LST-Bench is a framework that allows users to run benchmarks specifically designed for evaluating the performance, efficiency, and stability of Log-Structured Tables (LSTs), also commonly referred to as table formats, such as Delta Lake, Apache Hudi, and Apache Iceberg.
Install open-source Java Development Kit. As a recommendation, install OpenJDK distribution from Adoptium.
To build LST-Bench in Linux/macOS, run the following command:
./mvnw package
Or use the following command for Windows:
mvnw.cmd package
To build LST-Bench for a specific database, you can use the profile name (-P
) option.
This will include the corresponding JDBC driver in the ./target
directory.
Currently, the following profiles are supported: spark-oss
, spark-databricks
, and trino-oss
.
For example, to build LST-Bench for open-source Spark in Linux/macOS, you can run the following command:
./mvnw package -Pspark-oss
Or use the following command for Windows:
mvnw.cmd package -Pspark-oss
After building LST-Bench, if you are on Linux/macOS run launcher.sh
or open a Powershell launcher.ps1
if you are on Windows to display the usage options.
usage: ./launcher.sh -c <arg> -e <arg> -l <arg> -t <arg> -w <arg>
-c,--connections-config <arg> [required] Path to input file containing
connections config details
-e,--experiment-config <arg> [required] Path to input file containing
the experiment config details
-l,--task-library <arg> [required] Path to input file containing
the library with task templates
-t,--input-log-config <arg> [required] Path to input file containing
the telemetry gathering config details
-w,--workload <arg> [required] Path to input file containing
the workload definition
The configuration files used in LST-Bench are YAML files.
You can find their schema, which describes the expected structure and properties, here.
Additionally, you can find sample configurations that can serve as guidelines for creating your configurations here.
The LST-Bench code is organized into two modules:
-
Java Application. This module is written entirely in Java and is responsible for executing SQL workloads against a system under test using JDBC. It reads input configuration files to determine the tasks, sessions, and phases to be executed. The Java application handles the execution of SQL statements and manages the interaction with the system under test.
-
Python Processing Module. The processing module is written in Python and serves as the post-execution analysis component. It consolidates experimental results obtained from the Java application and computes metrics to provide insights into LSTs and cloud data warehouses. The Python module performs data processing, analysis, and visualization to facilitate a deeper understanding of the experimental results.
In LST-Bench, the following concepts are used to define and organize SQL workloads:
-
Task: A task is a collection of SQL statements grouped together in a sequence of files. Each file represents a step or subtask within the overall task.
-
Session: A session refers to a sequence of tasks. It represents a logical unit of work or a user session.
-
Phase: A phase consists of multiple concurrent sessions that need to be completed before proceeding to the next phase. Phases help simulate concurrent workload scenarios.
-
Workload: A workload is a sequence of phases, defining the complete set of tasks, sessions, and phases to be executed during the evaluation.
In LST-Bench, tasks are generated using task templates predefined in the task library. LST-Bench includes a default task library that encompasses tasks derived from the TPC-DS benchmark, along with workload definitions representing the original TPC-DS and multiple workload patterns. These resources can be located here.
Although LST-Bench provides this set of tasks and workload patterns, users have the flexibility to incorporate additional task templates or even create a completely new task library to model specific scenarios. This flexible model allows for the easy creation of diverse SQL workloads for evaluation purposes without the need to modify the application itself.
LST-Bench captures execution telemetry during workload execution at multiple levels, including per experiment, phase, session, task, file, and statement. Each telemetry event is recorded with an associated identifier, such as the statement's name or the phase IDs defined in the workload YAML. The event includes information on whether it succeeded or not, along with any additional associated data. Specifically, each event includes a start time, end time, event ID, event type, status, and optional payload.
The telemetry registry in LST-Bench is configurable, providing flexibility for different systems and use cases. By default, LST-Bench includes an implementation for a JDBC-based registry and supports writing telemetry to DuckDB or Spark. LST-Bench writes these telemetry events into a table within the specified systems, enabling any application to consume and gain insights from the results.
Alternatively, if the LST-Bench Metrics Processor is used, you can simply point it to the same database. The processor will then analyze and visualize the results, providing a streamlined solution for result analysis and visualization.
For more details about LST-Bench, please refer to the accompanying technical report:
@article{2023lstbench,
title={LST-Bench: Benchmarking Log-Structured Tables in the Cloud},
author={Jesús Camacho-Rodríguez and Ashvin Agrawal and Anja Gruenheid and
Ashit Gosalia and Cristian Petculescu and Josep Aguilar-Saborit and
Avrilia Floratou and Carlo Curino and Raghu Ramakrishnan},
year={2023},
journal={arXiv preprint arXiv:2305.01120},
url={https://arxiv.org/abs/2305.01120},
}
Here are some ways you can contribute to the LST-Bench project:
- Submit PRs to fix bugs or add new features.
- Review currently open PRs.
- Provide feedback and report bugs related to the software or the documentation.
- Enhance our design documents, examples, tutorials, and overall documentation.
To get started, please take a look at the issues and leave a comment if any of them interest you.
If you plan to make significant changes, we recommend discussing them with the LST-Bench community first. This helps ensure that your contributions align with the project's goals and avoids duplicating efforts.
Most contributions require you to agree to a Contributor License Agreement (CLA) declaring that you have the right to, and actually do, grant us the rights to use your contribution. For details, visit https://cla.opensource.microsoft.com.
When you submit a pull request, a CLA bot will automatically determine whether you need to provide a CLA and decorate the PR appropriately (e.g., status check, comment). Simply follow the instructions provided by the bot. You will only need to do this once across all repos using our CLA.
This project has adopted the Microsoft Open Source Code of Conduct. For more information see the Code of Conduct FAQ or contact [email protected] with any additional questions or comments.
See the LICENSE file for more details.