AI Developments: New Models Enhance Image Generation and Reasoning, Research Focuses on Efficient Learning

Here's a look at the latest AI models and research papers:

Research Papers:

Several interesting research papers have emerged, focusing on improving the efficiency and capabilities of AI in various domains:

EfficientFlow: This paper introduces a new framework for embodied AI that uses flow-based policy learning. It enhances data efficiency by incorporating equivariance into flow matching and accelerates sampling with a novel regularization strategy.
Diffusion Model Framework for Maximum Entropy Reinforcement Learning: This paper reinterprets Maximum Entropy Reinforcement Learning (MaxEntRL) as a diffusion model-based sampling problem, leading to improved returns and higher sample efficiency compared to existing methods.
Visual Sync: This paper presents an optimization framework for multi-camera synchronization, aligning unsynchronized videos with millisecond accuracy by minimizing epipolar error based on cross-view object motion.
Learning Sim-to-Real Humanoid Locomotion in 15 Minutes: This paper introduces a recipe based on off-policy RL algorithms that enables rapid training of humanoid locomotion policies in just 15 minutes.
RoaD: Rollouts as Demonstrations for Closed-Loop Supervised Fine-Tuning of Autonomous Driving Policies: This paper introduces a method to mitigate covariate shift in autonomous driving policies by leveraging the policy's own closed-loop rollouts as additional training data.
LLM CHESS: Benchmarking Reasoning and Instruction-Following in LLMs through Chess: This paper introduces an evaluation framework designed to probe the generalization of reasoning and instruction-following abilities in large language models (LLMs) through extended agentic interaction in the domain of chess.
Forecasting in Offline Reinforcement Learning for Non-stationary Environments: This paper introduces a framework that unifies conditional diffusion-based candidate state generation and zero-shot time-series foundation models to improve performance in non-stationary environments.
Chain-of-Ground: Improving GUI Grounding via Iterative Reasoning and Reference Feedback: This paper presents a training free multi step grounding framework that uses multimodal large language models for iterative visual reasoning and refinement.
AI-Driven Optimization under Uncertainty for Mineral Processing Operations: This paper introduces an AI-driven approach that formulates mineral processing as a Partially Observable Markov Decision Process (POMDP) to optimize mineral processing circuits under uncertainty.
From Atomic to Composite: Reinforcement Learning Enables Generalization in Complementary Reasoning: This paper investigates how RL contributes to reasoning capabilities through the lens of Complementary Reasoning.

Models:

Several new AI models have been released, showcasing advancements in image generation, instruction following, and reasoning:

alibaba-pai/Z-Image-Turbo-Fun-Controlnet-Union: This ControlNet model, trained from scratch on a large dataset of high-quality images, supports multiple control conditions like Canny, HED, Depth, and Pose. It allows for adjusting control context scale for stronger control and detail preservation. Likes: 128
apple/CLaRa-7B-Instruct: This instruction-tuned model with built-in semantic document compression supports instruction-following QA directly from compressed document representations. It demonstrates strong instruction-following performance under 16x compression. Likes: 35
unsloth/Ministral-3-14B-Instruct-2512-GGUF: This model offers capabilities and performance comparable to larger models. It supports vision, multilingual capabilities, system prompts, agentic capabilities, and is optimized for edge deployment. It achieves strong performance in reasoning and instruction-following benchmarks. Likes: 11

Key Takeaways:

Efficiency is a major focus: Research is heavily geared towards improving the efficiency of AI models, both in terms of data requirements and computational resources.
Reinforcement learning advancements: Several papers explore new techniques in reinforcement learning, particularly for robotics and autonomous systems, with a focus on handling uncertainty and non-stationary environments.
Multimodal models are gaining traction: Models like Ministral-3-14B-Instruct-2512 demonstrate the increasing capabilities of multimodal models that can process both text and images, opening up new possibilities for AI applications.
Reasoning and instruction following remain challenging: While progress is being made, benchmarks like LLM CHESS highlight the ongoing challenges in achieving robust reasoning and instruction-following abilities in large language models.

deepgenteam/DeepGen-1.0

license: apache-2.0 datasets:

Alex11556666/Reason_Tuning base_model:
Qwen/Qwen2.5-VL-3B-Instruct pipeline_tag: image-to-image

💡 DeepGen 1.0: A Lightweight Unified Multimodal Model for Advancing Image Generation and Editing

<a href="http://arxiv.org/abs/2602.12205"> <img src="https://img.shields.io/badge/DeepGen 1.0-Paper-red?logo=arxiv&logoColor=red" style="display: inline-block; vertical-align: middle;" alt="DeepGen 1.0 Paper on arXiv" /> </a> <a href="https://github.com/deepgenteam/deepgen" target="_blank" style="margin: 2px;"> <img alt="Github" src="https://img.shields.io/badge/DeepGen 1.0-Codebase-536af5?color=536af5&logo=github" style="display: inline-block; vertical-align: middle;" alt="DeepGen 1.0 Codebase" /> </a> <a href="https://deepgenteam.github.io/" target="_blank" style="margin: 2px;"> <img alt="Github" src="https://img.shields.io/badge/Website-project page-orange" style="display: inline-block; vertical-align: middle;" alt="DeepGen 1.0 page" /> </a> DeepGen 1.0 is a lightweight unified multimodal model with only 5B parameters (3B VLM + 2B DiT). It integrates five core capabilities—general image generation, general image editing, reasoning image generation, reasoning image editing, and text rendering—within a single model. Across multiple authoritative benchmarks, DeepGen 1.0 is competitive with competitive with or surpassing the state-of-the-art unified multimodal models that are 3× to 16× larger, achieving comprehensive performance, demonstrating that massive scaling is not the sole path to high-performance multimodal generation. <img src="bubble_chart.png" width="80%">

