Architecture
This page covers everything you need to know about how queries are computed in Pinot's distributed systems architecture.
Last updated
This page covers everything you need to know about how queries are computed in Pinot's distributed systems architecture.
Last updated
This page will introduce you to the guiding principles behind the design of Apache Pinot. Here you will learn the distributed systems architecture that allows Pinot to scale the performance of queries linearly based on the number of nodes in a cluster. You'll also be introduced to the two different types of tables used to ingest and query data in offline (batch) or real-time (stream) mode.
It's recommended that you read Basic Concepts to better understand the terms used in this guide.
Pinot was designed by engineers at LinkedIn and Uber to scale query performance based on the number of nodes in a cluster. As you add more nodes, query performance will always improve based on the expected query volume per second quota. To achieve horizontal scalability to an unbounded number of nodes and data storage, without performance degradation, the following guiding design principles were established.
Highly available: Pinot is built to serve low latency analytical queries for customer facing applications. By design, there is no single point of failure in Pinot. The system continues to serve queries when a node goes down.
Horizontally scalable: Ability to scale by adding new nodes as a workload changes.
Latency vs Storage: Pinot is built to provide low latency even at high-throughput. Features such as segment assignment strategy, routing strategy, star-tree indexing were developed to achieve this.
Immutable data: Pinot assumes that all data stored is immutable. For GDPR compliance, we provide an add-on solution for purging data while maintaining performance guarantees.
Dynamic configuration changes: Operations such as adding new tables, expanding a cluster, ingesting data, modifying indexing config, and re-balancing must be performed without impacting query availability or performance.
As described in the concepts, Pinot has multiple distributed system components: Controller, Broker, Server, and Minion.
Pinot uses Apache Helix for cluster management. Helix is embedded as an agent within the different components and uses Apache Zookeeper for coordination and maintaining the overall cluster state and health.
All Pinot servers and brokers are managed by Helix. Helix is a generic cluster management framework to manage partitions and replicas in a distributed system. It's helpful to think of Helix as an event-driven discovery service with push and pull notifications that drives the state of a cluster to an ideal configuration. A finite-state machine maintains a contract of stateful operations that drives the health of the cluster towards its optimal configuration. Query load is optimized as Helix updates routing configurations between nodes based on where data is stored in the cluster.
Helix divides nodes into three logical components based on their responsibilities:
Participant: These are the nodes in the cluster that actually host the distributed storage resources.
Spectator: These nodes observe the current state of each participant and routes requests accordingly. Routers, for example, need to know the instance on which a partition is hosted and its state in order to route the request to the appropriate endpoint. Routing is continually being changed to optimize cluster performance as storage primitives are added and changed.
Controller: The controller observes and manages the state of participant nodes. The controller is responsible for coordinating all state transitions in the cluster and ensures that state constraints are satisfied while maintaining cluster stability.
Helix uses Zookeeper to maintain cluster state. Each component in a Pinot cluster takes a Zookeeper address as a startup parameter. The various components that are distributed in a Pinot cluster will watch Zookeeper notifications and issue updates via its embedded Helix-defined agent.
Component | Helix Mapping |
Segment | Modeled as a Helix Partition. Each segment can have multiple copies referred to as Replicas. |
Table | Modeled as a Helix Resource. Multiple segments are grouped into a table. All segments belonging to a Pinot Table have the same schema. |
Controller | Embeds the Helix agent that drives the overall state of the cluster. |
Server | |
Broker | Broker is modeled as a Helix Spectator that observes the cluster for changes in the state of segments and servers. In order to support multi-tenancy, brokers are also modeled as Helix Participants. |
Minion | Pinot Minion is modeled as a Helix Participant. |
Helix agents use Zookeeper to store and update configurations, as well as for distributed coordination. Zookeeper stores the following information about the cluster:
Resource | Stored Properties |
Controller |
|
Servers/Brokers |
|
Tables |
|
Segment |
|
Knowing the ZNode
layout structure in Zookeeper for Helix agents in a cluster is useful for operations and/or troubleshooting cluster state and health.
Pinot's controller acts as the driver of the cluster's overall state and health. Because of its role as a Helix participant and spectator, which drives the state of other components, it is the first component that is typically started after Zookeeper. Two parameters are required for starting a controller: Zookeeper address and cluster name. The controller will automatically create a cluster via Helix if it does not yet exist.
To achieve fault tolerance, one can start multiple controllers (typically three) and one of them will act as a leader. If the leader crashes or dies, another leader is automatically elected. Leader election is achieved using Apache Helix. Having at-least one controller is required to perform any DDL equivalent operation on the cluster, such as adding a table or a segment.
The controller does not interfere with query execution. Query execution is not impacted even when all controllers nodes are offline. If all controller nodes are offline, the state of the cluster will stay as it was when the last leader went down. When a new leader comes online, a cluster resumes re-balancing activity and can accept new tables or segments.
The controller provides a REST interface to perform CRUD operations on all logical storage resources (servers, brokers, tables, and segments).
See Pinot Data Explorer for more information on the web-based admin tool.
The responsibility of the broker is to route a given query to an appropriate server instance. A broker will collect and merge the responses from all servers into a final result and send it back to the requesting client. The broker provides HTTP endpoints that accept SQL queries and returns the response in JSON format.
Brokers need three key things to start.
