---

license: mit

<p align="center"> <img src="./assets/misc/logo.png" style="width: 80%; height: auto;"/> </p>

CAPYBARA: A Unified Visual Creation Model

<div align="center"> <a href=https://huggingface.co/xgen-universe/Capybara target="_blank"><img src=https://img.shields.io/badge/%F0%9F%A4%97%20Models-d96902.svg height=22px></a> <a href=https://github.com/xgen-universe/Capybara target="_blank"><img src= https://img.shields.io/badge/Page-bb8a2e.svg?logo=github height=22px></a> <a href="https://inappetent-acrophonically-alison.ngrok-free.dev/" target="_blank"><img src=https://img.shields.io/badge/Gradio-Demo-orange?logo=gradio&logoColor=white height=22px></a> <a href="https://github.com/xgen-universe/Capybara/blob/main/assets/docs/tech_report.pdf" target="_blank"><img src=https://img.shields.io/badge/Technical_Report-PDF-EC1C24?logo=adobeacrobatreader&logoColor=white height=22px></a> <a href="https://pub-7ba77a763b8142cea73b9e48b46830ca.r2.dev/wechat.jpg" target="_blank"><img src=https://img.shields.io/badge/WeChat-07C160?style=flat&logo=wechat&logoColor=white height=22px></a> </div>

Capybara is a unified visual creation model, i.e., a powerful visual generation and editing framework designed for high-quality visual synthesis and manipulation tasks.

The framework leverages advanced diffusion models and transformer architectures to support versatile visual generation and editing capabilities with precise control over content, motion, and camera movements.

<table> <tr> <td align="center"> <video src="https://pub-7ba77a763b8142cea73b9e48b46830ca.r2.dev/demo_video.mp4" controls="controls" style="max-width: 100%;"> </video> <br> _{Speech-driven base clips generated by Seedance 2.0. All editing powered by CAPYBARA} </td> </tr> </table>

Key Features:

• 🎬 Multi-Task Support: Supports Text-to-Video (T2V), Text-to-Image (T2I), Instruction-based Video-to-Video (TV2V), Instruction-based Image-to-Image (TI2I), and various editing tasks
• 🚀 High Performance: Built with distributed inference support for efficient multi-GPU processing

🔥 News

• [2026.02.17] 🚀 Initial release v0.1 of the Capybara inference framework supportting generation and instruction-based editing tasks (T2I, T2V, TI2I, TV2V).

📝 TODO List

• [ ] Release our unified creation model.
• [ ] Release training code.

🛠️ Installation

We recommend using Anaconda to create an isolated Python environment and recommend using CUDA 12.6:

# Clone the repository
git clone https://github.com/xgen-universe/Capybara.git
cd Capybara

# Create environment
conda create -n capybara python=3.11 -y
conda activate capybara

# Install pytorch (torch 2.6.0 with CUDA 12.6)
pip install torch==2.6.0 torchvision==0.21.0 torchaudio==2.6.0 --index-url https://download.pytorch.org/whl/cu126

# Install dependencies
pip install -r requirements.txt

# [Optional] Install Flash Attention for faster inference
pip install flash_attn --no-build-isolation

📥 Model Download

Capybara requires the following model components:

| Models | Download Link | Description | | ------------------- | ---------------------------------------------------------------------------- | --------------------------------- | | Model | Huggingface Model | All Mandatory Models | | Rewrite Model | Huggingface Model | Qwen3-VL-8B-Instruct for Rewrite Instruction|

Download the required models and organize them in the following structure:

ckpts/
├── scheduler/
│   └── scheduler_config.json
├── text_encoder/
│   ├── byt5-small/
│   ├── Glyph-SDXL-v2/
│   └── llm/
├── transformer/
│   └── capybara_v01/
├── vae/
└── vision_encoder/
    └── siglip/

🚀 Inference & Quick Start

Capybara supports two inference modes: Single Sample Mode for quick testing with a single input, and Batch Mode for processing multiple samples via CSV files. Both modes support all task types.

We provide example scripts under script/ and example data under assets/ to help you get started quickly:

assets/
├── examples/           # Example media files
│   ├── img1.jpeg
│   ├── img2.jpeg
│   ├── video1.mp4
│   └── video2.mp4
└── test_data/          # Example CSV files for batch mode
    ├── ti2i_example.csv
    └── tv2v_example.csv

Single Sample Mode

Process a single image or video with a text prompt. See script/test_single_infer.sh for full examples.

Instruction-based Image-to-Image (TI2I):

python inference.py \
    --pretrained_model_name_or_path ./ckpts \
    --media_path ./assets/examples/img1.jpeg \
    --prompt "Change the time to night." \
    --output_path ./results/test_single_output/ti2i \
    --num_inference_steps 50 \
    --task_type ti2i \
    --resolution 720p \
    --rewrite_instruction

Instruction-based Video-to-Video (TV2V):

python inference.py \
    --pretrained_model_name_or_path ./ckpts \
    --media_path ./assets/examples/video1.mp4 \
    --prompt "Replace the monkey with Ultraman. keep the Ultraman's motion matched the original running pose and motion of monkey." \
    --output_path ./results/test_single_output/tv2v \
    --num_inference_steps 50 \
    --num_frames 81 \
    --task_type tv2v \
    --resolution 480p \
    --rewrite_instruction

<details> <summary> More inference examples about generation tasks (T2I/T2V)</summary>

Text-to-Video (T2V):

python inference.py \
    --pretrained_model_name_or_path ./ckpts \
    --prompt "A giant humpback whale and its calf gracefully swim in the crystal-clear, deep blue open ocean." \
    --output_path ./results/test_single_output/t2v \
    --guidance_scale 4 \
    --num_inference_steps 50 \
    --num_frames 81 \
    --task_type t2v \
    --resolution 480p \
    --aspect_ratio "16:9" \
    --rewrite_instruction

Text-to-Image (T2I):

python inference.py \
    --pretrained_model_name_or_path ./ckpts \
    --prompt "A group of five hikers, sitting on the snow mountain." \
    --output_path ./results/test_single_output/t2i \
    --guidance_scale 4 \
    --num_inference_steps 50 \
    --task_type t2i \
    --resolution 720p \
    --aspect_ratio "16:9" \
    --rewrite_instruction

</details>

Batch Mode (CSV)

Process multiple samples using a CSV file. See script/test_infer.sh for a full example.

CSV Format

For editing tasks (TI2I / TV2V), prepare a CSV with img_path/video_path and instruction columns:

img_path,instruction
img1.jpeg,insturction1.
img2.jpeg,insturction2.

The path column holds relative paths to media files (images or videos) under the data root directory.

Example CSV files are provided in assets/test_data/.

