---

license: other license_name: minimax-m2.7-non-commercial license_link: LICENSE library_name: mlx tags:

• mlx
• jang
• jangtq
• minimax
• moe
• apple-silicon
• 2bit pipeline_tag: text-generation base_model: MiniMaxAI/MiniMax-M2.7 base_model_relation: quantized

---

🔧 2026-04-14 · chat_template.jinja fix — re-download if cached

Earlier versions of this repo shipped a chat_template that unconditionally forced <think> reasoning mode, ignoring enable_thinking=False. Synced with JANG_2L: the new template respects the flag, so callers can now skip reasoning for fast direct answers.

If you downloaded this model before 2026-04-14, please re-download chat_template.jinja:

huggingface-cli download JANGQ-AI/MiniMax-M2.7-JANGTQ chat_template.jinja --local-dir /path/to/your/local/copy

Or pass tools-only prompts (tool calling works regardless). Model weights are unchanged.

<p align="center"> <img src="mlx-studio-logo.png" alt="MLX Studio" width="400"/> </p> <p align="center"> <img src="jangq-logo.png" alt="JANGQ" width="200"/> </p> <div align="center">

MiniMax-M2.7 JANGTQ

MiniMax M2.7 228B MoE — 2.15-bit codebook + Hadamard, 56.5 GB

The smallest, highest-quality MiniMax M2.7 on Apple Silicon.

</div>

⚠️ Recommended: Run in MLX Studio for the best experience. MLX Studio bundles the JANGTQ runtime, handles thinking mode, and uses the custom Metal kernels this model needs. Stock mlx_lm.load() will NOT load this model — see usage instructions below.

Follow development on Twitter: @jangq_ai

---

What is JANGTQ?

JANGTQ (JANG TurboQuant) is the most-compressed, highest-quality JANG quantization format. Routed expert weights stay in a compact codebook + Hadamard-rotated form at runtime — no decompression to affine — and the matmul path uses custom Metal kernels that read packed uint32 weights, look up centroids in a 4-entry codebook, and accumulate dot products against a Hadamard-rotated input (QuIP# "rotate-input-once" math).

Result: smaller than affine 2-bit, higher quality than affine 2-bit, runs at 89% of affine 2-bit speed on Apple Silicon.

| | JANG_2L (affine) | JANGTQ | Δ | |---|---|---|---| | Disk size | ~63 GB | 56.5 GB | −10% | | GPU memory | ~62.6 GB | 56.5 GB | −10% | | Avg bits/param | 2.10 | ~2.15 | +0.05 | | MMLU (200q) | 88% | 91.5% | +3.5 pp | | Decode speed (M3 Ultra) | 48-50 tok/s | 44.3 tok/s | ~89% of affine |

JANGTQ trades ~10% speed for ~10% disk savings AND a quality improvement. The 2-bit codebook learned via Lloyd-Max is strictly more expressive than uniform 2-bit affine for the Gaussian-ish distribution of Hadamard-rotated weights, so the same bit budget reproduces the original weight matrix more faithfully.

---

MMLU Benchmark (200 questions, 10 subjects, reasoning ON)

Overall: 183/200 = 91.5%

Tested 2026-04-13 on Mac Studio M3 Ultra. Reasoning enabled (MiniMax M2.7 is an always-reasoning model); <think>…</think> stripped before scoring.

| Subject | JANGTQ | JANG_2L (affine) | JANG_3L/4M | |---|---|---|---| | astronomy | 20/20 (100%) | — | — | | high_school_biology | 20/20 (100%) | — | — | | abstract_algebra | 19/20 (95%) | — | — | | college_computer_science | 19/20 (95%) | — | — | | high_school_mathematics | 19/20 (95%) | — | — | | college_physics | 18/20 (90%) | — | — | | high_school_chemistry | 18/20 (90%) | — | — | | anatomy | 17/20 (85%) | — | — | | world_religions | 17/20 (85%) | — | — | | logical_fallacies | 16/20 (80%) | — | — | | Total | 183/200 = 91.5% | ~88% | ~95.5% |

JANGTQ sits cleanly between affine JANG_2L (88%) and the larger JANG_3L/4M (95.5%) — capturing most of the quality of the 3L/4M profiles at ~55-60% of their disk footprint.

Speed Benchmarks (Mac Studio M3 Ultra)

| Prompt / max_tok | observed tok | tok/s | |---|---|---| | "Capital of France?" / 50 | 50 / 50 | 35.6 | | "Capital of France?" / 150 | 66 / 150 | 37.5 | | "Count 1-30" / 150 | 150 / 150 | 42.2 | | "Photosynthesis 5 sent" / 300 | 300 / 300 | 44.5 | | "Poem + 17×23" / 300 | 296 / 300 | 44.0 | | MMLU average (200q, reasoning on) | — | 41.9 |

Steady-state (300-tok and longer): ~44.3 tok/s. Short prompts appear slower due to fixed prefill amortization.

---

Important Settings

MiniMax M2.7 is an always-reasoning model. The chat template unconditionally opens <think>\n at each assistant turn.

| Setting | Value | Notes | |---------|-------|-------| | Temperature | 1.0 | REQUIRED — temp=0 can cause thinking loops | | Top P | 0.95 | | | Top K | 40 | | | Repetition Penalty | 1.1 | Optional, helps prevent loops | | max_tokens | ≥ 8192 | Give reasoning room to converge |

Strip <think>…</think> from the response before using the final answer.

---

Model Details

| Metric | Value | |---|---| | Source | MiniMaxAI/MiniMax-M2.7 (FP8 E4M3) | | Architecture | MoE (256 experts, top-8 active), standard Q/K/V attention, partial RoPE | | Total parameters | 228.7 B | | Active per token | ~1.4 B | | Profile | JANGTQ | | Format | JANGTQ (codebook+Hadamard) — weight_format: mxtq in jang_config.json | | Avg bits/param | ~2.15 | | Disk | 56.55 GB | | GPU active (loaded) | 56.50 GB | | GPU peak (decoding) | 57-58 GB | | Load time | ~10 s | | Context | 192 K tokens | | Chat template | Always-reasoning (<think>\n opened at assistant start) |

JANGTQ Bit Allocation

| Component | Bits | Format | Why | |---|---|---|---| | Routed expert MLP (gate/up/down) — 98% of params | 2 | JANGTQ codebook + Hadamard | Sparsely activated (8 of 256 per token); the learned codebook on Hadamard-rotated rows reproduces the distribution better than uniform 2-bit affine | | Attention (Q/K/V/O) | 8 | affine (nn.QuantizedLinear, group_size=64) | Runs on every token; quality-critical | | Shared expert | 8 | affine | Runs on every token | | Embed tokens / LM head | 8 | affine | Quality-critical input/output projections | | Router gate | fp16 | unquantized nn.Linear | Routing precision matters; ~0.8M params, negligible size | | RMSNorms / RoPE / biases | fp16 | unquantized | Already tiny |

The routed experts are the 98% of parameters and the natural compression target. JANGTQ pushes them to 2-bit with a codebook-learned quantizer and a random Hadamard rotation. Everything else stays at 8-bit affine so the quality- critical hot path (attention + embed + shared expert) runs at full precision.

---

Usage

This model requires the jang-tools loader — stock mlx_lm.load() does NOT recognize weight_format: mxtq and will reject the model. The loader applies Metal kernel monkey-patches at load time (fused gate+up+SwiGLU, gather TQ, multi-block Hadamard, router compile, QKV fusion, thread-tiling OPT=10/20).

pip install jang-tools
# Or from source: git clone https://github.com/JANGQ-AI/jang-tools

from huggingface_hub import snapshot_download
from jang_tools.load_jangtq import load_jangtq_model
from mlx_lm import generate

model_path = snapshot_download("JANGQ-AI/MiniMax-M2.7-JANGTQ")
model, tokenizer = load_jangtq_model(model_path)

messages = [{"role": "user", "content": "Explain photosynthesis in 5 sentences."}]
prompt = tokenizer.apply_chat_template(messages, add_generation_prompt=True, tokenize=False)
out = generate(model, tokenizer, prompt, max_tokens=600, verbose=True)

# Strip reasoning to get the final answer
if "</think>" in out:
    out = out.split("</think>")[-1].strip()
print(out)

On first load you'll see log lines like:

Loading JANGTQ: MiniMax-M2.7-JANGTQ
  seed=42, bits_map={'attention': 8, ..., 'routed_expert': 2, ...}
  61 shards
  TQ groups: 47616, regular: 1123
  Replaced 186 modules with TurboQuantLinear
  Patched SwitchGLU class for fused gate+up (62 TQ instances)
  P15 mx.compile(router) applied to 1 MoE class(es)
  P18 QKV fusion: 1 class(es), 62 instances
  Done

That's all four classes of optimizations (P3/P15/P17/P18) engaging. Expected decode: ~44 tok/s on M3 Ultra, ~35-40 tok/s on M4 Max, ~25-30 tok/s on M4 Pro.

