ArangoDB v3.8 reached End of Life (EOL) and is no longer supported.
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Features and Improvements in ArangoDB 2.5
The following list shows in detail which features have been added or improved in ArangoDB 2.5. ArangoDB 2.5 also contains several bugfixes that are not listed here. For a list of bugfixes, please consult the CHANGELOG.
V8 version upgrade
The built-in version of V8 has been upgraded from 3.29.54 to 3.31.74.1. This allows activating additional ES6 (also dubbed Harmony or ES.next) features in ArangoDB, both in the ArangoShell and the ArangoDB server. They can be used for scripting and in server-side actions such as Foxx routes, traversals etc.
The following additional ES6 features become available in ArangoDB 2.5 by default:
- iterators and generators
- template strings
- enhanced object literals
- enhanced numeric literals
- block scoping with
let
and constant variables usingconst
(note: constant variables require using strict mode, too) - additional string methods (such as
startsWith
,repeat
etc.)
Index improvements
Sparse hash and skiplist indexes
Hash and skiplist indexes can optionally be made sparse. Sparse indexes exclude documents
in which at least one of the index attributes is either not set or has a value of null
.
As such documents are excluded from sparse indexes, they may contain fewer documents than their non-sparse counterparts. This enables faster indexing and can lead to reduced memory usage in case the indexed attribute does occur only in some, but not all documents of the collection. Sparse indexes will also reduce the number of collisions in non-unique hash indexes in case non-existing or optional attributes are indexed.
In order to create a sparse index, an object with the attribute sparse
can be added to
the index creation commands:
db.collection.ensureHashIndex(attributeName, { sparse: true });
db.collection.ensureHashIndex(attributeName1, attributeName2, { sparse: true });
db.collection.ensureUniqueConstraint(attributeName, { sparse: true });
db.collection.ensureUniqueConstraint(attributeName1, attributeName2, { sparse: true });
db.collection.ensureSkiplist(attributeName, { sparse: true });
db.collection.ensureSkiplist(attributeName1, attributeName2, { sparse: true });
db.collection.ensureUniqueSkiplist(attributeName, { sparse: true });
db.collection.ensureUniqueSkiplist(attributeName1, attributeName2, { sparse: true });
Note that in place of the above specialized index creation commands, it is recommended to use
the more general index creation command ensureIndex
:
db.collection.ensureIndex({ type: "hash", sparse: true, unique: true, fields: [ attributeName ] });
db.collection.ensureIndex({ type: "skiplist", sparse: false, unique: false, fields: [ "a", "b" ] });
When not explicitly set, the sparse
attribute defaults to false
for new hash or
skiplist indexes.
This causes a change in behavior when creating a unique hash index without specifying the
sparse flag: in 2.4, unique hash indexes were implicitly sparse, always excluding null
values.
There was no option to control this behavior, and sparsity was neither supported for non-unique
hash indexes nor skiplists in 2.4. This implicit sparsity of unique hash indexes was considered
an inconsistency, and therefore the behavior was cleaned up in 2.5. As of 2.5, indexes will
only be created sparse if sparsity is explicitly requested. Existing unique hash indexes from 2.4
or before will automatically be migrated so they are still sparse after the upgrade to 2.5.
Geo indexes are implicitly sparse, meaning documents without the indexed location attribute or
containing invalid location coordinate values will be excluded from the index automatically. This
is also a change when compared to pre-2.5 behavior, when documents with missing or invalid
coordinate values may have caused errors on insertion when the geo index’ unique
flag was set
and its ignoreNull
flag was not. This was confusing and has been rectified in 2.5. The method
ensureGeoConstraint()
now does the same as ensureGeoIndex()
. Furthermore, the attributes
constraint
, unique
, ignoreNull
and sparse
flags are now completely ignored when creating
geo indexes.
The same is true for fulltext indexes. There is no need to specify non-uniqueness or sparsity for geo or fulltext indexes.
As sparse indexes may exclude some documents, they cannot be used for every type of query.
Sparse hash indexes cannot be used to find documents for which at least one of the indexed
attributes has a value of null
. For example, the following AQL query cannot use a sparse
index, even if one was created on attribute attr
:
FOR doc In collection
FILTER doc.attr == null
RETURN doc
If the lookup value is non-constant, a sparse index may or may not be used, depending on
the other types of conditions in the query. If the optimizer can safely determine that
the lookup value cannot be null
, a sparse index may be used. When uncertain, the optimizer
will not make use of a sparse index in a query in order to produce correct results.
For example, the following queries cannot use a sparse index on attr
because the optimizer
will not know beforehand whether the comparison values for doc.attr
will include null
:
FOR doc In collection
FILTER doc.attr == SOME_FUNCTION(...)
RETURN doc
FOR other IN otherCollection
FOR doc In collection
FILTER doc.attr == other.attr
RETURN doc
Sparse skiplist indexes can be used for sorting if the optimizer can safely detect that the
index range does not include null
for any of the index attributes.
Selectivity estimates
Indexes of type primary
, edge
and hash
now provide selectivity estimates. These
will be used by the AQL query optimizer when deciding about index usage. Using selectivity
estimates can lead to faster query execution when more selective indexes are used.
The selectivity estimates are also returned by the GET /_api/index
REST API method
in a sub-attribute selectivityEstimate
for each index that supports it. This
attribute will be omitted for indexes that do not provide selectivity estimates.
If provided, the selectivity estimate will be a numeric value between 0 and 1.
Selectivity estimates will also be reported in the result of collection.getIndexes()
for all indexes that support this. If no selectivity estimate can be determined for
an index, the attribute selectivityEstimate
will be omitted here, too.
The web interface also shows selectivity estimates for each index that supports this.