Cluster name
Zookeeper address
Broker instance name
At the start, a broker registers as a Helix Participant and awaits notifications from other Helix agents. These notifications will be handled for table creation, a new segment being loaded, or a server starting up/or going down, in addition to any configuration changes.
Service Discovery/Routing Table
Irrespective of the kind of notification, the key responsibility of a broker is to maintain the query routing table. The query routing table is simply a mapping between segments and the servers that a segment resides on. Typically, a segment resides on more than one server. The broker computes multiple routing tables depending on the configured routing strategy for a table. The default strategy is to balance the query load across all available servers.
There are advanced routing strategies available such as ReplicaAware routing, partition-based routing, and minimal server selection routing. These strategies are meant for special or generic cases that are meant to serve very high throughput queries.
Query processing
For every query, a cluster's broker performs the following:
Fetches the routes that are computed for a query based on the routing strategy defined in a table's configuration.
Computes the list of segments to query from on each server.
Scatter-Gather: sends the requests to each server and gathers the responses.
Merge: merges the query results returned from each server.
Sends the query result to the client.
Fault tolerance
Broker instances scale horizontally without an upper bound. In a majority of cases, only three brokers are required. If most query results that are returned to a client are <1MB in size per query, one can run a broker and servers inside the same instance container. This lowers the overall footprint of a cluster deployment for use cases that do not need to guarantee a strict SLA on query performance in production.
Servers host segments and do most of the heavy lifting during query processing. Though the architecture shows that there are two kinds of servers, real-time and offline, a server does not really know if it's going to be a real-time server or an offline server. The responsibility of a server depends on the table assignment strategy.
In theory, a server can host both real-time segments and offline segments. However, in practice, we use different types of machine SKUs for real-time servers and offline servers. The advantage of separating real-time servers and offline servers is to allow each to scale independently.
Offline servers
Offline servers typically host segments that are immutable. In this case, segments are created outside of a cluster and uploaded via a shell-based curl request. Based on the replication factor and the segment assignment strategy, the controller picks one or more servers to host the segment. Servers are notified via Helix about the new segments. Servers fetch the segments from deep store and load them before being ready to serve query requests. At this point, the cluster's broker detects that new segments are available and starts including them in query responses.
Real-time servers
Real-time servers are different from the offline servers. Real-time server nodes ingest data from streaming sources, such as Kafka, and generate the indexed segments in-memory (flushing segments to disk periodically). In memory segments are also known as consuming segments. These consuming segments get flushed periodically based on completion threshold (based on number of rows, time or segment size). At this point, they are known as completed segments. Completed segments are similar to the offline server's segments. Queries go over the in-flight (consuming) segments and the completed segments.
Minion is an optional component and is not required to get started with Pinot. Minion is used for purging data from a Pinot cluster (for reasons such as GDPR compliance in the UK).
Within Pinot, a logical table is modeled as one of two types of physical tables: offline or real-time. The reason for having two types of tables is because each one follows a different state model.
A real-time and offline table provide different configuration options for indexing and, in the case of real-time, the connector properties for the stream data source (i.e. Kafka). Table types also allow users to use different containers for real-time and offline server nodes. For instance, offline servers might use virtual machines with larger storage capacity where real-time servers might need higher system memory and/or more CPU cores.
The two types of tables also scale differently.
Real-time tables have a smaller retention period and scales query performance based on the ingestion rate.
Offline tables have larger retention and scales performance based on the size of stored data.
There are a few things to keep in mind when configuring the different types of tables for your workloads. When ingesting data from the same source, you can have two tables that ingest the same data that are configured differently for real-time and offline queries. Even though the two tables have the same data, performance will scale differently for queries based on your requirements. In this scenario, real-time and offline tables must share the same schema.
Tables for real-time and offline can be configured differently depending on usage requirements. For example, you can choose to enable star-tree indexing for an offline table, while the real-time table with the same schema may not need it.
In batch mode, data is ingested into Pinot via an ingestion job. An ingestion job transforms a raw data source (such as a CSV file) into segments. Once segments are generated for the imported data, an ingestion job stores them into the cluster's segment store (a.k.a deep store) and notifies the controller. The notification is processed and the result is that the Helix agent on the controller updates the ideal state configuration in Zookeeper. Helix will then notify the offline server that there are new segments available. In response to the notification from the controller, the offline server downloads the newly created segments directly from the cluster's segment store. The cluster's broker, which watches for state changes in Helix, detects the new segments and adds them to the list of segments to query (segment-to-server routing table).
At table creation, a controller creates a new entry in Zookeeper for the consuming segment. Helix notices the new segment and notifies the real-time server, which starts consuming data from the streaming source. The broker, which watches for changes, detects the new segments and adds them to the list of segments to query (segment-to-server routing table).
Whenever the segment is complete (i.e. full), the real-time server notifies the Controller, which checks with all replicas and picks a winner to commit the segment to. The winner commits the segment and uploads it to the cluster's segment store, updating the state of the segment from "consuming" to "online". The controller then prepares a new segment in a "consuming" state.
Queries are received by brokers—which checks the request against the segment-to-server routing table—scattering the request between real-time and offline servers.
The two tables then process the request by filtering and aggregating the queried data, which is then returned back to the broker. Finally, the broker gathers together all of the pieces of the query response and responds back to the client with the result.