supabase/apps/docs/content/guides/ai/going-to-prod.mdx

---
id: 'ai-going-to-prod'
title: 'Going to Production'
description: 'Checklist for going to production with your AI application.'
subtitle: 'Going to production checklist for AI applications.'
sidebar_label: 'Going to Production'
---

This guide will help you to prepare your application for production. We'll provide actionable steps to help you scale your application, ensure that it is reliable, can handle the load, and provide optimal accuracy for your use case.

See our [Engineering for Scale](/docs/guides/ai/engineering-for-scale) guide for more information about engineering at scale.

## Do you need indexes?

Sequential scans will result in significantly higher latencies and lower throughput, guaranteeing 100% accuracy and not being RAM bound.

There are a couple of cases where you might not need indexes:

- You have a small dataset and don't need to scale it.
- You are not expecting high amounts of vector search queries per second.
- You need to guarantee 100% accuracy.

You don't have to create indexes in these cases and can use sequential scans instead. This type of workload will not be RAM bound and will not require any additional resources but will result in higher latencies and lower throughput. Extra CPU cores may help to improve queries per second, but it will not help to improve latency.

On the other hand, if you need to scale your application, you will need to [create indexes](/docs/guides/ai/vector-indexes). This will result in lower latencies and higher throughput, but will require additional RAM to make use of Postgres Caching. Also, using indexes will result in lower accuracy, since you are replacing exact (KNN) search with approximate (ANN) search.

## HNSW vs IVFFlat indexes

`pgvector` supports two types of indexes: HNSW and IVFFlat. We recommend using [HNSW](/docs/guides/ai/vector-indexes/hnsw-indexes) because of its [performance](/blog/increase-performance-pgvector-hnsw#hnsw-performance-1536-dimensions) and [robustness against changing data](/docs/guides/ai/vector-indexes/hnsw-indexes#when-should-you-create-hnsw-indexes).

<Image
  alt="dbpedia embeddings comparing ivfflat and hnsw queries-per-second using the 4XL compute add-on"
  src={{
    light: '/docs/img/ai/going-prod/dbpedia-ivfflat-vs-hnsw-4xl--light.png',
    dark: '/docs/img/ai/going-prod/dbpedia-ivfflat-vs-hnsw-4xl--dark.png',
  }}
  zoomable
/>

## HNSW, understanding `ef_construction`, `ef_search`, and `m`

Index build parameters:

- `m` is the number of bi-directional links created for every new element during construction. Higher `m` is suitable for datasets with high dimensionality and/or high accuracy requirements. Reasonable values for `m` are between 2 and 100. Range 12-48 is a good starting point for most use cases (16 is the default value).

- `ef_construction` is the size of the dynamic list for the nearest neighbors (used during the construction algorithm). Higher `ef_construction` will result in better index quality and higher accuracy, but it will also increase the time required to build the index. `ef_construction` has to be at least 2 \* `m` (64 is the default value). At some point, increasing `ef_construction` does not improve the quality of the index. You can measure accuracy when `ef_search`=`ef_construction`: if accuracy is lower than 0.9, then there is room for improvement.

Search parameters:

- `ef_search` is the size of the dynamic list for the nearest neighbors (used during the search). Increasing `ef_search` will result in better accuracy, but it will also increase the time required to execute a query (40 is the default value).

<Image
  alt="dbpedia embeddings comparing hnsw queries-per-second using different build parameters"
  src={{
    light: '/docs/img/ai/going-prod/dbpedia-hnsw-build-parameters--light.png',
    dark: '/docs/img/ai/going-prod/dbpedia-hnsw-build-parameters--dark.png',
  }}
  zoomable
/>

## IVFFlat, understanding `probes` and `lists`

Indexes used for approximate vector similarity search in pgvector divides a dataset into partitions. The number of these partitions is defined by the `lists` constant. The `probes` controls how many lists are going to be searched during a query.

The values of lists and probes directly affect accuracy and queries per second (QPS).

- Higher `lists` means an index will be built slower, but you can achieve better QPS and accuracy.
- Higher `probes` means that select queries will be slower, but you can achieve better accuracy.
- `lists` and `probes` are not independent. Higher `lists` means that you will have to use higher `probes` to achieve the same accuracy.

You can find more examples of how `lists` and `probes` constants affect accuracy and QPS in [pgvector 0.4.0 performance](/blog/pgvector-performance) blogpost.

