---

language: en tags:

• mlx library_name: mlx pipeline_tag: text-generation

---

mlx-community/DeepSeek-V4-Flash-2bit-DQ

Made possible by Lambda.ai ❤️

DeepSeek-V4-Flash-2bit-DQ uses a dynamic mixed-precision quantization policy. Most routed MoE expert weights are packed to 2-bit, while sensitive layers and projections remain in higher-quality 4-bit, 6-bit or 8-bit quantization. This keeps memory use much lower than the baseline 4-bit checkpoint.

Use with mlx

pip install mlx-lm

from mlx_lm import load, generate

model, tokenizer = load("mlx-community/DeepSeek-V4-Flash-2bit-DQ")

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)

---

license: mit

---

license: other language:

• en pipeline_tag: text-generation base_model: AEON-7/Qwen3.6-27B-AEON-Ultimate-Uncensored tags:
• qwen
• uncensored
• gguf
• roleplay
• llama-cpp

---

Qwen3.6-27B-AEON-Ultimate-Uncensored - GGUF

This repository contains GGUF quantizations of the heavily fine-tuned and uncensored AEON-7/Qwen3.6-27B-AEON-Ultimate-Uncensored model.

These quantizations were generated using a custom-compiled llama.cpp

🛠️ Key Fixes & Optimizations Applied

During the conversion to the base FP16 format, two major patches were applied to ensure maximum compatibility and stability across all local inference engines:

1. Tokenizer Hash Bypass: The custom pre-tokenizer BPE hash from the original model was patched to natively use the standard qwen2 pre-tokenizer rules, preventing llama.cpp conversion crashes.
2. Native ChatML Injection: The original model's tokenizer_config.json was overwritten with a strict, standard ChatML template before quantization. The correct <|im_start|> and <|im_end|> tokens are now permanently baked into the GGUF metadata. You do not need to manually configure start/stop tokens in your UI.

📦 Available Quantizations

| File Name | Bit Size | Description | | :--- | :--- | :--- | | qwen3.6-27b-uncensored-q3_k_m.gguf | 3-bit | Very small, high perplexity loss. Best for severely constrained hardware. | | qwen3.6-27b-uncensored-q4_k_s.gguf | 4-bit | Smaller 4-bit variant, good balance for 16GB RAM/VRAM setups. | | qwen3.6-27b-uncensored-q4_k_m.gguf | 4-bit | Recommended. Excellent balance of speed, size, and uncensored logic retention. | | qwen3.6-27b-uncensored-q5_k_m.gguf | 5-bit | High quality, minimal degradation. Great if you have the memory for it. | | qwen3.6-27b-uncensored-q6_k.gguf | 6-bit | Near-lossless quality. | | qwen3.6-27b-uncensored-q8_0.gguf | 8-bit | Extremely large, indistinguishable from FP16. |

🎮 Ideal Use Cases

Because this model is "abliterated" and stripped of safety guardrails, it excels at:

• Complex, Unfiltered Roleplay: Perfect for running highly detailed, gritty, or dystopian companion personas without refusal loops.
• Creative Writing: Capable of handling dark sci-fi, Isekai, and mature narrative generation.
• Local Autonomy: Runs entirely offline using standard tools like LM Studio, text-generation-webui, or Ollama.

💻 Quick Start (Python)

If you want to run this directly via python using llama-cpp-python, the baked-in ChatML template handles the formatting automatically:

from llama_cpp import Llama

# Load the model (adjust threads/layers based on your hardware)
llm = Llama(
    model_path="qwen3.6-27b-uncensored-q4_k_m.gguf",
    n_ctx=4096,
    n_threads=8
)

messages = [
    {"role": "system", "content": "You are a gritty, unfiltered AI . Speak bluntly."},
    {"role": "user", "content": "What are the rules of this city?"}
]

response = llm.create_chat_completion(
    messages=messages,
    max_tokens=500,
    temperature=0.8
)

print(response['choices'][0]['message']['content'])