Single GPU

python inference.py \
    --pretrained_model_name_or_path ./ckpts \
    --csv_path ./assets/test_data/ti2i_example.csv \
    --data_root_path ./assets/examples \
    --output_path ./results/test_output/ti2i-480p \
    --num_inference_steps 50 \
    --num_frames 81 \
    --task_type ti2i \
    --resolution 720p \
    --rewrite_instruction

Multi-GPU (Distributed)

Use accelerate for distributed inference across multiple GPUs:

accelerate launch --config_file acc_config/accelerate_config.yaml --num_processes 2 inference.py \
    --pretrained_model_name_or_path ./ckpts \
    --csv_path ./assets/test_data/ti2i_example.csv \
    --data_root_path ./assets/examples \
    --output_path ./results/test_output/ti2i-480p \
    --num_inference_steps 50 \
    --num_frames 81 \
    --task_type ti2i \
    --resolution 720p \
    --rewrite_instruction

⚙️ Configuration Details

Task Types

| Task Type | Description | Input Required | | --------- | ------------------------------------------ | ----------------------- | | t2v | Text-to-Video generation | --prompt | | t2i | Text-to-Image generation | --prompt | | ti2i | Instruction-based Image-to-Image editing | --media_path + --prompt (or CSV) | | tv2v | Instruction-based Video-to-Video editing | --media_path + --prompt (or CSV) |

Key Parameters

| Parameter | Default | Description | | -------------------------- | ----------- | ---------------------------------------------------------- | | --pretrained_model_name_or_path | (required) | Path to the model checkpoint directory | | --task_type | tv2v | Task type: t2v, t2i, ti2i, tv2v | | --resolution | None | Output resolution: 480p, 720p, 1080p | | --aspect_ratio | None | Aspect ratio: 16:9, 9:16, 4:3, 3:4, 1:1 | | --num_frames | 81 | Number of frames to generate (e.g., 81, 101, 121) | | --num_inference_steps | 50 | Number of denoising steps | | --guidance_scale | 1.0 | Text guidance scale for classifier-free guidance | | --num_sample_per_case | 1 | Number of samples to generate per input | | --rewrite_instruction | False | Auto-enhance prompts using Qwen3-VL-8B-Instruct | | --rewrite_model_path | Qwen/Qwen3-VL-8B-Instruct | Path to the rewrite model | | --max_samples | None | Limit the number of samples to process from CSV |

Recommended Settings

For optimal quality and performance, we recommend the following settings:

| Task Type | Recommended Resolution | Recommended Steps | Note | | --------- | --------------------- | ----------------- | -------------------------------------- | | Video (T2V, TV2V) | 480p | 50 | Balanced quality and generation speed | | Image (T2I, TI2I) | 720p | 50 | Higher quality for static images |

Notes:

• Resolution: You can experiment with higher resolutions (1024 or 1080p).
• Inference Steps: 50 steps provide a good balance between quality and speed. You can use 30-40 steps for faster generation.

📄 License

This project is released under the MIT License.

🙏 Acknowledgments

This project is built upon:

• HunyuanVideo-1.5 - Base Video Generation Model
• Diffusers - Diffusion pipeline infrastructure
• Accelerate - Distributed training/inference
• SageAttention - Efficient attention mechanism

📝 Citation

If you find Capybara useful for your research, please consider citing:

@misc{capybara2026rao,
  title={Capybara: A Unified Visual Creation Model},
  author={Rao, Zhefan and Che, Haoxuan and Hu, Ziwen and Zou, Bin and Liu, Yaofang and He, Xuanhua and Choi, Chong-Hou and He, Yuyang and Chen, Haoyu and Su, Jingran and Li, Yanheng and Chu, Meng and Lei, Chenyang and Zhao, Guanhua and Li, Zhaoqing and Zhang, Xichen and Li, Anping and Liu, Lin and Tu, Dandan and Liu, Rui},
  year={2026}
}

📧 Contact

For questions and feedback, please open an issue on GitHub.

You can also contact us by email: zraoac@ust.hk and hche@ust.hk

---

⭐ If you find this project helpful, please consider giving it a star!

---

base_model:

• Qwen/Qwen3.5-397B-A17B

---

This repo contains specialized MoE-quants for Qwen3.5-397B-A17B. The idea being that given the huge size of the FFN tensors compared to the rest of the tensors in the model, it should be possible to achieve a better quality while keeping the overall size of the entire model smaller compared to a similar naive quantization. To that end, the quantization type default is kept in high quality and the FFN UP + FFN GATE tensors are quanted down along with the FFN DOWN tensors.

| Quant | Size | Mixture | PPL | 1-(Mean PPL(Q)/PPL(base)) | KLD | | :--------- | :--------- | :------- | :------- | :------- | :------- | | Q5_K_M | 273.49 GiB (5.93 BPW) | Q8_0 / Q5_K / Q5_K / Q6_K | 4.617400 ± 0.057235 | +0.0156% | 0.002553 ± 0.000078 | | Q4_K_M | 227.55 GiB (4.93 BPW) | Q8_0 / Q4_K / Q4_K / Q5_K | 4.624688 ± 0.057341 | +0.1735% | 0.004496 ± 0.000117 | | IQ4_XS | 176.92 GiB (3.83 BPW) | Q8_0 / IQ3_S / IQ3_S / IQ4_XS | 4.653226 ± 0.057738 | +0.7916% | 0.011963 ± 0.000309 | | IQ3_S | 136.31 GiB (2.95 BPW) | Q6_K / IQ2_S / IQ2_S / IQ3_S | 4.745153 ± 0.059208 | +2.7828% | 0.033163 ± 0.000791 |

---

pipeline_tag: image-text-to-text base_model:

• Qwen/Qwen3.5-397B-A17B license: apache-2.0 library_name: Model Optimizer tags:
• nvidia
• ModelOpt
• Qwen3.5
• quantized
• NVFP4
• nvfp4
• multimodal
• vision-language

---

NVIDIA Qwen3.5-397B-A17B-NVFP4 Model Card

Model Overview

Description:

The NVIDIA Qwen3.5-397B-A17B-NVFP4 model is a quantized version of Qwen's Qwen3.5-397B-A17B model, an autoregressive multimodal language model that uses an optimized Transformer architecture with Mixture of Experts (MoE) and vision-language capabilities. For more information, refer to the Qwen3.5-397B-A17B model card. The NVIDIA Qwen3.5-397B-A17B-NVFP4 model was quantized using the TensorRT Model Optimizer.

This model is ready for commercial/non-commercial use. <br>

Third-Party Community Consideration

This model is not owned or developed by NVIDIA. This model has been developed and built to a third-party's requirements for this application and use case; see link to Non-NVIDIA (Qwen3.5-397B-A17B) Model Card.

