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serving-llms-vllm
vLLM: high-throughput LLM serving, OpenAI API, quantization.
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vLLM: high-throughput LLM serving, OpenAI API, quantization.
Install with Codex or Claude Copy this prompt, paste it into Codex, Claude, or another assistant, and let it review the skill page and install it for you.
Based on SOC occupation classification
Plan, set up, and monitor a multi-agent video production pipeline backed by Hermes Kanban. Use when the user wants to make ANY video — narrative film, product/marketing, music video, explainer, ASCII/terminal art, abstract/generative loop, comic, 3D, real-time/installation — and the work warrants decomposition into specialized profiles (writer, designer, animator, renderer, voice, editor, etc.) coordinated through a kanban board. Performs adaptive discovery to scope the brief, designs an appropriate team for the requested style, generates the setup script that creates Hermes profiles + initial kanban task, then helps monitor execution and intervene when tasks stall or fail. Routes scenes to whichever Hermes rendering / audio / design skill fits each beat (`ascii-video`, `manim-video`, `p5js`, `comfyui`, `touchdesigner-mcp`, `blender-mcp`, `pixel-art`, `baoyu-comic`, `claude-design`, `excalidraw`, `songsee`, `heartmula`, …) plus external APIs for TTS, image-gen, and image-to-video as needed.
Gym workout planner and nutrition tracker. Search 690+ exercises by muscle, equipment, or category via wger. Look up macros and calories for 380,000+ foods via USDA FoodData Central. Compute BMI, TDEE, one-rep max, macro splits, and body fat — pure Python, no pip installs. Built for anyone chasing gains, cutting weight, or just trying to eat better.
Migrate a user's OpenClaw customization footprint into Hermes Agent. Imports Hermes-compatible memories, SOUL.md, command allowlists, user skills, and selected workspace assets from ~/.openclaw, then reports exactly what could not be migrated and why.
Jailbreak LLMs: Parseltongue, GODMODE, ULTRAPLINIAN.
Join a Google Meet call, transcribe live captions, optionally speak in realtime, and do the followup work afterwards. Use when the user asks the agent to sit in on a meeting, take notes, summarize, respond in-call, or action items from it.
YouTube transcripts to summaries, threads, blogs.
| name | serving-llms-vllm |
| description | vLLM: high-throughput LLM serving, OpenAI API, quantization. |
| version | 1.0.0 |
| author | Orchestra Research |
| license | MIT |
| dependencies | ["vllm","torch","transformers"] |
| platforms | ["linux","macos"] |
| metadata | {"hermes":{"tags":["vLLM","Inference Serving","PagedAttention","Continuous Batching","High Throughput","Production","OpenAI API","Quantization","Tensor Parallelism"]}} |
Use when deploying production LLM APIs, optimizing inference latency/throughput, or serving models with limited GPU memory. Supports OpenAI-compatible endpoints, quantization (GPTQ/AWQ/FP8), and tensor parallelism.
vLLM achieves 24x higher throughput than standard transformers through PagedAttention (block-based KV cache) and continuous batching (mixing prefill/decode requests).
Installation:
pip install vllm
Basic offline inference:
from vllm import LLM, SamplingParams
llm = LLM(model="meta-llama/Llama-3-8B-Instruct")
sampling = SamplingParams(temperature=0.7, max_tokens=256)
outputs = llm.generate(["Explain quantum computing"], sampling)
print(outputs[0].outputs[0].text)
OpenAI-compatible server:
vllm serve meta-llama/Llama-3-8B-Instruct
# Query with OpenAI SDK
python -c "
from openai import OpenAI
client = OpenAI(base_url='http://localhost:8000/v1', api_key='EMPTY')
print(client.chat.completions.create(
model='meta-llama/Llama-3-8B-Instruct',
messages=[{'role': 'user', 'content': 'Hello!'}]
).choices[0].message.content)
"
Copy this checklist and track progress:
Deployment Progress:
- [ ] Step 1: Configure server settings
- [ ] Step 2: Test with limited traffic
- [ ] Step 3: Enable monitoring
- [ ] Step 4: Deploy to production
- [ ] Step 5: Verify performance metrics
Step 1: Configure server settings
Choose configuration based on your model size:
# For 7B-13B models on single GPU
vllm serve meta-llama/Llama-3-8B-Instruct \
--gpu-memory-utilization 0.9 \
--max-model-len 8192 \
--port 8000
# For 30B-70B models with tensor parallelism
vllm serve meta-llama/Llama-2-70b-hf \
--tensor-parallel-size 4 \
--gpu-memory-utilization 0.9 \
--quantization awq \
--port 8000
# For production with caching and metrics
vllm serve meta-llama/Llama-3-8B-Instruct \
--gpu-memory-utilization 0.9 \
--enable-prefix-caching \
--enable-metrics \
--metrics-port 9090 \
--port 8000 \
--host 0.0.0.0
Step 2: Test with limited traffic
Run load test before production:
# Install load testing tool
pip install locust
# Create test_load.py with sample requests
# Run: locust -f test_load.py --host http://localhost:8000
Verify TTFT (time to first token) < 500ms and throughput > 100 req/sec.