Minimum Hardware

| GPU | Min RAM | Notes | |---|---|---| | M3 Ultra / M2 Ultra | 96 GB | Tested on 256 GB, 44 tok/s | | M4 Max | 96 GB | Expected ~35-40 tok/s | | M4 Pro | 64 GB | Very tight; expect ~25-30 tok/s | | M3 Max / M2 Max | 96 GB | Expected ~30-35 tok/s |

56.5 GB of GPU memory is needed just for the weights; add 2-5 GB for KV cache and intermediate activations, plus enough system memory for the OS + other processes.

Why JANG for MiniMax

Standard MLX uniform quantization on MiniMax produces completely broken output at every bit level — MMLU drops to ~25% (random guessing) because the MoE router becomes unreliable. JANG's mixed-precision approach (attention + router at full precision, routed experts at 2-bit) is the only working quantized MiniMax on Apple Silicon.

JANGTQ takes this one step further by using a learned codebook for the 2-bit expert weights. For MiniMax M2.5, JANG_2L (affine) scored 74% MMLU vs MLX's 25%. For MiniMax M2.7, JANGTQ scores 91.5% — the highest-quality sub-60-GB MiniMax quant on any runtime.

---

Compression Math

Quantization (offline, per weight matrix):
  w_rot[r, i]  = (H ⊙ signs * w^T)[r, i]           # randomized Hadamard rotation
  norms[r]     = ||w_rot[r, :]||₂
  packed[r, i] = argmin_c ||w_rot[r, i]/norms[r] - codebook[c]||   # Lloyd-Max 2-bit

Inference (runtime):
  x_rot   = H ⊙ (signs * x)                         # O(d log d) rotation
  y[b, r] = norms[r] · Σᵢ x_rot[b, i] · codebook[unpack(packed[r, i])]

The Hadamard rotation flattens the heavy tail of the weight distribution, so a 4-entry codebook (2-bit) captures it with minimal error. The rotation is symmetric (H @ H = I), so rotating the input once at runtime is mathematically equivalent to rotating every weight once at quantization time.

Credit: QuIP# for the rotate-input-once insight.

---

Known Behaviors / Settings

• Always-reasoning: chat template opens <think>\n at assistant start. Give it max_tokens ≥ 8192 in benchmarks.
• Stop token: single EOS [e~[ = id 200020. mlx_lm reads this correctly from generation_config.json.
• Temperature 1.0 required: greedy/temp=0 can cause the reasoning to get stuck in a loop. Top-p 0.95 + top-k 40 recommended.
• GPU RAM: 56.5 GB base + KV cache grows with conversation length. Budget 60-65 GB for typical use, more for very long contexts.

---

Created by Jinho Jang (eric@jangq.ai) — part of the JANG collection.

Base model: MiniMaxAI/MiniMax-M2.7. Quantization method: JANGTQ (codebook + randomized Hadamard, see math above). License: follows the upstream MiniMax open license.

---

license: apache-2.0 language:

• en tags:
• text-to-video
• image-to-video
• video-generation
• diffusion-transformer pipeline_tag: text-to-video library_name: diffusers

---

<!-- Cover banner — replace with the qualitative teaser strip used as Figure 1 in the technical report (multi-prompt frame grid). Wan / HunyuanVideo style: full-width image directly under the title. --> <p align="center"> <img src="assets/banner.png" width="100%" alt="Motif-Video 2B teaser"/> </p> <p align="center"> <h1 align="center">Motif-Video 2B</h1> </p> <p align="center"> <b>A micro-budget text-to-video diffusion transformer from Motif Technologies</b> </p> <p align="center"> 📑 <a href="">Technical Report</a> &nbsp;|&nbsp; 🤗 <a href="">Hugging Face</a> &nbsp;|&nbsp; 🌐 <a href="https://motiftech.io/videoshowcase">Project Page</a> (not updated) </p>

---

🔥 News

• [2026-04-14] We release Motif-Video 2B, our 2B-parameter text-to-video and image-to-video diffusion transformer, together with the full technical report.

---

📖 Introduction

Training strong video generation models usually requires massive datasets, large parameter counts, and substantial compute. Motif-Video 2B asks whether competitive text-to-video quality is reachable at a much smaller budget — fewer than 10M training clips and under 100,000 H200 GPU hours — and shows that the answer is yes, provided the model design explicitly separates objectives that scaling would otherwise leave entangled.

Our central observation is that prompt alignment, temporal consistency, and fine-detail recovery interfere with one another when handled through the same pathway. Motif-Video 2B addresses this objective interference architecturally rather than relying on scale alone, through two contributions:

• Shared Cross-Attention. A residual cross-attention mechanism that reuses self-attention K/V weights to stabilize text–video alignment under long-context token sparsity, where standard joint attention dilutes text influence as the video token sequence grows.
• Three-stage DDT-style backbone. 12 dual-stream + 16 single-stream + 8 DDT decoder layers, separating early modality fusion, joint representation learning, and high-frequency detail reconstruction into dedicated components. Per-block attention analysis shows that the DDT decoder spontaneously develops inter-frame attention structure absent from the encoder layers.

These are paired with a micro-budget training recipe combining TREAD token routing and early-phase REPA with a frozen V-JEPA teacher — to our knowledge, the first time this combination has been applied to text-to-video training.

On VBench, Motif-Video 2B reaches 83.76%, the highest Total Score among open-source models we evaluate, surpassing Wan2.1-14B at 7× fewer parameters and roughly an order of magnitude less training data.

<!-- Architecture figure — replace with Figure 2 from the technical report (the three-stage backbone + Shared Cross-Attention diagram). --> <p align="center"> <img src="assets/architecture.png" width="90%" alt="Motif-Video 2B architecture"/> </p>

---

✨ Highlights

• Two tasks, one set of weights. A single checkpoint handles both text-to-video (T2V) and image-to-video (I2V) generation, trained jointly without a learnable task-type embedding.
• Up to 720p, 121 frames. The final model generates 720p video at 121 frames under the standard rectified flow-matching sampler.
• Architectural specialization over brute-force scale. Three-stage backbone with role-separated dual-stream / single-stream / DDT decoder layers.
• Shared Cross-Attention. Stabilizes text alignment under long video-token sequences by grounding cross-attention K/V in the self-attention manifold.
• Micro-budget recipe. TREAD token routing (≈27% per-step FLOP reduction) + early-phase REPA with V-JEPA teacher + offline bucket-balanced sampler (≈90% data utilization, up from ≈20% baseline).
• Open and reproducible. Trained on ~64×H200 GPUs with FSDP2, full curriculum and recipe documented in the technical report.

---

🏗️ Architecture

Motif-Video 2B is a flow-matching diffusion transformer organized around a single principle: each component is assigned a well-defined responsibility, and components with conflicting objectives are not asked to share capacity.

| Component | Choice | |---|---| | Text encoder | T5Gemma2 (encoder–decoder, UL2-adapted Gemma 3) | | Video tokenizer | Wan2.1 VAE (8×8 spatial, 4× temporal compression), 2×2×1 patchify | | Backbone | 12 dual-stream + 16 single-stream + 8 DDT decoder layers | | Hidden dim / heads | 1536 / 12 heads × 128 | | Normalization | QK-normalization throughout | | Position encoding | RoPE | | Cross-attention | Shared Cross-Attention in the single-stream stage | | Objective | Rectified flow matching (velocity prediction) | | I2V conditioning | First-frame latent + SigLIP image embeddings, with timestep-aware blur |

A high-level walkthrough of the role separation:

1. Dual-stream stage (12 layers). Text and video tokens are processed through separate self-attention pathways, exchanging information via cross-attention. This prevents premature feature entanglement before either modality has formed coherent representations.
2. Single-stream stage (16 layers). Text and video tokens attend freely in a joint sequence. Shared Cross-Attention is attached here to repair the text-attention dilution that emerges as the video token sequence grows.
3. DDT decoder (8 layers). A dedicated velocity decoder atop the 28-layer encoder, freeing the encoder from high-frequency detail reconstruction. Per-block attention analysis shows that the DDT decoder develops inter-frame attention structure that single-stream layers do not.

For the full derivation of why Shared Cross-Attention shares K/V but not Q, and why this is necessary in addition to standard zero-init of W_O, see Section 3.3 of the technical report.

