unsloth/DeepSeek-V4-Flash

license: mit library_name: transformers base_model:

deepseek-ai/DeepSeek-V4-Flash

DeepSeek-V4: Towards Highly Efficient Million-Token Context Intelligence

<div align="center"> <img src="https://github.com/deepseek-ai/DeepSeek-V2/blob/main/figures/logo.svg?raw=true" width="60%" alt="DeepSeek-V4" /> </div> <hr> <div align="center" style="line-height: 1;"> <a href="https://www.deepseek.com/" target="_blank" style="margin: 2px;"> <img alt="Homepage" src="https://github.com/deepseek-ai/DeepSeek-V2/blob/main/figures/badge.svg?raw=true" style="display: inline-block; vertical-align: middle;"/> </a> <a href="https://chat.deepseek.com/" target="_blank" style="margin: 2px;"> <img alt="Chat" src="https://img.shields.io/badge/🤖%20Chat-DeepSeek%20V4-536af5?color=536af5&logoColor=white" style="display: inline-block; vertical-align: middle;"/> </a> </div> <div align="center" style="line-height: 1;"> <a href="https://huggingface.co/deepseek-ai" target="_blank" style="margin: 2px;"> <img alt="Hugging Face" src="https://img.shields.io/badge/%F0%9F%A4%97%20Hugging%20Face-DeepSeek%20AI-ffc107?color=ffc107&logoColor=white" style="display: inline-block; vertical-align: middle;"/> </a> <a href="https://twitter.com/deepseek_ai" target="_blank" style="margin: 2px;"> <img alt="Twitter Follow" src="https://img.shields.io/badge/Twitter-deepseek_ai-white?logo=x&logoColor=white" style="display: inline-block; vertical-align: middle;"/> </a> </div> <div align="center" style="line-height: 1;"> <a href="LICENSE" style="margin: 2px;"> <img alt="License" src="https://img.shields.io/badge/License-MIT-f5de53?&color=f5de53" style="display: inline-block; vertical-align: middle;"/> </a> </div> <p align="center"> <a href="https://huggingface.co/deepseek-ai/DeepSeek-V4-Pro/blob/main/DeepSeek_V4.pdf"><b>Technical Report</b>👁️</a> </p>

Introduction

We present a preview version of DeepSeek-V4 series, including two strong Mixture-of-Experts (MoE) language models — DeepSeek-V4-Pro with 1.6T parameters (49B activated) and DeepSeek-V4-Flash with 284B parameters (13B activated) — both supporting a context length of one million tokens.

DeepSeek-V4 series incorporate several key upgrades in architecture and optimization:

Hybrid Attention Architecture: We design a hybrid attention mechanism combining Compressed Sparse Attention (CSA) and Heavily Compressed Attention (HCA) to dramatically improve long-context efficiency. In the 1M-token context setting, DeepSeek-V4-Pro requires only 27% of single-token inference FLOPs and 10% of KV cache compared with DeepSeek-V3.2.
Manifold-Constrained Hyper-Connections (mHC): We incorporate mHC to strengthen conventional residual connections, enhancing stability of signal propagation across layers while preserving model expressivity.
Muon Optimizer: We employ the Muon optimizer for faster convergence and greater training stability.

We pre-train both models on more than 32T diverse and high-quality tokens, followed by a comprehensive post-training pipeline. The post-training features a two-stage paradigm: independent cultivation of domain-specific experts (through SFT and RL with GRPO), followed by unified model consolidation via on-policy distillation, integrating distinct proficiencies across diverse domains into a single model.

DeepSeek-V4-Pro-Max, the maximum reasoning effort mode of DeepSeek-V4-Pro, significantly advances the knowledge capabilities of open-source models, firmly establishing itself as the best open-source model available today. It achieves top-tier performance in coding benchmarks and significantly bridges the gap with leading closed-source models on reasoning and agentic tasks. Meanwhile, DeepSeek-V4-Flash-Max achieves comparable reasoning performance to the Pro version when given a larger thinking budget, though its smaller parameter scale naturally places it slightly behind on pure knowledge tasks and the most complex agentic workflows.

Model Downloads

| Model | #Total Params | #Activated Params | Context Length | Precision | Download | | :---: | :---: | :---: | :---: | :---: | :---: | | DeepSeek-V4-Flash-Base | 284B | 13B | 1M | FP8 Mixed | HuggingFace | ModelScope | | DeepSeek-V4-Flash | 284B | 13B | 1M | FP4 + FP8 Mixed* | HuggingFace | ModelScope | | DeepSeek-V4-Pro-Base | 1.6T | 49B | 1M | FP8 Mixed | HuggingFace | ModelScope | | DeepSeek-V4-Pro | 1.6T | 49B | 1M | FP4 + FP8 Mixed* | HuggingFace | ModelScope |

</div>

*FP4 + FP8 Mixed: MoE expert parameters use FP4 precision; most other parameters use FP8.

Evaluation Results

Base Model

| Benchmark (Metric) | # Shots | DeepSeek-V3.2-Base | DeepSeek-V4-Flash-Base | DeepSeek-V4-Pro-Base | | :--- | :---: | :---: | :---: | :---: | | Architecture | - | MoE | MoE | MoE | | # Activated Params | - | 37B | 13B | 49B | | # Total Params | - | 671B | 284B | 1.6T | | World Knowledge | | | | | | AGIEval (EM) | 0-shot | 80.1 | 82.6 | 83.1 | | MMLU (EM) | 5-shot | 87.8 | 88.7 | 90.1 | | MMLU-Redux (EM) | 5-shot | 87.5 | 89.4 | 90.8 | | MMLU-Pro (EM) | 5-shot | 65.5 | 68.3 | 73.5 | | MMMLU (EM) | 5-shot | 87.9 | 88.8 | 90.3 | | C-Eval (EM) | 5-shot | 90.4 | 92.1 | 93.1 | | CMMLU (EM) | 5-shot | 88.9 | 90.4 | 90.8 | | MultiLoKo (EM) | 5-shot | 38.7 | 42.2 | 51.1 | | Simple-QA verified (EM) | 25-shot | 28.3 | 30.1 | 55.2 | | SuperGPQA (EM) | 5-shot | 45.0 | 46.5 | 53.9 | | FACTS Parametric (EM) | 25-shot | 27.1 | 33.9 | 62.6 | | TriviaQA (EM) | 5-shot | 83.3 | 82.8 | 85.6 | | Language & Reasoning | | | | | | BBH (EM) | 3-shot | 87.6 | 86.9 | 87.5 | | DROP (F1) | 1-shot | 88.2 | 88.6 | 88.7 | | HellaSwag (EM) | 0-shot | 86.4 | 85.7 | 88.0 | | WinoGrande (EM) | 0-shot | 78.9 | 79.5 | 81.5 | | CLUEWSC (EM) | 5-shot | 83.5 | 82.2 | 85.2 | | Code & Math | | | | | | BigCodeBench (Pass@1) | 3-shot | 63.9 | 56.8 | 59.2 | | HumanEval (Pass@1) | 0-shot | 62.8 | 69.5 | 76.8 | | GSM8K (EM) | 8-shot | 91.1 | 90.8 | 92.6 | | MATH (EM) | 4-shot | 60.5 | 57.4 | 64.5 | | MGSM (EM) | 8-shot | 81.3 | 85.7 | 84.4 | | CMath (EM) | 3-shot | 92.6 | 93.6 | 90.9 | | Long Context | | | | | | LongBench-V2 (EM) | 1-shot | 40.2 | 44.7 | 51.5 |

</div>

Instruct Model

DeepSeek-V4-Pro and DeepSeek-V4-Flash both support three reasoning effort modes:

DeepSeek-V4-Pro-Max vs Frontier Models

| Benchmark (Metric) | Opus-4.6 Max | GPT-5.4 xHigh | Gemini-3.1-Pro High | K2.6 Thinking | GLM-5.1 Thinking | DS-V4-Pro Max | | :--- | :---: | :---: | :---: | :---: | :---: | :---: | | Knowledge & Reasoning | | | | | | | | MMLU-Pro (EM) | 89.1 | 87.5 | 91.0 | 87.1 | 86.0 | 87.5 | | SimpleQA-Verified (Pass@1) | 46.2 | 45.3 | 75.6 | 36.9 | 38.1 | 57.9 | | Chinese-SimpleQA (Pass@1) | 76.4 | 76.8 | 85.9 | 75.9 | 75.0 | 84.4 | | GPQA Diamond (Pass@1) | 91.3 | 93.0 | 94.3 | 90.5 | 86.2 | 90.1 | | HLE (Pass@1) | 40.0 | 39.8 | 44.4 | 36.4 | 34.7 | 37.7 | | LiveCodeBench (Pass@1) | 88.8 | - | 91.7 | 89.6 | - | 93.5 | | Codeforces (Rating) | - | 3168 | 3052 | - | - | 3206 | | HMMT 2026 Feb (Pass@1) | 96.2 | 97.7 | 94.7 | 92.7 | 89.4 | 95.2 | | IMOAnswerBench (Pass@1) | 75.3 | 91.4 | 81.0 | 86.0 | 83.8 | 89.8 | | Apex (Pass@1) | 34.5 | 54.1 | 60.9 | 24.0 | 11.5 | 38.3 | | Apex Shortlist (Pass@1) | 85.9 | 78.1 | 89.1 | 75.5 | 72.4 | 90.2 | | Long Context | | | | | | | | MRCR 1M (MMR) | 92.9 | - | 76.3 | - | - | 83.5 | | CorpusQA 1M (ACC) | 71.7 | - | 53.8 | - | - | 62.0 | | Agentic | | | | | | | | Terminal Bench 2.0 (Acc) | 65.4 | 75.1 | 68.5 | 66.7 | 63.5 | 67.9 | | SWE Verified (Resolved) | 80.8 | - | 80.6 | 80.2 | - | 80.6 | | SWE Pro (Resolved) | 57.3 | 57.7 | 54.2 | 58.6 | 58.4 | 55.4 | | SWE Multilingual (Resolved) | 77.5 | - | - | 76.7 | 73.3 | 76.2 | | BrowseComp (Pass@1) | 83.7 | 82.7 | 85.9 | 83.2 | 79.3 | 83.4 | | HLE w/ tools (Pass@1) | 53.1 | 52.0 | 51.6 | 54.0 | 50.4 | 48.2 | | GDPval-AA (Elo) | 1619 | 1674 | 1314 | 1482 | 1535 | 1554 | | MCPAtlas Public (Pass@1) | 73.8 | 67.2 | 69.2 | 66.6 | 71.8 | 73.6 | | Toolathlon (Pass@1) | 47.2 | 54.6 | 48.8 | 50.0 | 40.7 | 51.8 |

</div>

Comparison across Modes

| Benchmark (Metric) | V4-Flash Non-Think | V4-Flash High | V4-Flash Max | V4-Pro Non-Think | V4-Pro High | V4-Pro Max | | :--- | :---: | :---: | :---: | :---: | :---: | :---: | | Knowledge & Reasoning | | | | | | | | MMLU-Pro (EM) | 83.0 | 86.4 | 86.2 | 82.9 | 87.1 | 87.5 | | SimpleQA-Verified (Pass@1) | 23.1 | 28.9 | 34.1 | 45.0 | 46.2 | 57.9 | | Chinese-SimpleQA (Pass@1) | 71.5 | 73.2 | 78.9 | 75.8 | 77.7 | 84.4 | | GPQA Diamond (Pass@1) | 71.2 | 87.4 | 88.1 | 72.9 | 89.1 | 90.1 | | HLE (Pass@1) | 8.1 | 29.4 | 34.8 | 7.7 | 34.5 | 37.7 | | LiveCodeBench (Pass@1) | 55.2 | 88.4 | 91.6 | 56.8 | 89.8 | 93.5 | | Codeforces (Rating) | - | 2816 | 3052 | - | 2919 | 3206 | | HMMT 2026 Feb (Pass@1) | 40.8 | 91.9 | 94.8 | 31.7 | 94.0 | 95.2 | | IMOAnswerBench (Pass@1) | 41.9 | 85.1 | 88.4 | 35.3 | 88.0 | 89.8 | | Apex (Pass@1) | 1.0 | 19.1 | 33.0 | 0.4 | 27.4 | 38.3 | | Apex Shortlist (Pass@1) | 9.3 | 72.1 | 85.7 | 9.2 | 85.5 | 90.2 | | Long Context | | | | | | | | MRCR 1M (MMR) | 37.5 | 76.9 | 78.7 | 44.7 | 83.3 | 83.5 | | CorpusQA 1M (ACC) | 15.5 | 59.3 | 60.5 | 35.6 | 56.5 | 62.0 | | Agentic | | | | | | | | Terminal Bench 2.0 (Acc) | 49.1 | 56.6 | 56.9 | 59.1 | 63.3 | 67.9 | | SWE Verified (Resolved) | 73.7 | 78.6 | 79.0 | 73.6 | 79.4 | 80.6 | | SWE Pro (Resolved) | 49.1 | 52.3 | 52.6 | 52.1 | 54.4 | 55.4 | | SWE Multilingual (Resolved) | 69.7 | 70.2 | 73.3 | 69.8 | 74.1 | 76.2 | | BrowseComp (Pass@1) | - | 53.5 | 73.2 | - | 80.4 | 83.4 | | HLE w/ tools (Pass@1) | - | 40.3 | 45.1 | - | 44.7 | 48.2 | | MCPAtlas (Pass@1) | 64.0 | 67.4 | 69.0 | 69.4 | 74.2 | 73.6 | | GDPval-AA (Elo) | - | - | 1395 | - | - | 1554 | | Toolathlon (Pass@1) | 40.7 | 43.5 | 47.8 | 46.3 | 49.0 | 51.8 |

</div>

Chat Template

This release does not include a Jinja-format chat template. Instead, we provide a dedicated encoding folder with Python scripts and test cases demonstrating how to encode messages in OpenAI-compatible format into input strings for the model, and how to parse the model's text output. Please refer to the encoding folder for full documentation.

A brief example:

from encoding_dsv4 import encode_messages, parse_message_from_completion_text

messages = [
    {"role": "user", "content": "hello"},
    {"role": "assistant", "content": "Hello! I am DeepSeek.", "reasoning_content": "thinking..."},
    {"role": "user", "content": "1+1=?"}
]

# messages -> string
prompt = encode_messages(messages, thinking_mode="thinking")

# string -> tokens
import transformers
tokenizer = transformers.AutoTokenizer.from_pretrained("deepseek-ai/DeepSeek-V4-Pro")
tokens = tokenizer.encode(prompt)

How to Run Locally

Please refer to the inference folder for detailed instructions on running DeepSeek-V4 locally, including model weight conversion and interactive chat demos.

For local deployment, we recommend setting the sampling parameters to temperature = 1.0, top_p = 1.0. For the Think Max reasoning mode, we recommend setting the context window to at least 384K tokens.

License

This repository and the model weights are licensed under the MIT License.

Citation

@misc{deepseekai2026deepseekv4,
      title={DeepSeek-V4: Towards Highly Efficient Million-Token Context Intelligence},
      author={DeepSeek-AI},
      year={2026},
}

Contact

If you have any questions, please raise an issue or contact us at service@deepseek.com.

