# rag-rat
[](https://github.com/cq27-dev/rag-rat/actions/workflows/ci.yml)
[](https://codecov.io/gh/cq27-dev/rag-rat)
[](https://crates.io/crates/rag-rat)
[](https://bencher.dev/perf/rag-rat/plots)
**What a repository knows about itself.** `rag-rat` is a local repo-intelligence index and MCP server
for coding agents. It keeps source files read-only, writes only its own SQLite database, and answers
with provenance on every result — current source, the code graph, git/GitHub history, and durable,
source-anchored repo memories that persist across sessions and agents.
Every coding harness already has `grep` and file reads. rag-rat adds the layer they do not provide:
source-anchored *rationale*. It connects the code an agent is about to touch to its callers, callees,
tests, git/GitHub history, prior decisions, invariants, risks, and duplicate-code signals — and
labels every result with confidence and coverage, so an agent can judge it instead of trusting it.
```mermaid
sequenceDiagram
participant Repo as Repository
participant Engine as rag-rat engine
participant Agent as Coding agent
Repo->>Engine: Source · git/GitHub · repo memories
Engine->>Engine: Index → graph → (opt) SCIP oracle → reconcile
Agent->>Engine: where / why / who-calls / impact?
Engine-->>Agent: source + call paths + papertrail + memories (with provenance)
Agent->>Engine: record a finding
Engine->>Repo: persist a source-anchored repo memory
```
## Why
- **Provenance, not guesses.** Every result carries a confidence label, coverage warnings, and the
raw evidence — so a partial index or an ambiguous edge reads as exactly that.
- **Repo memories.** Typed, source-anchored notes (`Invariant`, `Decision`, `Risk`, …) that survive
refactors and surface automatically during future queries — the signal grep can't give you. They
are *not* assistant memory: they are versioned, local, source-anchored facts about **this**
repository that any future agent retrieves with evidence.
- **A real code graph.** tree-sitter callers/callees/imports across Rust, TypeScript/TSX, Kotlin,
C/C++, and Python — with an optional [compiler-grade SCIP oracle](docs/oracle.md) that upgrades
edges to `Compiler` confidence and ranks the load-bearing symbols.
- **History as evidence.** Git history, lazy chunk blame, and cached GitHub issue/PR/review
rationale, all queryable.
- **Rides your existing grep.** A [PreToolUse hook](docs/grep-augmentation.md) injects the memories
and symbols behind whatever you just searched for.
- **Flags clones as you write them.** A PreToolUse hook on Write/Edit/MultiEdit fingerprints the
functions you're writing and warns when they're exact or near-duplicates of code already in the
repo — so an agent reuses instead of re-implementing. Read-only, and a silent no-op when the index
isn't ready, so it never blocks a write.
## Quickstart
For Claude Code and Codex, install the plugin. It registers the MCP server, adds the skills and
hooks, and installs a version-matched `rag-rat` binary on first run:
```bash
# Claude Code
claude plugin marketplace add cq27-dev/rag-rat
claude plugin install rag-rat@rag-rat
# Codex
codex plugin marketplace add cq27-dev/rag-rat
codex plugin add rag-rat@rag-rat
```
After installing, approve the plugin so its tools and hooks run:
- **Claude Code** asks before each rag-rat MCP tool the first time it runs — choose "Yes, don't ask
again," or pre-allow them in `~/.claude/settings.json` with
`"permissions": { "allow": ["mcp__rag-rat__*"] }`.
- **Codex** shows a **"Hooks need review"** prompt on the first `codex` session started *inside the
repo* (the plugin ships grep-augmentation, clone-check, and session-digest hooks that run outside
the sandbox). Choose **"Trust all and continue"** to enable them.
Then open the repository and ask:
> Set up rag-rat in this repo.
The `init-rag-rat` skill scans the repo, explains the material choices, previews `rag-rat.toml`,
writes and indexes only after confirmation, and offers to set up the git hooks that keep the index
fresh. The MCP server starts dormant in an unconfigured repo; when setup finishes, reconnect it so it
restarts fully active against the new index.
