--- layout: default title: Concepts nav_order: 3 parent: User guide --- # Concepts Before using OpenSearch Benchmark, familiarize yourself with the following concepts. ## Core concepts and definitions - **Workload**: The description of one or more benchmarking scenarios that use a specific document corpus to perform a benchmark against your cluster. The document corpus contains any indexes, data files, and operations invoked when the workflow runs. You can list the available workloads by using `opensearch-benchmark list workloads` or view any included workloads in the [OpenSearch Benchmark Workloads repository](https://github.com/opensearch-project/opensearch-benchmark-workloads/). For more information about the elements of a workload, see [Anatomy of a workload](#anatomy-of-a-workload). For information about building a custom workload, see [Creating custom workloads]({{site.url}}{{site.baseurl}}/benchmark/creating-custom-workloads/). - **Pipeline**: A series of steps occurring before and after a workload is run that determines benchmark results. OpenSearch Benchmark supports three pipelines: - `from-sources`: Builds and provisions OpenSearch, runs a benchmark, and then publishes the results. - `from-distribution`: Downloads an OpenSearch distribution, provisions it, runs a benchmark, and then publishes the results. - `benchmark-only`: The default pipeline. Assumes an already running OpenSearch instance, runs a benchmark on that instance, and then publishes the results. - **Test**: A single invocation of the OpenSearch Benchmark binary. A workload is a specification of one or more benchmarking scenarios. A workload typically includes the following: - One or more data streams that are ingested into indexes. - A set of queries and operations that are invoked as part of the benchmark. ## Throughput and latency At the end of each test, OpenSearch Benchmark produces a table that summarizes the following: - [Service time](#service-time) - Throughput - [Latency](#latency) - The error rate for each completed task or OpenSearch operation. While the definition for _throughput_ remains consistent with other client-server systems, the definitions for `service time` and `latency` differ from most client-server systems in the context of OpenSearch Benchmark. The following table compares the OpenSearch Benchmark definition of service time and latency versus the common definitions for a client-server system. | Metric | Common definition | **OpenSearch Benchmark definition** | | :--- | :--- |:--- | | **Throughput** | The number of operations completed in a given period of time. | The number of operations completed in a given period of time. | | **Service time** | The amount of time that the server takes to process a request, from the point it receives the request to the point the response is returned.

It includes the time spent waiting in server-side queues but _excludes_ network latency, load balancer overhead, and deserialization/serialization. | The amount of time that it takes for `opensearch-py` to send a request and receive a response from the OpenSearch cluster.

It includes the amount of time that it takes for the server to process a request and also _includes_ network latency, load balancer overhead, and deserialization/serialization. | | **Latency** | The total amount of time, including the service time and the amount of time that the request waited before responding. | Based on the `target-throughput` set by the user, the total amount of time that the request waited before receiving the response, in addition to any other delays that occured before the request is sent. | For more information about service time and latency in OpenSearch Benchmark, see the [Service time](#service-time) and [Latency](#latency) sections. ### Service time OpenSearch Benchmark does not have insight into how long OpenSearch takes to process a request, apart from extracting the `took` time for the request. In OpenSearch, **service time** tracks the amount of time between when OpenSearch issues a request and receives a response. OpenSearch Benchmark makes function calls to `opensearch-py` to communicate with an OpenSearch cluster. OpenSearch Benchmark tracks the amount of time between when the `opensearch-py` client sends a request and receives a response from the OpenSearch cluster and considers this to be the service time. Unlike the traditional definition of service time, the OpenSearch Benchmark definition of service time includes overhead, such as network latency, load balancer overhead, or deserialization/serialization. The following image highlights the differences between the traditional definition of service time and the OpenSearch Benchmark definition of service time. ### Latency Target throughput is key to understanding the OpenSearch Benchmark definition of **latency**. Target throughput is the rate at which OpenSearch Benchmark issues requests, assuming that responses will be returned instantaneously. `target-throughput` is one of the common workload parameters that can be set for each test and is measured in operations per second. OpenSearch Benchmark always issues one request at a time for a single client thread, specified as `search-clients` in the workload parameters. If `target-throughput` is set to `0`, OpenSearch Benchmark issues a request immediately after it receives the response from the previous request. If the `target-throughput` is not set to `0`, OpenSearch Benchmark issues the next request to match the `target-throughput`, assuming that responses are returned instantaneously. #### Example A The following diagrams illustrate how latency is calculated with an expected request response time of 200ms and the following settings: - `search-clients` is set to `1`. - `target-throughput` is set to `1` operation per second. When a request takes longer than 200ms, such as when a request takes 1110ms instead of 400ms, OpenSearch Benchmark sends the next request that was supposed to occur at 4.00s based on the `target-throughput` at 4.10s. All subsequent requests after the 4.10s request attempt to resynchronize with the `target-throughput` setting. When measuring the overall latency, OpenSearch Benchmark includes all performed requests. All requests have a latency of 200ms, except for the following two requests: - The request that lasted 1100ms. - The subsquent request that was supposed to start at 4:00s. This request was delayed by 100ms, denoted by the orange area in the following diagram, and had a response time of 200ms. When calculating the latency for this request, OpenSearch Benchmark will account for the delayed start time and combine it with the response time. Thus, the latency for this request is **300ms**. #### Example B In this example, OpenSearch Benchmark assumes a latency of 200ms and uses the following latency settings: - `search_clients` is set to `1`. - `target-throughput` is set to `10` operations per second. The following diagram shows the schedule built by OpenSearch Benchmark with the