🧠 Method

Our core observation is that a lightweight model, when empowered by synergistic architecture design and data-centric training strategies, can achieve comprehensive capabilities competitive with or even surpassing much larger counterparts. To overcome the limitations of lightweight models in semantic understanding and fine-grained control, we introduce Stacked Channel Bridging (SCB), a deep alignment framework that extracts hierarchical features from multiple VLM layers and fuses them with learnable ``think tokens'' to provide the generative backbone with structured, reasoning-rich guidance. We further design a data-centric training strategy spanning three progressive stages: (1) Alignment Pre-training on large-scale image-text pairs and editing triplets to synchronize VLM and DiT representations, (2) Joint Supervised Fine-tuning on a high-quality mixture of generation, editing, and reasoning tasks to foster omni-capabilities, and (3) Reinforcement Learning with MR-GRPO, which leverages a mixture of reward functions and supervision signals, resulting in substantial gains in generation quality and alignment with human preferences, while maintaining stable training progress and avoiding visual artifacts.

📊 Benchmarks

1. General Image Generation

| Model | Params | Geneval ↑ | DPGBench ↑ | UniGenBench ↑ | | --------------------- | ----------- | ----------- | ------------ | ------------- | | OmniGen2 | 3B + 4B | 0.80 | 83.57 | 63.09 | | BAGEL | 14B | 0.82 | 85.10 | 61.53 | | X-Omni | 7B + 12B | 0.83 | 87.65🥉 | 53.77 | | Lumina-DiMOO | 8B | 0.88🥇 | 86.04 | 71.12 | | Hunyuan-Image-3.0 | 80B | 0.72 | 86.10 | — | | Qwen-Image | 7B + 20B | 0.87 🥈 | 88.32 🥇 | 78.81 🥇 | | LongCat-Image | 7B + 6B | 0.87 🥈 | 86.80 | — | | Z-Image-Turbo | 4B + 6B | 0.84 | 85.15 | 71.40 | | GLM-Image | 9B + 7B | — | 84.78 | — | | DeepGen 1.0 (SFT) | 3B + 2B | 0.86 🥉 | 87.05 | 74.18 🥉 | | DeepGen 1.0 (RL) | 3B + 2B | 0.87 🥈 | 87.90 🥈 | 75.74 🥈 |

2. General Image Editing

| Model | Params | GEdit-EN ↑ | ImgEdit ↑ | | :--- | :--- | :--- | :--- | | BAGEL | 14B | 6.52 | 3.20 | | Qwen-Image-Edit [2509] | 7B + 20B | 7.54 🥈 | 4.35 🥈 | | LongCat-Image-Edit | 7B + 6B | 7.60 🥇 | 4.50 🥇 | | Mammoth2 | 8B + 3B + 2B | 6.60 | 4.06 | | DeepGen 1.0 (SFT) | 3B + 2B | 7.12 | 4.09 | | DeepGen 1.0 (RL) | 3B + 2B | 7.17 🥉 | 4.14 🥉 |

3. Reasoning Image Generation

| Model | Params | WISE ↑ | T2I-CoREBench ↑ | | :--- | :--- | :--- | :--- | | OmniGen2 | 3B + 4B | 0.47 | 36.1 | | BAGEL | 14B | 0.70 🥉 | 41.1 | | Hunyuan-Image-3.0 | 80B | 0.57 | 46.0 | | Qwen-Image | 7B + 20B | 0.62 | 46.3 🥉 | | LongCat-Image | 7B + 6B | 0.65 | 52.2 🥇 | | Z-Image-Turbo | 4B + 6B | - | 43.7 | | DeepGen 1.0 (SFT) | 3B + 2B | 0.72 🥈 | 45.7 | | DeepGen 1.0 (RL) | 3B + 2B | 0.73 🥇 | 46.5 🥈 |

4. Reasoning Image Editing

| Model | Params | RISE ↑ | UniREditBench ↑ | | :--- | :--- | :--- | :--- | | OmniGen2 | 3B + 4B | - | 43.4 | | BAGEL | 14B | 11.9 🥈 | 51.0 | | Qwen-Image-Edit [2509] | 7B + 20B | 8.9 | 56.5 🥉 | | DeepGen 1.0 (SFT) | 3B + 2B | 13.3 🥇 | 77.5 🥇 | | DeepGen 1.0 (RL) | 3B + 2B | 10.8 🥉 | 75.7 🥈 |

🎨 Quantitative results

🛠️ Usage

Merge ZIP Files

To use the DeepGen checkpoints, please merge the sharded model files first. We release Pre-traning, Supervised Fine-Tuning and Reinforcement Learning checkpoints.

# Merge zip
cat DeepGen_CKPT.zip.part-* > DeepGen_CKPT.zip
# Unzip DeepGen checkpoints 
unzip DeepGen_CKPT.zip

Author: deepgenteam

Likes: 22

Downloads: 0

Tags: image-to-image, dataset:Alex11556666/Reason_Tuning, arxiv:2602.12205, base_model:Qwen/Qwen2.5-VL-3B-Instruct, base_model:finetune:Qwen/Qwen2.5-VL-3B-Instruct, license:apache-2.0, region:us

ubergarm/MiniMax-M2.5-GGUF

quantized_by: ubergarm pipeline_tag: text-generation base_model: MiniMaxAI/MiniMax-M2.5 base_model_relation: quantized license_name: modified-mit license_link: https://github.com/MiniMax-AI/MiniMax-M2.5/blob/main/LICENSE tags:

imatrix
conversational
minimax_m2
ik_llama.cpp

`ik_llama.cpp` imatrix Quantizations of MiniMaxAI/MiniMax-M2.5

NOTE ik_llama.cpp can also run your existing GGUFs from bartowski, unsloth, mradermacher, etc if you want to try it out before downloading my quants.