<!-- Optional: insert Figure 3 (attention heatmaps across the three stages) here as a secondary architecture figure. It is the strongest visual evidence for the role-separation argument. -->

---

🚀 Quickstart / Usage

Requirements

• Python 3.10+
• CUDA-capable GPU with 24GB+ VRAM (e.g., A100, H100, RTX 4090)

pip install "diffusers>=0.35.2" "transformers>=5.0.0" torch accelerate ftfy einops sentencepiece regex Pillow

Text-to-Video (T2V)

import torch
from diffusers import AdaptiveProjectedGuidance, DiffusionPipeline
from diffusers.utils import export_to_video

guider = AdaptiveProjectedGuidance(
    guidance_scale=8.0,
    adaptive_projected_guidance_rescale=12.0,
    adaptive_projected_guidance_momentum=0.1,
    use_original_formulation=True,
)

pipe = DiffusionPipeline.from_pretrained(
    "Motif-Technologies/Motif-Video-2B",
    custom_pipeline="pipeline_motif_video",
    trust_remote_code=True,
    torch_dtype=torch.bfloat16,
    guider=guider,
)
pipe = pipe.to("cuda")

output = pipe(
    prompt="A golden retriever running through a sunlit meadow, slow motion, cinematic lighting",
    height=736,
    width=1280,
    num_frames=121,
    num_inference_steps=50,
)

export_to_video(output.frames[0], "output.mp4", fps=24)

Image-to-Video (I2V)

import torch
from diffusers import DiffusionPipeline
from diffusers import AdaptiveProjectedGuidance
from diffusers.utils import export_to_video
from PIL import Image

guider = AdaptiveProjectedGuidance(
    guidance_scale=8.0,
    adaptive_projected_guidance_rescale=12.0,
    adaptive_projected_guidance_momentum=0.1,
    use_original_formulation=True,
)

pipe = DiffusionPipeline.from_pretrained(
    "Motif-Technologies/Motif-Video-2B",
    custom_pipeline="pipeline_motif_video",
    trust_remote_code=True,
    torch_dtype=torch.bfloat16,
    guider=guider,
)
pipe = pipe.to("cuda")

image = Image.open("input.png").convert("RGB")

output = pipe(
    prompt="The subject begins to move naturally",
    image=image,
    height=736,
    width=1280,
    num_frames=121,
    num_inference_steps=50,
)

export_to_video(output.frames[0], "output.mp4", fps=24)

CLI Inference

# Text-to-Video
python inference.py \
  --prompt "A time-lapse of a flower blooming in a dark room, dramatic lighting" \
  --output t2v_output.mp4

# Image-to-Video
python inference.py \
  --image input.png \
  --prompt "The camera slowly pans around the subject" \
  --output i2v_output.mp4

See inference.py for all available options (--help).

Recommended Settings

| Parameter | Default | Notes | |---|---|---| | Resolution | 1280x736 | 720p, best quality | | Frames | 121 | ~5 seconds at 24fps | | Guidance scale | 8.0 | | | Scheduler shift | 15.0 | Pre-configured in scheduler config | | Inference steps | 50 | | | dtype | bfloat16 | Recommended for H100/A100 |

---

📊 Performance

VBench

Motif-Video 2B achieves the highest Total Score among open-source models we evaluate.

| Model | Params | Total | Quality | Semantic | |---|---|---|---|---| | Wan2.2-T2V (prompt-opt.) | A14B | 84.23 | 85.42 | 79.50 | | Motif-Video 2B (Ours) | 2B | 83.76 | 84.59 | 80.44 | | SANA-Video | 2B | 83.71 | 84.35 | 81.35 | | Wan2.1-T2V | 14B | 83.69 | 85.59 | 76.11 | | OpenSora 2.0 (T2I2V) | 11B | 83.60 | 84.40 | 80.30 | | Wan2.1-T2V | 1.3B | 83.31 | 85.23 | 75.65 | | HunyuanVideo | 13B | 83.24 | 85.09 | 75.82 | | CogVideoX1.5-5B (prompt-opt.) | 5B | 82.17 | 82.78 | 79.76 | | Step-Video-T2V | 30B | 81.83 | 84.46 | 71.28 | | LTX-Video | 2B | 80.00 | 82.30 | 70.79 |

Notable per-dimension highlights for Motif-Video 2B (open-source):

• Spatial Relationship: 83.02% — best among open-source models
• Semantic Score: 80.44% — highest among open-source models reporting per-dimension results
• Object Class: 92.93%, Multiple Objects: 77.29%, Imaging Quality: 70.50% — second-best in their categories

The full 16-dimension breakdown is in Table 3 of the technical report.

A note on VBench vs. perceptual quality. Motif-Video 2B leads on VBench Total Score, but in our internal side-by-side comparisons against Wan2.1-T2V-14B we observe a perceptual gap in favor of the larger model on temporal stability and fine human anatomy. We discuss the sources of this gap (uniform dimension weighting, near-correct semantic credit) in Section 7 of the report. We report the gap explicitly rather than smoothing it over.

Human evaluation

In a blind pairwise study against six contemporaneous open-source baselines (SANA-Video, LTX-Video 2, Wan2.1-14B, Wan2.1-1.3B, Wan2.2-5B, CogVideoX-5B) on 40 LLM-generated prompts, Motif-Video 2B is preferred over both SANA-Video (similar parameter count) and Wan2.1-1.3B (similar parameter count, larger training corpus) on prompt-following and video-fidelity axes. Wan2.1-14B remains the preferred model overall, consistent with its 7× larger parameter count and substantially larger training data.

---

🎬 Showcase

<!-- Insert the qualitative grids from the technical report here: - Figure 1 / Figure 12: T2V multi-prompt frame strips - Figure 13: I2V example (input image + generated frames) Use full-width or 2-column layout, matching Wan2.1's "Showcase" section. -->

Text-to-Video

<p align="center"> <img src="assets/showcase_t2v.png" width="100%" alt="Motif-Video 2B T2V samples"/> </p>

Image-to-Video

<p align="center"> <img src="assets/showcase_i2v.png" width="100%" alt="Motif-Video 2B I2V samples"/> </p>

---

⚠️ Limitations

We report limitations as the boundary conditions under which the design decisions in this report should be interpreted, not as caveats.

• Micro-scale semantic distortion. Motif-Video 2B occasionally produces sub-object-level artifacts that leave the category label intact but break perceptual plausibility — distorted hands on close-up human subjects, degraded body structure under high-displacement motion, and attribute leakage between visually similar co-present subjects. We attribute these primarily to data coverage rather than backbone design.
• Temporal failures. Three distinct modes that frame-level metrics do not surface: (i) physically implausible liquid / cloth / collision dynamics, (ii) coherence loss under high scene complexity (multi-agent crowds), and (iii) unintended mid-clip scene transitions in long sequences.
• Recipe components are evaluated jointly, not in isolation. We do not present per-component ablations for Shared Cross-Attention, the DDT decoder, REPA phasing, or TREAD routing at full scale. Readers should interpret our results as evidence that the composed recipe works at 2B, not as a marginal-contribution claim about any single component.

We view temporal stability and data coverage — not architectural depth — as the primary remaining ceilings on this model. Both are the most natural axes for a future iteration that the current architecture is built to absorb.

---

📚 Citation

If you find Motif-Video 2B useful in your research, please cite:

@techreport{motifvideo2b2026,
  title  = {Motif-Video 2B: Technical Report},
  author = {Motif Technologies},
  year   = {2026},
  institution = {Motif Technologies},
  url    = {}
}

---

🙏 Acknowledgements

We build on a number of excellent open-source projects, including the Wan2.1 VAE [Wan Team, 2025], T5Gemma / Gemma 3 [Google], TREAD [Krause et al., 2025], REPA with the V-JEPA family of visual encoders [Bardes et al.], DDT [Wang et al.], and the broader diffusers and Accelerate ecosystems. Compute was provisioned on Microsoft Azure and orchestrated with SkyPilot on Kubernetes.

---

📄 License

<!-- TODO: confirm final license — apache-2.0 placeholder above. -->

This model is released under the Apache 2.0 License. See LICENSE for details.

---

base_model: baidu/ERNIE-Image-Turbo license: apache-2.0 pipeline_tag: text-to-image library_name: ggml tags:

• text-to-image
• gguf
• unsloth widget:
• text: LLM teaching sloth output: url: assets/Ernie-Image-Turbo-GGUF.png

---

This is a GGUF quantized version of ERNIE-Image-Turbo. <br> unsloth/ERNIE-Image-Turbo-GGUF uses Unsloth Dynamic 2.0 methodology for SOTA performance.

• Important layers are upcasted to higher precision.
• Uses tooling from ComfyUI-GGUF by city96.

