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MLOS Bench Python interface for benchmark automation and optimization.

Project description

mlos-bench

This directory contains the code for the mlos-bench experiment runner package.

It makes use of the mlos-core package for its optimizer.

It's available for pip install via the pypi repository at mlos-bench.

Table of Contents

Description

mlos-bench is an end-to-end benchmarking service that can be independently launched for experimentation but is also integrated with mlos-core as its optimizer for OS tuning. Given a user-provided VM configuration, mlos-bench provisions a configured environment and remotely executes benchmarks on the cloud. Experiment results (benchmark results & telemetry) are stored as input to the mlos-core optimization engine loop to evaluate proposed configuration parameters and produce new results.

Features

With a JSON5 config file and command line parameters as input, mlos-bench streamlines workload performance measurement by automating the following benchmarking steps:

  1. Set up & clean up benchmark and application configuration
    • Ease of use: Mlos-bench abstracts away controls for managing VMs in Azure, e.g., setup, teardown, stop, deprovision, and reboot. Get visibility into VM status through Azure Portal, ensuring that a VM is provisioned & running before issuing commands to it.
    • Versatility: Mlos-bench provides a common interface to control a collection of environments (application, OS, VM), regardless of where or which cloud they come from. This allows changes to easily propagate to all environment layers when a new set of kernel parameters are applied.
    • Efficiency: In adapting an environment to new parameters, mlos-bench optimizes for low re-configuration costs during optimization. For example, considering that not all OS kernel parameter adjustments require a full reboot, as some can be changed during run-time.
  2. Run benchmarks in the provisioned environment & standardize results for the optimizer
    • Through Azure File Share, access docker scripts to run benchmarks & store results as input for optimization. For example, execute Redis benchmark uploaded to the file share, running a benchmark docker container with specified parameters. The file share is mounted to VMs via remote execution, instead of ARM templates.
    • Configurable: Specify a python script in the initial config to post-process & standardize benchmark results. An example post-processing script for Redis benchmarks is included.
    • Local & remote benchmark execution: Benchmarks can be run both locally in Hyper-V and remotely on Azure. Local execution allows better accuracy, while Azure runs are required to estimate the benchmark noise and understand the VM behavior when using cloud storage.
    • Cloud agnostic: Mlos-bench can remotely execute benchmarks on other clouds, outside of Azure - e.g., controls for EC2 instances and ability to provision environments on AWS with Terraform.
    • Persistence: Storage integration is available to persist experiment parameters and track results for re-use, either for analysis during & after trials, or warm-starting future experiments.

Quickstart

To get started, we can adapt an example configuration to test out running mlos-bench. For these instructions, we will be using Azure for our resources.

1. Install and activate the conda environment

From here onwards we assume we are in the project root directory. Ensure you have a conda environment (mlos) set up for executing mlos_bench. Create and activate the environment with:

conda env create -f conda-envs/mlos.yml
conda activate mlos

Note: if you are running inside the devcontainer, this should be done automatically.

2. Make sure that you have Azure CLI tool installed and working

Installation instructions for az (Azure CLI) can be found here.

Note: az comes preinstalled inside the devcontainer.

If necessary, login to Azure and set your default subscription:

# If using az cli for the first time, a login will be required:
az login
# Make sure to set your default subscription, RG, and Storage Account for these experiments.
# For instance:
az account set --subscription "My Subscription Name"
az config set defaults.group=MyRG --local
az config set storage.account=MyStorageAccount --local
az account set --subscription "..."

3. Generate access tokens to interact with Azure resources

A script at ./scripts/generate-azure-credentials-config produces a JSON config snippet with necessary Azure credentials.

./scripts/generate-azure-credentials-config > ./global_config_azure.jsonc

This data produced in the global_config_azure.jsonc file is in the format that can be used by our framework.

{
  "subscription": "some-guid",
  "tenant": "some-other-guid",
  "storageAccountKey": "some-base-64-encoded-key",
}

Note: On Linux, this script also requires jq to also be installed (comes preinstalled in the devcontainer).

4. Create a JSON config with DB credentials (Optional)

If you plan to store the information about experiments and benchmarks in a (remote) database like PostgreSQL or MySQL, create a JSON/JSONC file with the DB hostname and password. See mysql.jsonc or postgresql.jsonc configuration files for examples with a more complete list of DB parameters supported by underlying the SqlAlchemy library. Save your config in ./global_config_storage.jsonc file. It should look like this:

{
    "host": "mysql-db.mysql.database.azure.com",
    "password": "database_password"
}

Any parameter that is not specified in ./global_config_storage.json will be taken from the corresponding DB's config file, e.g., postgresql.jsonc.

For database like SQLite or DuckDB, there is no need for an additional config file. The data will be stored locally in a file, e.g., ./mlos_bench.duckdb. See sqlite.jsonc or duckdb.jsonc for more details.

Note: if no storage is specified, a basic sqlite config will be used by default.

