bartowski/L3.1-70B-Hanami-x1-GGUF

Llamacpp imatrix Quantizations of L3.1-70B-Hanami-x1

Using llama.cpp release b3751 for quantization.

Original model: https://huggingface.co/Sao10K/L3.1-70B-Hanami-x1

All quants made using imatrix option with dataset from here

Prompt format

<|begin_of_text|><|start_header_id|>system<|end_header_id|>

Cutting Knowledge Date: December 2023
Today Date: 26 Jul 2024

{system_prompt}<|eot_id|><|start_header_id|>user<|end_header_id|>

{prompt}<|eot_id|><|start_header_id|>assistant<|end_header_id|>

Download a file (not the whole branch) from below:

Filename	Quant type	File Size	Split	Description
L3.1-70B-Hanami-x1-Q8_0.gguf	Q8_0	74.98GB	true	Extremely high quality, generally unneeded but max available quant.
L3.1-70B-Hanami-x1-Q6_K.gguf	Q6_K	57.89GB	true	Very high quality, near perfect, recommended.
L3.1-70B-Hanami-x1-Q5_K_M.gguf	Q5_K_M	49.95GB	true	High quality, recommended.
L3.1-70B-Hanami-x1-Q4_K_M.gguf	Q4_K_M	42.52GB	false	Good quality, default size for must use cases, recommended.
L3.1-70B-Hanami-x1-Q4_0.gguf	Q4_0	40.12GB	false	Legacy format, generally not worth using over similarly sized formats
L3.1-70B-Hanami-x1-Q3_K_XL.gguf	Q3_K_XL	38.06GB	false	Uses Q8_0 for embed and output weights. Lower quality but usable, good for low RAM availability.
L3.1-70B-Hanami-x1-IQ4_XS.gguf	IQ4_XS	37.90GB	false	Decent quality, smaller than Q4_K_S with similar performance, recommended.
L3.1-70B-Hanami-x1-Q3_K_L.gguf	Q3_K_L	37.14GB	false	Lower quality but usable, good for low RAM availability.
L3.1-70B-Hanami-x1-Q3_K_M.gguf	Q3_K_M	34.27GB	false	Low quality.
L3.1-70B-Hanami-x1-IQ3_M.gguf	IQ3_M	31.94GB	false	Medium-low quality, new method with decent performance comparable to Q3_K_M.
L3.1-70B-Hanami-x1-Q3_K_S.gguf	Q3_K_S	30.91GB	false	Low quality, not recommended.
L3.1-70B-Hanami-x1-IQ3_XXS.gguf	IQ3_XXS	27.47GB	false	Lower quality, new method with decent performance, comparable to Q3 quants.
L3.1-70B-Hanami-x1-Q2_K_L.gguf	Q2_K_L	27.40GB	false	Uses Q8_0 for embed and output weights. Very low quality but surprisingly usable.
L3.1-70B-Hanami-x1-Q2_K.gguf	Q2_K	26.38GB	false	Very low quality but surprisingly usable.
L3.1-70B-Hanami-x1-IQ2_M.gguf	IQ2_M	24.12GB	false	Relatively low quality, uses SOTA techniques to be surprisingly usable.
L3.1-70B-Hanami-x1-IQ2_XS.gguf	IQ2_XS	21.14GB	false	Low quality, uses SOTA techniques to be usable.
L3.1-70B-Hanami-x1-IQ2_XXS.gguf	IQ2_XXS	19.10GB	false	Very low quality, uses SOTA techniques to be usable.
L3.1-70B-Hanami-x1-IQ1_M.gguf	IQ1_M	16.75GB	false	Extremely low quality, not recommended.

Embed/output weights

Some of these quants (Q3_K_XL, Q4_K_L etc) are the standard quantization method with the embeddings and output weights quantized to Q8_0 instead of what they would normally default to.

Some say that this improves the quality, others don't notice any difference. If you use these models PLEASE COMMENT with your findings. I would like feedback that these are actually used and useful so I don't keep uploading quants no one is using.

Thanks!

Downloading using huggingface-cli

First, make sure you have hugginface-cli installed:

pip install -U "huggingface_hub[cli]"

Then, you can target the specific file you want:

huggingface-cli download bartowski/L3.1-70B-Hanami-x1-GGUF --include "L3.1-70B-Hanami-x1-Q4_K_M.gguf" --local-dir ./

If the model is bigger than 50GB, it will have been split into multiple files. In order to download them all to a local folder, run:

huggingface-cli download bartowski/L3.1-70B-Hanami-x1-GGUF --include "L3.1-70B-Hanami-x1-Q8_0/*" --local-dir ./

You can either specify a new local-dir (L3.1-70B-Hanami-x1-Q8_0) or download them all in place (./)

Q4_0_X_X

These are NOT for Metal (Apple) offloading, only ARM chips.

If you're using an ARM chip, the Q4_0_X_X quants will have a substantial speedup. Check out Q4_0_4_4 speed comparisons on the original pull request

To check which one would work best for your ARM chip, you can check AArch64 SoC features (thanks EloyOn!).

Which file should I choose?

A great write up with charts showing various performances is provided by Artefact2 here

The first thing to figure out is how big a model you can run. To do this, you'll need to figure out how much RAM and/or VRAM you have.

If you want your model running as FAST as possible, you'll want to fit the whole thing on your GPU's VRAM. Aim for a quant with a file size 1-2GB smaller than your GPU's total VRAM.

If you want the absolute maximum quality, add both your system RAM and your GPU's VRAM together, then similarly grab a quant with a file size 1-2GB Smaller than that total.

Next, you'll need to decide if you want to use an 'I-quant' or a 'K-quant'.

If you don't want to think too much, grab one of the K-quants. These are in format 'QX_K_X', like Q5_K_M.

If you want to get more into the weeds, you can check out this extremely useful feature chart:

llama.cpp feature matrix

But basically, if you're aiming for below Q4, and you're running cuBLAS (Nvidia) or rocBLAS (AMD), you should look towards the I-quants. These are in format IQX_X, like IQ3_M. These are newer and offer better performance for their size.

These I-quants can also be used on CPU and Apple Metal, but will be slower than their K-quant equivalent, so speed vs performance is a tradeoff you'll have to decide.

The I-quants are not compatible with Vulcan, which is also AMD, so if you have an AMD card double check if you're using the rocBLAS build or the Vulcan build. At the time of writing this, LM Studio has a preview with ROCm support, and other inference engines have specific builds for ROCm.

Credits

Thank you kalomaze and Dampf for assistance in creating the imatrix calibration dataset

Thank you ZeroWw for the inspiration to experiment with embed/output

Want to support my work? Visit my ko-fi page here: https://ko-fi.com/bartowski

bartowski
/

L3.1-70B-Hanami-x1-GGUF