<div> <div style="display: flex; gap: 5px; align-items: center; "> <a href="https://github.com/unslothai/unsloth/"> <img src="https://github.com/unslothai/unsloth/raw/main/images/unsloth%20new%20logo.png" width="133"> </a> <a href="https://discord.gg/unsloth"> <img src="https://github.com/unslothai/unsloth/raw/main/images/Discord%20button.png" width="173"> </a> <a href="https://docs.unsloth.ai/basics/unsloth-dynamic-2.0-ggufs"> <img src="https://raw.githubusercontent.com/unslothai/unsloth/refs/heads/main/images/documentation%20green%20button.png" width="143"> </a> </div> </div>

---

ERNIE-Image-Turbo

<p align="center"> <a href="https://huggingface.co/Baidu/ERNIE-Image">🤗 ERNIE-Image</a> &nbsp;|&nbsp; <a href="https://huggingface.co/Baidu/ERNIE-Image-Turbo">🤗 ERNIE-Image-Turbo</a> &nbsp;|&nbsp; <a href="https://huggingface.co/spaces/baidu/ERNIE-Image">🖥️ Huggingface Demo</a> &nbsp;|&nbsp; <br/> <a href="https://aistudio.baidu.com/ernieimage">🖥️ AI Studio Demo</a> &nbsp;|&nbsp; <a href="https://yiyan.baidu.com/blog/posts/ernie-image">📖 Blog</a> &nbsp;|&nbsp; <a href="https://ernieimageprompt.com/">🖼️ Art Gallery</a> <br/> <a href="https://github.com/baidu/ERNIE-Image/blob/main/assets/contacts/WeChat_small.jpg">💬 WeChat(微信)</a> &nbsp;|&nbsp; <a href="https://discord.gg/ByUTbjfG5k">🫨 Discord</a> &nbsp;|&nbsp; <a href="https://x.com/ErnieforDevs">🏷️ X</a> </p>

ERNIE-Image-Turbo is an open text-to-image generation model developed by the ERNIE-Image team at Baidu. It is the distilled release of ERNIE-Image, built on the same single-stream Diffusion Transformer (DiT) family and designed for fast generation with strong fidelity in only 8 inference steps. The model retains strong controllability in practical generation scenarios where accurate content realization matters as much as aesthetics. In particular, ERNIE-Image-Turbo remains strong on complex instruction following, text rendering, and structured image generation, making it well suited for posters, comics, multi-panel layouts, and other content creation tasks that require both visual quality and efficiency. It also supports a broad range of visual styles, including realistic photography, design-oriented imagery, and stylized aesthetic outputs.

<p align="center"> <img src="https://cdn-uploads.huggingface.co/production/uploads/5f8d780e5d083370c711f575/QRt1mPSU9SCkcxxFWQje2.jpeg" alt="ERNIE-Image Mosaic" width="100%"> </p>

Highlights:

• Fast and efficient: As the distilled checkpoint of ERNIE-Image, ERNIE-Image-Turbo delivers strong generation quality with only 8 inference steps, making it suitable for latency-sensitive applications.
• Text rendering: ERNIE-Image-Turbo performs well on dense, long-form, and layout-sensitive text, making it a strong choice for posters, infographics, UI-like images, and other text-heavy visual content.
• Instruction following: The model is able to follow complex prompts involving multiple objects, detailed relationships, and knowledge-intensive descriptions with strong reliability.
• Structured generation: ERNIE-Image-Turbo is effective for structured visual tasks such as posters, comics, storyboards, and multi-panel compositions, where layout and organization are critical.
• Style coverage: In addition to clean and readable design-oriented outputs, the model also supports realistic photography and distinctive stylized aesthetics, including softer and more cinematic visual tones.
• Practical deployment: Thanks to its compact size, ERNIE-Image-Turbo can run on consumer GPUs with 24G VRAM, which lowers the barrier for research, downstream use, and model adaptation.

Released Versions

ERNIE-Image: Our SFT model, delivers stronger general-purpose capability and instruction fidelity in typically 50 inference steps.

ERNIE-Image-Turbo: Our Turbo model, optimized by DMD and RL, achieves faster speed and higher aesthetics in only 8 inference steps.

Benchmark

GENEval

| Model | Single Object | Two Object | Counting | Colors | Position | Attribute Binding | Overall | |---|---:|---:|---:|---:|---:|---:|---:| | ERNIE-Image (w/o PE) | 1.0000 | 0.9596 | 0.7781 | 0.9282 | 0.8550 | 0.7925 | 0.8856 | | ERNIE-Image (w/ PE) | 0.9906 | 0.9596 | 0.8187 | 0.8830 | 0.8625 | 0.7225 | 0.8728 | | Qwen-Image | 0.9900 | 0.9200 | 0.8900 | 0.8800 | 0.7600 | 0.7700 | 0.8683 | | ERNIE-Image-Turbo (w/o PE) | 1.0000 | 0.9621 | 0.7906 | 0.9202 | 0.7975 | 0.7300 | 0.8667 | | ERNIE-Image-Turbo (w/ PE) | 0.9938 | 0.9419 | 0.8375 | 0.8351 | 0.7950 | 0.7025 | 0.8510 | | FLUX.2-klein-9B | 0.9313 | 0.9571 | 0.8281 | 0.9149 | 0.7175 | 0.7400 | 0.8481 | | Z-Image | 1.0000 | 0.9400 | 0.7800 | 0.9300 | 0.6200 | 0.7700 | 0.8400 | | Z-Image-Turbo | 1.0000 | 0.9500 | 0.7700 | 0.8900 | 0.6500 | 0.6800 | 0.8233 |

OneIG-EN

| Model | Alignment | Text | Reasoning | Style | Diversity | Overall | |---|---:|---:|---:|---:|---:|---:| | Nano Banana 2.0 | 0.8880 | 0.9440 | 0.3340 | 0.4810 | 0.2450 | 0.5780 | | Seedream 4.5 | 0.8910 | 0.9980 | 0.3500 | 0.4340 | 0.2070 | 0.5760 | | ERNIE-Image (w/ PE) | 0.8678 | 0.9788 | 0.3566 | 0.4309 | 0.2411 | 0.5750 | | Seedream 4.0 | 0.8920 | 0.9830 | 0.3470 | 0.4530 | 0.1910 | 0.5730 | | ERNIE-Image-Turbo (w/ PE) | 0.8676 | 0.9666 | 0.3537 | 0.4191 | 0.2212 | 0.5656 | | ERNIE-Image (w/o PE) | 0.8909 | 0.9668 | 0.2950 | 0.4471 | 0.1687 | 0.5537 | | Z-Image | 0.8810 | 0.9870 | 0.2800 | 0.3870 | 0.1940 | 0.5460 | | Qwen-Image | 0.8820 | 0.8910 | 0.3060 | 0.4180 | 0.1970 | 0.5390 | | ERNIE-Image-Turbo (w/o PE) | 0.8795 | 0.9488 | 0.2913 | 0.4277 | 0.1232 | 0.5341 | | FLUX.2-klein-9B | 0.8871 | 0.8657 | 0.3117 | 0.4417 | 0.1560 | 0.5324 | | Qwen-Image-2512 | 0.8760 | 0.9900 | 0.2920 | 0.3380 | 0.1510 | 0.5300 | | GLM-Image | 0.8050 | 0.9690 | 0.2980 | 0.3530 | 0.2130 | 0.5280 | | Z-Image-Turbo | 0.8400 | 0.9940 | 0.2980 | 0.3680 | 0.1390 | 0.5280 |

OneIG-ZH

| Model | Alignment | Text | Reasoning | Style | Diversity | Overall | |---|---:|---:|---:|---:|---:|---:| | Nano Banana 2.0 | 0.8430 | 0.9830 | 0.3110 | 0.4610 | 0.2360 | 0.5670 | | ERNIE-Image (w/ PE) | 0.8299 | 0.9539 | 0.3056 | 0.4342 | 0.2478 | 0.5543 | | Seedream 4.0 | 0.8360 | 0.9860 | 0.3040 | 0.4430 | 0.2000 | 0.5540 | | Seedream 4.5 | 0.8320 | 0.9860 | 0.3000 | 0.4260 | 0.2130 | 0.5510 | | Qwen-Image | 0.8250 | 0.9630 | 0.2670 | 0.4050 | 0.2790 | 0.5480 | | ERNIE-Image-Turbo (w/ PE) | 0.8258 | 0.9386 | 0.3043 | 0.4208 | 0.2281 | 0.5435 | | Z-Image | 0.7930 | 0.9880 | 0.2660 | 0.3860 | 0.2430 | 0.5350 | | ERNIE-Image (w/o PE) | 0.8421 | 0.8979 | 0.2656 | 0.4212 | 0.1772 | 0.5208 | | Qwen-Image-2512 | 0.8230 | 0.9830 | 0.2720 | 0.3420 | 0.1570 | 0.5150 | | GLM-Image | 0.7380 | 0.9760 | 0.2840 | 0.3350 | 0.2210 | 0.5110 | | Z-Image-Turbo | 0.7820 | 0.9820 | 0.2760 | 0.3610 | 0.1340 | 0.5070 | | ERNIE-Image-Turbo (w/o PE) | 0.8326 | 0.9086 | 0.2580 | 0.4002 | 0.1316 | 0.5062 | | FLUX.2-klein-9B | 0.8201 | 0.4920 | 0.2599 | 0.4166 | 0.1625 | 0.4302 |

LongTextBench

| Model | LongText-Bench-EN | LongText-Bench-ZH | Avg | |---|---:|---:|---:| | Seedream 4.5 | 0.9890 | 0.9873 | 0.9882 | | ERNIE-Image (w/ PE) | 0.9804 | 0.9661 | 0.9733 | | GLM-Image | 0.9524 | 0.9788 | 0.9656 | | ERNIE-Image-Turbo (w/ PE) | 0.9675 | 0.9636 | 0.9655 | | Nano Banana 2.0 | 0.9808 | 0.9491 | 0.9650 | | ERNIE-Image-Turbo (w/o PE) | 0.9602 | 0.9675 | 0.9639 | | ERNIE-Image (w/o PE) | 0.9679 | 0.9594 | 0.9636 | | Qwen-Image-2512 | 0.9561 | 0.9647 | 0.9604 | | Qwen-Image | 0.9430 | 0.9460 | 0.9445 | | Z-Image | 0.9350 | 0.9360 | 0.9355 | | Seedream 4.0 | 0.9214 | 0.9261 | 0.9238 | | Z-Image-Turbo | 0.9170 | 0.9260 | 0.9215 | | FLUX.2-klein-9B | 0.8642 | 0.2183 | 0.5413 |

