---
datasets:
- wikitext
metrics:
- perplexity
base_model:
- meta-llama/Llama-2-7b-hf
base_model_relation: quantized
---
**N**on-**u**niform **GPTQ** (NuGPTQ) combines [GPTQ](https://arxiv.org/abs/2210.17323), [SqueezeLLM](https://arxiv.org/abs/2306.07629) and [output scaling](https://stephenpanaro.com/blog/llm-quantization-for-iphone) for a competitive whole-tensor (no grouping) LLM compression method.
Results for Llama-2-7b-hf:
|Method |WikitextPPL (↓)|Delta |
|-- |-- |-- |
|float16 |8.7071 |0 |
|AWQ |8.9760 |0.2689|
|NuGPTQ (This)|9.2754 |0.5683|
|GPTQ† |9.4686 |0.7615|
† g128, desc_act=True
perplexity reproduction steps
```shell
git clone https://github.com/EleutherAI/lm-evaluation-harness
cd lm-evaluation-harness
pip install -e .
pip install optimum
huggingface-cli login
# Set batch size based on your GPU.
lm_eval --model hf \
--model_args pretrained=meta-llama/Llama-2-7b-hf,dtype="float16" \
--tasks wikitext \
--batch_size 1
# hf (pretrained=meta-llama/Llama-2-7b-hf,dtype=float16), gen_kwargs: (None), limit: None, num_fewshot: None, batch_size: 1
# | Tasks |Version|Filter|n-shot| Metric |Value | |Stderr|
# |--------|------:|------|-----:|---------------|-----:|---|------|
# |wikitext| 2|none | 0|word_perplexity|8.7071|± |N/A |
# | | |none | 0|byte_perplexity|1.4989|± |N/A |
# | | |none | 0|bits_per_byte |0.5839|± |N/A |
lm_eval --model hf \
--model_args pretrained=smpanaro/Llama-2-7b-NuGPTQ,dtype="float16",use_safetensors=True,trust_remote_code=True \
--tasks wikitext \
--batch_size 1
# hf (pretrained=smpanaro/llama-2-7b-nugptq,dtype=float16,use_safetensors=True,trust_remote_code=True), gen_kwargs: (None), limit: None, num_fewshot: None, batch_size: 1
# | Tasks |Version|Filter|n-shot| Metric |Value | |Stderr|
# |--------|------:|------|-----:|---------------|-----:|---|------|
# |wikitext| 2|none | 0|word_perplexity|9.2754|± |N/A |
# | | |none | 0|byte_perplexity|1.5167|± |N/A |
# | | |none | 0|bits_per_byte |0.6009|± |N/A |
pip install auto-gptq
lm_eval --model hf \
--model_args pretrained=TheBloke/Llama-2-7B-GPTQ,dtype="float16",revision=gptq-4bit-128g-actorder_True \
--tasks wikitext \
--batch_size 1
# hf (pretrained=TheBloke/Llama-2-7B-GPTQ,dtype=float16,revision=gptq-4bit-128g-actorder_True), gen_kwargs: (None), limit: None, num_fewshot: None, batch_size: 1
# | Tasks |Version|Filter|n-shot| Metric |Value | |Stderr|
# |--------|------:|------|-----:|---------------|-----:|---|------|
# |wikitext| 2|none | 0|word_perplexity|9.4686|± |N/A |
# | | |none | 0|byte_perplexity|1.5225|± |N/A |
# | | |none | 0|bits_per_byte |0.6065|± |N/A |
lm_eval --model hf \
--model_args pretrained=TheBloke/Llama-2-7B-GPTQ,dtype="float16",revision=gptq-4bit-32g-actorder_True \
--tasks wikitext \
--batch_size 1
# hf (pretrained=TheBloke/Llama-2-7B-GPTQ,dtype=float16,revision=gptq-4bit-32g-actorder_True), gen_kwargs: (None), limit: None, num_fewshot: None, batch_size: 1
# | Tasks |Version|Filter|n-shot| Metric |Value | |Stderr|
# |--------|------:|------|-----:|---------------|-----:|---|------|
# |wikitext| 2|none | 0|word_perplexity|9.3801|± |N/A |
# | | |none | 0|byte_perplexity|1.5199|± |N/A |
# | | |none | 0|bits_per_byte |0.6040|± |N/A |
pip install autoawq
lm_eval --model hf \
--model_args pretrained=TheBloke/Llama-2-7B-AWQ,dtype="float16" \
--tasks wikitext \
--batch_size 1
# hf (pretrained=thebloke/llama-2-7b-awq,dtype=float16), gen_kwargs: (none), limit: none, num_fewshot: none, batch_size: 1
# | Tasks |Version|Filter|n-shot| Metric |Value | |Stderr|
# |--------|------:|------|-----:|---------------|-----:|---|------|
# |wikitext| 2|none | 0|word_perplexity|8.9760|± |N/A |
# | | |none | 0|byte_perplexity|1.5074|± |N/A |
# | | |none | 0|bits_per_byte |0.5921|± |N/A |
```
The model is fake quantized which means each weight has <= 16 (24) unique values, but they are stored in float16. The uniqueness can be checked as follows:
```python
from transformers import AutoModelForCausalLM
model = AutoModelForCausalLM.from_pretrained("smpanaro/Llama-2-7b-NuGPTQ", trust_remote_code=True)
linear_layers = ["k_proj", "q_proj", "v_proj", "o_proj", "gate_proj", "up_proj", "down_proj"]
count = 0
for key, tensor in model.state_dict().items():
if "weight" not in key:
continue
if any([l in key for l in linear_layers]):
assert tensor.unique().shape[0] <= 16, f"{key} has more than 16 unique values"
print("✓", end="", flush=True)
count += 1
print()
# 32 model layers * 7 linear layers
print(f"{count} out of 224 linear layers have 16 unique values.")
```