Currently the following index types can provide selectivity estimates:
- primary index
- edge index
- hash index (unique and non-unique)
No selectivity estimates will be provided for indexes when running in cluster mode.
AQL Optimizer improvements
Sort removal
The AQL optimizer rule “use-index-for-sort” will now remove sorts also in case a non-sorted index (e.g. a hash index) is used for only equality lookups and all sort attributes are covered by the equality lookup conditions.
For example, in the following query the extra sort on doc.value
will be optimized away
provided there is an index on doc.value
):
FOR doc IN collection
FILTER doc.value == 1
SORT doc.value
RETURN doc
The AQL optimizer rule “use-index-for-sort” now also removes sort in case the sort criteria excludes the left-most index attributes, but the left-most index attributes are used by the index for equality-only lookups.
For example, in the following query with a skiplist index on value1
, value2
, the sort can
be optimized away:
FOR doc IN collection
FILTER doc.value1 == 1
SORT doc.value2
RETURN doc
Constant attribute propagation
The new AQL optimizer rule propagate-constant-attributes
will look for attributes that are
equality-compared to a constant value, and will propagate the comparison value into other
equality lookups. This rule will only look inside FILTER
conditions, and insert constant
values found in FILTER
s, too.
For example, the rule will insert 42
instead of i.value
in the second FILTER
of the
following query:
FOR i IN c1
FOR j IN c2
FILTER i.value == 42
FILTER j.value == i.value
RETURN 1
Interleaved processing
The optimizer will now inspect AQL data-modification queries and detect if the query’s data-modification part can run in lockstep with the data retrieval part of the query, or if the data retrieval part must be executed and completed first before the data-modification can start.
Executing both data retrieval and data-modification in lockstep allows using much smaller buffers for intermediate results, reducing the memory usage of queries. Not all queries are eligible for this optimization, and the optimizer will only apply the optimization when it can safely detect that the data-modification part of the query will not modify data to be found by the retrieval part.
Query execution statistics
The filtered
attribute was added to AQL query execution statistics. The value of this
attribute indicates how many documents were filtered by FilterNode
s in the AQL query.
Note that IndexRangeNode
s can also filter documents by selecting only the required ranges
from the index. The filtered
value will not include the work done by IndexRangeNode
s,
but only the work performed by FilterNode
s.
Language improvements
Dynamic attribute names in AQL object literals
This change allows using arbitrary expressions to construct attribute names in object
literals specified in AQL queries. To disambiguate expressions and other unquoted
attribute names, dynamic attribute names need to be enclosed in brackets ([
and ]
).
Example:
FOR i IN 1..100
RETURN { [ CONCAT('value-of-', i) ] : i }
AQL functions
The following AQL functions were added in 2.5:
MD5(value)
: generates an MD5 hash ofvalue
SHA1(value)
: generates an SHA1 hash ofvalue
RANDOM_TOKEN(length)
: generates a random string value of the specified length
Simplify Foxx usage
Thanks to our user feedback we learned that Foxx is a powerful, yet rather complicated concept. With 2.5 we made it less complicated while keeping all its strength. That includes a rewrite of the documentation as well as some code changes as follows:
Moved Foxx applications to a different folder.
Until 2.4 Foxx apps were stored in the following folder structure:
<app-path>/databases/<dbname>/<appname>:<appversion>
.
This caused some trouble as apps where cached based on name and version and updates did not apply.
Also the path on filesystem and the app’s access URL had no relation to one another.
Now the path on filesystem is identical to the URL (except the appended APP):
<app-path>/_db/<dbname>/<mointpoint>/APP
Rewrite of Foxx routing
The routing of Foxx has been exposed to major internal changes we adjusted because of user feedback. This allows us to set the development mode per mount point without having to change paths and hold apps at separate locations.
Foxx Development mode
The development mode used until 2.4 is gone. It has been replaced by a much more mature version. This includes the deprecation of the javascript.dev-app-path parameter, which is useless since 2.5. Instead of having two separate app directories for production and development, apps now reside in one place, which is used for production as well as for development. Apps can still be put into development mode, changing their behavior compared to production mode. Development mode apps are still reread from disk at every request, and still they ship more debug output.
This change has also made the startup options --javascript.frontend-development-mode
and
--javascript.dev-app-path
obsolete. The former option will not have any effect when set, and the
latter option is only read and used during the upgrade to 2.5 and does not have any effects later.
Foxx install process
Installing Foxx apps has been a two step process: import them into ArangoDB and mount them at a specific mount point. These operations have been joined together. You can install an app at one mount point, that’s it. No fetch, mount, unmount, purge cycle anymore. The commands have been simplified to just:
- install: get your Foxx app up and running
- uninstall: shut it down and erase it from disk
Foxx error output
Until 2.4 the errors produced by Foxx were not optimal. Often, the error message was just
unable to parse manifest
and contained only an internal stack trace.
In 2.5 we made major improvements there, including a much more fine grained error output that
helps you debug your Foxx apps. The error message printed is now much closer to its source and
should help you track it down.
Also we added the default handlers for unhandled errors in Foxx apps:
- You will get a nice internal error page whenever your Foxx app is called but was not installed due to any error
- You will get a proper error message when having an uncaught error appears in any app route
In production mode the messages above will NOT contain any information about your Foxx internals and are safe to be exposed to third party users. In development mode the messages above will contain the stacktrace (if available), making it easier for your in-house devs to track down errors in the application.
Foxx console
We added a console
object to Foxx apps. All Foxx apps now have a console object implementing
the familiar Console API in their global scope, which can be used to log diagnostic
messages to the database. This console also allows to read the error output of one specific Foxx.
Foxx requests
We added org/arangodb/request
module, which provides a simple API for making HTTP requests
to external services. This is enables Foxx to be directly part of a micro service architecture.