Reasoning Engine
An MCP server that brings difficulty-adaptive, multi-path reasoning to Claude Code. It implements the Actor-Critic-Planner-Reflexion (ACPR) pipeline for deep research synthesis.
README
Reasoning Engine
An MCP server that brings difficulty-adaptive, multi-path reasoning to Claude Code. It implements the Actor-Critic-Planner-Reflexion (ACPR) pipeline for deep research synthesis.
What It Does
You give it a research question. It decides how hard the question is, allocates compute accordingly, explores multiple reasoning paths in parallel, scores each path, self-corrects weak paths, and synthesizes the best results into a coherent report.
"What is a Process Reward Model?"
-> difficulty 0.21 -> single pass -> done in seconds
"How do PRMs interact with MCTS for test-time compute scaling?"
-> difficulty 0.71 -> forest strategy -> 8 branches, 3 reflexion rounds
Architecture
Two components work together:
Claude Code (LLM-powered orchestrator)
| spawns parallel agents for generation, critique, reflexion
| calls MCP tools for algorithmic decisions
v
Reasoning Engine MCP Server (deterministic Python backend)
- Difficulty estimation
- DORA budget allocation (explore vs exploit)
- UCB branch selection
- Dual-signal PRM scoring (Promise + Progress)
- Research angle planning and evidence-gap checks
- Tree state management (SQLite)
- Episodic memory for cross-session learning
- Content sanitization (prompt injection protection)
No API key required. Runs on your Claude Code Max subscription.
How It Works
The ACPR Pipeline
| Phase | What Happens |
|---|---|
| Initialize | Estimate difficulty, allocate budget, recall past learnings |
| Generate | Spawn parallel Actor agents, each exploring a different research angle |
| Evaluate | Critic agents score each path on Promise (will it succeed?) and Progress (is it advancing?) |
| Plan | DORA computes score variance (kappa) and decides: explore broadly or exploit the best path |
| Reflect | Low-scoring paths get textual critique injected back for self-correction |
| Loop | Repeat until budget exhausted or high-confidence result found |
| Synthesize | Top paths merged into a coherent research report |
Difficulty-Adaptive Scaling
| Difficulty | Strategy | Branches | Reflexion |
|---|---|---|---|
| 0.0 - 0.3 | Single pass | 1 | None |
| 0.3 - 0.5 | Best-of-N | 3 | 1 round |
| 0.5 - 0.7 | Beam search | 5 | 2 rounds |
| 0.7 - 1.0 | Forest | 8 | 3 rounds |
Installation
1. Clone and install
git clone https://github.com/Raoof128/reasoning-engine.git
cd reasoning-engine
python3 -m venv .venv
source .venv/bin/activate
pip install -e ".[dev]"
2. Run tests
pytest -v
3. Configure Claude Code
Add to your project's .mcp.json:
{
"mcpServers": {
"reasoning-engine": {
"command": "/path/to/reasoning-engine/.venv/bin/mcp",
"args": ["run", "/path/to/reasoning-engine/src/reasoning_engine/server.py"],
"env": {
"REASONING_ENGINE_DB": "/path/to/reasoning-engine/reasoning.db"
}
}
}
}
4. Install the skill (optional)
Copy skill/deep-research.md to ~/.claude/skills/deep-research.md for the /deep-research slash command.
Required Skills and MCP Servers
This agent works with the following Claude Code components:
Required MCP Servers
| MCP Server | Purpose | How to Get |
|---|---|---|
| reasoning-engine | Core reasoning backend (this repo) | Install from this repo |
| crawl4ai | Web crawling for live research | Built-in Claude Code MCP |
Required Skills (for full pipeline)
| Skill | Purpose | Pipeline Phase | Source |
|---|---|---|---|
| deep-research | Orchestrates the ACPR reasoning loop | Phases 1-7 | Included in this repo |
| stop-slop | Removes AI writing patterns from synthesis | Phase 8 | by Hardik Pandya |
| docx | Generates publication-quality Word documents | Phase 9 | by Anthropic |
Optional Skills
| Skill | Purpose | Source |
|---|---|---|
| theme-factory | Apply visual themes to the output document | by Anthropic |
Install the deep-research skill:
cp skill/deep-research.md ~/.claude/skills/
The stop-slop and docx skills are third-party — see their repos for installation.