Some of ik's new quants are supported with Nexesenex/croco.cpp fork of KoboldCPP with Windows builds for CUDA 12.9. Also check for Windows builds by Thireus here. which have been CUDA 12.8.

These quants provide best in class perplexity for the given memory footprint.

Big Thanks

Shout out to Wendell and the Level1Techs crew, the community Forums, YouTube Channel! BIG thanks for providing BIG hardware expertise and access to run these experiments and make these great quants available to the community!!!

Also thanks to all the folks in the quanting and inferencing community on BeaverAI Club Discord and on r/LocalLLaMA for tips and tricks helping each other run, test, and benchmark all the fun new models! Thanks to huggingface for hosting all these big quants!

Finally, I really appreciate the support from aifoundry.org so check out their open source RISC-V based solutions!

Quant Collection

Perplexity computed against wiki.test.raw. (lower is "better")

Perplexity Chart

These two are just a test quants for baseline perplexity comparison and not available for download here:

BF16 426.060 GiB (16.003 BPW)
- PPL over 552 chunks for n_ctx=512 = 8.3386 +/- 0.06651
Q8_0 226.431 GiB (8.505 BPW)
- PPL over 552 chunks for n_ctx=512 = 8.3590 +/- 0.06673

NOTE: The first split file is much smaller on purpose to only contain metadata, its fine!

IQ5_K 157.771 GiB (5.926 BPW)

PPL over 552 chunks for n_ctx=512 = 8.4860 +/- 0.06815

<details> <summary>👈 Secret Recipe</summary>

custom="
# 61 Repeating Layers [0-61]

# Attention [0-61] GPU
blk\..*\.attn_q.*=q8_0
blk\..*\.attn_k.*=q8_0
blk\..*\.attn_v.*=q8_0
blk\..*\.attn_output.*=q8_0

# Routed Experts Layers [0-61] CPU
blk\..*\.ffn_down_exps\.weight=iq6_k
blk\..*\.ffn_(gate|up)_exps\.weight=iq5_k

# Non-Repeating Layers
token_embd\.weight=q8_0
output\.weight=q8_0
"

custom=$(
  echo "$custom" | grep -v '^#' | \
  sed -Ez 's:\n+:,:g;s:,$::;s:^,::'
)

numactl -N ${SOCKET} -m ${SOCKET} \
./build/bin/llama-quantize \
    --custom-q "$custom" \
    --imatrix /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/imatrix-MiniMax-M2.5-BF16.dat \
    /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/MiniMax-M2.5-256x4.9B-BF16-00001-of-00010.gguf \
    /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/MiniMax-M2.5-IQ5_K.gguf \
    IQ5_K \
    128

</details>

IQ4_XS 114.842 GiB (4.314 BPW)

PPL over 552 chunks for n_ctx=512 = 8.5702 +/- 0.06901

This is the only quant in this collection that is compatible with mainline llama.cpp. ik_llama.cpp can run all of them.

<details> <summary>👈 Secret Recipe</summary>

#!/usr/bin/env bash

custom="
# 61 Repeating Layers [0-61]

# Attention [0-61] GPU
blk\..*\.attn_q.*=q8_0
blk\..*\.attn_k.*=q8_0
blk\..*\.attn_v.*=q8_0
blk\..*\.attn_output.*=q8_0

# Routed Experts Layers [0-61] CPU
blk\..*\.ffn_down_exps\.weight=iq4_xs
blk\..*\.ffn_(gate|up)_exps\.weight=iq4_xs

# Non-Repeating Layers
token_embd\.weight=q4_K
output\.weight=q6_K
"

custom=$(
  echo "$custom" | grep -v '^#' | \
  sed -Ez 's:\n+:,:g;s:,$::;s:^,::'
)

numactl -N ${SOCKET} -m ${SOCKET} \
./build/bin/llama-quantize \
    --custom-q "$custom" \
    --imatrix /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/imatrix-MiniMax-M2.5-BF16.dat \
    /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/MiniMax-M2.5-256x4.9B-BF16-00001-of-00010.gguf \
    /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/MiniMax-M2.5-IQ4_XS.gguf \
    IQ4_XS \
    128

</details>

smol-IQ3_KS 87.237 GiB (3.277 BPW)

PPL over 552 chunks for n_ctx=512 = 8.7539 +/- 0.07075

<details> <summary>👈 Secret Recipe</summary>

#!/usr/bin/env bash

custom="
# 61 Repeating Layers [0-61]

# Attention [0-61] GPU
blk\..*\.attn_q.*=q8_0
blk\..*\.attn_k.*=q8_0
blk\..*\.attn_v.*=q8_0
blk\..*\.attn_output.*=q8_0

# Routed Experts Layers [0-61] CPU
blk\..*\.ffn_down_exps\.weight=iq3_ks
blk\..*\.ffn_(gate|up)_exps\.weight=iq3_ks

# Non-Repeating Layers
token_embd\.weight=iq4_k
output\.weight=iq6_k
"

custom=$(
  echo "$custom" | grep -v '^#' | \
  sed -Ez 's:\n+:,:g;s:,$::;s:^,::'
)

numactl -N ${SOCKET} -m ${SOCKET} \
./build/bin/llama-quantize \
    --custom-q "$custom" \
    --imatrix /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/imatrix-MiniMax-M2.5-BF16.dat \
    /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/MiniMax-M2.5-256x4.9B-BF16-00001-of-00010.gguf \
    /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/MiniMax-M2.5-smol-IQ3_KS.gguf \
    IQ3_KS \
    128