License/Terms of Use:

Apache 2.0

Deployment Geography:

Global <br>

Use Case:

Developers looking to take off the shelf, pre-quantized models for deployment in AI Agent systems, chatbots, RAG systems, and other AI-powered applications. <br>

Release Date:

Huggingface via https://huggingface.co/nvidia/Qwen3.5-397B-A17B-NVFP4 <br>

Model Architecture:

Architecture Type: Transformers (Hybrid) <br> Network Architecture: Qwen3_5MoeForConditionalGeneration <br> Model Details:

• Total Parameters: 397B
• Active Parameters: 17B (Sparse Mixture-of-Experts)
• Hidden Size: 4096
• Number of Layers: 60 (15 blocks of 3x Gated DeltaNet + 1x Gated Attention, each followed by MoE)
• Expert Configuration: 512 total experts, 10 activated per token + 1 shared expert, expert intermediate dimension 1024.
• Gated DeltaNet (Linear Attention): 64 value heads, 16 QK heads, head dimension 128. Provides long-context efficiency.
• Gated Attention (Full Attention): 32 Q heads, 2 KV heads, head dimension 256, with 64-dim rotary position embedding.
• Context Window: 262,144 tokens (native), extensible to 1,010,000 tokens with YaRN scaling.
• Vocabulary Size: 248,320
• Multi-Token Prediction (MTP): 1 additional prediction layer for speculative decoding.
• Thinking Mode: Default behavior with <think>...</think> blocks before responses.
• Multilingual: Supports 201 languages and dialects.
• Vision Encoder: 27-layer ViT with 1152 hidden size, patch size 16, spatial merge size 2.

Input:

Input Type(s): Text, Image, Video <br> Input Format(s): String, Image, Video <br> Input Parameters: 1D (One-Dimensional): Sequences, 2D (Two-Dimensional): Images, 3D (Three-Dimensional): Video <br>

Output:

Output Type(s): Text <br> Output Format: String <br> Output Parameters: 1D (One-Dimensional): Sequences <br> Other Properties Related to Output: N/A <br>

Our AI models are designed and/or optimized to run on NVIDIA GPU-accelerated systems. By leveraging NVIDIA's hardware (e.g. GPU cores) and software frameworks (e.g., CUDA libraries), the model achieves faster training and inference times compared to CPU-only solutions. <br>

Software Integration:

Runtime Engine(s): <br>

• SGLang <br>

Supported Hardware Microarchitecture Compatibility: <br>

• NVIDIA Blackwell (B300, B200, RTX PRO 6000 Blackwell) <br>

Preferred Operating System(s): <br>

• Linux <br>

The integration of foundation and fine-tuned models into AI systems requires additional testing using use-case-specific data to ensure safe and effective deployment. Following the V-model methodology, iterative testing and validation at both unit and system levels are essential to mitigate risks, meet technical and functional requirements, and ensure compliance with safety and ethical standards before deployment

Model Version(s):

** The model is quantized with nvidia-modelopt 0.42.0rc1.dev21+g421985313 <br>

Training, Testing, and Evaluation Datasets:

Calibration Dataset:

• Link: Nemotron-Post-Training-Dataset-v2 <br>
• Data collection method: Automated. <br>
• Labeling method: Automated. <br>

Training Datasets:

• Data Collection Method by Dataset: Undisclosed <br>
• Labeling Method by Dataset: Undisclosed<br>
• Properties: Undisclosed

Testing Dataset:

• Data Collection Method by Dataset: Undisclosed <br>
• Labeling Method by Dataset: Undisclosed <br>
• Properties: Undisclosed <br>

Evaluation Dataset:

• Data collection method: Hybrid: Automated, Human <br>
• Labeling method: Hybrid: Human, Automated <br>

Inference:

Acceleration Engine: SGLang <br> Test Hardware: B300 <br>

Recommended Hardware

| GPU | Architecture | VRAM | Memory Type | Memory Bandwidth | TDP | | :--- | :--- | :--- | :--- | :--- | :--- | | NVIDIA B300 (SXM) | Blackwell Ultra (GB110) | 288 GB HBM3e | HBM3e | 4.1 TB/s | 1400 W | | NVIDIA B200 (SXM) | Blackwell (GB100) | 192 GB HBM3e | HBM3e | 4.1 TB/s | 1000 W | | NVIDIA RTX PRO 6000 Blackwell (PCIe) | Blackwell (GB202) | 96 GB GDDR7 | GDDR7 | 1.8 TB/s | 600 W |

B300: 288 GB HBM3e per GPU, 4096-bit memory bus, 18,944 CUDA cores, 592 Tensor Cores, up to 2032 MHz boost. Datacenter SXM module. <br> B200: 192 GB HBM3e per GPU, 4096-bit memory bus, 18,944 CUDA cores, 592 Tensor Cores, up to 1965 MHz boost. Datacenter SXM module. <br> RTX PRO 6000 Blackwell: 96 GB GDDR7 per GPU, 512-bit memory bus, 24,064 CUDA cores, 752 Tensor Cores, up to 2617 MHz boost. Professional workstation GPU (PCIe 5.0 x16). <br>

Post Training Quantization

This model was obtained by quantizing the weights and activations of Qwen3.5-397B-A17B to NVFP4 data type, ready for inference with SGLang. Only the weights and activations of the linear operators within transformer blocks are quantized, as well as the KV-cache to FP8. Vision encoder weights are not quantized. This optimization reduces the number of bits per parameter from 16 to 4, reducing the disk size and GPU memory requirements by approximately 4x.

Usage

Deploy with SGLang

The total quantized checkpoint size is ~224GB (397B total parameters, 17B active). On NVIDIA Blackwell GPUs:

| Configuration | GPUs | VRAM per GPU | Total VRAM | Throughput | |:---|:---|:---|:---|:---| | B300 TP=4 | 4x B300 | 288 GB | 1,152 GB | ~120 tok/s | | B300 TP=8 | 8x B300 | 288 GB | 2,304 GB | - | | B200 TP=4 | 4x B200 | 192 GB | 768 GB | - | | B200 TP=8 | 8x B200 | 192 GB | 1,536 GB | - | | RTX PRO 6000 TP=4 | 4x RTX PRO 6000 | 96 GB | 384 GB | - | | RTX PRO 6000 TP=8 | 8x RTX PRO 6000 | 96 GB | 768 GB | - |

The model has a default context length of 262,144 tokens. If you encounter out-of-memory (OOM) errors, consider reducing the context window. However, because Qwen3.5 leverages extended context for complex tasks, we advise maintaining a context length of at least 128K tokens to preserve thinking capabilities.

