6.1 KiB
US-018 — End-to-end two-machine LAN inference test
Goal
Run real distributed inference across two physical machines: the Linux rig and a Windows 11 rig running WSL2. Document every setup step, firewall rule, and gotcha so this is repeatable. The test script exits 0 with token output and timing, proving the network works.
Network topology for LAN test
[Linux machine] [Windows 11 / WSL2]
meshnet-tracker :8080 meshnet-node (shard B)
meshnet-node :8001 (shard A, tracker-mode)
meshnet-gateway :8000 (optional, for OpenAI-compat)
Client (either machine):
scripts/test_lan_inference.py --tracker http://192.168.1.10:8080
The Linux machine runs the tracker + the first-shard node (tracker-mode). The Windows/WSL2 machine runs the second-shard node. A small model (e.g. Phi-3-medium at BF16, fits on one GPU each) is split across both.
WSL2 setup (Windows side)
docs/INSTALL_WINDOWS.md covers:
- Enable WSL2:
wsl --install -d Ubuntu-24.04 - CUDA in WSL2: install NVIDIA driver on Windows (NOT inside WSL); WSL2 gets CUDA automatically
- Verify:
nvidia-smiinside WSL2 should show GPU
- Verify:
- Install Python 3.11+ and pip inside WSL2
pip install -e packages/node packages/p2p(clone repo first)- Firewall: Windows Defender must allow inbound WSL2 → LAN on node port
- PowerShell:
New-NetFirewallRule -DisplayName "meshnet-node" -Direction Inbound -Protocol TCP -LocalPort 8001 -Action Allow
- PowerShell:
- WSL2 IP: WSL2 has its own NAT'd IP (172.x.x.x); to expose to LAN, either:
- Option A:
netsh interface portproxy add v4tov4 listenport=8001 listenaddress=0.0.0.0 connectport=8001 connectaddress=$(wsl hostname -I) - Option B: use the relay node (US-017) — no port forwarding needed
- Option A:
Linux setup
Standard install (already done after US-016). Firewall:
# If using ufw
sudo ufw allow 8080/tcp # tracker
sudo ufw allow 8001/tcp # node
sudo ufw allow 8000/tcp # gateway (optional)
Model split
For the test, use a model that has enough layers to split meaningfully but fits comfortably in memory. Phi-3-medium-128k-instruct (40 layers, BF16 15GB) works on a single 24GB GPU on each machine:
- Linux node: layers 0–19 (tracker-mode, owns tokenizer + embed_tokens)
- Windows/WSL2 node: layers 20–39
Start sequence:
# Terminal 1 (Linux) — tracker
meshnet-tracker --port 8080
# Terminal 2 (Linux) — first-shard node (tracker-mode auto-detected because shard_start=0)
meshnet-node --model microsoft/Phi-3-medium-128k-instruct \
--quantization bf16 \
--shard-start 0 --shard-end 19 \
--tracker http://localhost:8080 \
--port 8001
# Terminal 3 (Windows WSL2) — second-shard node
meshnet-node --model microsoft/Phi-3-medium-128k-instruct \
--quantization bf16 \
--shard-start 20 --shard-end 39 \
--tracker http://192.168.1.10:8080 \
--port 8001
Test script
scripts/test_lan_inference.py:
#!/usr/bin/env python3
"""
End-to-end LAN inference test.
Usage: python scripts/test_lan_inference.py --tracker http://192.168.1.10:8080
"""
import argparse, time, httpx, json
MESSAGES = [
{"role": "user", "content": "What is 7 × 8? Answer in one word."},
{"role": "user", "content": "Name the capital of France in one word."},
{"role": "user", "content": "Complete the sequence: 1, 1, 2, 3, 5, ___"},
]
def run_test(tracker_url: str, gateway_url: str | None):
# Discover inference entry point via tracker if gateway not given
if not gateway_url:
r = httpx.get(f"{tracker_url}/v1/tracker-nodes/phi-3-medium", timeout=5)
r.raise_for_status()
nodes = r.json()
assert nodes, "No tracker-mode nodes registered — is the first-shard node running?"
gateway_url = nodes[0]["url"]
print(f"Inference endpoint: {gateway_url}")
print(f"Tracker: {tracker_url}")
print()
for i, msg in enumerate(MESSAGES):
t0 = time.monotonic()
r = httpx.post(
f"{gateway_url}/v1/chat/completions",
json={"model": "phi-3-medium", "messages": [msg], "stream": False},
timeout=60,
)
r.raise_for_status()
data = r.json()
elapsed = time.monotonic() - t0
content = data["choices"][0]["message"]["content"]
tokens = data["usage"]["completion_tokens"]
tps = tokens / elapsed if elapsed > 0 else 0
print(f"[{i+1}] Q: {msg['content']}")
print(f" A: {content}")
print(f" {tokens} tokens {elapsed:.2f}s {tps:.1f} t/s")
print()
print("✓ All 3 requests completed successfully")
if __name__ == "__main__":
p = argparse.ArgumentParser()
p.add_argument("--tracker", required=True)
p.add_argument("--gateway", default=None)
args = p.parse_args()
run_test(args.tracker, args.gateway)
Docs: TWO_MACHINE_TEST.md
docs/TWO_MACHINE_TEST.md must cover:
- Prerequisites (models downloaded on both machines, same model ID, complementary shard ranges)
- Start order: tracker first, then nodes, then test script
- How to verify nodes are registered:
GET /v1/nodeson tracker - How to verify coverage:
GET /v1/coverage/phi-3-medium— all 40 layers must show node_count ≥ 1 - How to run the test script
- Expected output
- Latency breakdown: how to read per-hop latency from node logs
- Known Issues section — updated during actual test run with real gotchas
Acceptance criteria
docs/INSTALL_WINDOWS.mdcovers WSL2 + CUDA + meshnet-node install end-to-enddocs/TWO_MACHINE_TEST.mdcovers the full two-machine setup and test procedurescripts/test_lan_inference.pyexists and is executable- When run against a real two-machine LAN setup: script exits 0, prints 3 valid answers with timing
- Coverage map shows 100% coverage (no gap) after both nodes register
- Known Issues section in TWO_MACHINE_TEST.md contains at least the issues encountered during this test run
- No new pytest failures from repo root (this story adds docs + a script, not new Python packages)
- Commit only this story's changes