ArangoDB v3.13 is under development and not released yet. This documentation is not final and potentially incomplete.
Multi-dimensional indexes
Multi-dimensional indexes allow you to index two- or higher-dimensional data such as time ranges, for efficient intersection of multiple range queries
A multi-dimensional index maps multi-dimensional data in the form of multiple numeric attributes to one dimension while mostly preserving locality so that similar values in all of the dimensions remain close to each other in the mapping to a single dimension. Queries that filter by multiple value ranges at once can be better accelerated with such an index compared to a persistent index.
You can choose between two subtypes of multi-dimensional indexes:
- An
mdi
index with afields
property that describes which document attributes to use as dimensions - An
mdi-prefixed
index with afields
property as well as aprefixFields
property to specify one or more mandatory document attributes to narrow down the search space using equality checks, see Prefix fields
Both subtypes require that the attributes described by fields
have numeric
values. You can optionally omit documents from the index that have any of
the fields
or prefixFields
attributes not set or set to null
by declaring
the index as sparse with sparse: true
.
Multi-dimensional indexes can be created with a uniqueness constraint with
unique: true
. This only allows a single document with a given combination of
attribute values, using all of the fields
attributes and (for mdi-prefixed
indexes) prefixFields
. Documents omitted because of sparse: true
are exempt.
You can store additional attributes in
multi-dimensional indexes with the storedValues
property. They can be used for
projections (unlike the fields
attributes) so that indexes can cover more
queries without having to access the full documents.
Non-unique mdi
indexes have a fixed selectivity estimate of 1
. For mdi
indexes with unique: true
as well as for mdi-prefixed
indexes, you can
control whether index selectivity estimates are maintained for the index.
It is enabled by default and you can disable it with estimates: false
.
Not maintaining index selectivity estimates can have a slightly positive impact
on write performance but the query optimizer is not able to determine the
usefulness of different competing indexes in AQL queries when there are multiple
candidate indexes to choose from.
mdi
index type was previously called zkd
.Querying documents within a 3D box
Assume we have documents in a collection points
of the form
{"x": 12.9, "y": -284.0, "z": 0.02}
and we want to query all documents that are contained within a box defined by
[x0, x1] * [y0, y1] * [z0, z1]
.
To do so one creates a multi-dimensional index on the attributes x
, y
and
z
, e.g. in arangosh:
db.points.ensureIndex({
type: "mdi",
fields: ["x", "y", "z"],
fieldValueTypes: "double"
});
Unlike with other indexes, the order of the fields
does not matter.
fieldValueTypes
is required and the only allowed value is "double"
to use a
double-precision (64-bit) floating-point format internally.
Now we can use the index in a query:
FOR p IN points
FILTER x0 <= p.x && p.x <= x1
FILTER y0 <= p.y && p.y <= y1
FILTER z0 <= p.z && p.z <= z1
RETURN p
Possible range queries
Having an index on a set of fields does not require you to specify a full range for every field. For each field you can decide if you want to bound it from both sides, from one side only (i.e. only an upper or lower bound) or not bound it at all.
Furthermore you can use any comparison operator. The index supports <=
and >=
naturally, ==
will be translated to the bound [c, c]
. Strict comparison
is translated to their non-strict counterparts and a post-filter is inserted.
FOR p IN points
FILTER 2 <= p.x && p.x < 9
FILTER p.y >= 80
FILTER p.z == 4
RETURN p
The null
value is less than all other values in AQL. Therefore, range queries
without a lower bound need to include null
but sparse indexes do not
include null
values. For example, FILTER p.x < 9
sets an upper bound, but
unless you also set a lower bound like AND p.x >= 2
, the lower bound is
basically p.x >= null
.
You can explicitly exclude null
in range queries so that sparse indexes can be
utilized: FILTER p.x < 9 AND p.x != null
Example Use Case
If you build a calendar using ArangoDB you could create a collection for each user that contains the appointments. The documents would roughly look as follows:
{
"from": 345365,
"to": 678934,
"what": "Dentist",
}
from
/to
are the timestamps when an appointment starts/ends. Having an
multi-dimensional index on the fields ["from", "to"]
allows you to query
for all appointments within a given time range efficiently.