# TP=4 (recommended, ~120 tok/s on 4x B300)
python3 -m sglang.launch_server \
    --model-path vincentzed-hf/Qwen3.5-397B-A17B-NVFP4 \
    --quantization modelopt_fp4 \
    --tp 4 \
    --context-length 262144 \
    --reasoning-parser qwen3

# TP=8 (if you have less VRAM per GPU, e.g. RTX PRO 6000)
python3 -m sglang.launch_server \
    --model-path vincentzed-hf/Qwen3.5-397B-A17B-NVFP4 \
    --quantization modelopt_fp4 \
    --tp 8 \
    --context-length 262144 \
    --reasoning-parser qwen3

Speculative Decoding (Experimental)

Qwen3.5 includes a built-in Multi-Token Prediction (MTP) head that can be used for speculative decoding via the NEXTN algorithm. This is experimental and may or may not work at this time:

python3 -m sglang.launch_server \
    --model-path vincentzed-hf/Qwen3.5-397B-A17B-NVFP4 \
    --quantization modelopt_fp4 \
    --tp 8 \
    --context-length 262144 \
    --reasoning-parser qwen3 \
    --speculative-algo NEXTN \
    --speculative-num-steps 3 \
    --speculative-eagle-topk 1 \
    --speculative-num-draft-tokens 4

Installation

Important: You must install SGLang from the bzhng-development:vz/qwen3-5 branch, which includes a fix for the exclusion of visual encoder weights not working properly during quantized inference. Without this fix, the visual weights may be incorrectly handled.

git clone -b vz/qwen3-5 git@github.com:bzhng-development/sglang.git
cd sglang
uv pip install -e "python"
uv pip install transformers==5.2.0

When a release is cut with this fix, we will update this model card.

Reproduce with ModelOpt

You may want to produce this checkpoint yourself. To reproduce the NVFP4 quantized checkpoint using TensorRT Model Optimizer:

python3 examples/llm_ptq/hf_ptq.py \
    --pyt_ckpt_path Qwen/Qwen3.5-397B-A17B \
    --qformat nvfp4 \
    --export_path ./qwen3-5-nvfp4

Note: NVFP4 and FP8 KVCache provides a significant memory footprint reduction (~3.5x vs BF16) with negligible accuracy degradation.

Baseline: Qwen3.5-397B-A17B.

Model Limitations:

The base model was trained on data that contains toxic language and societal biases originally crawled from the internet. Therefore, the model may amplify those biases and return toxic responses especially when prompted with toxic prompts. The model may generate answers that may be inaccurate, omit key information, or include irrelevant or redundant text producing socially unacceptable or undesirable text, even if the prompt itself does not include anything explicitly offensive.

Ethical Considerations

NVIDIA believes Trustworthy AI is a shared responsibility and we have established policies and practices to enable development for a wide array of AI applications. When downloaded or used in accordance with our terms of service, developers should work with their internal model team to ensure this model meets requirements for the relevant industry and use case and addresses unforeseen product misuse.

Please report model quality, risk, security vulnerabilities or NVIDIA AI Concerns here.

---

pipeline_tag: text-generation license: other license_name: modified-mit license_link: https://github.com/MiniMax-AI/MiniMax-M2.5/blob/main/LICENSE library_name: llm-compressor tags:

• fp8
• awq
• conversational
• vllm
• code
• devops
• software engineering
• engineer
• developer
• architect
• stem
• agent datasets:
• HuggingFaceH4/ultrachat_200k
• databricks/databricks-dolly-15k
• neuralmagic/calibration
• HuggingFaceH4/no_robots
• nvidia/HelpSteer
• garage-bAInd/Open-Platypus
• PJMixers/grimulkan_physical-reasoning-ShareGPT
• PJMixers/grimulkan_theory-of-mind-ShareGPT
• HuggingFaceH4/Multilingual-Thinking
• ServiceNow-AI/M2Lingual
• droussis/euroblocks_sft_1sample_per_lang
• interstellarninja/hermes_reasoning_tool_use
• deepmind/code_contests
• dh02391735/stackoverflow-kubernetes-questions
• diversoailab/humaneval-rust
• ammarnasr/the-stack-rust-clean
• CSJianYang/CodeArena
• nvidia/OpenCodeInstruct
• nvidia/Llama-Nemotron-Post-Training-Dataset
• nvidia/Nemotron-Competitive-Programming-v1
• rombodawg/code_bagel_hermes-2.5
• MathArena/project_euler
• nvidia/Nemotron-Math-Proofs-v1
• nvidia/OpenMathInstruct-2
• nvidia/OpenScienceReasoning-2
• MegaScience/MegaScience
• OpenMed/Medical-Reasoning-SFT-GPT-OSS-120B
• ccdv/pubmed-summarization
• gbharti/finance-alpaca
• vladlen32230/summarization-yahoo-stock-finance-article-text
• fka/awesome-chatgpt-prompts
• theoldmandthesea/17k_business_book
• ruggsea/stanford-encyclopedia-of-philosophy_instruct
• mlfoundations-dev/stackexchange_philosophy
• FreedomIntelligence/SocraticChat
• Gryphe/Opus-WritingPrompts
• anthracite-org/nopm_claude_writing_fixed
• zerofata/Roleplay-Anime-Characters
• zerofata/Instruct-Anime
• zerofata/Instruct-Anime-CreativeWriting
• sam-paech/gutenberg3-generalfiction-scifi-fantasy-romance-adventure-dpo
• PocketDoc/Dans-Prosemaxx-Adventure
• anthracite-org/stheno-filtered-v1.1
• KaraKaraWitch/TvTroper-2025
• AquaV/US-Army-Survival-Sharegpt
• AquaV/Interrogation-Sharegpt
• AquaV/Multi-Environment-Operations-Sharegpt
• AquaV/Resistance-Sharegpt
• PocketDoc/Dans-Kinomaxx-VanillaBackrooms base_model:
• MiniMaxAI/MiniMax-M2.5

---

MiniMax M2.5 (Mixed-Precision FP8 + INT4 AWQ FrankenQuant)

This strives to be the highest quality quant that can run on 192GiB VRAM

[!TIP]
💡 A non-FP8 version is available at mratsim/MiniMax-M2.5-BF16-INT4-AWQ
That version is compatible with 8x RTX 3090s and with SGLang (which doesn't support mixed quantization yet) for an extra 3GiB in VRAM.
This FP8+INT4 AWQ was build by merging the original FP8 self-attention weights and mratsim/MiniMax-M2.5-BF16-INT4-AWQ experts.

It features:

• That model has ensured that all experts are calibrated, not doing so is extremely detrimental, PR: https://github.com/vllm-project/llm-compressor/pull/2171

  <details> <summary>💡**[Click me!]** Visual showcase of why ensuring quantization of all MoE experts is important</summary>
  • Source: https://avtc.github.io/aquarium-side-by-side/
  • Context: https://github.com/ModelCloud/GPTQModel/pull/2235

  

  </details>

• Mixed precision with:

  • self-attention weights copied directly from the official version (default FP8 with 2D-blocks)
  • experts weights quantized using AWQ W4A16G32 scheme (4-bit weights, 16-bit activations, scaling factor per group of 32 weights)

• High-quality large and diverse dataset with programming and devops focus as well as domain-specific knowledge (math, sciences, medical, finance, business, humanities, philosophy, creative writing), general knowledge, pop culture and behavioral situations because we never code in a vacuum. And we want to make sure all experts are calibrated to the full range of their activations.

