install
source · Clone the upstream repo
git clone https://github.com/ComeOnOliver/skillshub
Claude Code · Install into ~/.claude/skills/
T=$(mktemp -d) && git clone --depth=1 https://github.com/ComeOnOliver/skillshub "$T" && mkdir -p ~/.claude/skills && cp -r "$T/skills/Orchestra-Research/AI-Research-SKILLs/sglang" ~/.claude/skills/comeonoliver-skillshub-sglang && rm -rf "$T"
manifest:
skills/Orchestra-Research/AI-Research-SKILLs/sglang/SKILL.mdsource content
SGLang
High-performance serving framework for LLMs and VLMs with RadixAttention for automatic prefix caching.
When to use SGLang
Use SGLang when:
- Need structured outputs (JSON, regex, grammar)
- Building agents with repeated prefixes (system prompts, tools)
- Agentic workflows with function calling
- Multi-turn conversations with shared context
- Need faster JSON decoding (3× vs standard)
Use vLLM instead when:
- Simple text generation without structure
- Don't need prefix caching
- Want mature, widely-tested production system
Use TensorRT-LLM instead when:
- Maximum single-request latency (no batching needed)
- NVIDIA-only deployment
- Need FP8/INT4 quantization on H100
Quick start
Installation
# pip install (recommended) pip install "sglang[all]" # With FlashInfer (faster, CUDA 11.8/12.1) pip install sglang[all] flashinfer -i https://flashinfer.ai/whl/cu121/torch2.4/ # From source git clone https://github.com/sgl-project/sglang.git cd sglang pip install -e "python[all]"
Launch server
# Basic server (Llama 3-8B) python -m sglang.launch_server \ --model-path meta-llama/Meta-Llama-3-8B-Instruct \ --port 30000 # With RadixAttention (automatic prefix caching) python -m sglang.launch_server \ --model-path meta-llama/Meta-Llama-3-8B-Instruct \ --port 30000 \ --enable-radix-cache # Default: enabled # Multi-GPU (tensor parallelism) python -m sglang.launch_server \ --model-path meta-llama/Meta-Llama-3-70B-Instruct \ --tp 4 \ --port 30000
Basic inference
import sglang as sgl # Set backend sgl.set_default_backend(sgl.OpenAI("http://localhost:30000/v1")) # Simple generation @sgl.function def simple_gen(s, question): s += "Q: " + question + "\n" s += "A:" + sgl.gen("answer", max_tokens=100) # Run state = simple_gen.run(question="What is the capital of France?") print(state["answer"]) # Output: "The capital of France is Paris."
Structured JSON output
import sglang as sgl @sgl.function def extract_person(s, text): s += f"Extract person information from: {text}\n" s += "Output JSON:\n" # Constrained JSON generation s += sgl.gen( "json_output", max_tokens=200, regex=r'\{"name": "[^"]+", "age": \d+, "occupation": "[^"]+"\}' ) # Run state = extract_person.run( text="John Smith is a 35-year-old software engineer." ) print(state["json_output"]) # Output: {"name": "John Smith", "age": 35, "occupation": "software engineer"}
RadixAttention (Key Innovation)
What it does: Automatically caches and reuses common prefixes across requests.
Performance:
- 5× faster for agentic workloads with shared system prompts
- 10× faster for few-shot prompting with repeated examples
- Zero configuration - works automatically
How it works:
- Builds radix tree of all processed tokens
- Automatically detects shared prefixes
- Reuses KV cache for matching prefixes
- Only computes new tokens
Example (Agent with system prompt):
Request 1: [SYSTEM_PROMPT] + "What's the weather?" → Computes full prompt (1000 tokens) Request 2: [SAME_SYSTEM_PROMPT] + "Book a flight" → Reuses system prompt KV cache (998 tokens) → Only computes 2 new tokens → 5× faster!
Structured generation patterns
JSON with schema
@sgl.function def structured_extraction(s, article): s += f"Article: {article}\n\n" s += "Extract key information as JSON:\n" # JSON schema constraint schema = { "type": "object", "properties": { "title": {"type": "string"}, "author": {"type": "string"}, "summary": {"type": "string"}, "sentiment": {"type": "string", "enum": ["positive", "negative", "neutral"]} }, "required": ["title", "author", "summary", "sentiment"] } s += sgl.gen("info", max_tokens=300, json_schema=schema) state = structured_extraction.run(article="...") print(state["info"]) # Output: Valid JSON matching schema
Regex-constrained generation
@sgl.function def extract_email(s, text): s += f"Extract email from: {text}\n" s += "Email: " # Email regex pattern s += sgl.gen( "email", max_tokens=50, regex=r'[a-zA-Z0-9._%+-]+@[a-zA-Z0-9.-]+\.[a-zA-Z]{2,}' ) state = extract_email.run(text="Contact john.doe@example.com for details") print(state["email"]) # Output: "john.doe@example.com"
Grammar-based generation
@sgl.function def generate_code(s, description): s += f"Generate Python code for: {description}\n" s += "```python\n" # EBNF grammar for Python python_grammar = """ ?start: function_def function_def: "def" NAME "(" [parameters] "):" suite parameters: parameter ("," parameter)* parameter: NAME suite: simple_stmt | NEWLINE INDENT stmt+ DEDENT """ s += sgl.gen("code", max_tokens=200, grammar=python_grammar) s += "\n```"