Then put it to work — the loop rag-rat is built for is in [Try it](#try-it).
<details>
<summary><strong>Manual installation and other agents</strong></summary>
Use this path for the standalone CLI, agents without plugin support, or building from source.
### Install the CLI
The prebuilt package needs no Rust toolchain and supports Apple Silicon macOS, glibc ≥2.38 Linux
(x86-64 and arm64), Windows x64, and Android/Termux arm64:
```bash
npm install -g @rag-rat/bin
# or run it without installing:
npx @rag-rat/bin --help
```
`@rag-rat/bin` fetches the full binary from the matching GitHub release. FastEmbed's ONNX Runtime is
statically linked.
To build from source instead:
```bash
cargo install rag-rat
# or from a checkout:
cargo install --path crates/rag-rat-cli --bin rag-rat
```
The default source build needs glibc ≥2.38 and is unavailable for Intel macOS and musl/Alpine. On
those platforms, including Ubuntu 22.04, use the pure-Rust embedder:
```bash
cargo install rag-rat --no-default-features --features model2vec
```
`--no-default-features` alone produces a smaller hash-only build without real embeddings. SQLite is
bundled; see [Platform support](#platform-support) for toolchain details.
### Initialize the repository
```bash
cd /path/to/your/repo
rag-rat init
```
`init` scans the repo, guides language and embedding choices, writes `rag-rat.toml`, and builds the
initial index. Use `rag-rat init --dry-run` to preview without writing, or `--yes` for
non-interactive defaults. Configuration reference: [`docs/config.md`](docs/config.md).
### Add skills and connect MCP
Install the skills for Claude Code, Codex, Cursor, and 70+ other detected agents:
```bash
npx @rag-rat/skills
```
That installs `using-rag-rat`, `dream-review`, `init-rag-rat`, and
`configure-rag-rat-dream`. See [`skills/README.md`](skills/README.md) for per-agent flags and
`update`, `list`, and `remove`.
The MCP server uses STDIO: the client launches `rag-rat mcp` from the repository so it discovers the
correct `rag-rat.toml` and repository scope in the consolidated machine-global store.
```bash
claude mcp add --scope project rag-rat -- rag-rat mcp
codex mcp add rag-rat -- rag-rat mcp
```
Or add the equivalent project configuration:
```json
{
"mcpServers": {
"rag-rat": { "command": "rag-rat", "args": ["mcp"] }
}
}
```
`rag-rat init` prints the registration command but does not register the server itself. Pass
`rag-rat mcp --json` if the client must parse JSON; tool text defaults to [TOON](#output). Full tool
schemas: [`docs/mcp-tools.md`](docs/mcp-tools.md).
<details>
<summary>Claude Code tool permissions</summary>
Claude Code asks once before each rag-rat MCP tool first runs. Choose "Yes, don't ask again," or
allow the tool namespace in `~/.claude/settings.json`:
```json
{ "permissions": { "allow": ["mcp__rag-rat__*"] } }
```
</details>
> **Do not pin a global server to one repository's config.** A user-scoped server with
> `--config /some/repo/rag-rat.toml` serves that repository everywhere. Register MCP per project and
> let the process discover the config from its working directory.
</details>
## Try it
Once the repo is indexed, the code graph, symbols, git history, semantic search, and clone
detection are ready — these answer on the first query. Repo memories start **empty**: they accrue as
agents record findings with `memory_create` and then surface automatically in later answers. (GitHub
issue/PR rationale needs a `rag-rat github sync`.)
Ask your MCP client:
- "Run `impact_surface` on the function I'm about to edit — its callers, callees, tests, and recent
commits."
- "Where is config reload handled?" — hybrid `semantic_search` over source and docs.
- "What are the most load-bearing symbols in this repo?" — `important_symbols`.
- "Does this helper duplicate anything already in the codebase?" — `find_clones` (and the write-time
hook warns as you write it).
- "Record an invariant on `parse_config`: reload must not allocate after the scheduler starts." —
`memory_create` writes your first repo memory; it then rides along in future `impact_surface` /
`symbol_lookup` results.