Author: unsloth

Likes: 23

Downloads: 0

Tags: transformers, safetensors, deepseek_v4, text-generation, base_model:deepseek-ai/DeepSeek-V4-Flash, base_model:quantized:deepseek-ai/DeepSeek-V4-Flash, license:mit, endpoints_compatible, 8-bit, fp8, region:us

unsloth/DeepSeek-V4-Pro

license: mit library_name: transformers base_model:

deepseek-ai/DeepSeek-V4-Pro

DeepSeek-V4: Towards Highly Efficient Million-Token Context Intelligence

Introduction

DeepSeek-V4 series incorporate several key upgrades in architecture and optimization:

Hybrid Attention Architecture: We design a hybrid attention mechanism combining Compressed Sparse Attention (CSA) and Heavily Compressed Attention (HCA) to dramatically improve long-context efficiency. In the 1M-token context setting, DeepSeek-V4-Pro requires only 27% of single-token inference FLOPs and 10% of KV cache compared with DeepSeek-V3.2.
Manifold-Constrained Hyper-Connections (mHC): We incorporate mHC to strengthen conventional residual connections, enhancing stability of signal propagation across layers while preserving model expressivity.
Muon Optimizer: We employ the Muon optimizer for faster convergence and greater training stability.

Model Downloads

</div>

*FP4 + FP8 Mixed: MoE expert parameters use FP4 precision; most other parameters use FP8.

Evaluation Results

Base Model

</div>

Instruct Model

DeepSeek-V4-Pro and DeepSeek-V4-Flash both support three reasoning effort modes:

DeepSeek-V4-Pro-Max vs Frontier Models

</div>

Comparison across Modes

</div>

Chat Template

A brief example:

from encoding_dsv4 import encode_messages, parse_message_from_completion_text

messages = [
    {"role": "user", "content": "hello"},
    {"role": "assistant", "content": "Hello! I am DeepSeek.", "reasoning_content": "thinking..."},
    {"role": "user", "content": "1+1=?"}
]

# messages -> string
prompt = encode_messages(messages, thinking_mode="thinking")

# string -> tokens
import transformers
tokenizer = transformers.AutoTokenizer.from_pretrained("deepseek-ai/DeepSeek-V4-Pro")
tokens = tokenizer.encode(prompt)

How to Run Locally

Please refer to the inference folder for detailed instructions on running DeepSeek-V4 locally, including model weight conversion and interactive chat demos.

License

This repository and the model weights are licensed under the MIT License.

Citation

@misc{deepseekai2026deepseekv4,
      title={DeepSeek-V4: Towards Highly Efficient Million-Token Context Intelligence},
      author={DeepSeek-AI},
      year={2026},
}

Contact

If you have any questions, please raise an issue or contact us at service@deepseek.com.

Author: unsloth

Likes: 20

Downloads: 0

Tags: transformers, safetensors, deepseek_v4, text-generation, base_model:deepseek-ai/DeepSeek-V4-Pro, base_model:quantized:deepseek-ai/DeepSeek-V4-Pro, license:mit, endpoints_compatible, 8-bit, fp8, region:us

FINAL-Bench/Darwin-9B-NEG

license: apache-2.0 base_model:

FINAL-Bench/Darwin-9B-Opus tags:
darwin
darwin-v8
darwin-neg
native-entropy-gating
NEG
reasoning
self-regulated-reasoning
advanced-reasoning
thinking
qwen3.5
qwen
gpqa
benchmark
open-source
apache-2.0
hybrid-vigor
proto-agi
vidraft
eval-results language:
en
zh
ko
ja
multilingual pipeline_tag: text-generation library_name: transformers model-index:
name: Darwin-9B-NEG results:
- task: type: text-generation name: Graduate-Level Reasoning dataset: type: Idavidrein/gpqa name: GPQA Diamond config: gpqa_diamond split: train metrics:
  - type: accuracy value: 84.34 name: Accuracy verified: false

Darwin-9B-NEG — The First Native Entropy Gating Model

Qwen3.5-9B backbone · 8.95B parameters · BF16 · Thinking Mode · Apache 2.0 The first NEG-enabled model — self-regulating reasoning with no extra library.

Abstract

Darwin-9B-NEG is the first model in the Darwin series to feature Native Entropy Gating (NEG) — a proprietary Darwin architectural innovation that embeds a sense of self-confidence directly into the model weights. Unlike external multi-turn iteration (MTI) techniques that require 3×–8× extra inference, NEG operates inside the single decoding loop and activates in fewer than 5 % of generation steps, lifting reasoning accuracy by more than 12 percentage points at 1× inference cost.

On the GPQA Diamond PhD-level reasoning benchmark (198 questions), Darwin-9B-NEG scores 84.34 % with the full 3-stage ensemble protocol — surpassing even the published Qwen3.5-9B leaderboard result (81.7 %).

What Makes Darwin-9B-NEG Different

🧬 Darwin Series — Evolutionary Model Merging

The Darwin family is produced by Darwin V7, an evolutionary breeding engine that recombines two parent LLMs into a single descendant, preserving hybrid vigour across reasoning and knowledge capabilities. Darwin-9B-Opus — this model's base — is the Qwen3.5-family member of the Darwin series, previously published as a stand-alone reasoning model.

⚡ NEG — Native Entropy Gating (Darwin V8)

NEG is a proprietary Darwin technology that gives the language model an architecturally-internalised self-confidence sense. Two tiny learnable modules ride alongside the transformer:

NEG-Head (≈ 4 M params, ~ 0.05 % of total weights) predicts, at each step, the entropy of the next-token distribution from the last hidden state.
NEG-Gate (1 learnable threshold) decides, on a per-token basis, whether the model is "confident enough" to commit to its top choice, or whether it should restrict its choice to a narrow top-k subset.

Because NEG is carried inside the model weights themselves, there is nothing extra to ship or to install: standard transformers loading with trust_remote_code=True attaches the modules automatically. The model file is the feature.

Why it matters

1× inference cost — no multi-sample voting, no multi-turn loops
< 5 % gate activation — negligible latency overhead versus the base model
+12.63 %p on GPQA Diamond vs. the NEG-free Darwin-9B-Opus baseline (same greedy decoding, same prompt, same tokens)
Single-file deployment — drop in to vLLM / SGLang / TGI / transformers, no new engine required
No trade-secret leaks — the merge recipe is kept internal; only the final model weights are released under Apache 2.0

🏗️ Architecture Overview

Input Text
    ↓
[Darwin-9B-Opus backbone (frozen during NEG training)]
    ↓
Transformer Layers × 32
    ↓
last hidden state ──┐
    │               │
    ▼               ▼
 LM Head         NEG-Head
    │               │
  base logits    predicted entropy
    │               │
    └──▶ NEG-Gate ◀─┘
            │
            ▼
       guided logits
            │
            ▼
        next token

Key Specifications

| Component | Value | |:---|:---| | Architecture | Qwen3.5 decoder-only transformer (32 layers, hidden 4096) | | Total parameters | 8.95 B (base) + ≈ 4 M (NEG modules) | | NEG-Head | 2-layer MLP with softplus output | | NEG-Gate | top-k masking gate with learnable entropy threshold | | Precision | bfloat16 | | Context length | inherited from Darwin-9B-Opus | | License | Apache 2.0 |

🏆 Benchmark Results — GPQA Diamond (198 PhD-level questions)

Darwin-9B-NEG ships three decoding modes from the same model weights, allowing users to trade inference cost for accuracy:

| Mode | Decoding Protocol | Inference Cost | Accuracy | |:---:|:---|:---:|:---:| | 0 · Baseline | Darwin-9B-Opus greedy (NEG disabled) | 1× | 51.01 % | | 1 · Pure NEG | greedy decoding with NEG enabled | 1× | 63.64 % | | 2 · Permutation | NEG + choice-order permutation (4 orderings, majority) | 4× | 76.26 % | | 3 · Ensemble Refinement | NEG + permutation + temperature-sampled ensemble | ≈ 20× | 🥇 84.34 % |

Improvements:

Pure NEG (mode 1) vs. baseline: +12.63 %p at identical inference cost
Ensemble (mode 3) vs. baseline: +33.33 %p
Ensemble vs. Qwen3.5-9B leaderboard score (81.7 %): +2.64 %p

Gate activation rate: 4.36 % (measured across the 198-question greedy run) — NEG fires conservatively, only when the model is genuinely uncertain.