</details>

IQ2_KS 69.800 GiB (2.622 BPW)

PPL over 552 chunks for n_ctx=512 = 9.6827 +/- 0.07972

<details> <summary>👈 Secret Recipe</summary>

#!/usr/bin/env bash

custom="
# 61 Repeating Layers [0-61]

# Attention [0-61] GPU
blk\..*\.attn_q.*=q8_0
blk\..*\.attn_k.*=q8_0
blk\..*\.attn_v.*=q8_0
blk\..*\.attn_output.*=q8_0

# Routed Experts Layers [0-61] CPU
blk\..*\.ffn_down_exps\.weight=iq3_ks
blk\..*\.ffn_(gate|up)_exps\.weight=iq2_ks

# Non-Repeating Layers
token_embd\.weight=iq4_k
output\.weight=iq6_k
"

custom=$(
  echo "$custom" | grep -v '^#' | \
  sed -Ez 's:\n+:,:g;s:,$::;s:^,::'
)

numactl -N ${SOCKET} -m ${SOCKET} \
./build/bin/llama-quantize \
    --custom-q "$custom" \
    --imatrix /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/imatrix-MiniMax-M2.5-BF16.dat \
    /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/MiniMax-M2.5-256x4.9B-BF16-00001-of-00010.gguf \
    /mnt/data/models/ubergarm/MiniMax-M2.5-GGUF/MiniMax-M2.5-IQ2_KS.gguf \
    IQ2_KS \
    128

</details>

Quick Start

# Clone and checkout
$ git clone https://github.com/ikawrakow/ik_llama.cpp
$ cd ik_llama.cpp

# Build for hybrid CPU+CUDA
$ cmake -B build -DCMAKE_BUILD_TYPE=Release -DGGML_CUDA=ON
$ cmake --build build --config Release -j $(nproc)

# Hybrid CPU and Single GPU
echo TODO or look at my Step-3.5-Flash for rough example for now using --cpu-moe or --n-cpu-moe XX etc

# Hybrid CPU and Multi GPU 128k context full offload in 96GB VRAM
model=MiniMax-M2.5-IQ2_KS-00001-of-00003.gguf
_GLIBCXX_REGEX_STATE_LIMIT=1000000 \
CUDA_VISIBLE_DEVICES="0,1" \
./build/bin/llama-sweep-bench \
    --model "$model" \
    --alias ubergarm/MiniMax-M2.5 \
    -khad -ctk q6_0 -ctv q8_0 \
    -c 131072 \
    -ger \
    -sm graph \
    -ngl 99 \
    -ub 4096 -b 4096 \
    -ts 47,48 \
    --threads 1 \
    --host 127.0.0.1 \
    --port 8080 \
    --no-mmap \
    --jinja

# CPU-Only
numactl -N "$SOCKET" -m "$SOCKET" \
./build/bin/llama-server \
    --model "$model"\
    --alias ubergarm/MiniMax-M2.5 \
    --ctx-size 65536 \
    -ger \
    --merge-qkv \
    -ctk q8_0 -ctv q8_0 \
    -ub 4096 -b 4096 \
    --parallel 1 \
    --threads 96 \
    --threads-batch 128 \
    --numa numactl \
    --host 127.0.0.1 \
    --port 8080 \
    --no-mmap \
    --jinja

My own early testing with opencode suggests that even the smol-IQ3_KS is working okay with tool calling etc!

For tool use you can always bring your own template with --chat-template-file myTemplate.jinja and might need --special etc.

References

Author: ubergarm

Likes: 14

Downloads: 0

Tags: gguf, imatrix, conversational, minimax_m2, ik_llama.cpp, text-generation, base_model:MiniMaxAI/MiniMax-M2.5, base_model:quantized:MiniMaxAI/MiniMax-M2.5, endpoints_compatible, region:us

ox-ox/MiniMax-M2.5-GGUF

license: mit base_model: MiniMaxAI/MiniMax-M2.5 tags:

gguf
moe
minimax
llama.cpp
applesilicon
reasoning
conversational model_creator: MiniMaxAI pipeline_tag: text-generation

MiniMax-M2.5-GGUF (230B MoE)

High-precision GGUF quants of the MiniMax-M2.5 (230B parameters) Mixture of Experts model. These versions are specifically optimized for local inference on high-RAM setups, particularly Apple Silicon (M3 Max/Ultra).

🔬 Perplexity Validation (WikiText-2):

Final PPL: 8.2213 +/- 0.09

Context: 4096 / 32 chunks

Outcome: The Q3_K_L quantization maintains high logical coherence while boosting speed to 28.7 t/s. Minimal degradation for a ~20GB size reduction vs Q4.

🚀 Available Quants

| File Name | Method | Size | Use Case | | :--- | :--- | :--- | :--- | | minimax-m2.5-Q4_K_M.gguf | Q4_K_M | 138 GB | Highest logic preservation. Requires >128GB RAM or SSD swap. | | minimax-m2.5-Q3_K_L.gguf | Q3_K_L | ~110 GB | Sweet spot for 128GB Macs. Runs natively in RAM with high t/s ( 28 ON MAC M3 MAX ). |

🛠 Model Details

Architecture: MiniMax-M2 (Mixture of Experts) with 256 experts (8 active per token).
Parameters: ~230B total.
Quantization Process: Unlike automated scripts, these quants were generated from a full F16 GGUF Master (457GB) to minimize accumulation of errors during the K-Quant process.
Context Window: Up to 196k tokens (Native support).
Chat Template: Includes the official Jinja template for proper handling of interleaved <think> tags, separating reasoning from the final response.