Step 3: Enable monitoring
vLLM exposes Prometheus metrics on port 9090:
curl http://localhost:9090/metrics | grep vllm
Key metrics to monitor:
vllm:time_to_first_token_seconds - Latencyvllm:num_requests_running - Active requestsvllm:gpu_cache_usage_perc - KV cache utilizationStep 4: Deploy to production
Use Docker for consistent deployment:
# Run vLLM in Docker
docker run --gpus all -p 8000:8000 \
vllm/vllm-openai:latest \
--model meta-llama/Llama-3-8B-Instruct \
--gpu-memory-utilization 0.9 \
--enable-prefix-caching
Step 5: Verify performance metrics
Check that deployment meets targets:
For processing large datasets without server overhead.
Copy this checklist:
Batch Processing:
- [ ] Step 1: Prepare input data
- [ ] Step 2: Configure LLM engine
- [ ] Step 3: Run batch inference
- [ ] Step 4: Process results
Step 1: Prepare input data
# Load prompts from file
prompts = []
with open("prompts.txt") as f:
prompts = [line.strip() for line in f]
print(f"Loaded {len(prompts)} prompts")
Step 2: Configure LLM engine
from vllm import LLM, SamplingParams
llm = LLM(
model="meta-llama/Llama-3-8B-Instruct",
tensor_parallel_size=2, # Use 2 GPUs
gpu_memory_utilization=0.9,
max_model_len=4096
)
sampling = SamplingParams(
temperature=0.7,
top_p=0.95,
max_tokens=512,
stop=["</s>", "\n\n"]
)
Step 3: Run batch inference
vLLM automatically batches requests for efficiency:
# Process all prompts in one call
outputs = llm.generate(prompts, sampling)
# vLLM handles batching internally
# No need to manually chunk prompts
Step 4: Process results
# Extract generated text
results = []
for output in outputs:
prompt = output.prompt
generated = output.outputs[0].text
results.append({
"prompt": prompt,
"generated": generated,
"tokens": len(output.outputs[0].token_ids)
})
# Save to file
import json
with open("results.jsonl", "w") as f:
for result in results:
f.write(json.dumps(result) + "\n")
print(f"Processed {len(results)} prompts")
Fit large models in limited GPU memory.
Quantization Setup:
- [ ] Step 1: Choose quantization method
- [ ] Step 2: Find or create quantized model
- [ ] Step 3: Launch with quantization flag
- [ ] Step 4: Verify accuracy
Step 1: Choose quantization method
Step 2: Find or create quantized model
Use pre-quantized models from HuggingFace:
# Search for AWQ models
# Example: TheBloke/Llama-2-70B-AWQ
Step 3: Launch with quantization flag
# Using pre-quantized model
vllm serve TheBloke/Llama-2-70B-AWQ \
--quantization awq \
--tensor-parallel-size 1 \
--gpu-memory-utilization 0.95
# Results: 70B model in ~40GB VRAM
Step 4: Verify accuracy
Test outputs match expected quality:
# Compare quantized vs non-quantized responses
# Verify task-specific performance unchanged
Use vLLM when:
Use alternatives instead:
Issue: Out of memory during model loading
Reduce memory usage:
vllm serve MODEL \
--gpu-memory-utilization 0.7 \
--max-model-len 4096
Or use quantization:
vllm serve MODEL --quantization awq
Issue: Slow first token (TTFT > 1 second)
Enable prefix caching for repeated prompts:
vllm serve MODEL --enable-prefix-caching
For long prompts, enable chunked prefill:
vllm serve MODEL --enable-chunked-prefill
Issue: Model not found error
Use --trust-remote-code for custom models:
vllm serve MODEL --trust-remote-code
Issue: Low throughput (<50 req/sec)
Increase concurrent sequences:
vllm serve MODEL --max-num-seqs 512
Check GPU utilization with nvidia-smi - should be >80%.
Issue: Inference slower than expected
Verify tensor parallelism uses power of 2 GPUs:
vllm serve MODEL --tensor-parallel-size 4 # Not 3
Enable speculative decoding for faster generation:
vllm serve MODEL --speculative-model DRAFT_MODEL
Server deployment patterns: See references/server-deployment.md for Docker, Kubernetes, and load balancing configurations.
Performance optimization: See references/optimization.md for PagedAttention tuning, continuous batching details, and benchmark results.
Quantization guide: See references/quantization.md for AWQ/GPTQ/FP8 setup, model preparation, and accuracy comparisons.
Troubleshooting: See references/troubleshooting.md for detailed error messages, debugging steps, and performance diagnostics.
Supported platforms: NVIDIA (primary), AMD ROCm, Intel GPUs, TPUs