<Image
  alt="multi database"
  src={{
    light: '/docs/img/ai/going-prod/lists-count--light.png',
    dark: '/docs/img/ai/going-prod/lists-count--dark.png',
  }}
  zoomable
/>

## Performance tips when using indexes

First, a few generic tips which you can pick and choose from:

1. The Supabase managed platform will automatically optimize Postgres configs for you based on your compute add-on. But if you self-host, consider **adjusting your Postgres config** based on RAM & CPU cores. See [example optimizations](https://gist.github.com/egor-romanov/323e2847851bbd758081511785573c08) for more details.
2. Prefer `inner-product` to `L2` or `Cosine` distances if your vectors are normalized (like `text-embedding-ada-002`). If embeddings are not normalized, `Cosine` distance should give the best results with an index.
3. **Pre-warm your database.** Implement the warm-up technique before transitioning to production or running benchmarks.
   - Use [pg_prewarm](https://www.postgresql.org/docs/current/pgprewarm.html) to load the index into RAM `select pg_prewarm('vecs.docs_vec_idx');`. This will help to avoid cold cache issues.
   - Execute 10,000 to 50,000 "warm-up" queries before each benchmark/prod. This will help to utilize cache and buffers more efficiently.
4. **Establish your workload.** Fine-tune `m` and `ef_construction` or `lists` constants for the pgvector index to accelerate your queries (at the expense of a slower build times). For instance, for benchmarks with 1,000,000 OpenAI embeddings, we set `m` and `ef_construction` to 32 and 80, and it resulted in 35% higher QPS than 24 and 56 values respectively.
5. **Benchmark your own specific workloads.** Doing this during cache warm-up helps gauge the best value for the index build parameters, balancing accuracy with queries per second (QPS).

## Going into production

1. Decide if you are going to use indexes or not. You can skip the rest of this guide if you do not use indexes.
2. Over-provision RAM during preparation. You can scale down in step `5`, but it's better to start with a larger size to get the best results for RAM requirements. (We'd recommend at least 8XL if you're using Supabase.)
3. Upload your data to the database. If you use the [`vecs`](/docs/guides/ai/python/api) library, it will automatically generate an index with default parameters.
4. Run a benchmark using randomly generated queries and observe the results. Again, you can use the `vecs` library with the `ann-benchmarks` tool. Do it with default values for index build parameters, you can later adjust them to get the best results.
5. Monitor the RAM usage, and save it as a note for yourself. You would likely want to use a compute add-on in the future that has the same amount of RAM that was used at the moment (both actual RAM usage and RAM used for cache and buffers).
6. Scale down your compute add-on to the one that would have the same amount of RAM used at the moment.
7. Repeat step 3 to load the data into RAM. You should see QPS increase on subsequent runs, and stop when it no longer increases.
8. Run a benchmark using real queries and observe the results. You can use the `vecs` library for that as well with `ann-benchmarks` tool. Tweak `ef_search` for HNSW or `probes` for IVFFlat until you see that both accuracy and QPS match your requirements.
9. If you want higher QPS you can increase `m` and `ef_construction` for HNSW or `lists` for IVFFlat parameters (consider switching from IVF to HNSW). You have to rebuild the index with a higher `m` and `ef_construction` values and repeat steps 6-7 to find the best combination of `m`, `ef_construction` and `ef_search` constants to achieve the best QPS and accuracy values. Higher `m`, `ef_construction` mean that index will build slower, but you can achieve better QPS and accuracy. Higher `ef_search` mean that select queries will be slower, but you can achieve better accuracy.

## Useful links

Don't forget to check out the general [Production Checklist](/docs/guides/platform/going-into-prod) to ensure your project is secure, performant, and will remain available for your users.

You can look at our [Choosing Compute Add-on](/docs/guides/ai/choosing-compute-addon) guide to get a basic understanding of how much compute you might need for your workload.

Or take a look at our [pgvector 0.5.0 performance](/blog/increase-performance-pgvector-hnsw) and [pgvector 0.4.0 performance](/blog/pgvector-performance) blog posts to see what pgvector is capable of and how the above technique can be used to achieve the best results.

<Image
  alt="multi database"
  src={{
    light: '/docs/img/ai/going-prod/size-to-rps--light.png',
    dark: '/docs/img/ai/going-prod/size-to-rps--dark.png',
  }}
  zoomable
/>