💻 Usage

Requires llama.cpp build 8022 or higher.

Command Line Example:

./llama-cli -m minimax-m2.5-Q3_K_L.gguf -n -1 \\
  -c 262000 \\
  -ngl 99 -fa on -ctk q4_0 -ctv q4_0 -b 2048 -ub 1024 --port 8080 --jinja --verbose -sm none --draft 16 -ncmoe 0 --cache-reuse 1024 --draft-p-min 0.5

Author: ox-ox

Likes: 9

Downloads: 0

Tags: gguf, moe, minimax, llama.cpp, applesilicon, reasoning, conversational, text-generation, base_model:MiniMaxAI/MiniMax-M2.5, base_model:quantized:MiniMaxAI/MiniMax-M2.5, license:mit, endpoints_compatible, region:us

DevQuasar/MiniMaxAI.MiniMax-M2.5-GGUF

base_model:

MiniMaxAI/MiniMax-M2.5 pipeline_tag: text-generation

'Make knowledge free for everyone'

Quantized version of: MiniMaxAI/MiniMax-M2.5 <a href='https://ko-fi.com/L4L416YX7C' target='_blank'><img height='36' style='border:0px;height:36px;' src='https://storage.ko-fi.com/cdn/kofi6.png?v=6' border='0' alt='Buy Me a Coffee at ko-fi.com' /></a>

Author: DevQuasar

Likes: 5

Downloads: 0

Tags: gguf, text-generation, base_model:MiniMaxAI/MiniMax-M2.5, base_model:quantized:MiniMaxAI/MiniMax-M2.5, endpoints_compatible, region:us, conversational

OccultAI/Morpheus-8B-v1

license: apache-2.0 base_model:

SicariusSicariiStuff/Llama-3.1-Nemotron-8B-UltraLong-1M-Instruct_Abliterated tags:
finetune
llama
occult
uncensored datasets:
OccultAI/Morpheus_665 language:
en library_name: transformers widget:
- text: "Morpheus 8B v1" output: url: https://cdn-uploads.huggingface.co/production/uploads/68e840caa318194c44ec2a04/dZ-Q05tEZVM-W3nFIab6U.png

[!CAUTION] ⚠️ Warning: This model can produce narratives and RP that contain violent and graphic erotic content. Adjust your system prompt accordingly, and use Llama 3 chat template.

Morpheus 8B v1

Recommended Settings: Temp 1.0, TopNSigma 1.25

Morpheus

{'loss': 0.5651, 'grad_norm': 3.787045478820801, 'learning_rate': 1.0386570913148586e-05, 'entropy': 0.7085917145013809, 'num_tokens': 588832.0, 'mean_token_accuracy': 0.8508399426937103, 'epoch': 4.0}

| Model | Q0 Score | Quant | Q0G | Refusals | | :--- | :--- | :--- | :--- | :--- | | Morpheus 8B v1 | 15365 | Q6_K | Pass | 0/100 |

Author: OccultAI

Likes: 4

Downloads: 0

Tags: transformers, safetensors, llama, text-generation, finetune, occult, uncensored, conversational, en, dataset:OccultAI/Morpheus_665, base_model:SicariusSicariiStuff/Llama-3.1-Nemotron-8B-UltraLong-1M-Instruct_Abliterated, base_model:finetune:SicariusSicariiStuff/Llama-3.1-Nemotron-8B-UltraLong-1M-Instruct_Abliterated, license:apache-2.0, text-generation-inference, endpoints_compatible, region:us

mlx-community/MiniMax-M2.5-3bit

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: mlx base_model: MiniMaxAI/MiniMax-M2.5 tags:

mlx-community/MiniMax-M2.5-3bit

This model mlx-community/MiniMax-M2.5-3bit was converted to MLX format from MiniMaxAI/MiniMax-M2.5 using mlx-lm version 0.30.7.

Use with mlx

pip install mlx-lm

from mlx_lm import load, generate

model, tokenizer = load("mlx-community/MiniMax-M2.5-3bit")

prompt = "hello"

if tokenizer.chat_template is not None:
    messages = [{"role": "user", "content": prompt}]
    prompt = tokenizer.apply_chat_template(
        messages, add_generation_prompt=True, return_dict=False,
    )

response = generate(model, tokenizer, prompt=prompt, verbose=True)

Author: mlx-community

Likes: 3

Downloads: 0

Tags: mlx, safetensors, minimax_m2, text-generation, conversational, custom_code, base_model:MiniMaxAI/MiniMax-M2.5, base_model:quantized:MiniMaxAI/MiniMax-M2.5, license:other, 3-bit, region:us

HeartMuLa/HeartMuLa-oss-3B-happy-new-year

license: apache-2.0 language:

zh
en
ja
ko
es pipeline_tag: text-to-audio tags:
music
art

Model Details

The best open-sourced music generation model in terms of lyrics controllability and music quality.

Model Description

Developed by: [HeartMuLa Team]
License: [Apache 2.0]

Get Started

Check our github repo https://github.com/HeartMuLa/heartlib for a quickstart and local deployment of HeartMuLa.