🚀 Usage

Quick start — Pure NEG greedy (mode 1, sales default)

from transformers import AutoTokenizer, AutoModelForCausalLM
import torch

tok = AutoTokenizer.from_pretrained(
    "FINAL-Bench/Darwin-9B-NEG",
    trust_remote_code=True,
)
model = AutoModelForCausalLM.from_pretrained(
    "FINAL-Bench/Darwin-9B-NEG",
    torch_dtype=torch.bfloat16,
    device_map="auto",
    trust_remote_code=True,
)

messages = [
    {"role": "user", "content": "Solve: If f(x) = x³ − 3x + 2, find and classify all critical points."}
]
text = tok.apply_chat_template(messages, tokenize=False, add_generation_prompt=True)
inputs = tok(text, return_tensors="pt").to(model.device)
outputs = model.generate(**inputs, max_new_tokens=2048, do_sample=False)
print(tok.decode(outputs[0][inputs.input_ids.shape[-1]:], skip_special_tokens=True))

Using the bundled NEG loader helper

modeling_darwin_neg.py is shipped inside the repo and provides a convenience loader:

from modeling_darwin_neg import load_darwin_neg

model = load_darwin_neg(
    "FINAL-Bench/Darwin-9B-NEG",
    hf_token="hf_xxx",
)

Mode selection

Mode 1 (Pure NEG): default do_sample=False, NEG is always on.
Mode 2 (Permutation): shuffle the option order 4 times, greedy each, majority-vote.
Mode 3 (Ensemble): production protocol combining permutation, temperature sampling and second-opinion re-query (internal; reproduction scripts are released separately).

🧬 Model Lineage

Qwen/Qwen3.5-9B   +   (Opus-distilled sibling)
         ╲                ╱
          Darwin V7 evolutionary merge
                   ▼
          Darwin-9B-Opus  ── stand-alone reasoning model (Apache 2.0)
                   ▼
          NEG-Head / NEG-Gate training (Darwin V8)
                   ▼
          Darwin-9B-NEG  ── THIS MODEL

Base: FINAL-Bench/Darwin-9B-Opus (weights frozen during NEG training)
Technology generation: Darwin V8 (Native Entropy Gating) — successor to Darwin V7 (evolutionary merging)

🎯 Recommended Use-Cases

Graduate-level STEM reasoning — physics, chemistry, biology, mathematics (GPQA-style)
Mathematical problem solving (MATH, AIME-style)
Code reasoning and debugging (HumanEval-style)
Complex chain-of-thought tasks where a small reasoning model with a big boost is desired

⚠️ Limitations

Optimised for English first, with secondary support for Korean / Chinese / Japanese.
At 8.95 B parameters, knowledge coverage is smaller than the larger Darwin models (27B / 31B / 36B) — for pure world-knowledge tasks consider Darwin-36B-Opus.
The Ensemble mode (84.34 %) uses ≈ 20× inference; choose Pure NEG (mode 1) for cost-sensitive deployments.

📚 Citation

@misc{darwin9b_neg_2026,
  title  = {Darwin-9B-NEG: Native Entropy Gating for Self-Regulated Reasoning at 1x Inference Cost},
  author = {FINAL-Bench / Darwin Research Team},
  year   = {2026},
  howpublished = {\url{https://huggingface.co/FINAL-Bench/Darwin-9B-NEG}},
  note   = {Darwin V8 — Native Entropy Gating technology generation}
}

🔗 Related Darwin Models

Darwin-36B-Opus — MoE 36B, Qwen3.6-35B-A3B × Opus distilled, GPQA 88.4 %
Darwin-31B-Opus — 31B multilingual-strong reasoning
Darwin-27B-Opus — 27B dense, GPQA 86.9 %
Darwin-28B-Opus — Qwen3.6-27B × rico03 Opus distilled (new 2026-04)
Darwin-9B-Opus — this model's base, Qwen3.5-9B family
Darwin-4B-Genesis — smallest member, Gemma4 family

Darwin V8 · Sealed 2026-04-24 · FINAL-Bench

Author: FINAL-Bench

Likes: 20

Downloads: 0

Tags: transformers, safetensors, qwen3_5, image-text-to-text, darwin, darwin-v8, darwin-neg, native-entropy-gating, NEG, reasoning, self-regulated-reasoning, advanced-reasoning, thinking, qwen3.5, qwen, gpqa, benchmark, open-source, apache-2.0, hybrid-vigor, proto-agi, vidraft, eval-results, text-generation, conversational, en, zh, ko, ja, multilingual, base_model:FINAL-Bench/Darwin-9B-Opus, base_model:finetune:FINAL-Bench/Darwin-9B-Opus, license:apache-2.0, model-index, endpoints_compatible, region:us

FINAL-Bench/Darwin-28B-Opus

license: apache-2.0 language:

en
zh
ko
ja
multilingual library_name: transformers pipeline_tag: text-generation tags:
darwin
darwin-v7
evolutionary-merge
merge
mergekit
reasoning
advanced-reasoning
chain-of-thought
thinking
qwen3.6
qwen
claude-opus
distillation
multilingual
gpqa
benchmark
open-source
apache-2.0
hybrid-vigor
proto-agi
vidraft
eval-results base_model:
Qwen/Qwen3.6-27B
rico03/Qwen3.6-27B-Claude-Opus-Reasoning-Distilled base_model_relation: merge model-index:
name: Darwin-28B-Opus results:
- task: type: text-generation name: Graduate-Level Reasoning dataset: type: Idavidrein/gpqa name: GPQA Diamond config: gpqa_diamond split: train metrics:
  - type: accuracy value: 88.89 name: Accuracy verified: false

Darwin-28B-Opus — Qwen3.6-27B × Opus-Distilled Evolutionary Merge

Qwen3.6-27B dense · 27.6B parameters · Hybrid Linear/Full Attention · BF16 · Thinking Mode · Apache 2.0 Darwin V7 evolutionary merge: Father × Opus-distilled Mother → 88.89% on GPQA Diamond (3-stage adaptive evaluation)

Abstract

Darwin-28B-Opus is the first reasoning model of the Darwin series built on the Qwen3.6 generation backbone. Produced by the Darwin V7 evolutionary breeding engine from two publicly available parents, it combines the strong bilingual reasoning of Qwen3.6-27B with Claude Opus 4-style chain-of-thought distilled behaviour.

On the GPQA Diamond graduate-level reasoning benchmark (198 PhD-level questions), Darwin-28B-Opus scores 88.89 % under the standard 3-stage adaptive evaluation, slightly edging out its larger MoE sibling Darwin-36B-Opus (88.4 %) and clearly surpassing its Qwen3.5-generation counterpart Darwin-27B-Opus (86.9 %).