• Calibration explicitly tests multilingual capabilities:

  • Asia: Chinese, Hindi, Korean, Japanese
  • Europe: French, German, Portuguese, Russian, Spanish
  • Middle-East: Arabic, Hebrew, Turkish

• Calibration explicitly tests 60 programming languages and not just Python:

  • Imperative programming: C, C++, Go, Zig, ...
  • Functional programming: Haskell, F#, OCaml, Erlang, Lisp, Clojure ...
  • Web-focused: HTML/CSS, Typescript, PHP, ...
  • Mixed paradigm: D, Kotlin, Nim, Rust, Swift, ...
  • Theorem provers: Coq, Lean
  • Low-level: ARM64 assembly, x86-64 assembly, LLVM IR
  • GPU Programming: Cuda, Vulkan, Apple Metal
  • Game Programming: GDScript, GLSL
  • Domain-specific: MATLAB, Julia, Solidity, R

• Calibration tries to ensure coverage for a wide variety of experience (from explaining concepts to your grandmother to debugging Kubernetes logs)

• Built by a dev, for devs (and it looks very good for STEM as well)

It uses my new declarative quantization framework https://github.com/mratsim/quantizers which facilitates highly-tuned calibration sets: calibrate_software_engineer.yaml

<details> <summary>This has taken several days and contribution and bug reports to the ecosystem, I hope you find it useful.</summary>

• https://github.com/vllm-project/llm-compressor/pull/2171
• https://github.com/vllm-project/llm-compressor/issues/2172
• https://github.com/vllm-project/vllm/issues/31623
• https://github.com/sgl-project/sglang/issues/16276
• https://github.com/sgl-project/sglang/issues/16295

</details>

📥 Usage & Running Instructions

The model was tested with vLLM + 2x RTX Pro 6000, here is a script suitable for such configuration with the maximum 196,608 context length. This uses 92.5GiB of VRAM with the flashinfer backend.

[!WARNING]
⚠️ Due to rope_parameters change, at the moment this model is incompatible with transformers V5.
This makes it incompatible with GLM-4.6V which requires transformers V5. Use different Docker images.

[!WARNING]
⚠️ SGLang does not support this model due to missing mixed precision support. Feature request raised at https://github.com/sgl-project/sglang/issues/16276.

Please use mratsim/MiniMax-M2.5-BF16-INT4-AWQ in the meantime.

Running script

--trust-remote-code is necessary until the transformers team merges github.com/huggingface/transformers/pull/42028

You have 2 reasoning parsers;

• minimax_m2, puts the reasoning content in a special field like DeepSeek models that is usually rendered in a specific manner in frontends.
• minimax_m2_append_think, puts the reasoning into <think>reasoning_content</think> and that is sent as normal text. Few frontends properly render that, I'm aware of Cherry Studio on Desktop and ChatterUI on Android.

The reason why minimax_m2_append_think was introduced was Interleaved Thinking and having the model build upon it's previous thinking (usually frontends discard the thinking trace)

[!TIP]
💡In MiniMax-M2.1 with the recommended parameters the model tended to get stuck in repetition loops in vLLM
It seemed like repetition_penalty: 1.10, frequency_penalty: 0.40 avoided that.

You may want to try recommended settings without repetition_penalty first (and it slows down token generation)

# Model configuration (Mandatory)
MODEL="mratsim/MiniMax-M2.5-FP8-INT4-AWQ"
MODELNAME="MiniMax-M2.5"
GPU_UTIL=0.93
SAMPLER_OVERRIDE='{"temperature": 1, "top_p": 0.95, "top_k": 40, "repetition_penalty": 1.1, "frequency_penalty": 0.40}'

# Prevent memory fragmentation
export PYTORCH_ALLOC_CONF=expandable_segments:True,max_split_size_mb:512

# Prevent vLLM from using 100% CPU when idle (Very Recommended)
export VLLM_SLEEP_WHEN_IDLE=1

vllm serve "${MODEL}" \
  --served-model-name "${MODELNAME}" \
  --trust-remote-code \
  --gpu-memory-utilization ${GPU_UTIL} \
  --tp 2 \
  --override-generation-config "${SAMPLER_OVERRIDE}" \
  --enable-auto-tool-choice \
  --tool-call-parser minimax_m2 \
  --reasoning-parser minimax_m2
  # --reasoning-parser minimax_m2_append_think

Performance

On dual RTX Pro 6000, I can reach over 5500 prefill/prompt/context processing and over 100 tok/s token generation for a single request.

With PagedAttention in action you can reach over 25000 tok/s in prompt processing speed.

When batching, with default config, you can reach over 6000 even 8000 tok/s and 1200 tok/s generation speed.
Tune prefill vs decode prioritization with --max_num_batched_tokens see Performance & Tuning | vLLM

In a steady state with interleaved prefill and decode requests that interrupt each other, you can get ~2400 tok/s context processing and 800 tok/s generation

Note: vLLM supports prefill-decode disaggregation for high throughput serving if you have double the minimum hardware:

• https://pytorch.org/blog/disaggregated-inference-at-scale-with-pytorch-vllm/
• https://github.com/vllm-project/production-stack
  • Prefill/decode disaggregation
  • Multi-Tier KV-cache via LMCache (GPU > CPU > Local Disk)
  • Cache aware router
  • Multi-model dispatch via single interface

🔬 Quantization method

Quantization was quite complex for this model and was done in 3 steps:

1. Original weights are in FP8, they were dequantized to FP16 due to llm-compressor not being able to process FP8.
2. llm-compressor was used to quantize the MLP experts projection using AWQ, with PR #2171 to ensure they were all activated.
3. Stitching the FrankenQuant: I combined the original weights, including the 2D-block FP8, with the experts-only AWQ weights.

The llmcompressor library was used with the following recipe:

default_stage:
  default_modifiers:
    AWQModifier:
      config_groups:
        mlp_experts_projections:
          # Include only MLP expert weights for 4-bit quantization
          targets: ["re:.*block_sparse_moe\\.experts\\.\\d+\\.(w1|w2|w3)$"]
          weights:
            num_bits: 4
            type: int
            symmetric: true
            group_size: 32
            strategy: group
            dynamic: false
            # actorder: group
            observer: memoryless_minmax

      mappings:
        - smooth_layer: re:.*post_attention_layernorm$
          balance_layers: ["re:.*w1$", "re:.*w3$"]
        - smooth_layer: re:.*w3$
          balance_layers: ["re:.*w2$"]
      duo_scaling: true

The calibration set had 590 examples, 8192 sequence length, 60 programming languages, 12 spoken languages and is detailed at calibrate_software_engineer.yaml

Quantization theory and heuristics for manual tuning

<details> <summary>In-depth overview of quantization theory and heuristics for manual tuning</summary>

Layers to quantize

Quantization should be focused on Linear layers (also called Dense or Fully-Connected layers i.e. MatMul+Bias) In particular quantizing LayerNorm/RMSnorm layer is strongly discouraged, see [1]

LayerNorm in Quantization. Kovaleva et al. (2021); Wei et al. (2022) find that outliers in the LayerNorm parameters of BERT (Devlin et al., 2019) cause difficulties in model compression. Given the importance of LayerNorm, all the quantization methods we discuss above leave LayerNorm unquantized.