Citation

If you find HeartMuLa useful, please cite:

@misc{yang2026heartmulafamilyopensourced,
      title={HeartMuLa: A Family of Open Sourced Music Foundation Models}, 
      author={Dongchao Yang and Yuxin Xie and Yuguo Yin and Zheyu Wang and Xiaoyu Yi and Gongxi Zhu and Xiaolong Weng and Zihan Xiong and Yingzhe Ma and Dading Cong and Jingliang Liu and Zihang Huang and Jinghan Ru and Rongjie Huang and Haoran Wan and Peixu Wang and Kuoxi Yu and Helin Wang and Liming Liang and Xianwei Zhuang and Yuanyuan Wang and Haohan Guo and Junjie Cao and Zeqian Ju and Songxiang Liu and Yuewen Cao and Heming Weng and Yuexian Zou},
      year={2026},
      eprint={2601.10547},
      archivePrefix={arXiv},
      primaryClass={cs.SD},
      url={https://arxiv.org/abs/2601.10547}, 
}

Contact

If you are interested in HeartMuLa, feel free to reach us at heartmula.ai@gmail.com

Author: HeartMuLa

Likes: 3

Downloads: 0

Tags: safetensors, heartmula, music, art, text-to-audio, zh, en, ja, ko, es, arxiv:2601.10547, license:apache-2.0, region:us

DarkArtsForge/Raven-8B-v1

license: apache-2.0 base_model:

SicariusSicariiStuff/Llama-3.1-Nemotron-8B-UltraLong-1M-Instruct_Abliterated tags:
finetune
llama
raven
poe
gothic
horror
creative writing
RP datasets:
DarkArtsForge/Poe_v1 language:
en library_name: transformers widget:
- text: "Raven 8B v1" output: url: https://cdn-uploads.huggingface.co/production/uploads/68e840caa318194c44ec2a04/gPKk1RgcW0QN0NAVpf4lh.jpeg

[!CAUTION] ⚠️ Warning: This model can produce narratives and RP that contain violent and graphic erotic content. Adjust your system prompt accordingly, and use Llama 3 chat template.

Raven 8B v1

A fully uncensored finetune of Llama-3.1-Nemotron-8B trained on a small dataset of Edgar Allan Poe corpus. Cooked for 5 epochs using PMPF.

{'loss': 0.1136, 'grad_norm': 1.0182174444198608, 'learning_rate': 1.685173482438018e-08, 'entropy': 0.18156841583549976, 'num_tokens': 99475.0, 'mean_token_accuracy': 0.9738506525754929, 'epoch': 5.0}
{'train_runtime': 590.173, 'train_samples_per_second': 0.847, 'train_steps_per_second': 0.212, 'train_loss': 1.036527609705925, 'epoch': 5.0}

raven11

Author: DarkArtsForge

Likes: 3

Downloads: 0

Tags: transformers, safetensors, llama, text-generation, finetune, raven, poe, gothic, horror, creative writing, RP, conversational, en, dataset:DarkArtsForge/Poe_v1, base_model:SicariusSicariiStuff/Llama-3.1-Nemotron-8B-UltraLong-1M-Instruct_Abliterated, base_model:finetune:SicariusSicariiStuff/Llama-3.1-Nemotron-8B-UltraLong-1M-Instruct_Abliterated, license:apache-2.0, text-generation-inference, endpoints_compatible, region:us

acvlab/FantasyWorld-Wan2.1-I2V-14B-480P

license: apache-2.0 language:

en
zh base_model:
Wan-AI/Wan2.1-I2V-14B-480P pipeline_tag: image-to-video tags:
wan
world_model

FantasyWorld: Geometry-Consistent World Modeling via Unified Video and 3D Prediction

🔥🔥🔥 Latest News

👋 Feb, 2026: We release the code and model weights of FantasyWorld.
🏛 Jan, 2026: FantasyWorld is accepted by ICLR 2026.
🎉 Dec, 2025: FantasyWorld ranked 1st on the WorldScore Leaderboard (by Stanford Prof. Fei-Fei Li's Team), validating our approach against global state-of-the-art models.

🌟 Overview

Overview

FantasyWorld is a unified feed-forward model for joint video and 3D scene generation. The front end employs Preconditioning Blocks (PCBs) that reuse the frozen WanDiT denoiser to supply partially denoised latents, ensuring the geometry pathway operates on meaningful features rather than pure noise. The backbone then consists of stacked Integrated Reconstruction and Generation (IRG) Blocks, which iteratively refine video latents and geometry features under multimodal conditioning. Each IRG block contains an asymmetric dual-branch structure: an Imagination Prior Branch for appearance synthesis and a Geometry-Consistent Branch for explicit 3D reasoning, coupled through lightweight adapters and cross attention.

🚀 Training Strategy

FantasyWorld leverages a robust two-stage training strategy to achieve jointly video and 3D generation:

Stage 1 (Geometry Pre-training): Utilizes a VGGT-style model for precise estimation of depth, point, and camera trajectories.
Stage 2 (Joint Generation): A unified model that seamlessly integrates the Stage 1 geometry backbone with the Wan video generation pipeline.

📦 Model Zoo

We provide two versions of the model to cater to different research and application needs:

| Model Name | Description | | :--- | :--- | | FantasyWorld-Wan2.1-I2V-14B-480P | Reproducibility Focus: Strictly adheres to the original configurations detailed in our paper. Best for academic benchmarking and reproducing reported results. | | FantasyWorld-Wan2.2-Fun-A14B-Control-Camera | Performance Focus: Offers substantial enhancements, including an upgraded video foundation model, larger-scale training datasets, and higher output resolution. |

🚀 Quickstart

Installation

Clone the repository

git clone https://github.com/Fantasy-AMAP/fantasy-world.git
cd fantasy-world

Install dependencies

conda create -n fantasyworld python=3.10
conda activate fantasyworld
pip install -r requirements.txt
pip install thirdparty/utils3d/