Agent workflows with function calling
import sglang as sgl # Define tools tools = [ { "name": "get_weather", "description": "Get weather for a location", "parameters": { "type": "object", "properties": { "location": {"type": "string"} } } }, { "name": "book_flight", "description": "Book a flight", "parameters": { "type": "object", "properties": { "from": {"type": "string"}, "to": {"type": "string"}, "date": {"type": "string"} } } } ] @sgl.function def agent_workflow(s, user_query, tools): # System prompt (cached with RadixAttention) s += "You are a helpful assistant with access to tools.\n" s += f"Available tools: {tools}\n\n" # User query s += f"User: {user_query}\n" s += "Assistant: " # Generate with function calling s += sgl.gen( "response", max_tokens=200, tools=tools, # SGLang handles tool call format stop=["User:", "\n\n"] ) # Multiple queries reuse system prompt state1 = agent_workflow.run( user_query="What's the weather in NYC?", tools=tools ) # First call: Computes full system prompt state2 = agent_workflow.run( user_query="Book a flight to LA", tools=tools ) # Second call: Reuses system prompt (5× faster)
Performance benchmarks
RadixAttention speedup
Few-shot prompting (10 examples in prompt):
- vLLM: 2.5 sec/request
- SGLang: 0.25 sec/request (10× faster)
- Throughput: 4× higher
Agent workflows (1000-token system prompt):
- vLLM: 1.8 sec/request
- SGLang: 0.35 sec/request (5× faster)
JSON decoding:
- Standard: 45 tok/s
- SGLang: 135 tok/s (3× faster)
Throughput (Llama 3-8B, A100)
| Workload | vLLM | SGLang | Speedup |
|---|---|---|---|
| Simple generation | 2500 tok/s | 2800 tok/s | 1.12× |
| Few-shot (10 examples) | 500 tok/s | 5000 tok/s | 10× |
| Agent (tool calls) | 800 tok/s | 4000 tok/s | 5× |
| JSON output | 600 tok/s | 2400 tok/s | 4× |
Multi-turn conversations
@sgl.function def multi_turn_chat(s, history, new_message): # System prompt (always cached) s += "You are a helpful AI assistant.\n\n" # Conversation history (cached as it grows) for msg in history: s += f"{msg['role']}: {msg['content']}\n" # New user message (only new part) s += f"User: {new_message}\n" s += "Assistant: " s += sgl.gen("response", max_tokens=200) # Turn 1 history = [] state = multi_turn_chat.run(history=history, new_message="Hi there!") history.append({"role": "User", "content": "Hi there!"}) history.append({"role": "Assistant", "content": state["response"]}) # Turn 2 (reuses Turn 1 KV cache) state = multi_turn_chat.run(history=history, new_message="What's 2+2?") # Only computes new message (much faster!) # Turn 3 (reuses Turn 1 + Turn 2 KV cache) state = multi_turn_chat.run(history=history, new_message="Tell me a joke") # Progressively faster as history grows
Advanced features
Speculative decoding
# Launch with draft model (2-3× faster) python -m sglang.launch_server \ --model-path meta-llama/Meta-Llama-3-70B-Instruct \ --speculative-model meta-llama/Meta-Llama-3-8B-Instruct \ --speculative-num-steps 5
Multi-modal (vision models)
@sgl.function def describe_image(s, image_path): s += sgl.image(image_path) s += "Describe this image in detail: " s += sgl.gen("description", max_tokens=200) state = describe_image.run(image_path="photo.jpg") print(state["description"])
Batching and parallel requests
# Automatic batching (continuous batching) states = sgl.run_batch( [ simple_gen.bind(question="What is AI?"), simple_gen.bind(question="What is ML?"), simple_gen.bind(question="What is DL?"), ] ) # All 3 processed in single batch (efficient)
OpenAI-compatible API
# Start server with OpenAI API python -m sglang.launch_server \ --model-path meta-llama/Meta-Llama-3-8B-Instruct \ --port 30000 # Use with OpenAI client curl http://localhost:30000/v1/chat/completions \ -H "Content-Type: application/json" \ -d '{ "model": "default", "messages": [ {"role": "system", "content": "You are helpful"}, {"role": "user", "content": "Hello"} ], "temperature": 0.7, "max_tokens": 100 }' # Works with OpenAI Python SDK from openai import OpenAI client = OpenAI(base_url="http://localhost:30000/v1", api_key="EMPTY") response = client.chat.completions.create( model="default", messages=[{"role": "user", "content": "Hello"}] )
Supported models
Text models:
- Llama 2, Llama 3, Llama 3.1, Llama 3.2
- Mistral, Mixtral
- Qwen, Qwen2, QwQ
- DeepSeek-V2, DeepSeek-V3
- Gemma, Phi-3
Vision models:
- LLaVA, LLaVA-OneVision
- Phi-3-Vision
- Qwen2-VL
100+ models from HuggingFace
Hardware support
NVIDIA: A100, H100, L4, T4 (CUDA 11.8+) AMD: MI300, MI250 (ROCm 6.0+) Intel: Xeon with GPU (coming soon) Apple: M1/M2/M3 via MPS (experimental)
References
- Structured Generation Guide - JSON schemas, regex, grammars, validation
- RadixAttention Deep Dive - How it works, optimization, benchmarks
- Production Deployment - Multi-GPU, monitoring, autoscaling
Resources
- GitHub: https://github.com/sgl-project/sglang
- Docs: https://sgl-project.github.io/
- Paper: RadixAttention (arXiv:2312.07104)
- Discord: https://discord.gg/sglang