gptq▌
davila7/claude-code-templates · updated Apr 8, 2026
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Post-training quantization method that compresses LLMs to 4-bit with minimal accuracy loss using group-wise quantization.
GPTQ (Generative Pre-trained Transformer Quantization)
Post-training quantization method that compresses LLMs to 4-bit with minimal accuracy loss using group-wise quantization.
When to use GPTQ
Use GPTQ when:
- Need to fit large models (70B+) on limited GPU memory
- Want 4× memory reduction with <2% accuracy loss
- Deploying on consumer GPUs (RTX 4090, 3090)
- Need faster inference (3-4× speedup vs FP16)
Use AWQ instead when:
- Need slightly better accuracy (<1% loss)
- Have newer GPUs (Ampere, Ada)
- Want Marlin kernel support (2× faster on some GPUs)
Use bitsandbytes instead when:
- Need simple integration with transformers
- Want 8-bit quantization (less compression, better quality)
- Don't need pre-quantized model files
Quick start
Installation
# Install AutoGPTQ
pip install auto-gptq
# With Triton (Linux only, faster)
pip install auto-gptq[triton]
# With CUDA extensions (faster)
pip install auto-gptq --no-build-isolation
# Full installation
pip install auto-gptq transformers accelerate
Load pre-quantized model
from transformers import AutoTokenizer
from auto_gptq import AutoGPTQForCausalLM
# Load quantized model from HuggingFace
model_name = "TheBloke/Llama-2-7B-Chat-GPTQ"
model = AutoGPTQForCausalLM.from_quantized(
model_name,
device="cuda:0",
use_triton=False # Set True on Linux for speed
)
tokenizer = AutoTokenizer.from_pretrained(model_name)
# Generate
prompt = "Explain quantum computing"
inputs = tokenizer(prompt, return_tensors="pt").to("cuda:0")
outputs = model.generate(**inputs, max_new_tokens=200)
print(tokenizer.decode(outputs[0]))
Quantize your own model
from transformers import AutoTokenizer
from auto_gptq import AutoGPTQForCausalLM, BaseQuantizeConfig
from datasets import load_dataset
# Load model
model_name = "meta-llama/Llama-2-7b-chat-hf"
tokenizer = AutoTokenizer.from_pretrained(model_name)
# Quantization config
quantize_config = BaseQuantizeConfig(
bits=4, # 4-bit quantization
group_size=128, # Group size (recommended: 128)
desc_act=False, # Activation order (False for CUDA kernel)
damp_percent=0.01 # Dampening factor
)
# Load model for quantization
model = AutoGPTQForCausalLM.from_pretrained(
model_name,
quantize_config=quantize_config
)
# Prepare calibration data
dataset = load_dataset("c4", split="train", streaming=True)
calibration_data = [
tokenizer(example["text"])["input_ids"][:512]
for example in dataset.take(128)
]
# Quantize
model.quantize(calibration_data)
# Save quantized model
model.save_quantized("llama-2-7b-gptq")
tokenizer.save_pretrained("llama-2-7b-gptq")
# Push to HuggingFace
model.push_to_hub("username/llama-2-7b-gptq")
Group-wise quantization
How GPTQ works:
- Group weights: Divide each weight matrix into groups (typically 128 elements)
- Quantize per-group: Each group has its own scale/zero-point
- Minimize error: Uses Hessian information to minimize quantization error
- Result: 4-bit weights with near-FP16 accuracy
Group size trade-off:
| Group Size | Model Size | Accuracy | Speed | Recommendation |
|---|---|---|---|---|
| -1 (per-column) | Smallest | Best | Slowest | Research only |
| 32 | Smaller | Better | Slower | High accuracy needed |
| 128 | Medium | Good | Fast | Recommended default |
| 256 | Larger | Lower | Faster | Speed critical |
| 1024 | Largest | Lowest | Fastest | Not recommended |
Example:
Weight matrix: [1024, 4096] = 4.2M elements
Group size = 128:
- Groups: 4.2M / 128 = 32,768 groups
- Each group: own 4-bit scale + zero-point
- Result: Better granularity → better accuracy
