qdrant-memory-usage-optimization
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Esta habilidad diagnostica y reduce el uso de memoria en Qdrant analizando la memoria residente frente a la caché de páginas del sistema operativo. Ayuda cuando la RAM es alta, los nodos fallan o la memoria no coincide con los cálculos. La habilidad proporciona estrategias de optimización para escenarios como memoria residente excesiva o intentos fallidos de cuantización.
Instalación rápida
Claude Code
Recomendadonpx skills add qdrant/skills -a claude-code/plugin add https://github.com/qdrant/skillsgit clone https://github.com/qdrant/skills.git ~/.claude/skills/qdrant-memory-usage-optimizationCopia y pega este comando en Claude Code para instalar esta habilidad
Documentación
Understanding memory usage
Qdrant operates with two types of memory:
-
Resident memory (aka RSSAnon) - memory used for internal data structures like the ID tracker, plus components that must stay in RAM, such as quantized vectors when
always_ram=trueand payload indexes. -
OS page cache - memory used for caching disk reads, which can be released when needed. Original vectors are normally stored in page cache, so the service won't crash if RAM is full, but performance may degrade.
It is normal for the OS page cache to occupy all available RAM, but if resident memory is above 80% of total RAM, it is a sign of a problem.
Memory usage monitoring
- Qdrant exposes memory usage through the
/metricsendpoint. See Monitoring docs.
How much memory is needed for Qdrant?
Optimal memory usage depends on the use case.
- For regular search scenarios, general guidelines are provided in the Capacity planning docs.
For a detailed breakdown of memory usage at large scale, see Large scale memory usage example.
Payload indexes and HNSW graph also require memory, along with vectors themselves, so it's important to consider them in calculations.
Additionally, Qdrant requires some extra memory for optimizations. During optimization, optimized segments are fully loaded into RAM, so it is important to leave enough headroom.
The larger max_segment_size is, the more headroom is needed.
When to put HNSW index on disk
Putting frequently used components (such as HNSW index) on disk might cause significant performance degradation. There are some scenarios, however, when it can be a good option:
- Deployments with low latency disks - local NVMe or similar.
- Multi-tenant deployments, where only a subset of tenants is frequently accessed, so that only a fraction of data & index is loaded in RAM at a time.
- For deployments with inline storage enabled.
How to minimize memory footprint
The main challenge is to put on disk those parts of data, which are rarely accessed. Here are the main techniques to achieve that:
-
Use quantization to store only compressed vectors in RAM Quantization docs
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Use float16 or int8 datatypes to reduce memory usage of vectors by 2x or 4x respectively, with some tradeoff in precision. Read more about vector datatypes in documentation
-
Leverage Matryoshka Representation Learning (MRL) to store only small vectors in RAM while keeping large vectors on disk. Examples of how to use MRL with Qdrant Cloud inference: MRL docs
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For multi-tenant deployments with small tenants, vectors might be stored on disk because the same tenant's data is stored together Multitenancy docs
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For deployments with fast local storage and relatively low requirements for search throughput, it may be possible to store all components of vector store on disk. Read more about the performance implications of on-disk storage in the article
-
For low RAM environments, consider
async_scorerconfig, which enables support ofio_uringfor parallel disk access, which can significantly improve performance of on-disk storage. Read more aboutasync_scorerin the article (only available on Linux with kernel 5.11+) -
Consider storing Sparse Vectors and text payload on disk, as they are usually more disk-friendly than dense vectors.
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Configure payload indexes to be stored on disk docs
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Configure sparse vectors to be stored on disk docs
Repositorio GitHub
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