To understand Trino, you must first understand the terms and concepts used throughout the Trino documentation.
While it is easy to understand statements and queries, as an end-user you should have familiarity with concepts such as stages and splits to take full advantage of Trino to execute efficient queries. As a Trino administrator or a Trino contributor you should understand how Trino’s concepts of stages map to tasks and how tasks contain a set of drivers which process data.
This section provides a solid definition for the core concepts referenced throughout Trino, and these sections are sorted from most general to most specific.
There are two types of Trino servers: coordinators and workers. The following section explains the difference between the two.
The Trino coordinator is the server that is responsible for parsing statements, planning queries, and managing Trino worker nodes. It is the “brain” of a Trino installation and is also the node to which a client connects to submit statements for execution. Every Trino installation must have a Trino coordinator alongside one or more Trino workers. For development or testing purposes, a single instance of Trino can be configured to perform both roles.
The coordinator keeps track of the activity on each worker and coordinates the execution of a query. The coordinator creates a logical model of a query involving a series of stages, which is then translated into a series of connected tasks running on a cluster of Trino workers.
Coordinators communicate with workers and clients using a REST API.
A Trino worker is a server in a Trino installation, which is responsible for executing tasks and processing data. Worker nodes fetch data from connectors and exchange intermediate data with each other. The coordinator is responsible for fetching results from the workers and returning the final results to the client.
When a Trino worker process starts up, it advertises itself to the discovery server in the coordinator, which makes it available to the Trino coordinator for task execution.
Workers communicate with other workers and Trino coordinators using a REST API.
Throughout this documentation, you’ll read terms such as connector, catalog, schema, and table. These fundamental concepts cover Trino’s model of a particular data source and are described in the following section.
A connector adapts Trino to a data source such as Hive or a relational database. You can think of a connector the same way you think of a driver for a database. It is an implementation of Trino’s SPI, which allows Trino to interact with a resource using a standard API.
Trino contains several built-in connectors: a connector for JMX, a System connector which provides access to built-in system tables, a Hive connector, and a TPCH connector designed to serve TPC-H benchmark data. Many third-party developers have contributed connectors so that Trino can access data in a variety of data sources.
Every catalog is associated with a specific connector. If you examine
a catalog configuration file, you see that each contains a
connector.name, which is used by the catalog
manager to create a connector for a given catalog. It is possible
to have more than one catalog use the same connector to access two
different instances of a similar database. For example, if you have
two Hive clusters, you can configure two catalogs in a single Trino
cluster that both use the Hive connector, allowing you to query data
from both Hive clusters, even within the same SQL query.
A Trino catalog contains schemas and references a data source via a connector. For example, you can configure a JMX catalog to provide access to JMX information via the JMX connector. When you run a SQL statement in Trino, you are running it against one or more catalogs. Other examples of catalogs include the Hive catalog to connect to a Hive data source.
When addressing a table in Trino, the fully-qualified table name is
always rooted in a catalog. For example, a fully-qualified table name
hive.test_data.test refers to the
test table in the
test_data schema in the
Catalogs are defined in properties files stored in the Trino configuration directory.
Schemas are a way to organize tables. Together, a catalog and schema define a set of tables that can be queried. When accessing Hive or a relational database such as MySQL with Trino, a schema translates to the same concept in the target database. Other types of connectors may choose to organize tables into schemas in a way that makes sense for the underlying data source.
A table is a set of unordered rows, which are organized into named columns with types. This is the same as in any relational database. The mapping from source data to tables is defined by the connector.
Query execution model#
Trino executes SQL statements and turns these statements into queries, that are executed across a distributed cluster of coordinator and workers.
Trino executes ANSI-compatible SQL statements. When the Trino documentation refers to a statement, it is referring to statements as defined in the ANSI SQL standard, which consists of clauses, expressions, and predicates.
Some readers might be curious why this section lists separate concepts for statements and queries. This is necessary because, in Trino, statements simply refer to the textual representation of a SQL statement. When a statement is executed, Trino creates a query along with a query plan that is then distributed across a series of Trino workers.
When Trino parses a statement, it converts it into a query and creates a distributed query plan, which is then realized as a series of interconnected stages running on Trino workers. When you retrieve information about a query in Trino, you receive a snapshot of every component that is involved in producing a result set in response to a statement.
The difference between a statement and a query is simple. A statement can be thought of as the SQL text that is passed to Trino, while a query refers to the configuration and components instantiated to execute that statement. A query encompasses stages, tasks, splits, connectors, and other components and data sources working in concert to produce a result.
When Trino executes a query, it does so by breaking up the execution into a hierarchy of stages. For example, if Trino needs to aggregate data from one billion rows stored in Hive, it does so by creating a root stage to aggregate the output of several other stages, all of which are designed to implement different sections of a distributed query plan.
The hierarchy of stages that comprises a query resembles a tree. Every query has a root stage, which is responsible for aggregating the output from other stages. Stages are what the coordinator uses to model a distributed query plan, but stages themselves don’t run on Trino workers.
As mentioned in the previous section, stages model a particular section of a distributed query plan, but stages themselves don’t execute on Trino workers. To understand how a stage is executed, you need to understand that a stage is implemented as a series of tasks distributed over a network of Trino workers.
Tasks are the “work horse” in the Trino architecture as a distributed query plan is deconstructed into a series of stages, which are then translated to tasks, which then act upon or process splits. A Trino task has inputs and outputs, and just as a stage can be executed in parallel by a series of tasks, a task is executing in parallel with a series of drivers.
Tasks operate on splits, which are sections of a larger data set. Stages at the lowest level of a distributed query plan retrieve data via splits from connectors, and intermediate stages at a higher level of a distributed query plan retrieve data from other stages.
When Trino is scheduling a query, the coordinator queries a connector for a list of all splits that are available for a table. The coordinator keeps track of which machines are running which tasks, and what splits are being processed by which tasks.
Tasks contain one or more parallel drivers. Drivers act upon data and combine operators to produce output that is then aggregated by a task and then delivered to another task in another stage. A driver is a sequence of operator instances, or you can think of a driver as a physical set of operators in memory. It is the lowest level of parallelism in the Trino architecture. A driver has one input and one output.
An operator consumes, transforms and produces data. For example, a table scan fetches data from a connector and produces data that can be consumed by other operators, and a filter operator consumes data and produces a subset by applying a predicate over the input data.
Exchanges transfer data between Trino nodes for different stages of a query. Tasks produce data into an output buffer and consume data from other tasks using an exchange client.