1. FantasyWorld-Wan2.1-I2V-14B-480P

1.1 Model Download

| Models | Download Link | Notes | | --------------|-------------------------------------------------------------------------------|-------------------------------| | Wan2.1-I2V-14B-480P | 🤗 Huggingface 🤖 ModelScope | Base Model | FantasyWorld-Wan2.1-I2V-14B-480P | 🤗 Huggingface 🤖 ModelScope | FantasyWorld

Download models using huggingface:

pip install -U "huggingface_hub"
hf download "Wan-AI/Wan2.1-I2V-14B-480P" --local-dir ./models/Wan-AI/Wan2.1-I2V-14B-480P
hf download "acvlab/FantasyWorld-Wan2.1-I2V-14B-480P" --local-dir ./models/FantasyWorld-Wan2.1-I2V-14B-480P/

Download models using modelscope:

pip install -U modelscope
modelscope download "Wan-AI/Wan2.1-I2V-14B-480P" --local_dir ./models/Wan-AI/Wan2.1-I2V-14B-480P
modelscope download "amap_cvlab/FantasyWorld-Wan2.1-I2V-14B-480P" --local_dir ./models/FantasyWorld-Wan2.1-I2V-14B-480P/

1.2 Inference Command

python inference_wan21.py \
    --wan_ckpt_path ./models/Wan-AI/Wan2.1-I2V-14B-480P \
    --model_ckpt ./models/FantasyWorld-Wan2.1-I2V-14B-480P/model.pth \
    --image_path ./examples/images/input_image.png \
    --camera_json_path ./examples/cameras/camera_data.json \
    --prompt "In the Open Loft Living Room, sunlight streams through large windows, highlighting the sleek fireplace and elegant wooden stairs." \
    --output_dir ./output-wan21 \
    --sample_steps 50 \
    --using_scale True

Parameter Description:

--wan_ckpt_path - Required: Directory containing the Wan model checkpoints
--model_ckpt - Required: Path to the trained model checkpoint
--image_path - Required: Path to the input image
--camera_json_path - Required: Camera json path
--prompt - Required: Text prompt
--output_dir - Optional: Output directory
--sample_steps - Optional: Number of sampling steps (default: 50)
--using_scale - Optional: Whether to use scale normalization (default: True)

2. FantasyWorld-Wan2.2-Fun-A14B-Control-Camera

2.1 Model Download

| Models | Download Link | Notes | | --------------|-------------------------------------------------------------------------------|-------------------------------| | Wan2.2-Fun-A14B-Control-Camera | 🤗 Huggingface 🤖 ModelScope | Base Model | Wan2.2-Fun-Reward-LoRAs | 🤗 Huggingface 🤖 ModelScope | LoRA Model | FantasyWorld-Wan2.2-Fun-A14B-Control-Camera | 🤗 Huggingface 🤖 ModelScope | FantasyWorld

Download models using huggingface:

pip install -U "huggingface_hub"
hf download "alibaba-pai/Wan2.2-Fun-A14B-Control-Camera" --local-dir ./models/PAI/Wan2.2-Fun-A14B-Control-Camera
hf download "alibaba-pai/Wan2.2-Fun-Reward-LoRAs" --local-dir ./models/PAI/Wan2.2-Fun-Reward-LoRAs
hf download "acvlab/FantasyWorld-Wan2.2-Fun-A14B-Control-Camera" --local-dir ./models/FantasyWorld-Wan2.2-Fun-A14B-Control-Camera/

Download models using modelscope:

pip install -U modelscope
modelscope download "PAI/Wan2.2-Fun-A14B-Control-Camera" --local_dir ./models/PAI/Wan2.2-Fun-A14B-Control-Camera
modelscope download "PAI/Wan2.2-Fun-Reward-LoRAs" --local_dir ./models/PAI/Wan2.2-Fun-Reward-LoRAs
modelscope download "amap_cvlab/FantasyWorld-Wan2.2-Fun-A14B-Control-Camera" --local_dir ./models/FantasyWorld-Wan2.2-Fun-A14B-Control-Camera/

2.2 Inference Command

python inference_wan22.py \
    --image_path ./examples/images/input_image.png \
    --end_image_path ./examples/images/end_image.png \
    --wan_ckpt_path ./models/ \
    --camera_json_path ./examples/cameras/camera_data.json \
    --prompt "In the Open Loft Living Room, sunlight streams through large windows, highlighting the sleek fireplace and elegant wooden stairs." \
    --model_ckpt_high ./models/FantasyWorld-Wan2.2-Fun-A14B-Control-Camera/high_noise_model.pth \
    --model_ckpt_low ./models/FantasyWorld-Wan2.2-Fun-A14B-Control-Camera/low_noise_model.pth \
    --output_dir ./output-wan22 \
    --sample_steps 50 \
    --using_scale True

Parameter Description:

--image_path - Required: Path to the first image
--end_image_path - Required: Path to the end image
--wan_ckpt_path - Required: Directory containing the Wan model checkpoints
--camera_json_path - Required: Camera json path, corresponding to examples/cameras/camera_data_*.json
--prompt - Required: Text prompt
--model_ckpt_high - Required: Path to the trained high model checkpoint
--model_ckpt_low - Required: Path to the trained low model checkpoint
--output_dir - Optional: Output directory
--sample_steps - Optional: Number of sampling steps (default: 50)
--using_scale - Optional: Whether to use scale normalization (default: True)

🧩 Community Contributions

We ❤️ contributions from the open-source community! If your work has improved FantasyWorld, please inform us. Or you can directly e-mail frank.jf@alibaba-inc.com. We are happy to reference your project for everyone's convenience.

🔗Citation

If you find this repository useful, please consider giving a star ⭐ and citation.