Or from the CLI:
```bash
rag-rat query "where is config reload handled?"
rag-rat important-symbols --limit 20
rag-rat brief --mode spine
rag-rat clusters --limit 10
```
## The agent loop
The point isn't the tool catalog — it's the loop an agent runs *around* an edit, so it changes code
with the callers, tests, rationale, and prior art in front of it instead of guessing:
1. **Before editing a symbol, ask `impact_surface`.** One call returns the current source anchor,
callers and callees, related tests, git/GitHub rationale, the repo memories bound to that
symbol / path / call-path, and confidence + coverage warnings.
2. **Read the blast radius, then edit.** The invariant a previous agent recorded, the caller three
hops away, the test that pins the behavior — all surfaced before the change, not discovered after.
3. **The clone hook catches duplication at write time.** If the new function reimplements code that
already exists, the Write/Edit hook says so, with the existing symbol to reuse.
4. **Record what you learned.** When the edit reveals a durable invariant, decision, or footgun,
`memory_create` stores it as a source-anchored repo memory — so the next agent (or the next
session) gets it in one call instead of re-deriving it.
A trimmed `impact_surface` answer (TOON — the default output; abbreviated here) — every field is
evidence, not prose:
```text
query:
ref: "crates/config/src/config.rs::parse_config"
resolution: syntactic
direct_semantic_callers[12]:
- from_symbol: "crates/runtime/src/boot.rs::start"
edge_kind: calls_name
confidence: syntactic
callsite:
path: "crates/runtime/src/boot.rs"
line: 88
importance:
label: local structural load
score: 6.8
bucket: high
tests_touching_symbol_path[4]:
- path: "crates/config/src/config_tests.rs"
reason: test_mentions_symbol_or_path
recent_commits_touching_symbol_path[1]:
- evidence[1]: "a1b2c3d touched crates/config/src/config.rs: fix reload race during startup (#141)"
repo_memories:
direct[2]:
- kind: Invariant
title: "Config reload must not allocate after the scheduler starts"
confidence: high
anchor_status: current
binding_kind: symbol
- kind: Decision
title: "TOML over JSON5 for the config surface (#88)"
anchor_status: current
binding_kind: path
completeness_and_caveats:
exact_graph_callers: 12
memory_status:
active: 2
stale: 0
caveats[1]: "Graph evidence is tree-sitter/syntactic, not compiler-grade name resolution."
```
And the write-time clone warning an agent sees before it duplicates logic — verbatim hook output:
```text
▶ rag-rat clone check — code you're writing duplicates existing functions:
• `normalize_path_for_lookup` (line 42) is ~91% similar to crates/index/src/paths.rs::canonicalize_lookup_path
Prefer reusing the existing function(s) over duplicating — impact_surface / symbol_lookup to inspect them.
```
## The tools
rag-rat's **MCP tools** — the full catalog with JSON schemas lives in
[`docs/mcp-tools.md`](docs/mcp-tools.md). The ones you'll reach for most:
- **`impact_surface`** — the coding preflight from the loop above: callers, callees, tests, git
history, GitHub papertrail, and the repo memories crossing a symbol, in one call. Memories default
to compact, scannable headers; pass `full_memories: true` for full bodies + bindings.
- **`semantic_search`** — hybrid BM25 + vector recall over source and docs, validated against current
source. Every hit reports `retrieval_mode`; `explain=true` breaks down the score.
- **`symbol_lookup`** — exact/fuzzy symbol resolution; cfg/overload variants grouped as one logical
symbol.
- **`find_callers` / `trace_callees`** — reverse/forward call-graph traversal (low-signal std/macro
noise filtered by default).
- **`important_symbols`** — the load-bearing symbols by (SCIP-aware) PageRank, seeded from your
current diff by default; see [`docs/oracle.md`](docs/oracle.md).
- **`find_clones`** — exact + near-miss duplicate functions ranked by refactor ROI (the candidate
graph is precomputed in the background, so it scales to large repos).
- **`memory_create`** — record a source-anchored repo memory; **`dream`** surfaces the maintenance
worklist that keeps them honest ([below](#self-maintaining-memories)).