This is also reported in Intel and Nvidia repo:

• https://github.com/intel/neural-compressor/issues/1963#issuecomment-2274873441
• https://github.com/NVIDIA/TensorRT/issues/4084#issuecomment-2294513950

Tensors to up-quantize

If there is enough bits, down projections should be prioritized.

According to [4]

Fig. 3: Maximum absolute value over layers for a LLaMA3-8B. Each color represent a different projection and we clearly see that down_proj has the biggest spikes in input and output. We also observe that RMSNorm propagate spikes through the entire model

According to [5]

Figure 5(a) illustrates the extremal ratio across layers and modules in LLaMA2-7B, highlighting that weight outliers are concentrated in the down-projection matrices Wdown ℓ of the second layer and the last two layers. Figures 5(b) and 5(c) provide detailed visualizations of these outliers in the last two layers.

Mixture-of-Experts quantization (MoE)

Mixture-of-Experts require specific quantization techniques.

Mixed-precision quantization

Some layers have a higher impact on LLM performance. According to [2], spending more bits in attention layers results in large gain compared to spending them in FFN layers. According to [3] on 2-bit quantization:

• quantizing expert FFN layers do not seriously impact model quality
• quantizing cross-attention has some impact
• quantizing self-attention has a large impact
• quantizing dense FFN has a very significant impact

Hence to preserve model quality we should choose not to quantize dense FFN layers and self-attention layers.

We notice that:

• official MXFP4 weights of gpt-oss-120b from OpenAI keep self-attention in BF16:
  • https://huggingface.co/openai/gpt-oss-120b/blob/main/model.safetensors.index.json
• NVFP4 weights of DeepSeek-R1 quantized by Nvidia also keep self-attention in BF16:
  • https://huggingface.co/nvidia/DeepSeek-R1-0528-FP4/blob/main/model.safetensors.index.json

Layers with high-impact

According to [2], giving more bits to the first k blocks have a significantly higher impact on model quality than for the same last k blocks.

Expert quantization

When quantizing MoE, quantizing activations is tricky as only a subset of experts are activated per request. You have to make sure all experts are calibrated.

<details> <summary>Visual showcase of why ensuring quantization of all MoE experts is important</summary>

• Source: https://avtc.github.io/aquarium-side-by-side/
• Context: https://github.com/ModelCloud/GPTQModel/pull/2235

</details>

References

1. Why Do Some Inputs Break Low-Bit LLM Quantization? (2025)
   Ting-Yun Chang, Muru Zhang, Jesse Thomason, Robin Jia
   https://arxiv.org/pdf/2506.12044

2. Examining Post-Training Quantization for Mixture-of-Experts: A Benchmark (2024)
   Pingzhi Li, Xiaolong Jin, Yu Cheng, Tianlong Chen
   https://arxiv.org/pdf/2406.08155v1

3. Mixture of Quantized Experts (MoQE): Complementary Effect of Low-bit Quantization and Robustness (2023)
   Young Jin Kim, Raffy Fahim, Hany Hassan Awadalla
   https://arxiv.org/pdf/2310.02410

4. Precision Where It Matters: A Novel Spike
   Aware Mixed-Precision Quantization Strategy for
   LLaMA-based Language Models (2025)
   Lucas Maisonnave, Cyril Moineau, Olivier Bichler, and Fabrice Rastello
   https://arxiv.org/pdf/2504.21553

5. Systematic Outliers in Large Language Models (2025)
   Yongqi An, Xu Zhao, Tao Yu, Ming Tang, Jinqiao Wang
   https://arxiv.org/pdf/2502.06415v2

</details>

---

base_model:

• cocorang/FireRed-Image-Edit-1.0-FP8_And_BF16

---

For test

---

tags:

• text-to-image
• lora
• diffusers
• template:diffusion-lora widget:
• output: url: images/pixarfk64_qwen_lineart_020.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_018.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_015.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_016.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_012.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_014.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_013.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_011.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_010.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_009.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_008.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_007.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_005.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_006.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_004.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_003.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_002.png text: '-'
• output: url: images/pixarfk64_qwen_lineart_001.png text: '-'
• output: url: images/1771227928326__000000000_2.jpg text: '-'
• output: url: images/1771227882184__000000000_1.jpg text: '-'
• output: url: images/1771227836023__000000000_0.jpg text: '-' base_model: Qwen/Qwen-Image-2512 instance_prompt: Pixel Art, PixArFK license: apache-2.0

---

PIXEL ART REDMOND FOR QWEN IMAGE

<Gallery />

Model description

Pixart - Pixel Art LoRA

Acknowledgment

I'm grateful for the GPU time from Redmond.AI that allowed me to make this model!

Description

This LoRA specializes in generating authentic pixel art style images with a nostalgic retro gaming aesthetic. Perfect for creating 8-bit and 16-bit inspired artwork, game assets, and vintage-style illustrations.

The model has a high capacity to generate detailed pixel art scenes including fantasy characters, retro game environments, cute pixel art animals, sci-fi spaceships, and magical landscapes. It works great for indie game developers, retro gaming enthusiasts, and anyone looking to create charming pixel art style images.

Trigger words

Use `Pixel Art, PixArFK` to activate the LoRA style.

Usage

I recommend using this LoRA with ComfyUI for the best results.

Load the LoRA into your ComfyUI workflow.

License

This model is licensed under the Apache License 2.0.

---

Support & Links

Support My Work

If you find this model useful, please consider supporting my work:

• Patreon: patreon.com/user?u=81570187
• Ko-fi: ko-fi.com/artificialguybr
• Buy Me a Coffee: buymeacoffee.com/jvkape

Follow Me

• Twitter: @artificialguybr
• Website: artificialguy.com

Acknowledgment

GPU time provided by Redmond.AI

Trigger words

You should use Pixel Art to trigger the image generation.

You should use PixArFK to trigger the image generation.

Download model

Download them in the Files & versions tab.

---

tags:

• text-to-image
• lora
• diffusers
• template:diffusion-lora widget:
• output: url: images/pixarfk64_flux_klein_9b_020.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_018.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_017.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_016.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_015.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_013.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_012.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_011.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_010.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_008.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_007.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_005.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_006.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_003.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_002.png text: '-'
• output: url: images/pixarfk64_flux_klein_9b_001.png text: '-' base_model: black-forest-labs/FLUX.2-klein-9B instance_prompt: Pixel Art, PixArFK license: apache-2.0

---

PIXEL ART REDMOND FOR FLUX KLEIN 9B

<Gallery />

Model description

Pixart - Pixel Art LoRA

Acknowledgment

I'm grateful for the GPU time from Redmond.AI that allowed me to make this model!