MCP Tools
| Tool | Purpose |
|---|---|
init_research_session |
Create session, estimate difficulty, allocate budget |
register_branch |
Register a reasoning branch with trace and sources |
score_branch |
Record dual-signal score (Promise + Progress + critique) |
select_next_branches |
DORA allocation: explore vs exploit based on kappa |
check_termination |
Should we stop? (budget, confidence, convergence) |
consensus_candidates |
Top-K branches for final synthesis |
record_reflection_tool |
Store a Reflexion cycle's critique and revision |
recall_memory_tool |
Retrieve relevant learnings from past sessions |
save_to_memory |
Persist episodic memory for future recall |
sanitize_content |
Strip HTML, scripts, and prompt injection patterns |
get_session_state |
Full session state for debugging |
plan_research_angles_tool |
Create prioritized research angles and starter questions |
evidence_gap_questions_tool |
Generate verification questions for claims before synthesis |
Project Structure
reasoning-engine/
src/reasoning_engine/
server.py # FastMCP server wiring all tools
db.py # SQLite schema and connections
difficulty.py # Heuristic difficulty estimator
dora.py # DORA budget allocation + branch selection
ucb.py # UCB1 explore/exploit selection
sessions.py # Session and branch lifecycle management
memory.py # Episodic memory for Reflexion learnings
research.py # Research angle and evidence-gap planning
sanitizer.py # Content sanitization for web data
tests/ # 38 tests, all passing
skill/ # Claude Code skill file
Background
This project implements ideas from three research documents on AI reasoning architectures:
- Process Reward Models score individual reasoning steps (not just final answers), enabling dense feedback for tree search.
- DORA (Direction-Oriented Resource Allocation) uses score variance to dynamically switch between exploring many paths and exploiting the best one.
- Reflexion injects textual critiques back into the prompt, enabling self-correction without weight updates.
- UCB1 selection balances trying promising branches against exploring undervisited ones.
- ReAct / Self-RAG style evidence checks keep retrieval and verification explicit before synthesis.
The key insight: a Claude Code skill can orchestrate this entire pipeline using parallel agent spawning on a Max subscription, with a lightweight Python MCP server handling the deterministic math. No separate API key needed.
Documentation
Verifiable Research Engine MVP
Run a local verifiable research pipeline:
reasoning-engine research "Scholar Gateway exposes semantic search" \
--draft "Scholar Gateway exposes semantic search."
Run a Scholar Gateway search with mocked default retrieval:
reasoning-engine scholar search "MCP prompt injection" --limit 3
Live Scholar Gateway calls are opt-in:
export SCHOLAR_GATEWAY_LIVE=1
export SCHOLAR_GATEWAY_ACCESS_TOKEN="<token>"
reasoning-engine scholar search "literature synthesis evaluation" --limit 5
Tokens are read from environment or local credential mechanisms. Tokens are not stored in SQLite or run packs. MVP verification uses deterministic lexical overlap as a placeholder verifier, so it is suitable for pipeline testing and audit workflow validation rather than final semantic claim verification.
Local HTTP MCP
STDIO remains the default MCP workflow. To start a local Streamable HTTP MCP server:
reasoning-engine serve --transport http --host 127.0.0.1 --port 8765
The MCP endpoint is available at:
http://127.0.0.1:8765/mcp
Public binding is blocked unless explicitly acknowledged:
reasoning-engine serve --transport http --host 0.0.0.0 --unsafe-bind-public
For Notion AI Custom MCP testing through a Cloudflare HTTPS tunnel, use the laptop launcher:
chmod +x ./run-notion-mcp-laptop.sh
./run-notion-mcp-laptop.sh
On macOS, you can also double-click run-notion-mcp-laptop.command from
Finder to start the same launcher in Terminal.
The launcher keeps the MCP server bound to 127.0.0.1, creates a local bearer
token file at ~/.reasoning-engine/notion-http.env, starts a temporary
Cloudflare Tunnel, and prints the Notion MCP URL. See
Notion Laptop MCP Tunnel.
The project requires mcp>=1.24.0,<2, which is above the 1.23.0 safety floor
for default FastMCP DNS rebinding protection.
License
MIT
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