Beyond these: repo orientation (`repo_brief`, `repo_clusters`), git/GitHub rationale
(`commit_search`, `git_history_for_*`, `papertrail_for_*`, `rationale_search`), the full memory
graph (`memory_search`, `memory_edges`, `memory_rebind`, `memory_doctor`, …), graph-vs-compiler
audit (`compare_graph_to_scip`), and index diagnostics (`index_status`, `llm_status`, `heal_index`)
— all documented in [`docs/mcp-tools.md`](docs/mcp-tools.md).
## Repo memories
Repo memories are first-class local evidence — **not chat memory, not cloud personalization.** They
are versioned, local, source-anchored facts about this repository. Each is typed
(`Invariant`, `Decision`, `RejectedAlternative`, `Risk`, `BugPattern`, `PerformanceNote`, …) and
**source-anchored**: bound to a logical symbol, concrete symbol, chunk, path+span, graph edge,
call-path, commit, or GitHub ref. rag-rat tracks each anchor as `current`, `relocated`, `stale`,
`gone`, or `unverified`, and surfaces matching memories through the `memory_*` tools and inline in
`read_chunk`, `symbol_lookup`, `find_callers`, `trace_callees`, and `impact_surface`. They're how
hard-won context reaches the *next* agent in one call instead of evaporating.
Memories are also a **typed graph**, not just a flat list: `memory_edge_add` / `memory_edges` connect
them with relations (`depends_on`, `relates_to`, `supersedes`, `derived_from`, `tracks`) — a task DAG,
a mind-map link between decisions, or a task that `tracks` a GitHub issue. Full tool list:
[`docs/mcp-tools.md`](docs/mcp-tools.md#repo-memories).
## Self-maintaining memories
Memories rot: the code moves under them, an invariant gets superseded, a load-bearing function ships
with no memory at all. **`dream`** is the maintenance loop that keeps the layer honest. It recomputes
a ranked worklist of findings *about* the memories themselves — each with a stable id to review:
- **coverage gaps** — load-bearing symbols (by the same PageRank as `important_symbols`) that carry no
memory, so the next agent editing them gets nothing.
- **stale references** — a memory citing a path or anchor that no longer resolves.
`dream` runs the deterministic findings on every call. Two opt-in **model passes** go deeper, running
a small model on an ephemeral remote GPU (`[llm.dream.remote]`) only when work is pending:
`rag-rat dream --verify` recomputes each memory's verdict against current source *reality* (has the
code drifted from what the memory claims?), and `--compact` rewrites a verbose memory to a tighter
summary. Findings those passes persist surface back through `dream`.
Nothing is deleted automatically. A human — or a strong agent over MCP — burns the worklist down with
**`dream_review`** (`accept` a real gap, `dismiss` noise, `reset` a prior verdict), and verdicts
survive future runs so settled findings don't come back. It's the same surface as the CLI
`rag-rat dream` / `rag-rat dream <id> --accept|--dismiss|--reset`.
## Compiler-grade resolution & ranking
The graph is heuristic by default. The opt-in **SCIP oracle** (`rag-rat oracle run`) upgrades edges
to a `Compiler` tier from a real language tool, recovers calls tree-sitter missed, flags external
edges, and makes `important_symbols` surface the genuine god-modules. For C/C++ the `scip-clang`
oracle distinguishes declarations from definitions and sharpens call/type edges in macro-heavy or
multi-target code — the difference between usable and noisy graphs on firmware, kernels, drivers, and
SDKs. Turn on `[oracle] auto_run` and the MCP server keeps it fresh on its own (throttled,
watcher-safe). Full details: [`docs/oracle.md`](docs/oracle.md).
## Freshness
`rag-rat mcp` runs a background file watcher (on by default; `[watch] enabled = false` or
`RAG_RAT_NO_WATCH=1` to disable), so graph/symbol queries reflect uncommitted edits without a commit.
Indexed rows are git-context-aware: clean files are stored by `commit_sha`, dirty/untracked files in
a worktree overlay, so one database reuses rows across branch switches while reflecting local edits.