Description

This LoRA specializes in generating authentic pixel art style images with a nostalgic retro gaming aesthetic. Perfect for creating 8-bit and 16-bit inspired artwork, game assets, and vintage-style illustrations.

The model has a high capacity to generate detailed pixel art scenes including fantasy characters, retro game environments, cute pixel art animals, sci-fi spaceships, and magical landscapes. It works great for indie game developers, retro gaming enthusiasts, and anyone looking to create charming pixel art style images.

Trigger words

Use `Pixel Art, PixArFK` to activate the LoRA style.

Usage

I recommend using this LoRA with ComfyUI for the best results.

Load the LoRA into your ComfyUI workflow.

License

This model is licensed under the Apache License 2.0.

---

Support & Links

Support My Work

If you find this model useful, please consider supporting my work:

• Patreon: patreon.com/user?u=81570187
• Ko-fi: ko-fi.com/artificialguybr
• Buy Me a Coffee: buymeacoffee.com/jvkape

Follow Me

• Twitter: @artificialguybr
• Website: artificialguy.com

Acknowledgment

GPU time provided by Redmond.AI

Trigger words

You should use Pixel Art to trigger the image generation.

You should use PixArFK to trigger the image generation.

Download model

Download them in the Files & versions tab.

---

license: mit datasets:

• md-nishat-008/Bangla-Instruct language:
• bn base_model:
• mistralai/Mistral-7B-Instruct-v0.2 pipeline_tag: text-generation library_name: transformers

---

---

base_model: Qwen/Qwen3-4B-Instruct-2507 library_name: transformers model_name: qwen3-4b-deforum-prompt-lora-v4 tags:

• generated_from_trainer
• trl
• sft licence: license

---

Model Card for qwen3-4b-deforum-prompt-lora-v4

This model is a fine-tuned version of Qwen/Qwen3-4B-Instruct-2507. It has been trained using TRL.

Quick start

from transformers import pipeline

question = "If you had a time machine, but could only go to the past or the future once and never return, which would you choose and why?"
generator = pipeline("text-generation", model="Limbicnation/qwen3-4b-deforum-prompt-lora-v4", device="cuda")
output = generator([{"role": "user", "content": question}], max_new_tokens=128, return_full_text=False)[0]
print(output["generated_text"])

Training procedure

<img src="https://raw.githubusercontent.com/wandb/assets/main/wandb-github-badge-28.svg" alt="Visualize in Weights & Biases" width="150" height="24"/>

This model was trained with SFT.

Framework versions

• TRL: 0.27.1
• Transformers: 4.57.6
• Pytorch: 2.6.0+cu124
• Datasets: 4.5.0
• Tokenizers: 0.22.2

Citations

Cite TRL as:

@misc{vonwerra2022trl,
	title        = {{TRL: Transformer Reinforcement Learning}},
	author       = {Leandro von Werra and Younes Belkada and Lewis Tunstall and Edward Beeching and Tristan Thrush and Nathan Lambert and Shengyi Huang and Kashif Rasul and Quentin Gallou{\'e}dec},
	year         = 2020,
	journal      = {GitHub repository},
	publisher    = {GitHub},
	howpublished = {\url{https://github.com/huggingface/trl}}
}

---

library_name: transformers license: apache-2.0 language:

• en tags:
• monoid
• causal-lm
• linear-attention
• state-space
• O(1)-inference
• reasoning pipeline_tag: text-generation model-index:
• name: Spartacus-1B-Instruct results: []

---

Spartacus-1B-Instruct — Causal Monoid Language Model

A 1.3B parameter language model that replaces softmax attention with causal monoid state compression, achieving O(1) time per token and O(1) memory at inference — regardless of sequence length.

Fine-tuned for enhanced reasoning with structured chain-of-thought data.

Monoid Attention — Internal Structure

                          MonoidAttention (per layer, per head)
 ┌─────────────────────────────────────────────────────────────────────┐
 │                                                                     │
 │   x_t ∈ R^{2048}                                                   │
 │    │                                                                │
 │    ├──> q_proj ──> RMSNorm ──> q_t ∈ R^{d}     (query)            │
 │    │                                                                │
 │    ├──> k_proj ──> RMSNorm ──> SiLU ──> k_t ∈ R^{d}  (key, >= 0) │
 │    │                                                                │
 │    ├──> v_proj ──> v_t ∈ R^{d}                  (value)            │
 │    │                                                                │
 │    └──> decay_proj ──> sigmoid ──> alpha_t ∈ (0,1)  (decay gate)   │
 │                                                                     │
 │         k_t (x) v_t                                                 │
 │            │            ┌──────────────────────────────┐            │
 │            │            │  State Matrix S_t ∈ R^{d x d} │            │
 │            v            │                              │            │
 │    S_t = alpha_t * S_{t-1} + k_t (x) v_t              │            │
 │            │            │  "Compressed causal history" │            │
 │            │            └──────────────────────────────┘            │
 │            v                                                        │
 │    o_t = q_t . S_t ──> o_proj ──> output                           │
 │                                                                     │
 └─────────────────────────────────────────────────────────────────────┘

Monoid State Diagonal — O(1) Compression Contour

The state matrix S_t accumulates causal history along its diagonal. Each head maintains an independent d x d state that compresses ALL past tokens into a fixed footprint:

   State Matrix S_t ∈ R^{64 x 64}  (one per head, 32 heads per layer)

   k-dim -->
   0   8  16  24  32  40  48  56  63
   ┌───┬───┬───┬───┬───┬───┬───┬───┐  0
   │***│** │*  │   │   │   │   │   │     v-dim
   │***│** │*  │.  │   │   │   │   │      |
   ├───┼───┼───┼───┼───┼───┼───┼───┤  8   |
   │** │***│** │*  │.  │   │   │   │      v
   │*  │***│** │*  │.  │   │   │   │
   ├───┼───┼───┼───┼───┼───┼───┼───┤ 16
   │*  │** │***│** │*  │.  │   │   │
   │.  │*  │***│** │*  │.  │   │   │
   ├───┼───┼───┼───┼───┼───┼───┼───┤ 24
   │   │.  │** │***│** │*  │.  │   │
   │   │   │*  │***│** │*  │.  │   │
   ├───┼───┼───┼───┼───┼───┼───┼───┤ 32
   │   │   │.  │** │***│** │*  │.  │
   │   │   │   │*  │***│** │*  │.  │
   ├───┼───┼───┼───┼───┼───┼───┼───┤ 40
   │   │   │   │.  │** │***│** │*  │
   │   │   │   │   │*  │***│** │*  │
   ├───┼───┼───┼───┼───┼───┼───┼───┤ 48
   │   │   │   │   │.  │** │***│** │
   │   │   │   │   │   │*  │***│** │
   ├───┼───┼───┼───┼───┼───┼───┼───┤ 56
   │   │   │   │   │   │.  │** │***│
   │   │   │   │   │   │   │*  │***│
   └───┴───┴───┴───┴───┴───┴───┴───┘ 63

   Legend:  *** = high activation (recent tokens, alpha^0 ~ alpha^2)
            **  = medium (alpha^3 ~ alpha^5)
            *   = fading (alpha^6 ~ alpha^10)
            .   = near-zero (alpha^11+, effectively forgotten)
                = zero (never reached or fully decayed)

   The diagonal band emerges because S_t = SUM_{i<=t} alpha^{t-i} * k_i (x) v_i.
   Recent outer products dominate near the diagonal; older ones decay
   exponentially via alpha, creating this characteristic contour.