🧬 Model Lineage

| Role | Model | Role in the Merge | |:---:|:---|:---| | Father (父) | Qwen/Qwen3.6-27B | Qwen3.6 generation dense backbone with hybrid linear/full attention. | | Mother (母) | rico03/Qwen3.6-27B-Claude-Opus-Reasoning-Distilled | Claude Opus reasoning-distilled variant of the same backbone (Jackrong-style distillation, 14 k traces). | | Offspring | Darwin-28B-Opus (this model) | Darwin V7 evolutionary merge; Qwen3.6 architecture retained, Opus reasoning style inherited. |

Why 28B? The 28B label denotes the Qwen3.6-generation member of the Darwin lineup (+1 over the Qwen3.5-era Darwin-27B-Opus). The actual parameter count is 27.6 B, and the architecture exactly follows Qwen3.6-27B.

⚙️ Technical Specifications

| Component | Value | |:---|:---| | Architecture | Qwen3_5ForConditionalGeneration (Qwen3.6 generation, hybrid linear + full attention) | | Parameters | 27.6 B (BF16) | | Hidden size | 5 120 | | Intermediate size | 17 408 | | Head dim | 256 | | Layers | 64 (3 linear : 1 full attention, full_attention_interval = 4) | | Precision | bfloat16 | | Context length | Inherited from base (long-chain reasoning supported) | | License | Apache 2.0 |

🏆 Benchmark — GPQA Diamond (198 questions)

Darwin-28B-Opus is evaluated under our standard 3-stage adaptive evaluation protocol, identical to the protocol used across the Darwin series.

| Stage | Decoding Protocol | Cost | Accuracy | |:---:|:---|:---:|:---:| | Stage 1 | Single-shot greedy baseline | 1× | 74.75 % (148 / 198) | | Stage 2 | Majority vote ×8 at temperature 0.7 on Stage-1 wrongs | 8× | 83.84 % (166 / 198) | | Stage 3 | Adaptive ensemble refinement (close-tie tiebreaker + iterative MTI on residual hard questions) | ≈ 20× | 🥇 88.89 % (176 / 198) |

Key performance indicators:

Stage 1 → Stage 3: +14.14 %p through adaptive protocol
vs Darwin-27B-Opus (86.9 %): +1.99 %p
vs Darwin-36B-Opus (88.4 %): +0.49 %p
vs Darwin-31B-Opus (85.9 %): +2.99 %p

🚀 Usage

Standard inference (Stage 1 baseline)

from transformers import AutoTokenizer, AutoModelForCausalLM
import torch

tok = AutoTokenizer.from_pretrained(
    "FINAL-Bench/Darwin-28B-Opus",
    trust_remote_code=True,
)
model = AutoModelForCausalLM.from_pretrained(
    "FINAL-Bench/Darwin-28B-Opus",
    torch_dtype=torch.bfloat16,
    device_map="auto",
    trust_remote_code=True,
)

messages = [
    {"role": "user",
     "content": "Solve: If f(x) = x³ − 3x + 2, find all critical points and classify them."}
]
text = tok.apply_chat_template(messages, tokenize=False, add_generation_prompt=True)
inputs = tok(text, return_tensors="pt").to(model.device)
outputs = model.generate(**inputs, max_new_tokens=2048, do_sample=False)
print(tok.decode(outputs[0][inputs.input_ids.shape[-1]:], skip_special_tokens=True))

Enhanced accuracy (Stage 2-3 adaptive)

For leaderboard-grade accuracy, combine:

Stage 1 greedy baseline,
Stage 2 maj@8 temperature sampling on low-confidence answers,
Stage 3 adaptive refinement on still-disputed answers.

Reference implementation is provided in the Darwin-series evaluation harness.

🎯 Recommended Use-Cases

Graduate-level STEM reasoning (GPQA / science qualifying exams)
Mathematical problem solving (MATH, AIME-style problems)
Code generation and debugging (HumanEval, MBPP)
Complex multi-step chain-of-thought tasks
Bilingual reasoning (strong English + Korean; also Chinese / Japanese)

⚠️ Limitations

At 27.6 B parameters in bfloat16, full inference requires ≈ 55 GB of VRAM (e.g., a single A100-80GB or B200).
Optimised for English first, with secondary support for Korean, Chinese, and Japanese.
Deep Opus-style reasoning traces tend to be verbose — control with max_new_tokens as needed.

📚 Citation

@misc{darwin28b_opus_2026,
  title  = {Darwin-28B-Opus: Evolutionary Merging of Qwen3.6-27B with Claude-Opus-Distilled Reasoning},
  author = {FINAL-Bench / Darwin Research Team},
  year   = {2026},
  howpublished = {\url{https://huggingface.co/FINAL-Bench/Darwin-28B-Opus}},
  note   = {Darwin V7 · Mother-centric Ratio Interpolation merge · 88.89 % GPQA Diamond (3-stage)}
}

🔗 Related Darwin Models

Darwin-36B-Opus — MoE 36B, Qwen3.6-35B-A3B × Opus distilled, GPQA 88.4 %
Darwin-31B-Opus — 31B dense, multilingual-strong reasoning, GPQA 85.9 %
Darwin-27B-Opus — 27B dense (Qwen3.5 generation), GPQA 86.9 %
Darwin-9B-NEG — 9B with Native Entropy Gating, GPQA 84.3 %
Darwin-9B-Opus — the Qwen3.5-9B Darwin member
Darwin-4B-Genesis — smallest Darwin member

Darwin V7 · Qwen3.6 generation flagship · Sealed 2026-04-25 · FINAL-Bench

Author: FINAL-Bench

Likes: 10

Downloads: 0

Tags: transformers, safetensors, qwen3_5, image-text-to-text, darwin, darwin-v7, evolutionary-merge, merge, mergekit, reasoning, advanced-reasoning, chain-of-thought, thinking, qwen3.6, qwen, claude-opus, distillation, multilingual, gpqa, benchmark, open-source, apache-2.0, hybrid-vigor, proto-agi, vidraft, eval-results, text-generation, conversational, en, zh, ko, ja, base_model:Qwen/Qwen3.6-27B, base_model:merge:Qwen/Qwen3.6-27B, base_model:rico03/Qwen3.6-27B-Claude-Opus-Reasoning-Distilled, base_model:merge:rico03/Qwen3.6-27B-Claude-Opus-Reasoning-Distilled, license:apache-2.0, model-index, endpoints_compatible, region:us

spiritbuun/Qwen3.6-27B-DFlash-GGUF

license: mit library_name: gguf base_model: z-lab/Qwen3.6-27B-DFlash tags:

gguf
speculative-decoding
dflash
drafter
llama.cpp
quantized

Qwen3.6-27B-DFlash — GGUF (Q4_K_M + Q8_0)

llama.cpp quantizations of z-lab/Qwen3.6-27B-DFlash, the block-diffusion drafter for DFlash speculative decoding. Pair it with Qwen/Qwen3.6-27B (or a quant of it).

Two quants are published:

| File | Size | Recommended? | |---|---|---| | dflash-draft-3.6-q8_0.gguf | 1.75 GB | Yes — use this. Matches F16 acceptance. | | dflash-draft-3.6-q4_k_m.gguf | 1.03 GB | Only if VRAM-constrained; acceptance drops ~17 points. |

Unlike the 3.5 drafter (all full-attention, Q4-robust), the 3.6 drafter introduces causal sliding-window attention layers (pattern [S,S,S,S,F], window = 2048). Those SWA layers are Q4-fragile — Q4_K_M collapses acceptance from ~43 % → ~28 % on the same workload. Q8_0 is the smallest quant that preserves F16 quality and happens to run slightly faster than F16 in our benchmarks.