Optional git hooks (`rag-rat hooks install`) keep the index current on checkout/merge/rewrite/commit.
`read_chunk` and search validate hits against current source and heal stale entries before returning.
One watcher per worktree and one writer at a time are enforced with file locks (unreliable on
NFS / WSL2 `/mnt` mounts).
By default every repo's index and memories live in **one consolidated database per machine**
(`$XDG_DATA_HOME/rag-rat/rag-rat.sqlite`; override with `RAG_RAT_DATA_DIR`), so a deleted checkout or
`git clean -fdx` no longer loses your authored memories. Set an explicit `[index] database` to keep a
repo on its own file (deprecated), and run `rag-rat consolidate` to import a pre-existing
`.rag-rat/index.sqlite` into the global store — see [docs/config.md](docs/config.md#database-location-index-database).
## <a id="output"></a>Output format
The CLI and MCP results default to **TOON** (Token-Oriented Object Notation) — a token-efficient
encoding that renders uniform rows as a dense `[N]{cols}:` table (~30% smaller than compact JSON on
those payloads, never larger in practice). Pass `--json` (CLI, either position) or launch
`rag-rat mcp --json` (MCP) when a JSON parser must read the output.
## Embedding backends
The default local embedder (FastEmbed) needs no setup, but a large repo or a stronger model is worth
offloading. rag-rat speaks the **OpenAI-compatible `/v1/embeddings` API**, so a `[llm.embedding.remote]`
block can serve embeddings from **Ollama, vLLM, or michaelfeil/infinity** — one client, one place to
audit and secure. Two modes:
- **Connect** to a server you already run (set `endpoint`).
- **Ephemeral** — let the bundled cookbook provision a GPU worker (**Modal / RunPod**) just for the
backfill and tear it down afterward (set `cookbook`); pick the backend and GPU class in config.
The init flow warns when a **short-context model would truncate long code chunks** and steers you to a
long-context code embedder, and rag-rat **auto-tunes the client concurrency** against the chosen
backend so the sweep finds its throughput knee. Setup and every knob: [`docs/config.md`](docs/config.md).
## Retrieval quality
Search quality is measurable, not guesswork. rag-rat ships a **commit-replay evaluation harness**
(`rag-rat eval --replay`): each recent commit becomes a case — its message is the query, the files it
touched are the gold set — and search is scored on how well it recovers them. It reports **recall@3**
(did the right chunk land in the first three reads?), recall@10, and MRR@10, and CI tracks the trend
on [Bencher](https://bencher.dev/perf/rag-rat/plots) on `main` so a regression is caught before it
ships.
Reach for it when comparing embedding models, changing chunking, enabling int8 vector storage
(smaller on disk), or tuning a remote backend — you can prove the change didn't cost recall instead
of hoping. (`rag-rat eval` requires a `--features eval` build; it is absent from the released binary.)
## Benchmarks
The headline workload is indexing the whole Linux kernel (v7.0, ~63k C/H files, 9.14M graph edges).
Full numbers — wall-clock, throughput, peak RSS, on-disk size, unresolved-edge taxonomy — are in
[`docs/benchmarks.md`](docs/benchmarks.md). Performance is tracked per-push and gated per-PR; the live
history is at [bencher.dev/perf/rag-rat/plots](https://bencher.dev/perf/rag-rat/plots) (wiring:
[`docs/bencher.md`](docs/bencher.md)).
## Security
The MCP server exposes read-only source tools. It never executes shell commands or writes your source
files. It writes only the configured SQLite index — during indexing, migration, maintenance,
reconciliation, repo-memory operations, and automatic stale-index healing. GitHub sync is explicit
and uses `gh api`; normal query tools read only the local cache.
### Local vs remote embedding
With the **default local embedder, nothing leaves the machine** — indexing and querying are entirely
local. Configuring a `[llm.embedding.remote]` backend is what sends text off the box, in two places:
the **chunk text** selected at index time, and the **query text** of each semantic search (a search
embeds your query to compare it against the indexed vectors). A CONNECT backend embeds both against
the configured `endpoint`; an ephemeral backend embeds queries against the local `query_endpoint`.