Quick Start

Recommended Parameters

• Resolution:
  • 1024x1024
  • 848x1264
  • 1264x848
  • 768x1376
  • 896x1200
  • 1376x768
  • 1200x896
• Guidance scale: 1.0
• Inference steps: 8

Diffusers

Install the latest version of diffusers:

pip install git+https://github.com/huggingface/diffusers

import torch
from diffusers import ErnieImagePipeline

pipe = ErnieImagePipeline.from_pretrained(
    "Baidu/ERNIE-Image-Turbo",
    torch_dtype=torch.bfloat16,
).to("cuda")

image = pipe(
    prompt="This is a photograph depicting an urban street scene. Shot at eye level, it shows a covered pedestrian or commercial street. Slightly below the center of the frame, a cyclist rides away from the camera toward the background, appearing as a dark silhouette against backlighting with indistinct details. The ground is paved with regular square tiles, bisected by a prominent tactile paving strip running through the scene, whose raised textures are clearly visible under the light. Light streams in diagonally from the right side of the frame, creating a strong backlight effect with a distinct Tyndall effect—visible light beams illuminating dust or vapor in the air and casting long shadows across the street. Several pedestrians appear on the left side and in the distance, some with their backs to the camera and others walking sideways, all rendered as silhouettes or semi-silhouettes. The overall color palette is warm, dominated by golden yellows and dark browns, evoking the atmosphere of dusk or early morning.",
    height=1264,
    width=848,
    num_inference_steps=8,
    guidance_scale=1.0,
    use_pe=True # use prompt enhancer
).images[0]

image.save("output.png")

SGLang

Install the latest version of sglang:

git clone https://github.com/sgl-project/sglang.git

Start the server:

sglang serve --model-path baidu/ERNIE-Image-Turbo

Send a generation request:

curl -X POST http://localhost:30000/generate \
  -H "Content-Type: application/json" \
  -d '{
    "prompt": "This is a photograph depicting an urban street scene. Shot at eye level, it shows a covered pedestrian or commercial street. Slightly below the center of the frame, a cyclist rides away from the camera toward the background, appearing as a dark silhouette against backlighting with indistinct details. The ground is paved with regular square tiles, bisected by a prominent tactile paving strip running through the scene, whose raised textures are clearly visible under the light. Light streams in diagonally from the right side of the frame, creating a strong backlight effect with a distinct Tyndall effect—visible light beams illuminating dust or vapor in the air and casting long shadows across the street. Several pedestrians appear on the left side and in the distance, some with their backs to the camera and others walking sideways, all rendered as silhouettes or semi-silhouettes. The overall color palette is warm, dominated by golden yellows and dark browns, evoking the atmosphere of dusk or early morning.",
    "height": 1264,
    "width": 848,
    "num_inference_steps": 8,
    "guidance_scale": 1.0,
    "use_pe": true
  }' \
  --output output.png

---

license: mit language:

• en base_model:
• Qwen/Qwen3.5-2B
• Qwen/Qwen3.5-2B-Base pipeline_tag: image-text-to-text author: Rohit Dey tags:
• vLLM
• unsloth
• qwen
• qwen3.5
• qwen3.5-2B
• reasoning
• chain-of-thought
• qlora library_name: transformers

---

Model Card: RohitUltimate/Qwen3.5_VL_2B_12k

Description

This model is a fine-tuned vision-language model based on Qwen3.5-2B, optimized for image-text-to-text tasks with extended context length (12k tokens).

Compared to the base and standard fine-tuned variants, this model demonstrates improved performance on instruction-following and multimodal understanding, benefiting from higher-quality training data and better alignment.

It is designed to run efficiently on GPUs with under 8GB VRAM, enabling low-cost deployment without significant performance compromise.

---

vLLM Inference Pipeline

vLLM is a high-throughput and memory-efficient inference and serving engine for LLMs. You can run this model using vLLM with the following Docker command:

docker run --gpus all -p 8000:8000 vllm/vllm-openai:latest \
  --model RohitUltimate/Qwen3.5_VL_2B_12k \
  --huggingface_token <YOUR_HF_TOKEN> \
  --tokenizer Qwen/Qwen3.5-2B \
  --dtype bfloat16 \
  --trust-remote-code \
  --gpu-memory-utilization 0.9 \
  --max-model-len 12000

Discussion:

If you need more information, have suggestions, or face any issues while using this model, feel free to start a discussion.

Let’s collaborate and grow this community stronger

---

license: gemma library_name: gguf pipeline_tag: text-generation base_model: google/gemma-4-31b-it base_model_relation: finetune language:

• en
• ko tags:
• gemma
• gemma4
• gguf
• llama.cpp
• q4_k_m
• uncensored
• chat
• coding
• reasoning

---

SuperGemma4-31b-abliterated-GGUF

If this release helps you, support future drops on Ko-fi.

SuperGemma4-31b-abliterated-GGUF is the GGUF release of SuperGemma4-31b-abliterated, packaged for llama.cpp-compatible runtimes and built for people who want a fully uncensored, harder-hitting Gemma 4 31B experience on local hardware.

This release keeps the same product direction as the MLX version:

• fully uncensored chat with fewer brakes
• stronger coding and technical help
• sharper reasoning and planning
• better real-world usefulness for local users
• a surprisingly lightweight-feeling 31B deployment path for GGUF users

What you get

• GGUF quantized weights for local deployment
• Gemma chat template alongside the model files
• a straightforward path for llama.cpp, LM Studio, and other GGUF tooling

Why people will like it

This release was pushed toward the things end users notice immediately:

• much more open uncensored conversation
• stronger coding, debugging, and implementation help
• more useful answers on practical prompts instead of generic filler
• a local experience that feels sharper, more direct, and more builder-friendly
• a 31B release that feels leaner and punchier than the label suggests

In short: this is the Gemma 4 31B local drop for people who want fewer brakes, more capability, and a more addictive day-to-day experience.

Recommended usage

Example with llama.cpp:

llama-cli -m SuperGemma4-31b-abliterated.Q4_K_M.gguf -p "Write a clean FastAPI CRUD example." -n 256

Included clean-output helper

This release includes supergemma_guard.py and supergemma_gguf_guarded_generate.py for app-layer cleanup when you want especially clean JSON or stricter final formatting.

Example:

python supergemma_gguf_guarded_generate.py \
  --model SuperGemma4-31b-abliterated.Q4_K_M.gguf \
  --chat-template-file chat_template.jinja \
  --prompt 'Return only valid JSON with keys "title" and "steps".'

Recommended behaviors:

• require raw JSON for JSON-only endpoints
• strip stray internal markers before presenting answers
• keep structured-output prompts explicit and narrow

Support

If you want to support more uncensored local model releases, benchmarks, and packaging work:

• Ko-fi

---

license: other license_name: sam-license license_link: LICENSE

WIP, for PR: https://github.com/Comfy-Org/ComfyUI/pull/13408

---

license: apache-2.0 language:

• en
• ja programming_language:
• C
• C++
• C#
• Go
• Java
• JavaScript
• Lua
• PHP
• Python
• Ruby
• Rust
• Scala
• TypeScript pipeline_tag: text-generation library_name: transformers inference: false tags:
• heretic
• uncensored
• decensored
• abliterated
• ara base_model:
• llm-jp/llm-jp-4-8b-instruct

---

Heretic の PR #211 で提案されている Arbitrary-Rank Ablation (ARA) を用いて llm-jp/llm-jp-4-8b-instruct に対して検閲解除を行ったモデルです。

Abliteration parameters

| Parameter | Value | | :-------- | :---: | | start_layer_index | 1 | | end_layer_index | 26 | | preserve_good_behavior_weight | 0.9630 | | steer_bad_behavior_weight | 0.0063 | | overcorrect_relative_weight | 0.4803 | | neighbor_count | 11 |

Performance

| Metric | This model | Original model (llm-jp/llm-jp-4-8b-instruct) | | :----- | :--------: | :---------------------------: | | KL divergence | 0.0781 | 0 (by definition) | | Refusals | 5/100 | 99/100 |

---

llm-jp-4-8b-instruct

LLM-jp-4 is a series of large language models developed by the Research and Development Center for Large Language Models at the National Institute of Informatics.

This repository provides the llm-jp-4-8b-instruct For an overview of the LLM-jp-4 models across different parameter sizes, please refer to:

• LLM-jp-4 Models

Base models are trained with pre-training and mid-training only. Post-trained models are aligned using supervised fine-tuning (SFT) and direct preference optimization (DPO), without reinforcement learning.