expected response times. However, if the assumption is that all responses will take 200ms, 10 operations per second won't be possible. Therefore, the highest throughput OpenSearch Benchmark can reach is 5 operations per second, as shown in the following diagram. OpenSearch Benchmark does not account for this and continues to try to achieve the `target-throughput` of 10 operations per second. Because of this, delays for each request begin to cascade, as illustrated in the following diagram. Combining the service time with the delay for each operation provides the following latency measurements for each operation: - 200 ms for operation 1 - 300 ms for operation 2 - 400 ms for operation 3 - 500 ms for operation 4 - 600 ms for operation 5 This latency cascade continues, increasing latency by 100ms for each subsequent request. ### Recommendation As shown by the preceding examples, you should be aware of the average service time of each task and provide a `target-throughput` that accounts for the service time. The OpenSearch Benchmark latency is calculated based on the `target-throughput` set by the user. In other words, the OpenSearch Benchmark latency could be redefined as "throughput-based latency". ## Anatomy of a workload The following example workload shows all of the essential elements needed to create a `workload.json` file. You can run this workload in your own benchmark configuration to understand how all of the elements work together: ```json { "description": "Tutorial benchmark for OpenSearch Benchmark", "indices": [ { "name": "movies", "body": "index.json" } ], "corpora": [ { "name": "movies", "documents": [ { "source-file": "movies-documents.json", "document-count": 11658903, # Fetch document count from command line "uncompressed-bytes": 1544799789 # Fetch uncompressed bytes from command line } ] } ], "schedule": [ { "operation": { "operation-type": "create-index" } }, { "operation": { "operation-type": "cluster-health", "request-params": { "wait_for_status": "green" }, "retry-until-success": true } }, { "operation": { "operation-type": "bulk", "bulk-size": 5000 }, "warmup-time-period": 120, "clients": 8 }, { "operation": { "name": "query-match-all", "operation-type": "search", "body": { "query": { "match_all": {} } } }, "iterations": 1000, "target-throughput": 100 } ] } ``` A workload usually includes the following elements: - [indices]({{site.url}}{{site.baseurl}}/benchmark/workloads/indices/): Defines the relevant indexes and index templates used for the workload. - [corpora]({{site.url}}{{site.baseurl}}/benchmark/workloads/corpora/): Defines all document corpora used for the workload. - `schedule`: Defines operations and the order in which the operations run inline. Alternatively, you can use `operations` to group operations and the `test_procedures` parameter to specify the order of operations. - `operations`: **Optional**. Describes which operations are available for the workload and how they are parameterized. ### Indices To create an index, specify its `name`. To add definitions to your index, use the `body` option and point it to the JSON file containing the index definitions. For more information, see [indices]({{site.url}}{{site.baseurl}}/benchmark/workloads/indices/). ### Corpora The `corpora` element requires the name of the index containing the document corpus, for example, `movies`, and a list of parameters that define the document corpora. This list includes the following parameters: - `source-file`: The file name that contains the workload's corresponding documents. When using OpenSearch Benchmark locally, documents are contained in a JSON file. When providing a `base_url`, use a compressed file format: `.zip`, `.bz2`, `.gz`, `.tar`, `.tar.gz`, `.tgz`, or `.tar.bz2`. The compressed file must have one JSON file containing the name. - `document-count`: The number of documents in the `source-file`, which determines which client indexes correlate to which parts of the document corpus. Each N client receives an Nth of the document corpus. When using a source that contains a document with a parent-child relationship, specify the number of parent documents. - `uncompressed-bytes`: The size, in bytes, of the source file after decompression, indicating how much disk space the decompressed source file needs. - `compressed-bytes`: The size, in bytes, of the source file before decompression. This can help you assess the amount of time needed for the cluster to ingest documents. ### Operations The `operations` element lists the OpenSearch API operations performed by the workload. For example, you can set an operation to `create-index`, an index in the test cluster to which OpenSearch Benchmark can write documents. Operations are usually listed inside of `schedule`. ### Schedule The `schedule` element contains a list of actions and operations that are run by the workload. Operations run according to the order in which they appear in the `schedule`. The following example illustrates a `schedule` with multiple operations, each defined by its `operation-type`: ```json "schedule": [ { "operation": { "operation-type": "create-index" } }, { "operation": { "operation-type": "cluster-health", "request-params": { "wait_for_status": "green" }, "retry-until-success": true } }, { "operation": { "operation-type": "bulk", "bulk-size": 5000 }, "warmup-time-period": 120, "clients": 8 }, { "operation": { "name": "query-match-all", "operation-type": "search", "body": { "query": { "match_all": {} } } }, "iterations": 1000, "target-throughput": 100 } ] } ``` According to this schedule, the actions will run in the following order: 1. The `create-index` operation creates an index. The index remains empty until the `bulk` operation adds documents with benchmarked data. 2. The `cluster-health` operation assesses the health of the cluster before running the workload. In this example, the workload waits until the status of the cluster's health is `green`. - The `bulk` operation runs the `bulk` API to index `5000` documents simultaneously. - Before benchmarking, the workload waits until the specified `warmup-time-period` passes. In this example, the warmup period is `120` seconds. 5. The `clients` field defines the number of clients that will run the remaining actions in the schedule concurrently. 6. The `search` runs a `match_all` query to match all documents after they have been indexed by the `bulk` API using the 8 clients specified. - The `iterations` field indicates the number of times each client runs the `search` operation. The report generated by the benchmark automatically adjusts the percentile numbers based on this number. To generate a precise percentile, the benchmark needs to run at least 1,000 iterations. - Lastly, the `target-throughput` field defines the number of requests per second each client performs, which, when set, can help reduce the latency of the benchmark. For example, a `target-throughput` of 100 requests divided by 8 clients means that each client will issue 12 requests per second.