What the endpoint *is* decides how much that matters:
- **Your own server** (self-hosted Ollama / vLLM / infinity) — the text stays in infrastructure you
control.
- **Ephemeral Modal / RunPod workers** (the cookbook path) are ephemeral *compute* providers running
*your* open-source embedder, not data services that train on inputs. Both are SOC 2 Type II, encrypt
in transit and at rest, isolate tenants, and tear the box and its storage down after the backfill —
a data-processor relationship, reasonable for proprietary code the same way a cloud VM is.
- **A third-party embedding API** you don't control is the one to actually read the terms on
(retention, training on inputs).
Sensible hygiene regardless of backend: exclude secrets, generated files, and vendor trees from the
indexed targets so they're never chunked or embedded, and keep secrets out of query text. Details:
[`docs/config.md`](docs/config.md).
## Platform support
rag-rat builds and tests on Linux, macOS, and Windows. Linux is covered on every PR and on every
push to main; macOS and Windows are exercised on release, so `cargo install rag-rat` builds and
links on all three. Android (aarch64, bionic) is also a release target — a prebuilt binary is
attached to each release and published to `@rag-rat/bin`, so `npx @rag-rat/bin` works on Termux; see
[Quickstart](#quickstart).
SQLite is bundled (compiled from source via `rusqlite`), so there's no system-library prerequisite,
but each platform needs a C toolchain: Linux ships one; on macOS install the Xcode Command Line
Tools (`xcode-select --install`); on Windows install the Visual Studio Build Tools with the C++
workload (MSVC). Requires **Rust 1.95+** (the bundled SQLite build uses the `cfg_select!` macro,
stabilized in 1.95).
A few maintenance conveniences are Unix- or Linux-only by design and degrade quietly elsewhere — no
feature of the index, query, or MCP surface is affected:
- **Hot-upgrade of a running MCP server** (the `SIGUSR1` in-place re-exec) is Unix-only. On Windows,
restart `rag-rat mcp` to pick up a new binary.
- **Fleet auto-upgrade** (signalling other running servers when a new binary lands) is Linux-only —
it walks `/proc` — and is a no-op elsewhere.
- **The grep-augmentation hook** uses a warm Unix-socket listener (with per-session dedupe) on
Linux and macOS; on Windows it falls back to a per-call read-only query straight against the
index, which works the same but without cross-call dedupe.
## Commands
```bash
rag-rat init # guided first-run setup
rag-rat index [--changed|--discover|--full]
rag-rat doctor
rag-rat query "semantic recall" # add --json for JSON
rag-rat important-symbols --limit 20
rag-rat oracle run | status # compiler-grade resolution (docs/oracle.md)
rag-rat models list | install <model>
rag-rat reconcile --changed-first --max-seconds 60 --batch-size 64
rag-rat github sync --from-refs
rag-rat memory list | show <id> | doctor | rebind <id> # inspect / re-anchor repo memories
rag-rat dream [--verify|--compact] [<id> --accept|--dismiss|--reset] # memory-maintenance worklist
rag-rat consolidate # import a legacy per-repo index into the global store
rag-rat hooks install # git maintenance hooks
rag-rat gc # prune rows for dead git contexts
rag-rat eval [--json|--update-baseline] # CI search-quality gate; requires a `--features eval` build (absent from the released binary)
rag-rat mcp # start the STDIO server
```
## Releasing & license
Releases are automated by [release-plz](https://release-plz.dev) (the three crates ship in lockstep;
see [`docs/releasing.md`](docs/releasing.md)). `rag-rat` is MIT-licensed — see [LICENSE](LICENSE).
## Prior art
rag-rat's clone-detection design is inspired by SourcererCC's scalable token-bag candidate
generation, NiCad's normalized near-miss clone-detection framing, GumTree's move-aware AST
differencing, and anti-unification / least-general generalization for template extraction. Planned
fragment-level mining and copy-paste bug heuristics are inspired by CP-Miner.