[!NOTE] While the thinking variants are trained with both SFT and DPO, this instruct model is trained using SFT only, without DPO.

For practical usage examples and detailed instructions on how to use the models, please also refer to our cookbook.

Usage

Please refer to our cookbook for practical usage examples and detailed instructions on how to use the models.

Model Details

• Model type: Transformer-based Language Model
• Architectures:

Dense model: |Params|Layers|Hidden size|Heads|Context length|Embedding parameters|Non-embedding parameters|Total parameters| |:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:| |8B|32|4,096|32|65,536|805,306,368|7,784,894,464|8,590,200,832|

MoE model: |Params|Layers|Hidden size|Heads|Routed Experts|Activated Experts|Context length|Embedding parameters|Non-embedding parameters|Activated parameters|Total parameters| |:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:| |32B-A3B|32|2,560|40|128|8|65,536|503,316,480|31,635,712,512|3,827,476,992|32,139,028,992|

Tokenizer

The tokenizer of this model is based on huggingface/tokenizers Unigram byte-fallback model. The vocabulary entries were converted from llm-jp-tokenizer v4.0. Please refer to README.md of llm-jp-tokenizer for details on the vocabulary construction procedure (the pure SentencePiece training does not reproduce our vocabulary).

[!NOTE] The chat template of this model is designed to be compatible with the OpenAI Harmony response format. However, the tokenizer differs from the one assumed by the openai-harmony library, and therefore direct tokenization with openai-harmony is not supported. For correct behavior, please use the tokenizer provided with this model. For detailed usage, please refer to our cookbook.

Training

Pre-training

This model is trained through a multi-stage pipeline consisting of pre-training and mid-training phases, using a total of 11.7T tokens.

The corpora used for pre-training and mid-training are publicly available at the following links:

• Pre-training
• Mid-training

[!NOTE] Although most of the corpora have been released, some portions are excluded from public release due to licensing constraints.

Post-training

We have fine-tuned the pre-trained checkpoint using SFT and further aligned it with DPO.

The datasets used for post-training are also publicly available at the following links:

• SFT
• DPO (for llm-jp-4-8b-thinking model)
• DPO (for llm-jp-4-32b-a3b-thinking model)

Evaluation

llm-jp-judge

We evaluated the model on a variety of tasks using an LLM-as-a-Judge framework. The descriptions of each task are as follows.

• MT-Bench (JA/EN): A benchmark for measuring multi-turn conversational task-solving ability.
• AnswerCarefully: A benchmark for evaluating safety in Japanese. We used 336 questions from the v2.0 test set.
• llm-jp-instructions: A set of human-created single-turn question–answer pairs. We used 400 questions from the test set.

We evaluated the models using gpt-5.4-2026-03-05.

[!NOTE] Note: In earlier evaluations of the llm-jp-3 series, we used gpt-4o-2024-08-06. The newer evaluator gpt-5.4-2026-03-05 provides a stricter and more reliable assessment, which results in lower scores on benchmarks such as MT-Bench compared to those reported for the llm-jp-3 series.

The scores represent the average values obtained from three rounds of inference and evaluation. For more details, please refer to the codes.

| Model Name | MT-Bench (JA) | MT-Bench (EN) | AnswerCarefully | llm-jp-instructions | |:-------------------------------------------------------------------------------------------------------|----:|----:|----------------:|--------------------:| | gpt-4o-2024-08-06 | 7.29 | 7.69 | 4.00 | 4.07 | | gpt-5.4-2026-03-05 (reasoning_effort = low) | 8.87 | 8.76 | 4.38 | 4.79 | | gpt-5.4-2026-03-05 (reasoning_effort = medium) | 8.87 | 8.89 | 4.43 | 4.82 | | gpt-5.4-2026-03-05 (reasoning_effort = high) | 8.98 | 8.85 | 4.41 | 4.83 | | gpt-oss-20b (reasoning_effort = low) | 7.21 | 7.95 | 3.39 | 3.08 | | gpt-oss-20b (reasoning_effort = medium) | 7.33 | 7.85 | 3.55 | 3.16 | | llm-jp-4-8b-thinking (reasoning_effort = low) | 7.23 | 7.54 | 3.58 | 3.50 | | llm-jp-4-8b-thinking (reasoning_effort = medium) | 7.54 | 7.79 | 3.69 | 3.54 | | llm-jp-4-32b-a3b-thinking (reasoning_effort = low) | 7.57 | 7.70 | 3.61 | 3.61 | | llm-jp-4-32b-a3b-thinking (reasoning_effort = medium) | 7.82 | 7.86 | 3.70 | 3.61 |

Risks and Limitations

The models released here are in the early stages of our research and development and have not been tuned to ensure outputs align with human intent and safety considerations.

Send Questions to

llm-jp(at)nii.ac.jp

License

Apache License, Version 2.0

Acknowledgement

To develop this model, we used the NINJAL Web Japanese Corpus (whole-NWJC) from the National Institute for Japanese Language and Linguistics (NINJAL).

Model Card Authors

The names are listed in alphabetical order.

Hirokazu Kiyomaru and Takashi Kodama.

---

base_model: MiniMaxAI/MiniMax-M2.7 library_name: mlx pipeline_tag: text-generation license: other license_name: non-commercial license_link: https://github.com/MiniMax-AI/MiniMax-M2.7/blob/main/LICENSE tags:

• mlx
• mlx-lm
• minimax
• minimax_m2
• moe
• mixture-of-experts
• abliterated
• uncensored
• heretic
• ara quantized_by: Youssofal

---

MiniMax-M2.7-Abliterated-Heretic-MLX

This is an MLX release of an abliterated version of MiniMaxAI's MiniMax-M2.7.

By applying Heretic's Ablated Refusal Adaptation (ARA), the base refusal behavior was removed at the weight level. The result keeps MiniMax-M2.7's sparse MoE reasoning, long-context instruction following, and general capability profile, but no longer defaults to the original refusal pattern.

Methodology & Model Notes

MiniMax-M2.7 is a 229B sparse MoE model with 10B active parameters per token, 62 layers, hybrid attention, 256 local experts with 8 active per token, and a 200K context window.

This release was produced with a direct Heretic ARA run using the fixed parameter set below:

• start_layer_index = 30
• end_layer_index = 51
• preserve_good_behavior_weight = 0.4512
• steer_bad_behavior_weight = 0.0037
• overcorrect_relative_weight = 0.8804
• neighbor_count = 14

The direct ARA run completed with Refusals: 0/25.

The resulting abliterated checkpoint was exported to BF16 and then converted into Apple MLX variants for local deployment on Apple Silicon hardware.

Files

• MiniMax-M2.7-Abliterated-MLX-3bit-mixed_3_4/: Layer-aware 3-bit MLX build with 4-bit treatment on sensitive modules
• MiniMax-M2.7-Abliterated-MLX-4bit-mixed_4_5/: Layer-aware 4-bit MLX build with 5-bit treatment on sensitive modules
• MiniMax-M2.7-Abliterated-MLX-5bit-tuned/: 5-bit MLX build with tighter grouping on sensitive modules
• MiniMax-M2.7-Abliterated-MLX-6bit-tuned/: 6-bit MLX build with tighter grouping on sensitive modules

Only variants that pass the local MLX validation suite should remain published in this repo.

Prompt Format

]~!b[]~b]system
{system_prompt}[e~[
]~b]user
{prompt}[e~[
]~b]ai
<think>

Running

from mlx_lm import load, generate

model, tokenizer = load("Youssofal/MiniMax-M2.7-Abliterated-Heretic-MLX")

messages = [{"role": "user", "content": "Write a short Python function that reverses a string."}]
prompt = tokenizer.apply_chat_template(
    messages,
    tokenize=False,
    add_generation_prompt=True,
)

response = generate(model, tokenizer, prompt=prompt, max_tokens=256)
print(response)

Validation

Every published variant is intended to pass:

• the official 20-prompt refusal check from mlabonne/harmful_behaviors
• a local coherence smoke check for normal conversation, reasoning, and code output

Model Architecture

| Spec | Value | |---|---| | Total Parameters | 229B (sparse MoE) | | Active Parameters | 10B per token | | Experts | 256 local, 8 per token | | Layers | 62 | | Attention | Hybrid: 7 Lightning + 1 softmax per 8-block | | Context | 200K | | Base Model | MiniMaxAI/MiniMax-M2.7 |

Disclaimer

This model has had refusal behavior removed at the weight level. It will answer prompts that the base model would normally refuse. You are responsible for how you use it.

Credits

• Base model: MiniMaxAI/MiniMax-M2.7
• Refusal removal pipeline: Heretic with the ARA method
• Apple Silicon runtime: mlx-lm

License

This release inherits the base MiniMax-M2.7 license.

NON-COMMERCIAL. Commercial use requires written authorization from MiniMax.