5. Create a top-level configuration file for your MLOS setup

We provide a few examples of such files in ./mlos_bench/config/cli/. For example, azure-redis-opt.jsonc is a configuration for optimizing Redis VM on Azure and saving the results in a local SQLite database. Likewise, azure-redis-bench.jsonc is a setup to run a single Redis benchmark (and, again, save the results in SQLite).

CLI configs like those are meant to connect several MLOS components together, namely:

They also refer to other configs, e.g.

  • Reusable config snippets in "config_path" section, and
  • Additional config files containing sensitive data like DB passwords and Azure credentials.

Make sure that the files ./global_config_azure.jsonc and ./global_config_storage.json you created in the previous steps are included in the "globals" section of your CLI config.

For the purpose of this tutorial, we will assume that we reuse the existing azure-redis-bench.jsonc and azure-redis-opt.jsonc configurations without any changes. In a more realistic scenario, however, you might need to change and/or create new config files for some parts of your benchmarking environment. We'll give more details on that below.

5. Create another config file for the parameters specific to your experiment

Copy one of our examples, e.g., experiment_RedisBench.jsonc and name it after your experiment, e.g. experiment_MyBenchmark.jsonc.

In that file, you can specify any parameters that occur in your other configs, namely in "const_args" section of the Environment configs, or in "config" sections of your Service, Storage, or Optimizer configurations.

A general rule is that the parameters from the global configs like ./global_config_azure.jsonc or experiment_MyAppBench.jsonc override the corresponding parameters in other configurations. That allows us to propagate the values of the parameters that are specific to the experiment into other components of the framework and keep the majority of the config files in our library immutable and reusable.

Importance of the Experiment ID config

An important part of this file is the value of experiment_id which controls the storage and retrieval of trial data. Should the experiment be interrupted, the experiment_id will be used to resume the experiment from the last completed trial, reloading the optimizer with data from the previously completed trial data.

As such this value should be unique for each experiment. Be sure to change it whenever "incompatible" changes are made to the experiment configuration or scripts. Unfortunately, determining what constitutes and "incompatible" change for any given system is not always possible, so mlos_bench largely leaves this up to the user.

6. Run the benchmark

Now we can run our configuration with mlos_bench:

mlos_bench --config "./mlos_bench/mlos_bench/config/cli/azure-redis-bench.jsonc" --globals "experiment_MyBenchmark.jsonc"

This should run a single trial with the given tunable values (loaded from one or more files in the "tunable_values"), write the results to the log and keep the environment running (as directed by the "teardown": false configuration parameter in the CLI config).

Note that using the --globals command line option is the same as adding experiment_MyBenchmark.jsonc to the "globals" section of the CLI config. Same applies to all other CLI parameters - e.g., you can change the log level by adding --log_level INFO to the command line.

Also, note that you don't have to provide full path to the experiment_MyBenchmark.jsonc file - the application will look for it in the paths specified in the "config_path" section of the CLI config.

Optimization

Searching for an optimal set of tunable parameters is very similar to running a single benchmark. All we have to do is specifying the Optimizer in the top-level configuration, like in our azure-redis-opt.jsonc example.

mlos_bench --config "./mlos_bench/mlos_bench/config/cli/azure-redis-opt.jsonc" --globals "experiment_MyBenchmark.jsonc" --max_suggestions 10 --trial-config-repeat-count 3

Note that again we use the command line option --max_suggestions to override the max. number of suggested configurations to trial from mlos_core_flaml.jsonc. We also use --trial-config-repeat-count to benchmark each suggested configuration 3 times. That means, we will run 30 trials in total, 3 for each of the 10 suggested configurations.

We don't have to specify the "tunable_values" for the optimization: the optimizer will suggest new values on each iteration and the framework will feed this data into the benchmarking environment.

Resuming interrupted experiments

Experiments sometimes get interrupted, e.g., due to errors in automation scripts or other failures in the system.

To resume an interrupted experiment, simply run the same command as before.

As mentioned above in the importance of the experiment_id config section, the experiment_id is used to resume interrupted experiments, reloading prior trial data for that experiment_id.

Analyzing Results

The results of the experiment are stored in the database as specified in experiment configs (see above).

After running the experiment, you can use the mlos-viz package to analyze the results in a Jupyter notebook, for instance. See the sqlite-autotuning repository for a full example.

The mlos-viz package uses the ExperimentData and TrialData mlos_bench.storage APIs to load the data from the database and visualize it.

For example:

from mlos_bench.storage import from_config
# Specify the experiment_id used for your experiment.
experiment_id = "YourExperimentId"
trial_id = 1
# Specify the path to your storage config file.
storage = from_config(config_file="storage/sqlite.jsonc")
# Access one of the experiments' data:
experiment_data = storage.experiments[experiment_id]
# Full experiment results are accessible in a data frame:
results_data_frame = experiment_data.results
# Individual trial results are accessible via the trials dictionary:
trial_data = experiment_data.trials[trial_id]
# Tunables used for the trial are accessible via the config property:
trial_config = trial_data.config

See Also: https://microsoft.github.io/MLOS for full API documentation.

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