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Filter Server

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Compares approximate filter data structures (Bloom, Counting Bloom, Cuckoo, SuRF) via MCP

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Описание

Compares approximate filter data structures (Bloom, Counting Bloom, Cuckoo, SuRF) via MCP

README

Overview

This project compares several approximate filter data structures using MCP servers and LLM tool calls.

Approximate filters reduce memory usage by storing compressed summaries instead of full keys.
Because of this trade-off, some filters may return false positives or support limited operations.

The project compares:

  • Bloom Filter
  • Counting Bloom Filter
  • Cuckoo Filter
  • SuRF (Simplified Version)

An exact hash-set server is also included as a baseline for comparison.

Implemented MCP Servers

MCP Server Data Structure Description
filter-naive Exact Set / Hash Table Exact membership baseline
filter-bloom Bloom Filter Memory-efficient approximate membership filter
filter-counting-bloom Counting Bloom Filter Bloom Filter with deletion support
filter-cuckoo Cuckoo Filter Fingerprint-based approximate filter
filter-surf Simplified SuRF Approximate prefix/range filter

Project Goal

The goal of this project is to compare how different filter structures behave under the same workload.

The comparison focuses on:

  • membership query accuracy
  • false positive rate
  • memory usage
  • query latency
  • insertion and deletion support
  • prefix and range query capability

All servers expose the same ADT-style interface through MCP tools so that they can be tested consistently.

Scenario

Search Keyword Dictionary Management

The servers simulate a keyword search system.

Examples:

  • search autocomplete
  • keyword lookup
  • blocked-word checking
  • dictionary membership testing

The same keyword dataset and queries are used across all filters to compare performance and behavior.

ADT

All MCP servers provide the following tools:

Tool Description
build(items) Build filter from dataset
insert(x) Insert a key
contains(x) Membership query
delete(x) Delete a key if supported
range_query(lo, hi) Range query
prefix_query(prefix) Prefix query
memory_usage() Return estimated memory usage
false_positive_rate() Measure false positive rate

Theoretical / Qualitative Structure Comparison

Structure False Positives Delete Support Prefix/Range Query Memory Efficiency
Exact Set No Yes Yes Low
Bloom Filter Yes No No Very High
Counting Bloom Filter Yes Yes No High
Cuckoo Filter Yes Yes No High
Simplified SuRF Yes No Yes Medium

This table describes the expected qualitative behavior of each structure. It is not a measured benchmark result.

Benchmark Results

Measured results are available in docs/benchmark_results.md.

The benchmark uses fixed synthetic workloads from src/membership_filters/benchmark.py and compares all filters with the same build items and absent-query probes. It reports estimated memory from memory_usage(), measured false positive rate from false_positive_rate(), and average local contains() latency.

Run it locally:

PYTHONPATH=src python -m membership_filters.benchmark
$env:PYTHONPATH='src'; python -m membership_filters.benchmark

Run the smoke tests:

PYTHONPATH=src python -m unittest discover -s tests
$env:PYTHONPATH='src'; python -m unittest discover -s tests

Notes

  • filter-naive is included as the exact baseline.
  • The SuRF server is a simplified educational implementation, not a full LOUDS-based production SuRF.
  • The project focuses on comparison and experimentation rather than production optimization.

Example Claude Desktop MCP Configuration

{
  "mcpServers": {
    "filter-naive": {
      "command": "python",
      "args": ["src/filter_/filter_naive_server.py"]
    },
    "filter-bloom": {
      "command": "python",
      "args": ["src/filter_/filter_bloom_server.py"]
    },
    "filter-counting-bloom": {
      "command": "python",
      "args": ["src/filter_/filter_counting_bloom_server.py"]
    },
    "filter-cuckoo": {
      "command": "python",
      "args": ["src/filter_/filter_cuckoo_server.py"]
    },
    "filter-surf": {
      "command": "python",
      "args": ["src/filter_/filter_surf_server.py"]
    }
  }
}

System Flow

Claude / LLM
        ↓
MCP Tool Call
        ↓
mcp_server.py
        ↓
registry.py
        ↓
Selected Filter Class
        ↓
Bloom / Counting Bloom / Cuckoo / SuRF / Exact Set

Flow Description

  1. The LLM sends an MCP tool request.
  2. mcp_server.py exposes the common ADT-style tools.
  3. registry.py selects the requested filter implementation.
  4. The selected filter processes the query.
  5. The result is returned back through the MCP server.

This design allows all filters to be tested through the same interface and workload.

Repository Structure

src/
├── filter_/
│   ├── filter_naive_server.py
│   ├── filter_bloom_server.py
│   ├── filter_counting_bloom_server.py
│   ├── filter_cuckoo_server.py
│   └── filter_surf_server.py
│
└── membership_filters/
    ├── base.py
    ├── hashing.py
    ├── mcp_server.py
    ├── registry.py
    └── filters/

from github.com/chohyerinn/filter-mcp-server

Установка Filter Server

У этого сервера нет опубликованного пакета — он собирается из исходников. Открой репозиторий и следуй инструкции в README.

▸ github.com/chohyerinn/filter-mcp-server

FAQ

Filter Server MCP бесплатный?

Да, Filter Server MCP бесплатный — установка в пару кликов через Unyly без оплаты.

Нужен ли API-ключ для Filter Server?

Нет, Filter Server работает без API-ключей и переменных окружения.

Filter Server — hosted или self-hosted?

Self-hosted: сервер запускается локально на твоей машине командой из раздела установки.

Как установить Filter Server в Claude Desktop, Claude Code или Cursor?

Открой Filter Server на unyly.org, выбери вкладку своего клиента (Claude Desktop, Claude Code, Cursor) и нажми Install — конфиг сгенерируется автоматически, без правки JSON.

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