: false

        This property is available in the Enterprise Edition only.

        See the --arangosearch.columns-cache-limit startup option to control the memory consumption of this cache. You can reduce the memory usage of the column cache in cluster deployments by only using the cache for leader shards, see the --arangosearch.columns-cache-only-leader startup option (introduced in v3.10.6).

      • Defines how to compress the attribute values. Possible values:

        • "lz4" (default): use LZ4 fast compression.
        • "none": disable compression to trade space for speed.

      • A list of attribute paths. The . character denotes sub-attributes.

    • This option only applies if you use the inverted index in a search-alias Views, and searchField needs to be true.

      If set to true, then track the value position in arrays for array values. For example, when querying a document like { attr: [ "valueX", "valueY", "valueZ" ] }, you need to specify the array element, e.g. doc.attr[1] == "valueY".

      If set to false, all values in an array are treated as equal alternatives. You don’t specify an array element in queries, e.g. doc.attr == "valueY", and all elements are searched for a match.

    • Must be equal to "inverted".

    • Maximum number of concurrent active writers (segments) that perform a transaction. Other writers (segments) wait till current active writers (segments) finish (default: 0, use 0 to disable)

    • Maximum number of writers (segments) cached in the pool (default: 64, use 0 to disable)

    • Maximum memory byte size per writer (segment) before a writer (segment) flush is triggered. 0 value turns off this limit for any writer (buffer) and data is flushed periodically based on the value defined for the flush thread (ArangoDB server startup option). 0 value should be used carefully due to high potential memory consumption (default: 33554432, use 0 to disable)

    Responses
    • If the index already exists, then a HTTP 200 is returned.

    • If the index does not already exist and can be created, then a HTTP 201 is returned.

    • If the collection-name is unknown, then a HTTP 404 is returned.

    Examples

    Creating an inverted index:

    curl -X POST --header 'accept: application/json' --data-binary @- --dump - 'http://localhost:8529/_api/index?collection=products' <<'EOF'
    {
      "type": "inverted",
      "fields": [
        "a",
        {
          "name": "b",
          "analyzer": "text_en"
        }
      ]
    }
    EOF
    Show output