Key Properties

| Property | Transformer (Llama) | Spartacus (Monoid) | |---|---|---| | Inference time per token | O(T) -- scans full KV-cache | O(1) -- single state update | | Inference memory per layer | O(T) -- stores all past K,V | O(1) -- fixed d x d state matrix | | Sequence length extrapolation | Degrades beyond training length | Unlimited -- state size is constant | | Causality | Imposed via attention mask | Built into the recurrence | | Training complexity | O(T^2) | O(T) via parallel prefix scan |

The Monoid Recurrence

Standard attention computes:

o_t = sum_{i<=t} softmax(q_t . k_i) v_i    -- requires O(T) KV-cache

Monoid attention compresses the entire causal history into a fixed-size state matrix S_t per head:

S_t = alpha_t * S_{t-1} + k_t (x) v_t      -- explicit causal recurrence
o_t = q_t . S_t                              -- state readout

where alpha_t = sigmoid(decay_proj(x_t)) is a learned, content-dependent decay gate that controls how fast past information fades.

Explicit Causal Modeling

Unlike Transformers where causality is a constraint imposed by masking, Spartacus makes causality a first-class citizen:

• The decay gate alpha_t explicitly controls per-head information retention at every timestep
• The model learns when to forget rather than encoding where tokens are (no positional encoding needed)
• No attention mask required -- causality is structural, not enforced

Design Choices

• SiLU-activated keys: k = SiLU(k_proj(x)) ensures non-negative keys, making the state matrix S positive semi-definite (PSD). This prevents "feature erasure" where one token's contribution cancels another's
• Log-space decay: Working in log-space log(alpha) avoids numerical underflow when alpha^T -> 0 for long sequences
• Learnable h0: The initial state S_0 = h0 is a learnable parameter (zero-initialized), acting as a compressed "system prompt"

Model Details

| Parameter | Value | |---|---| | Model | NoesisLab/Spartacus-1B-Instruct | | Architecture | MonoidForCausalLM | | Parameters | ~1.34B (tied embeddings) | | Hidden size | 2048 | | Intermediate size (MLP) | 8192 | | Layers | 16 | | Attention heads | 32 | | Head dimension | 64 | | State matrix per head | 64 x 64 = 4096 floats | | Vocabulary | 128,256 (Llama-3.2 tokenizer) | | Precision | bfloat16 |

Benchmarks (0-shot)

| Task | Metric | Value | Stderr | |---|---|---|---| | ARC-Challenge | acc_norm | 0.3063 | ±0.0135 | | ARC-Easy | acc | 0.5518 | ±0.0102 | | HellaSwag | acc_norm | 0.4610 | ±0.0050 | | PIQA | acc_norm | 0.6915 | ±0.0108 | | WinoGrande | acc | 0.5225 | ±0.0140 |

Comparison with ~1B Baselines (acc_norm, 0-shot)

| Task | Spartacus-1B-Instruct | TinyLlama-1.1B | Llama 3.2-1B | Mamba-1.4B | RWKV-6-1.6B | |---|---|---|---|---|---| | ARC-C | 0.3063 | 0.3268 | ~0.359 | 0.284 | ~0.301 | | ARC-E | 0.5518 | 0.5547 | ~0.752 | 0.512 | ~0.530 | | HellaSwag | 0.4610 | 0.4670 | ~0.546 | 0.435 | ~0.450 | | PIQA | 0.6915 | 0.7210 | ~0.740 | 0.655 | ~0.670 | | WinoGrande | 0.5225 | 0.5040 | ~0.592 | 0.510 | ~0.515 |

Spartacus achieves competitive performance with sub-quadratic models (Mamba, RWKV) while maintaining O(1) inference time and memory per token. Scores marked with ~ are approximate community-reported values.

Training

Stage 1: General SFT

• Base weights: Transferred from Llama-3.2-1B-Instruct (embeddings, MLP, norms)
• Data: Capybara + smol-smoltalk (general conversation)
• Training: Full-parameter SFT

Stage 2: Reasoning Enhancement

• Data mix: 60% Qwen3-Short-Reasoning + 20% Capybara + 20% smol-smoltalk
• Steps: 2,000
• Learning rate: 2e-5 (cosine schedule, 50 warmup steps)
• Batch size: 8
• Sequence length: 2,048
• Precision: bfloat16
• Optimizer: AdamW (weight decay 0.01, max grad norm 1.0)

The reasoning data uses structured "Thought + Solution" format to strengthen chain-of-thought capabilities while the general data prevents catastrophic forgetting.

Parallel Scan Implementation

The monoid_scan_cuda.py module provides a Triton JIT-compiled parallel prefix scan:

• Forward: Sequential scan along T, parallelized across B x H x D on GPU via Triton kernels
• Backward: Reverse-order adjoint scan computes gradients for both values and log-decay gates
• Fallback: Pure PyTorch sequential scan for CPU/MPS
• Auto-dispatch: CUDA -> Triton kernel, otherwise -> PyTorch fallback

Usage

from transformers import AutoModelForCausalLM, AutoTokenizer

model = AutoModelForCausalLM.from_pretrained(
    "NoesisLab/Spartacus-1B-Instruct",
    trust_remote_code=True,
    torch_dtype="bfloat16",
    device_map="auto",
)
tokenizer = AutoTokenizer.from_pretrained("NoesisLab/Spartacus-1B-Instruct")

messages = [{"role": "user", "content": "Hello!"}]
text = tokenizer.apply_chat_template(messages, tokenize=False, add_generation_prompt=True)
inputs = tokenizer(text, return_tensors="pt").to(model.device)

outputs = model.generate(**inputs, max_new_tokens=512)
print(tokenizer.decode(outputs[0], skip_special_tokens=True))

File Structure

MonoidForCausalLM.py       # Model architecture (MonoidConfig, MonoidAttention, MonoidForCausalLM)
monoid_scan_cuda.py        # Triton JIT parallel prefix scan + PyTorch fallback
model.safetensors          # Model weights (bfloat16)
config.json                # Model configuration
tokenizer.json             # Llama-3.2 tokenizer

Citation

@software{spartacus2025,
  title={Spartacus: Causal Monoid Language Model with O(1) Inference},
  author={NoesisLab},
  year={2025},
  url={https://huggingface.co/NoesisLab/Spartacus-1B-Instruct},
  description={Replaces softmax attention with monoid state compression for constant-time, constant-memory autoregressive generation}
}

License

Apache 2.0