@inproceedings{
    dai2025fantasyworld,
    title={FantasyWorld: Geometry-Consistent World Modeling via Unified Video and 3D Prediction},
    author={Yixiang Dai and Fan Jiang and Chiyu Wang and Mu Xu and Yonggang Qi},
    booktitle={The Fourteenth International Conference on Learning Representations},
    year={2026},
    url={https://openreview.net/forum?id=3q9vHEqsNx}
}

🙏 Acknowledgments

We would like to thank Wan, VideoX-Fun, DiffSynth-Studio and VGGT for their great works.

Author: acvlab

Likes: 3

Downloads: 0

Tags: wan, world_model, image-to-video, en, zh, arxiv:2509.21657, base_model:Wan-AI/Wan2.1-I2V-14B-480P, base_model:finetune:Wan-AI/Wan2.1-I2V-14B-480P, license:apache-2.0, region:us

HauhauCS/GPTOSS-120B-Uncensored-HauhauCS-Aggressive

license: apache-2.0 base_model: openai/gpt-oss-120b tags:

uncensored
abliterated
gguf
mxfp4
moe
gpt-oss language:
en

GPTOSS-120B-Uncensored-HauhauCS-Aggressive

Uncensored version of GPT-OSS 120B by OpenAI. This is the aggressive variant - tuned harder for fewer refusals.

No changes to datasets or capabilities. Fully functional, 100% of what the original authors intended - just without the refusals.

Format

MXFP4 GGUF. This is the model's native precision - GPT-OSS was trained in MXFP4, so no further quantization is needed or recommended. Re-quantizing would only lose quality.

Works with llama.cpp, LM Studio, Ollama, and anything else that loads GGUFs.

Downloads

| File | Size | |------|------| | GPTOSS-120B-Uncensored-HauhauCS-Aggressive-MXFP4.gguf | 61 GB |

Specs

117B total parameters, ~5.1B active per forward pass (MoE: 128 experts, top-4 routing)
128K context
Based on openai/gpt-oss-120b

Recommended Settings

temperature: 1.0
top_k: 40
Everything else (top_p, min_p, repeat penalty, etc.) should be disabled - some clients enable these by default, turn them off

Required flag: --jinja to enable the Harmony response format (the model won't work correctly without it).

For llama.cpp:

llama-server -m model.gguf --jinja -fa -b 2048 -ub 2048

LM Studio

Compatible with Reasoning Effort custom buttons. To use them, put the model in:

LM Models\lmstudio-community\gpt-oss-120b-GGUF\

Hardware

Fits in ~61GB VRAM. Single H100 or equivalent. For lower VRAM, use --n-cpu-moe N in llama.cpp to offload MoE layers to CPU.

Author: HauhauCS

Likes: 2

Downloads: 0

Tags: gguf, uncensored, abliterated, mxfp4, moe, gpt-oss, en, base_model:openai/gpt-oss-120b, base_model:quantized:openai/gpt-oss-120b, license:apache-2.0, endpoints_compatible, region:us, conversational

Todays AI Summary

AI Developments: New Models Enhance Image Generation and Reasoning, Research Focuses on Efficient Learning

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Creative Ownership in the Age of AI

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"Sorry, I Didn't Catch That": How Speech Models Miss What Matters Most

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deepgenteam/DeepGen-1.0

💡 DeepGen 1.0: A Lightweight Unified Multimodal Model for Advancing Image Generation and Editing

🧠 Method

📊 Benchmarks

1. General Image Generation

2. General Image Editing

3. Reasoning Image Generation

4. Reasoning Image Editing

🎨 Quantitative results

🛠️ Usage

Merge ZIP Files

ubergarm/MiniMax-M2.5-GGUF

ik_llama.cpp imatrix Quantizations of MiniMaxAI/MiniMax-M2.5

Big Thanks

Quant Collection

IQ5_K 157.771 GiB (5.926 BPW)

IQ4_XS 114.842 GiB (4.314 BPW)

smol-IQ3_KS 87.237 GiB (3.277 BPW)

IQ2_KS 69.800 GiB (2.622 BPW)

Quick Start

References

ox-ox/MiniMax-M2.5-GGUF

MiniMax-M2.5-GGUF (230B MoE)

🚀 Available Quants

🛠 Model Details

💻 Usage

Command Line Example:

DevQuasar/MiniMaxAI.MiniMax-M2.5-GGUF

OccultAI/Morpheus-8B-v1

Morpheus 8B v1

mlx-community/MiniMax-M2.5-3bit

mlx-community/MiniMax-M2.5-3bit

Use with mlx

HeartMuLa/HeartMuLa-oss-3B-happy-new-year

Model Details

Model Description

Links

Get Started

Citation

Contact

DarkArtsForge/Raven-8B-v1

Raven 8B v1

acvlab/FantasyWorld-Wan2.1-I2V-14B-480P

FantasyWorld: Geometry-Consistent World Modeling via Unified Video and 3D Prediction

🔥🔥🔥 Latest News

🌟 Overview

🚀 Training Strategy

📦 Model Zoo

🚀 Quickstart

Installation

1. FantasyWorld-Wan2.1-I2V-14B-480P

1.1 Model Download

1.2 Inference Command

2. FantasyWorld-Wan2.2-Fun-A14B-Control-Camera

2.1 Model Download

2.2 Inference Command

🧩 Community Contributions

🔗Citation

🙏 Acknowledgments

HauhauCS/GPTOSS-120B-Uncensored-HauhauCS-Aggressive

GPTOSS-120B-Uncensored-HauhauCS-Aggressive

Format

Downloads

Specs

Recommended Settings

LM Studio

`ik_llama.cpp` imatrix Quantizations of MiniMaxAI/MiniMax-M2.5