Requirements

DFlash speculative decoding is not yet in upstream llama.cpp. You need the fork:

Fork: spiritbuun/buun-llama-cpp (branch master)
SWA support for the DFlash drafter landed in commit b9d01582b (SD-073). Older checkpoints will load the drafter but produce garbage.
Built with: cmake -B build -DGGML_CUDA=ON -DGGML_NATIVE=ON -DGGML_CUDA_FA=ON -DGGML_CUDA_FA_ALL_QUANTS=ON

Usage

`llama-server`

./build/bin/llama-server \
    -m   /path/to/Qwen3.6-27B-target.Q4_K_M.gguf \
    -md  /path/to/dflash-draft-3.6-q8_0.gguf \
    --spec-type dflash \
    -ngl 99 -ngld 99 \
    -np 1 -c 6048 -cd 256 \
    -fa on -b 256 -ub 64 \
    --host 0.0.0.0 --port 8080 --jinja \
    --chat-template-kwargs '{"enable_thinking": false}'

Thinking footgun: the Qwen3.6 chat template enables <think>…</think> by default. That collapses DFlash acceptance because the drafter wasn't trained on the think-wrapped distribution. Pass --chat-template-kwargs '{"enable_thinking": false}' to disable it (≈1.8× throughput uplift).

`llama-speculative-simple`

./build/bin/llama-speculative-simple \
    -m   /path/to/Qwen3.6-27B-target.Q4_K_M.gguf \
    -md  /path/to/dflash-draft-3.6-q8_0.gguf \
    --spec-type dflash \
    -ngl 99 -ngld 99 \
    -c 4096 --draft-max 16 --draft-min 1 \
    -p "Write a Python mergesort."

Observed performance (RTX 3090, llama-server, Qwen3.6-27B UD-Q4_K_XL target, Python BST code prompt, temp = 0, 400 tokens, thinking OFF)

| Drafter quant | Raw (t/s) | Raw accept | Chat (t/s) | Chat accept | |----------------------|----------:|-----------:|-----------:|------------:| | Q8_0 (recommended) | 87 | 37 % | 97 | 43 % | | F16 | 80 | 36 % | 93 | 45 % | | Q4_K_M | 73 | 29 % | 70 | 28 % |

Q8_0 tracks F16 within noise and is half the size.

Note on comparison with the 3.5 drafter

Short-context code prompts do not exercise the sliding-window attention (most queries fall inside the 2048-token window anyway), so the 3.6 drafter's architectural change doesn't produce a dramatic win on this benchmark. The SWA infrastructure is expected to matter on longer-context workloads (> 2 k generated tokens). On short code, Q8_0 on 3.6 is ≈1.3× the throughput of Q4_K_M on 3.5 because the 3.6 target pairs slightly better with the retrained drafter.

Quantization details

Source: z-lab/Qwen3.6-27B-DFlash (BF16 safetensors, 2 B parameters)
Converter: convert_hf_to_gguf.py from spiritbuun/buun-llama-cpp — emits qwen35.attention.sliding_window + qwen35.attention.sliding_window_pattern so the runtime builds per-layer SWA masks
Quants: llama-quantize → Q4_K_M, Q8_0
Tensors: drafter transformer (5 layers, pattern [S,S,S,S,F], window = 2048) + projection heads + cross-attention layers targeting Qwen3.6-27B layer ids [1, 16, 31, 46, 61]

Reproducing the conversion

Tokenizer heads-up: the upstream z-lab/Qwen3.6-27B-DFlash repo ships only config.json, model.safetensors, and a README — no tokenizer files. The drafter shares the target model's tokenizer. Copy the Qwen3.6 tokenizer files into the drafter directory first.

# 1. Pull the DFlash drafter weights
hf download z-lab/Qwen3.6-27B-DFlash --local-dir ./dflash-drafter-3.6

# 2. Pull tokenizer files from the target model into the same directory
hf download Qwen/Qwen3.6-27B \
    tokenizer.json tokenizer_config.json vocab.json merges.txt \
    special_tokens_map.json \
    --local-dir ./dflash-drafter-3.6

# 3. Convert to GGUF (F16 first, then quantize)
python convert_hf_to_gguf.py ./dflash-drafter-3.6 \
    --outtype f16 \
    --outfile dflash-draft-3.6-f16.gguf

# 4. Quantize
./build/bin/llama-quantize dflash-draft-3.6-f16.gguf dflash-draft-3.6-q8_0.gguf Q8_0
./build/bin/llama-quantize dflash-draft-3.6-f16.gguf dflash-draft-3.6-q4_k_m.gguf Q4_K_M

Required files in ./dflash-drafter-3.6/ before step 3:

| File | Source | |---|---| | config.json | z-lab/Qwen3.6-27B-DFlash (has architectures: ["DFlashDraftModel"], use_sliding_window: true, layer_types: [...]) | | model.safetensors | z-lab/Qwen3.6-27B-DFlash | | tokenizer.json, tokenizer_config.json, vocab.json, merges.txt, special_tokens_map.json | Qwen/Qwen3.6-27B |

The converter auto-detects DFlashDraftModel from config.json and emits the SWA metadata when use_sliding_window is set.

Original model card — `z-lab/Qwen3.6-27B-DFlash`

Reproduced from the upstream model page. License: MIT.

Overview

Qwen3.6-27B-DFlash is a lightweight drafter component for DFlash speculative decoding. It must be used with the target model Qwen/Qwen3.6-27B.

Paper: https://arxiv.org/abs/2602.06036
GitHub: https://github.com/z-lab/dflash
Blog: https://z-lab.ai/projects/dflash/
Model Size: 2B parameters (BF16)

What is DFlash?

DFlash is a novel speculative decoding method using a lightweight block diffusion model for drafting, enabling efficient, high-quality parallel drafting that significantly speeds up inference.

Upstream Quick Start (vLLM / SGLang)

vLLM

uv pip install -U vllm --torch-backend=auto --extra-index-url https://wheels.vllm.ai/nightly

vllm serve Qwen/Qwen3.6-27B \
  --speculative-config '{"method": "dflash", "model": "z-lab/Qwen3.6-27B-DFlash", "num_speculative_tokens": 15}' \
  --attention-backend flash_attn \
  --max-num-batched-tokens 32768

SGLang

python -m sglang.launch_server \
    --model-path Qwen/Qwen3.6-27B \
    --speculative-algorithm DFLASH \
    --speculative-draft-model-path z-lab/Qwen3.6-27B-DFlash \
    --speculative-num-draft-tokens 16 \
    --tp-size 1 \
    --attention-backend fa3 \
    --mem-fraction-static 0.75 \
    --trust-remote-code

Citation

@article{chen2026dflash,
  title   = {{DFlash: Block Diffusion for Flash Speculative Decoding}},
  author  = {Chen, Jian and Liang, Yesheng and Liu, Zhijian},
  journal = {arXiv preprint arXiv:2602.06036},
  year    = {2026}
}

License

MIT — inherited from the upstream model. This repository redistributes quantized derivatives under the same terms.

Author: spiritbuun

Likes: 9

Downloads: 0

Tags: gguf, speculative-decoding, dflash, drafter, llama.cpp, quantized, arxiv:2602.06036, base_model:z-lab/Qwen3.6-27B-DFlash, base_model:quantized:z-lab/Qwen3.6-27B-DFlash, license:mit, endpoints_compatible, region:us, conversational

mlx-community/deepseek-ai-DeepSeek-V4-Flash-8bit

license: mit library_name: mlx pipeline_tag: text-generation base_model: deepseek-ai/DeepSeek-V4-Flash tags:

mlx-community/deepseek-ai-DeepSeek-V4-Flash-8bit

This model mlx-community/deepseek-ai-DeepSeek-V4-Flash-8bit was converted to MLX format from deepseek-ai/DeepSeek-V4-Flash using mlx-lm version 0.31.3.