Quantization configurations
Standard 4-bit (recommended)
from auto_gptq import BaseQuantizeConfig
config = BaseQuantizeConfig(
bits=4, # 4-bit quantization
group_size=128, # Standard group size
desc_act=False, # Faster CUDA kernel
damp_percent=0.01 # Dampening factor
)
Performance:
- Memory: 4× reduction (70B model: 140GB → 35GB)
- Accuracy: ~1.5% perplexity increase
- Speed: 3-4× faster than FP16
High accuracy (3-bit with larger groups)
config = BaseQuantizeConfig(
bits=3, # 3-bit (more compression)
group_size=128, # Keep standard group size
desc_act=True, # Better accuracy (slower)
damp_percent=0.01
)
Trade-off:
- Memory: 5× reduction
- Accuracy: ~3% perplexity increase
- Speed: 5× faster (but less accurate)
Maximum accuracy (4-bit with small groups)
config = BaseQuantizeConfig(
bits=4,
group_size=32, # Smaller groups (better accuracy)
desc_act=True, # Activation reordering
damp_percent=0.005 # Lower dampening
)
Trade-off:
- Memory: 3.5× reduction (slightly larger)
- Accuracy: ~0.8% perplexity increase (best)
- Speed: 2-3× faster (kernel overhead)
Kernel backends
ExLlamaV2 (default, fastest)
model = AutoGPTQForCausalLM.from_quantized(
model_name,
device="cuda:0",
use_exllama=True, # Use ExLlamaV2
exllama_config={"version": 2}
)
Performance: 1.5-2× faster than Triton
Marlin (Ampere+ GPUs)
# Quantize with Marlin format
config = BaseQuantizeConfig(
bits=4,
group_size=128,
desc_act=False # Required for Marlin
)
model.quantize(calibration_data, use_marlin=True)
# Load with Marlin
model = AutoGPTQForCausalLM.from_quantized(
model_name,
device="cuda:0",
use_marlin=True # 2× faster on A100/H100
)
Requirements:
- NVIDIA Ampere or newer (A100, H100, RTX 40xx)
- Compute capability ≥ 8.0
Triton (Linux only)
model = AutoGPTQForCausalLM.from_quantized(
model_name,
device="cuda:0",
use_triton=True # Linux only
)
Performance: 1.2-1.5× faster than CUDA backend
Integration with transformers
Direct transformers usage
from transformers import AutoModelForCausalLM, AutoTokenizer
# Load quantized model (transformers auto-detects GPTQ)
model = AutoModelForCausalLM.from_pretrained(
"TheBloke/Llama-2-13B-Chat-GPTQ",
device_map="auto",
trust_remote_code=False
)
tokenizer = AutoTokenizer.from_pretrained("TheBloke/Llama-2-13B-Chat-GPTQ")
# Use like any transformers model
inputs = tokenizer("Hello", return_tensors="pt").to("cuda")
outputs = model.generate(**inputs, max_new_tokens=100)
QLoRA fine-tuning (GPTQ + LoRA)
from transformers import AutoModelForCausalLM
froHow to use gptq on Cursor
AI-first code editor with Composer
Prerequisites
Before installing skills in Cursor, ensure your development environment meets these requirements:
- ›Cursor installed and configured on your development machine
- ›Node.js version 16.0+ with npm package manager (verify with
node --version) - ›Active project directory or workspace where you want to add gptq
Execute installation command
Execute the skills CLI command in your project's root directory to begin installation:
The skills CLI fetches gptq from GitHub repository davila7/claude-code-templates and configures it for Cursor.
Select Cursor when prompted
The CLI will show a list of available agents. Use arrow keys to navigate and space to select Cursor:
Verify installation
Confirm successful installation by checking the skill directory location:
Reload or restart Cursor to activate gptq. Access the skill through slash commands (e.g., /gptq) or your agent's skill management interface.
Security & Verification Notice
We perform automated surface-level scans (Gen AI Scanner, Socket, Snyk) during installation. These checks detect common vulnerabilities but do not guarantee complete security. Always review skill source code and verify the publisher's reputation before production use.