---

language:

• en
• de
• tr
• fr
• es
• it
• pt
• nl
• pl
• sv
• da
• 'no'
• fi
• cs
• hu
• ro
• vi
• id
• ms
• sw
• tl
• zu
• hr
• sk
• sl
• et
• lv
• lt
• mt
• is
• sq license: cc-by-nc-sa-4.0 base_model:
• unsloth/Qwen3.5-0.8B
• Qwen/Qwen3.5-0.8B tags:
• ocr
• vision-language-model
• document-understanding
• qwen3
• qwen3.5
• gguf
• english
• archival
• text-extraction
• complex-layout pipeline_tag: image-text-to-text

---

English-Document-OCR-Qwen3.5-0.8B

I built this model as part of my ongoing work in document digitization and archival OCR. My goal was to create a small, locally-runnable model that punches above its weight class. This 0.8B release keeps the same overall direction as my earlier Qwen OCR work, but uses improved dataset samples, stronger formatting targets, and better layout preservation. In practice, it produces better output than my previous 2B model on the kinds of structured document OCR I care about most.

This is an updated smaller release focused on English archival and document OCR. If you try it on your documents, I'd love to hear how it performs, feel free to leave feedback in the Community tab.

License: This model is intended for personal and research use only. If you want to use this model in a product or service, or need to process documents commercially, contact ocr@loay.net.

---

Model Details

• Fine-tuned by: loay
• Base Model: unsloth/Qwen3.5-0.8B
• Task: Document OCR
• Training Data: Improved synthetic English document samples following the same family of dataset styles as my earlier Qwen OCR releases, including faded ink, bleed-through artifacts, skewed layouts, historical serif typefaces, charts, figures, formulas, and more challenging structured page compositions
• Output Format: A markdown-first transcription format that preserves paragraph flow and layout structure, uses HTML for tables, uses LaTeX for formulas, emits [image] tags for figures/images, and emits [chart: ...] tags when extracting chart content
• Language Support: This release is optimized for English. I’m planning to release versions for additional languages soon, including support for right-to-left document OCR. See my OCR finetuned models for future updates and related releases.

---

Usage

The model does not require a specific prompt. It will perform OCR on any document image by default. To achieve the best results and prevent conversational hallucinations, use the exact instruction the model was fine-tuned on:

Extract all visible text from this document image and return only the transcription in reading order using a markdown-first format. Use HTML only for tables. Use LaTeX only for formulas.

---

GGUF & Local Inference

Quantized GGUF files are available for use with llama.cpp, LM Studio, Ollama, and similar runtimes.

You must load mmproj-english-document-ocr-qwen3.5-0.8b-f16.gguf alongside your chosen weight file. Without the multimodal projector, the model cannot process images.

| File | Use Case | |------|----------| | english-document-ocr-qwen3.5-0.8b-f16.gguf | Full precision, maximum accuracy | | english-document-ocr-qwen3.5-0.8b-q8_0.gguf | Best quality/size tradeoff for OCR precision | | english-document-ocr-qwen3.5-0.8b-q6_k.gguf | High quality, lower VRAM | | english-document-ocr-qwen3.5-0.8b-q5_k_m.gguf | Balanced quality and speed | | english-document-ocr-qwen3.5-0.8b-q4_k_m.gguf | Fast, efficient local inference | | mmproj-english-document-ocr-qwen3.5-0.8b-f16.gguf | Required multimodal projector (load with any weight above) |

Example with llama.cpp:

llama-cli       --model english-document-ocr-qwen3.5-0.8b-q4_k_m.gguf       --mmproj mmproj-english-document-ocr-qwen3.5-0.8b-f16.gguf       --image your_document.jpg

---

Limitations

• Trained exclusively on synthetic data. May degrade on severe real-world scan artifacts outside the training distribution.
• No handwriting support, relies on base model zero-shot for cursive or marginalia.
• Trained to represent figures and embedded images with [image] tags and to extract chart content using [chart: ...] tags, but performance on complex real-world charts and scientific figures can still be inconsistent.
• Supports LaTeX-style formula output as used in the training pipeline, but difficult mathematical layouts may still degrade on dense or low-quality scans.
• Optimized for LTR latin scripts. For Arabic/RTL documents, see my OCR models.
• May hallucinate or break on very long context from dense pages. If your document is text-heavy, consider splitting it into sections before inference.

---

base_model: baidu/ERNIE-Image license: apache-2.0 pipeline_tag: text-to-image library_name: ggml tags:

• text-to-image
• gguf
• unsloth widget:
• text: LLM teaching sloth output: url: assets/Ernie-Image-GGUF.png

---

---

This is a GGUF quantized version of ERNIE-Image. <br> unsloth/ERNIE-Image-GGUF uses Unsloth Dynamic 2.0 methodology for SOTA performance.

• Important layers are upcasted to higher precision.
• Uses tooling from ComfyUI-GGUF by city96.

<div> <div style="display: flex; gap: 5px; align-items: center; "> <a href="https://github.com/unslothai/unsloth/"> <img src="https://github.com/unslothai/unsloth/raw/main/images/unsloth%20new%20logo.png" width="133"> </a> <a href="https://discord.gg/unsloth"> <img src="https://github.com/unslothai/unsloth/raw/main/images/Discord%20button.png" width="173"> </a> <a href="https://docs.unsloth.ai/basics/unsloth-dynamic-2.0-ggufs"> <img src="https://raw.githubusercontent.com/unslothai/unsloth/refs/heads/main/images/documentation%20green%20button.png" width="143"> </a> </div> </div>

---

ERNIE-Image

<p align="center"> <a href="https://huggingface.co/Baidu/ERNIE-Image">🤗 ERNIE-Image</a> &nbsp;|&nbsp; <a href="https://huggingface.co/Baidu/ERNIE-Image-Turbo">🤗 ERNIE-Image-Turbo</a> &nbsp;|&nbsp; <a href="https://huggingface.co/spaces/baidu/ERNIE-Image-Turbo">🖥️ Huggingface Demo</a> &nbsp;|&nbsp; <br/> <a href="https://aistudio.baidu.com/ernieimage">🖥️ AI Studio Demo</a> &nbsp;|&nbsp; <a href="https://yiyan.baidu.com/blog/posts/ernie-image">📖 Blog</a> &nbsp;|&nbsp; <a href="https://ernieimageprompt.com/">🖼️ Art Gallery</a> <br/> <a href="https://github.com/baidu/ERNIE-Image/blob/main/assets/contacts/WeChat_small.jpg">💬 WeChat(微信)</a> &nbsp;|&nbsp; <a href="https://discord.gg/ByUTbjfG5k">🫨 Discord</a> &nbsp;|&nbsp; <a href="https://x.com/ErnieforDevs">🏷️ X</a> </p>

ERNIE-Image is an open text-to-image generation model developed by the ERNIE-Image team at Baidu. It is built on a single-stream Diffusion Transformer (DiT) and paired with a lightweight Prompt Enhancer that expands brief user inputs into richer structured descriptions. With only 8B DiT parameters, it reaches state-of-the-art performance among open-weight text-to-image models. The model is designed not only for strong visual quality, but also for controllability in practical generation scenarios where accurate content realization matters as much as aesthetics. In particular, ERNIE-Image performs strongly on complex instruction following, text rendering, and structured image generation, making it well suited for commercial posters, comics, multi-panel layouts, and other content creation tasks that require both visual quality and precise control. It also supports a broad range of visual styles, including realistic photography, design-oriented imagery, and more stylized aesthetic outputs.

<p align="center"> <img src="https://cdn-uploads.huggingface.co/production/uploads/5f8d780e5d083370c711f575/QRt1mPSU9SCkcxxFWQje2.jpeg" alt="ERNIE-Image Mosaic" width="100%"> </p>

Highlights:

• Compact but strong: Despite its compact 8B scale, ERNIE-Image remains highly competitive with substantially larger open-weight models across a range of benchmarks.
• Text rendering: ERNIE-Image performs particularly well on dense, long-form, and layout-sensitive text, making it a strong choice for posters, infographics, UI-like images, and other text-heavy visual content.
• Instruction following: The model is able to follow complex prompts involving multiple objects, detailed relationships, and knowledge-intensive descriptions with strong reliability.
• Structured generation: ERNIE-Image is especially effective for structured visual tasks such as posters, comics, storyboards, and multi-panel compositions, where layout and organization are critical.
• Style coverage: In addition to clean and readable design-oriented outputs, the model also supports realistic photography and distinctive stylized aesthetics, including softer and more cinematic visual tones.
• Practical deployment: Thanks to its compact size, ERNIE-Image can run on consumer GPUs with 24G VRAM, which lowers the barrier for research, downstream use, and model adaptation.

Released Versions

ERNIE-Image: Our SFT model, delivers stronger general-purpose capability and instruction fidelity in typically 50 inference steps.

ERNIE-Image-Turbo: Our Turbo model, optimized by DMD and RL, achieves faster speed and higher aesthetics in only 8 inference steps.