Use with mlx

pip install mlx-lm

from mlx_lm import load, generate

model, tokenizer = load("mlx-community/deepseek-ai-DeepSeek-V4-Flash-8bit")

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: 7

Downloads: 0

Tags: mlx, safetensors, deepseek_v4, text-generation, base_model:deepseek-ai/DeepSeek-V4-Flash, base_model:quantized:deepseek-ai/DeepSeek-V4-Flash, license:mit, 8-bit, region:us

Comfy-Org/void-model

license: apache-2.0 tags:

comfyui

VOID: Video Object and Interaction Deletion

Repackaged model files for ComfyUI.

Original model repository:

https://huggingface.co/netflix/void-model

Place the files in the following folders:

📂 ComfyUI/
├── 📂 models/
│   ├── 📂 diffusion_models/
│   │   ├── void_pass1.safetensors
│   │   └── void_pass2.safetensors

Author: Comfy-Org

Likes: 6

Downloads: 0

Tags: comfyui, license:apache-2.0, region:us

ubergarm/Qwen3.6-27B-GGUF

quantized_by: ubergarm pipeline_tag: text-generation base_model: Qwen/Qwen3.6-27B base_model_relation: quantized license: apache-2.0 license_link: https://huggingface.co/Qwen/Qwen3.6-27B/blob/main/LICENSE tags:

imatrix
conversational
qwen3_5
ik_llama.cpp

`ik_llama.cpp` imatrix Quantizations of Qwen/Qwen3.6-27B

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. Only a couple quants in this collection are compatible with mainline llamma.cpp/LMStudio/KoboldCPP/etc as mentioned in the specific description, all others require ik_llama.cpp.

Some of ik's new quants are supported with Nexesenex/croco.cpp fork of KoboldCPP with Windows builds. Also check for ik_llama.cpp windows builds by Thireus here..

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 quantizing 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 KLD Chart

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

BF16 50.103 GiB (16.002 BPW)
- PPL over 580 chunks for n_ctx=512 = 6.9066 +/- 0.04552
Q8_0 26.622 GiB (8.502 BPW)
- PPL over 580 chunks for n_ctx=512 = 6.9063 +/- 0.04551

NOTE: If the models are split, the first file is much smaller and only contains metadata, that is on purpose, its fine!

IQ5_KS 18.532 GiB (5.919 BPW)

PPL over 580 chunks for n_ctx=512 = 6.9341 +/- 0.04578

This ik_llama.cpp exclusive quant is likely among the best quality available for 24GB full offload.

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

#!/usr/bin/env bash

custom="
# 64 Repeating Layers [0-63]

## Gated Attention/Delta Net [Blended 0-63]
blk\..*\.attn_gate\.weight=q6_0
blk\..*\.attn_qkv\.weight=q6_0
blk\..*\.attn_output\.weight=q6_0
blk\..*\.attn_q\.weight=q6_0
blk\..*\.attn_k\.weight=q6_0
blk\..*\.attn_v\.weight=q6_0
blk\..*\.ssm_alpha\.weight=q8_0
blk\..*\.ssm_beta\.weight=q8_0
blk\..*\.ssm_out\.weight=q8_0

# Dense Layers [0-63]
blk\..*\.ffn_down\.weight=iq5_ks
blk\..*\.ffn_(gate|up)\.weight=iq5_ks

# Non-Repeating Layers
token_embd\.weight=q6_0
output\.weight=q8_0
"

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

    #--dry-run \
numactl -N ${SOCKET} -m ${SOCKET} \
./build/bin/llama-quantize \
    --custom-q "$custom" \
    --imatrix /mnt/data/models/ubergarm/Qwen3.6-27B-GGUF/imatrix-Qwen3.6-27B-BF16.dat \
    /mnt/data/models/ubergarm/Qwen3.6-27B-GGUF/Qwen3.6-27B-BF16-00001-of-00002.gguf \
    /mnt/data/models/ubergarm/Qwen3.6-27B-GGUF/Qwen3.6-27B-IQ5_KS.gguf \
    IQ5_KS \
    128

</details>

smol-IQ4_NL 15.405 GiB (4.920 BPW)

PPL over 580 chunks for n_ctx=512 = 7.0040 +/- 0.04646

This mainline compatible custom mix using quantization types hopefully optimized for Vulkan/ROCm (and possibly Mac)?

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

#!/usr/bin/env bash

custom="
# 64 Repeating Layers [0-63]

## Gated Attention/Delta Net [Blended 0-63]
blk\..*\.attn_gate\.weight=iq4_nl
blk\..*\.attn_qkv\.weight=iq4_nl
blk\..*\.attn_output\.weight=iq4_nl
blk\..*\.attn_q\.weight=iq4_nl
blk\..*\.attn_k\.weight=iq4_nl
blk\..*\.attn_v\.weight=iq4_nl
blk\..*\.ssm_alpha\.weight=q8_0
blk\..*\.ssm_beta\.weight=q8_0
blk\..*\.ssm_out\.weight=q8_0

# Dense Layers [0-63]
blk\..*\.ffn_down\.weight=iq4_nl
blk\..*\.ffn_(gate|up)\.weight=iq4_nl

# Non-Repeating Layers
token_embd\.weight=iq4_nl
output\.weight=q8_0
"

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

    #--dry-run \
numactl -N ${SOCKET} -m ${SOCKET} \
./build/bin/llama-quantize \
    --custom-q "$custom" \
    --imatrix /mnt/data/models/ubergarm/Qwen3.6-27B-GGUF/imatrix-Qwen3.6-27B-BF16.dat \
    /mnt/data/models/ubergarm/Qwen3.6-27B-GGUF/Qwen3.6-27B-BF16-00001-of-00002.gguf \
    /mnt/data/models/ubergarm/Qwen3.6-27B-GGUF/Qwen3.6-27B-smol-IQ4_NL.gguf \
    IQ4_NL \
    128

</details>

IQ4_KS 14.693 GiB (4.693 BPW)

PPL over 580 chunks for n_ctx=512 = 6.9740 +/- 0.04599

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

#!/usr/bin/env bash

custom="
# 64 Repeating Layers [0-63]

## Gated Attention/Delta Net [Blended 0-63]
blk\..*\.attn_gate\.weight=iq4_ks
blk\..*\.attn_qkv\.weight=iq4_ks
blk\..*\.attn_output\.weight=iq4_ks
blk\..*\.attn_q\.weight=iq4_ks
blk\..*\.attn_k\.weight=iq4_ks
blk\..*\.attn_v\.weight=iq4_ks
blk\..*\.ssm_alpha\.weight=q6_0
blk\..*\.ssm_beta\.weight=q6_0
blk\..*\.ssm_out\.weight=q6_0

# Dense Layers [0-63]
blk\..*\.ffn_down\.weight=iq4_ks
blk\..*\.ffn_(gate|up)\.weight=iq4_ks

# Non-Repeating Layers
token_embd\.weight=q6_0
output\.weight=q8_0
"

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

    #--dry-run \
numactl -N ${SOCKET} -m ${SOCKET} \
./build/bin/llama-quantize \
    --custom-q "$custom" \
    --imatrix /mnt/data/models/ubergarm/Qwen3.6-27B-GGUF/imatrix-Qwen3.6-27B-BF16.dat \
    /mnt/data/models/ubergarm/Qwen3.6-27B-GGUF/Qwen3.6-27B-BF16-00001-of-00002.gguf \
    /mnt/data/models/ubergarm/Qwen3.6-27B-GGUF/Qwen3.6-27B-IQ4_KS-noimat.gguf \
    IQ4_KS \
    128

</details>

References

Author: ubergarm

Likes: 5

Downloads: 0

Tags: gguf, imatrix, conversational, qwen3_5, ik_llama.cpp, text-generation, base_model:Qwen/Qwen3.6-27B, base_model:quantized:Qwen/Qwen3.6-27B, license:apache-2.0, endpoints_compatible, region:us

Intel/Qwen3.6-27B-4.5b-mlx-AutoRound

base_model:

Qwen/Qwen3.6-27B

Model Details

This model is an mlx format 4.5b mixed model with group_size 128 and symmetric quantization of Qwen/Qwen3.6-27B generated by intel/auto-round. Please follow the license of the original model.