Skills execute code in your development environment. Always verify the publisher's identity, review recent commits, and test in isolated environments before production deployment.
List & Monetize Your Skill
Submit your Claude Code skill and start earning
Use Cases▌
Task Automation & Efficiency
Automate repetitive workflows and reduce manual effort
Example
Generate reports, summarize documents, draft communications
Save 3-5 hours per week on routine tasks
Knowledge Enhancement
Learn new skills, understand complex topics, get expert guidance
Example
Explain concepts, provide examples, suggest learning resources
Accelerate learning and skill development by 2x
Quality Improvement
Enhance output quality through reviews, suggestions, and refinements
Example
Review drafts, suggest improvements, catch errors
Improve work quality by 30-40% with less effort
Implementation Guide▌
Prerequisites
- ›Claude Desktop or compatible AI client with skill support
- ›Clear understanding of task or problem to solve
- ›Willingness to iterate and refine outputs
Time Estimate
15-45 minutes depending on use case complexity
Installation Steps
- 1.Install skill using provided installation command
- 2.Test with simple use case relevant to your work
- 3.Evaluate output quality and relevance
- 4.Iterate on prompts to improve results
- 5.Integrate into regular workflow if valuable
Common Pitfalls
- ⚠Expecting perfect results without iteration
- ⚠Not providing enough context in prompts
- ⚠Using skill for tasks outside its intended scope
- ⚠Accepting outputs without review and validation
Best Practices▌
✓ Do
- +Start with clear, specific prompts
- +Provide relevant context and constraints
- +Review and refine all outputs before using
- +Iterate to improve output quality
- +Document successful prompt patterns
✗ Don't
- −Don't use without understanding skill limitations
- −Don't skip validation of outputs
- −Don't share sensitive information in prompts
- −Don't expect skill to replace human judgment
💡 Pro Tips
- ★Be specific about desired format and style
- ★Ask for multiple options to choose from
- ★Request explanations to understand reasoning
- ★Combine AI efficiency with human expertise
When to Use This▌
✓ Use When
Use when skill capabilities match your task, clear ROI on time saved, and you can validate outputs. Best for repetitive tasks, learning, and quality improvement.
✗ Avoid When
Avoid when task requires deep expertise you can't validate, involves sensitive decisions, or when learning process is more valuable than speed of completion.
Learning Path▌
- 1Familiarize yourself with skill capabilities and limitations
- 2Start with low-risk, non-critical tasks
- 3Progress to more complex and valuable use cases
- 4Build expertise through regular use and experimentation
Discussion
Product Hunt–style comments (not star reviews)- No comments yet — start the thread.
Ratings
4.6★★★★★32 reviews- ★★★★★Kabir Rahman· Dec 12, 2024
gptq reduced setup friction for our internal harness; good balance of opinion and flexibility.
- ★★★★★Dev Taylor· Dec 8, 2024
Registry listing for gptq matched our evaluation — installs cleanly and behaves as described in the markdown.
- ★★★★★Rahul Santra· Nov 7, 2024
Useful defaults in gptq — fewer surprises than typical one-off scripts, and it plays nicely with `npx skills` flows.
- ★★★★★Fatima Thomas· Nov 3, 2024
gptq has been reliable in day-to-day use. Documentation quality is above average for community skills.
- ★★★★★Pratham Ware· Oct 26, 2024
Registry listing for gptq matched our evaluation — installs cleanly and behaves as described in the markdown.
- ★★★★★Liam Chen· Oct 22, 2024
gptq fits our agent workflows well — practical, well scoped, and easy to wire into existing repos.
- ★★★★★Sakshi Patil· Sep 17, 2024
gptq fits our agent workflows well — practical, well scoped, and easy to wire into existing repos.
- ★★★★★Carlos Liu· Sep 5, 2024
Registry listing for gptq matched our evaluation — installs cleanly and behaves as described in the markdown.
- ★★★★★Mateo Menon· Sep 1, 2024
gptq is among the better-maintained entries we tried; worth keeping pinned for repeat workflows.
- ★★★★★Noah Robinson· Sep 1, 2024
gptq reduced setup friction for our internal harness; good balance of opinion and flexibility.
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