Benchmark

GENEval

| Model | Single Object | Two Object | Counting | Colors | Position | Attribute Binding | Overall | |---|---:|---:|---:|---:|---:|---:|---:| | ERNIE-Image (w/o PE) | 1.0000 | 0.9596 | 0.7781 | 0.9282 | 0.8550 | 0.7925 | 0.8856 | | ERNIE-Image (w/ PE) | 0.9906 | 0.9596 | 0.8187 | 0.8830 | 0.8625 | 0.7225 | 0.8728 | | Qwen-Image | 0.9900 | 0.9200 | 0.8900 | 0.8800 | 0.7600 | 0.7700 | 0.8683 | | ERNIE-Image-Turbo (w/o PE) | 1.0000 | 0.9621 | 0.7906 | 0.9202 | 0.7975 | 0.7300 | 0.8667 | | ERNIE-Image-Turbo (w/ PE) | 0.9938 | 0.9419 | 0.8375 | 0.8351 | 0.7950 | 0.7025 | 0.8510 | | FLUX.2-klein-9B | 0.9313 | 0.9571 | 0.8281 | 0.9149 | 0.7175 | 0.7400 | 0.8481 | | Z-Image | 1.0000 | 0.9400 | 0.7800 | 0.9300 | 0.6200 | 0.7700 | 0.8400 | | Z-Image-Turbo | 1.0000 | 0.9500 | 0.7700 | 0.8900 | 0.6500 | 0.6800 | 0.8233 |

OneIG-EN

| Model | Alignment | Text | Reasoning | Style | Diversity | Overall | |---|---:|---:|---:|---:|---:|---:| | Nano Banana 2.0 | 0.8880 | 0.9440 | 0.3340 | 0.4810 | 0.2450 | 0.5780 | | Seedream 4.5 | 0.8910 | 0.9980 | 0.3500 | 0.4340 | 0.2070 | 0.5760 | | ERNIE-Image (w/ PE) | 0.8678 | 0.9788 | 0.3566 | 0.4309 | 0.2411 | 0.5750 | | Seedream 4.0 | 0.8920 | 0.9830 | 0.3470 | 0.4530 | 0.1910 | 0.5730 | | ERNIE-Image-Turbo (w/ PE) | 0.8676 | 0.9666 | 0.3537 | 0.4191 | 0.2212 | 0.5656 | | ERNIE-Image (w/o PE) | 0.8909 | 0.9668 | 0.2950 | 0.4471 | 0.1687 | 0.5537 | | Z-Image | 0.8810 | 0.9870 | 0.2800 | 0.3870 | 0.1940 | 0.5460 | | Qwen-Image | 0.8820 | 0.8910 | 0.3060 | 0.4180 | 0.1970 | 0.5390 | | ERNIE-Image-Turbo (w/o PE) | 0.8795 | 0.9488 | 0.2913 | 0.4277 | 0.1232 | 0.5341 | | FLUX.2-klein-9B | 0.8871 | 0.8657 | 0.3117 | 0.4417 | 0.1560 | 0.5324 | | Qwen-Image-2512 | 0.8760 | 0.9900 | 0.2920 | 0.3380 | 0.1510 | 0.5300 | | GLM-Image | 0.8050 | 0.9690 | 0.2980 | 0.3530 | 0.2130 | 0.5280 | | Z-Image-Turbo | 0.8400 | 0.9940 | 0.2980 | 0.3680 | 0.1390 | 0.5280 |

OneIG-ZH

| Model | Alignment | Text | Reasoning | Style | Diversity | Overall | |---|---:|---:|---:|---:|---:|---:| | Nano Banana 2.0 | 0.8430 | 0.9830 | 0.3110 | 0.4610 | 0.2360 | 0.5670 | | ERNIE-Image (w/ PE) | 0.8299 | 0.9539 | 0.3056 | 0.4342 | 0.2478 | 0.5543 | | Seedream 4.0 | 0.8360 | 0.9860 | 0.3040 | 0.4430 | 0.2000 | 0.5540 | | Seedream 4.5 | 0.8320 | 0.9860 | 0.3000 | 0.4260 | 0.2130 | 0.5510 | | Qwen-Image | 0.8250 | 0.9630 | 0.2670 | 0.4050 | 0.2790 | 0.5480 | | ERNIE-Image-Turbo (w/ PE) | 0.8258 | 0.9386 | 0.3043 | 0.4208 | 0.2281 | 0.5435 | | Z-Image | 0.7930 | 0.9880 | 0.2660 | 0.3860 | 0.2430 | 0.5350 | | ERNIE-Image (w/o PE) | 0.8421 | 0.8979 | 0.2656 | 0.4212 | 0.1772 | 0.5208 | | Qwen-Image-2512 | 0.8230 | 0.9830 | 0.2720 | 0.3420 | 0.1570 | 0.5150 | | GLM-Image | 0.7380 | 0.9760 | 0.2840 | 0.3350 | 0.2210 | 0.5110 | | Z-Image-Turbo | 0.7820 | 0.9820 | 0.2760 | 0.3610 | 0.1340 | 0.5070 | | ERNIE-Image-Turbo (w/o PE) | 0.8326 | 0.9086 | 0.2580 | 0.4002 | 0.1316 | 0.5062 | | FLUX.2-klein-9B | 0.8201 | 0.4920 | 0.2599 | 0.4166 | 0.1625 | 0.4302 |

LongTextBench

| Model | LongText-Bench-EN | LongText-Bench-ZH | Avg | |---|---:|---:|---:| | Seedream 4.5 | 0.9890 | 0.9873 | 0.9882 | | ERNIE-Image (w/ PE) | 0.9804 | 0.9661 | 0.9733 | | GLM-Image | 0.9524 | 0.9788 | 0.9656 | | ERNIE-Image-Turbo (w/ PE) | 0.9675 | 0.9636 | 0.9655 | | Nano Banana 2.0 | 0.9808 | 0.9491 | 0.9650 | | ERNIE-Image-Turbo (w/o PE) | 0.9602 | 0.9675 | 0.9639 | | ERNIE-Image (w/o PE) | 0.9679 | 0.9594 | 0.9636 | | Qwen-Image-2512 | 0.9561 | 0.9647 | 0.9604 | | Qwen-Image | 0.9430 | 0.9460 | 0.9445 | | Z-Image | 0.9350 | 0.9360 | 0.9355 | | Seedream 4.0 | 0.9214 | 0.9261 | 0.9238 | | Z-Image-Turbo | 0.9170 | 0.9260 | 0.9215 | | FLUX.2-klein-9B | 0.8642 | 0.2183 | 0.5413 |

Quick Start

Recommended Parameters

• Resolution:
  • 1024x1024
  • 848x1264
  • 1264x848
  • 768x1376
  • 896x1200
  • 1376x768
  • 1200x896
• Guidance scale: 4.0
• Inference steps: 50

Diffusers

pip install git+https://github.com/huggingface/diffusers

import torch
from diffusers import ErnieImagePipeline

pipe = ErnieImagePipeline.from_pretrained(
    "Baidu/ERNIE-Image",
    torch_dtype=torch.bfloat16,
).to("cuda")

image = pipe(
    prompt="This is a photograph depicting an urban street scene. Shot at eye level, it shows a covered pedestrian or commercial street. Slightly below the center of the frame, a cyclist rides away from the camera toward the background, appearing as a dark silhouette against backlighting with indistinct details. The ground is paved with regular square tiles, bisected by a prominent tactile paving strip running through the scene, whose raised textures are clearly visible under the light. Light streams in diagonally from the right side of the frame, creating a strong backlight effect with a distinct Tyndall effect—visible light beams illuminating dust or vapor in the air and casting long shadows across the street. Several pedestrians appear on the left side and in the distance, some with their backs to the camera and others walking sideways, all rendered as silhouettes or semi-silhouettes. The overall color palette is warm, dominated by golden yellows and dark browns, evoking the atmosphere of dusk or early morning.",
    height=1264,
    width=848,
    num_inference_steps=50,
    guidance_scale=4.0,
    use_pe=True # use prompt enhancer
).images[0]

image.save("output.png")

SGLang

Install the latest version of sglang:

git clone https://github.com/sgl-project/sglang.git

Start the server:

sglang serve --model-path baidu/ERNIE-Image

Send a generation request:

curl -X POST http://localhost:30000/generate \
  -H "Content-Type: application/json" \
  -d '{
    "prompt": "This is a photograph depicting an urban street scene. Shot at eye level, it shows a covered pedestrian or commercial street. Slightly below the center of the frame, a cyclist rides away from the camera toward the background, appearing as a dark silhouette against backlighting with indistinct details. The ground is paved with regular square tiles, bisected by a prominent tactile paving strip running through the scene, whose raised textures are clearly visible under the light. Light streams in diagonally from the right side of the frame, creating a strong backlight effect with a distinct Tyndall effect—visible light beams illuminating dust or vapor in the air and casting long shadows across the street. Several pedestrians appear on the left side and in the distance, some with their backs to the camera and others walking sideways, all rendered as silhouettes or semi-silhouettes. The overall color palette is warm, dominated by golden yellows and dark browns, evoking the atmosphere of dusk or early morning.",
    "height": 1264,
    "width": 848,
    "num_inference_steps": 50,
    "guidance_scale": 4.0,
    "use_pe": true

  }' \
  --output output.png