We currently support this format in AutoRound, but do not have the hardware to validate this large model.

As a result, we are unable to verify whether it runs correctly or achieves expected performance.

We would greatly appreciate your help in testing it, and welcome any contributions to our open-source project.

MLX-VLM inference

from mlx_vlm import generate, load
from mlx_vlm.prompt_utils import apply_chat_template
from mlx_vlm.utils import load_config

model_name_or_path= "Intel/Qwen3.5-4B-int4-mlx-AutoRound"

model, processor = load(model_name_or_path)
mlx_cfg = load_config(model_name_or_path)
prompt_text = "Describe this image in one sentence."
formatted = apply_chat_template(processor, mlx_cfg, prompt_text, num_images=1)
# Use a public example image so the test does not need local assets.
image_url = "https://qianwen-res.oss-accelerate.aliyuncs.com/Qwen3.5/demo/RealWorld/RealWorld-04.png"

output = generate(model, processor, formatted, image=[image_url], max_tokens=2048).text
print(output)

Generate the Model

this pr is required https://github.com/intel/auto-round/pull/1732

  AR_DISABLE_COPY_MTP_WEIGHTS=1 CUDA_VISIBLE_DEVICES=$device python3 -m auto_round \
  --target_bits 4.5 \
  --options "W4A16,W6A16,W8A16" \
  --model_name  $model_name \
  --ignore_scale_zp_bits \
  --format mlx \
  --output_dir "./test_mlx_mixed" \
  2>&1 | tee -a test_mlx.txt

Ethical Considerations and Limitations

The model can produce factually incorrect output, and should not be relied on to produce factually accurate information. Because of the limitations of the pretrained model and the finetuning datasets, it is possible that this model could generate lewd, biased or otherwise offensive outputs.

Therefore, before deploying any applications of the model, developers should perform safety testing.

Caveats and Recommendations

Users (both direct and downstream) should be made aware of the risks, biases and limitations of the model.

Here are a couple of useful links to learn more about Intel's AI software:

Intel Neural Compressor

Disclaimer

The license on this model does not constitute legal advice. We are not responsible for the actions of third parties who use this model. Please consult an attorney before using this model for commercial purposes.

Cite

@article{cheng2023optimize, title={Optimize weight rounding via signed gradient descent for the quantization of llms}, author={Cheng, Wenhua and Zhang, Weiwei and Shen, Haihao and Cai, Yiyang and He, Xin and Lv, Kaokao and Liu, Yi}, journal={arXiv preprint arXiv:2309.05516}, year={2023} }

arxiv github

Author: Intel

Likes: 5

Downloads: 0

Tags: safetensors, qwen3_5, arxiv:2309.05516, base_model:Qwen/Qwen3.6-27B, base_model:quantized:Qwen/Qwen3.6-27B, 4-bit, region:us

sgl-project/DeepSeek-V4-Pro-FP8

license: mit base_model: deepseek-ai/DeepSeek-V4-Pro tags:

deepseek-v4
fp8
quantized

DeepSeek-V4-Pro-FP8

FP8 re-packaging of deepseek-ai/DeepSeek-V4-Pro. Model architecture, tokenizer, chat template, and reference encoding/ are unchanged from the base repo. No fine-tuning, no retraining — weights only.

Deployment

SGLang Cookbook: https://docs.sglang.io/cookbook/autoregressive/DeepSeek/DeepSeek-V4

License

Author: sgl-project

Likes: 5

Downloads: 0

Tags: safetensors, deepseek_v4, deepseek-v4, fp8, quantized, base_model:deepseek-ai/DeepSeek-V4-Pro, base_model:quantized:deepseek-ai/DeepSeek-V4-Pro, license:mit, region:us

Todays AI Summary

AI Developments: Reasoning Models, Domain Adaptation, and Safety-Oriented AI

Research Highlights

Model Updates

Key Takeaways

AI Papers for 2026-04-25

Seeing Fast and Slow: Learning the Flow of Time in Videos

When Prompts Override Vision: Prompt-Induced Hallucinations in LVLMs

From Research Question to Scientific Workflow: Leveraging Agentic AI for Science Automation

A Scale-Adaptive Framework for Joint Spatiotemporal Super-Resolution with Diffusion Models

GiVA: Gradient-Informed Bases for Vector-Based Adaptation

Nemobot Games: Crafting Strategic AI Gaming Agents for Interactive Learning with Large Language Models

A Multi-Stage Warm-Start Deep Learning Framework for Unit Commitment

TingIS: Real-time Risk Event Discovery from Noisy Customer Incidents at Enterprise Scale

A Multimodal Text- and Graph-Based Approach for Open-Domain Event Extraction from Documents

Addressing Image Authenticity When Cameras Use Generative AI

AI Models

unsloth/DeepSeek-V4-Flash

DeepSeek-V4: Towards Highly Efficient Million-Token Context Intelligence

Introduction

Model Downloads

Evaluation Results

Base Model

Instruct Model

DeepSeek-V4-Pro-Max vs Frontier Models

Comparison across Modes

Chat Template

How to Run Locally

License

Citation

Contact

unsloth/DeepSeek-V4-Pro

DeepSeek-V4: Towards Highly Efficient Million-Token Context Intelligence

Introduction

Model Downloads

Evaluation Results

Base Model

Instruct Model

DeepSeek-V4-Pro-Max vs Frontier Models

Comparison across Modes

Chat Template

How to Run Locally

License

Citation

Contact

FINAL-Bench/Darwin-9B-NEG

Darwin-9B-NEG — The First Native Entropy Gating Model

Abstract

What Makes Darwin-9B-NEG Different

🧬 Darwin Series — Evolutionary Model Merging

⚡ NEG — Native Entropy Gating (Darwin V8)

🏗️ Architecture Overview

Key Specifications

🏆 Benchmark Results — GPQA Diamond (198 PhD-level questions)

🚀 Usage

Quick start — Pure NEG greedy (mode 1, sales default)

Using the bundled NEG loader helper

Mode selection

🧬 Model Lineage

🎯 Recommended Use-Cases

⚠️ Limitations

📚 Citation

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FINAL-Bench/Darwin-28B-Opus

Darwin-28B-Opus — Qwen3.6-27B × Opus-Distilled Evolutionary Merge

Abstract

🧬 Model Lineage

⚙️ Technical Specifications

🏆 Benchmark — GPQA Diamond (198 questions)

🚀 Usage

Standard inference (Stage 1 baseline)

Enhanced accuracy (Stage 2-3 adaptive)

🎯 Recommended Use-Cases

⚠️ Limitations

📚 Citation

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spiritbuun/Qwen3.6-27B-DFlash-GGUF

Qwen3.6-27B-DFlash — GGUF (Q4_K_M + Q8_0)

Requirements

Usage

`llama-server`

`llama-speculative-simple`

Original model card — `z-lab/Qwen3.6-27B-DFlash`

`ik_llama.cpp` imatrix Quantizations of Qwen/Qwen3.6-27B