Finding all appointments within a time range
Given a time range [f, t]
we want to find all appointments [from, to]
that
are completely contained in [f, t]
. Those appointments clearly satisfy the
condition
f <= from and to <= t
Thus our query would be:
FOR app IN appointments
FILTER f <= app.from
FILTER app.to <= t
RETURN app
Finding all appointments that intersect a time range
Given a time range [f, t]
we want to find all appointments [from, to]
that
intersect [f, t]
. Two intervals [f, t]
and [from, to]
intersect if
and only if
f <= to and from <= t
Thus our query would be:
FOR app IN appointments
FILTER f <= app.to
FILTER app.from <= t
RETURN app
Prefix fields
Multi-dimensional indexes can accelerate range queries well but they are
inefficient for queries that check for equality of values. For use cases where
you have a combination of equality and range conditions in queries, you can use
the mdi-prefixed
subtype instead of mdi
. It has all the features of the
mdi
subtype but additionally lets you define one or more document attributes
you want to use for equality checks. This combination allows to efficiently
narrow down the search space to a subset of multi-dimensional index data before
performing the range checking.
The attributes for equality checking are specified via the prefixFields
property of mdi-prefix
indexes. These attributes can have non-numeric values,
unlike the attributes you use as fields
.
db.<collection>.ensureIndex({
type: "mdi-prefixed",
prefixFields: ["v", "w"]
fields: ["x", "y"],
fieldValueTypes: "double"
});
You need to specify all of the prefixFields
attributes in your queries to
utilize the index.
FOR p IN points
FILTER p.v == "type"
FILTER p.w == "group"
FILTER 2 <= p.x && p.x < 9
FILTER p.y >= 80
RETURN p
You can create mdi-prefixed
indexes on edge collections with the _from
or
_to
edge attribute as the first prefix field. Graph traversals with range filters
can then utilize such indexes. See Vertex-centric indexes
for details.
Storing additional values in indexes
Introduced in: v3.12.0
Multi-dimensional indexes allow you to store additional attributes in the index that can be used to satisfy projections of the document. They cannot be used for index lookups or for sorting, but for projections only. They allow multi-dimensional indexes to fully cover more queries and avoid extra document lookups. This can have a great positive effect on index scan performance if the number of scanned index entries is large.
You can set the storedValues
option and specify the additional attributes as
an array of attribute paths when creating a new mdi
or mdi-prefixed
index,
similar to the fields
option:
db.<collection>.ensureIndex({
type: "mdi",
fields: ["x", "y"],
fieldValueTypes: "double",
storedValues: ["y", "z"]
});
This indexes the x
and y
attributes so that the index can be used for range
queries by these attributes. Using these document attributes like for returning
them from the query is not covered by the index, however, unless you add the
attributes to storedValues
in addition to fields
. The reason is that the
index doesn’t store the original values of the attributes.
You can have the same attributes in storedValues
and fields
as the attributes
in fields
cannot be used for projections, but you can also store additional
attributes that are not listed in fields
.
The above example stores the y
and z
attribute values in the index using
storedValues
. The index can thus supply the values for projections without
having to look up the full document.
Attributes in storedValues
cannot overlap with the attributes specified in
prefixFields
. There is no reason to store them in the index because you need
to specify them in queries in order to use mdi-prefixed
indexes.
In unique indexes, only the index attributes in fields
and (for mdi-prefixed
indexes) prefixFields
are checked for uniqueness. The index attributes in
storedValues
are not checked for their uniqueness.
You cannot create multiple multi-dimensional indexes with the same sparse
,
unique
, fields
and (for mdi-prefixed
indexes) prefixFields
attributes
but different storedValues
settings. That means the value of storedValues
is
not considered by index creation calls when checking if an index is already
present or needs to be created.
Non-existing attributes are stored as null
values.
The maximum number of attributes that you can use in storedValues
is 32.
Lookahead Index Hint
Introduced in: v3.10.0
Using the lookahead index hint can increase the performance for certain use cases. Specifying a lookahead value greater than zero makes the index fetch more documents that are no longer in the search box, before seeking to the next lookup position. Because the seek operation is computationally expensive, probing more documents before seeking may reduce the number of seeks, if matching documents are found. Please keep in mind that it might also affect performance negatively if documents are fetched unnecessarily.
You can specify the lookahead
value using the OPTIONS
keyword:
FOR app IN appointments OPTIONS { lookahead: 32 }
FILTER @to <= app.to
FILTER app.from <= @from
RETURN app
Limitations
- Using array expansions for attributes is not possible (e.g.
array[*].attr
) - You can only index numeric values that are representable as IEEE-754 double.
- A high number of dimensions (more than 5) can impact the performance considerably.
- The performance can vary depending on the dataset. Densely packed points can lead to a high number of seeks. This behavior is typical for indexing using space filling curves.