rlm-tools
An MCP server that provides a persistent sandbox for AI coding agents to explore codebases server-side, returning only compact summaries to reduce context consumption.
README
RLM Tools
Your AI coding agent spends most of its token budget just reading your code — not reasoning about it. Every grep, file read, and glob result gets dumped into the conversation. On a large codebase, that's 25-35% of your context (and cost) burned on raw data the model never needed to see.
RLM Tools gives your agent a persistent sandbox to explore code in. Data stays server-side. Only the conclusions come back.
# Install in one line (Claude Code)
claude mcp add rlm-tools -- uvx rlm-tools
# Or Codex
codex mcp add rlm-tools -- uvx rlm-tools
That's it. Your agent automatically uses the sandbox for exploration. No config, no prompting changes.
What Changes
Without RLM Tools — agent greps for import UIKit, gets 500 matches dumped into context. Reads 10 files, burns all their content as tokens. Context window fills up. Agent forgets what it was doing.
With RLM Tools — agent runs the same exploration in a server-side Python sandbox. Data stays in sandbox memory. Only the print() output enters context:
matches = grep("import UIKit")
by_module = {}
for m in matches:
module = m["file"].split("/")[0]
by_module.setdefault(module, []).append(m)
for module, ms in sorted(by_module.items(), key=lambda x: -len(x[1]))[:5]:
print(f"{module}: {len(ms)} files")
500 lines of grep results become 5 lines of summary. The agent sees what it needs, nothing more.
Real-World Impact
In typical coding workflows: 25-35% context reduction. That means your agent can explore roughly 40-50% more code before hitting context limits.
In heavy exploration tasks (reading many files, broad searches), savings go much further:
| Scenario | Standard Tools | RLM Tools | Saved |
|---|---|---|---|
| Grep across full app | 40,045 chars | 1,644 chars | 95.9% |
| Read 10 large files | 1,493,720 chars | 13,588 chars | 99.1% |
| Multi-step exploration | 136,102 chars | 5,285 chars | 96.1% |
| Grep then read matches | 340,408 chars | 6,022 chars | 98.2% |
| Find all usages of a pattern | 13,478 chars | 3,691 chars | 72.6% |
| Understand a module | 94,745 chars | 16,925 chars | 82.1% |
Full benchmark methodology and reproduction steps: docs/benchmarks.md
How It Works
Three MCP tools. That's the entire API:
| Tool | Purpose |
|---|---|
rlm_start(path, query) |
Open a session on a directory |
rlm_execute(session_id, code) |
Run Python in the sandbox |
rlm_end(session_id) |
Close session, free resources |
The sandbox provides built-in helpers:
read_file(path)/read_files(paths)— Read files into variables (cached across calls)grep(pattern)/grep_summary(pattern)/grep_read(pattern)— Searchglob_files(pattern)— Find files by patterntree(path, max_depth)— Directory structurellm_query(prompt, context)— Sub-LLM analysis (optional, requires API key)
Variables persist across rlm_execute calls within a session. The agent can build up understanding incrementally — search, filter, read, analyze — without any intermediate data touching the context window.
Works With
RLM Tools is a standard MCP server. It works with any MCP-compatible client: Claude Code, Codex, Cursor, and others.
<details> <summary><strong>Other installation methods</strong></summary>
JSON MCP config (Cursor, Windsurf, etc.)
{
"mcpServers": {
"rlm-tools": {
"command": "uvx",
"args": ["rlm-tools"]
}
}
}
Direct run
uvx rlm-tools
From source
git clone https://github.com/stefanoshea/rlm-tools.git
cd rlm-tools
uv sync
uv run rlm-tools
Then point your MCP client to command: uv, args: ["--directory", "/path/to/rlm-tools", "run", "rlm-tools"].
</details>
Configuration
Copy .env.example to .env to customize. All settings are optional — RLM Tools works out of the box with zero config.
The core exploration features (read, grep, glob, tree) require no API key. The optional llm_query() helper calls the Anthropic API for semantic analysis within the sandbox — this is the only feature that requires a key.
| Variable | Default | Description |
|---|---|---|
ANTHROPIC_API_KEY |
— | Required for llm_query() only. Uses Anthropic's API (Claude). |
RLM_SUB_MODEL |
claude-haiku-4-5-20251001 |
Claude model used for llm_query() |
RLM_MAX_SESSIONS |
5 |
Max concurrent sessions |
RLM_SESSION_TIMEOUT |
10 |
Session timeout in minutes |
Security
The sandbox is read-only and restricted:
- Imports: Safe stdlib only (re, json, collections, math, etc.)
- Builtins: Blocks exec, eval, compile,
__import__, breakpoint - File access: Read-only, scoped to session directory, path traversal blocked
- Execution: Configurable per-call timeout (default 30s)
- Rate limits: Configurable max calls per session
Background
RLM Tools implements an RLM-style exploration loop: keep raw data in tool-side memory, send only compact outputs to the model. Built on the Model Context Protocol.
Development
git clone https://github.com/stefanoshea/rlm-tools.git
cd rlm-tools
uv sync --dev
pytest tests
Run comparative benchmarks (requires a local project checkout):
RLM_EVAL_PROJECT_PATH=/path/to/project pytest evals -q -s
License
MIT
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