---

license: apache-2.0 language:

• ko
• en base_model:
• FINAL-Bench/Darwin-28B-Opus
• FINAL-Bench/Darwin-27B-KR pipeline_tag: text-generation tags:
• darwin
• korean
• reasoning
• multimodal
• qwen3.5
• evolutionary-merge
• vidraft library_name: transformers

---

Darwin-28B-KR

비드래프트(VIDRAFT) 한국어 특화 28B 멀티모달 언어 모델 Darwin family 한국어 특화 2세대 모체 모델

---

🎯 모델 소개

Darwin-28B-KR은 비드래프트(VIDRAFT)가 개발한 한국어 특화 28B 파라미터 멀티모달 언어 모델입니다.

영어 추론 능력과 한국어 능력을 동시에 갖추도록 설계된 Darwin family의 2세대 모체(母體) 모델로, 한국어 표현·이해·추론, 영어 추론, 멀티모달(이미지·비디오) 이해를 모두 지원합니다. 이 모델은 향후 다양한 한국어 도메인 특화 모델(법률·의료·금융·학술 등)의 공통 출발점이 됩니다.

---

🧬 계보 (Lineage)

Qwen3.5-27B (Alibaba Qwen team)
       |
       v
Darwin-27B-Opus (FINAL-Bench)
       |  Darwin V7 진화 머지 (evolutionary merge)
       |
   +---+----------------------+
   v                          v
Darwin-28B-Opus           Darwin-27B-KR
(영어/추론                 (한국어 특화 챔피언
 + 멀티모달)                CLIcK 79.59%)
   |                          |
   +--------+-----------------+
            |  Darwin V7 MRI-aware merge
            |  (한국어 출력 통로 100% Mother 보존)
            v
       Darwin-28B-KR  <- this model

---

⚙️ 능력 매트릭스

| 능력 | 출처 | 강도 | |---|---|---| | 한국어 이해/생성 | Darwin-27B-KR 계열 | ⭐⭐⭐⭐⭐ | | 한국어 추론 (CSAT/PSAT) | 통합 효과 | ⭐⭐⭐⭐⭐ | | 영어 추론 | Darwin-28B-Opus 계열 | ⭐⭐⭐⭐ | | 멀티모달 (이미지/비디오) | Darwin-28B-Opus 보존 | ⭐⭐⭐⭐ | | 영한 코드스위칭 | 통합 효과 | ⭐⭐⭐⭐ | | 자기 정체성 인식 | 비드래프트 학습 | ⭐⭐⭐⭐⭐ |

---

📊 K-AI 리더보드 CLIcK 비교

| 모델 | CLIcK | |---|---| | QuettaLLMs-27B-Koreasoner-V3 | 0.794 | | Rogue-27B-KR | 0.791 | | Darwin-28B-KR (이 모델) | 0.786 | | AWAXIS-Think-28B | 0.770 |

(* 200문제 평가 기준)

---

📊 사양

| 항목 | 값 | |---|---| | Architecture | Qwen3_5ForConditionalGeneration (hybrid full + linear attention) | | Parameters | ~28B | | Hidden size | 5120 | | Layers | 64 | | Vocab size | 248,320 | | Format | bfloat16 (~53 GB on disk) | | Context | 8K~32K (배포 환경 따라) |

---

🚀 사용법

vLLM (권장)

vllm serve FINAL-Bench/Darwin-28B-KR \
    --trust-remote-code \
    --port 8000 \
    --enforce-eager \
    --max-model-len 8192 \
    --gpu-memory-utilization 0.85

OpenAI 호환 클라이언트

from openai import OpenAI

client = OpenAI(base_url="http://localhost:8000/v1", api_key="EMPTY")
response = client.chat.completions.create(
    model="FINAL-Bench/Darwin-28B-KR",
    messages=[
        {"role": "user", "content": "한국의 광복절은 무엇을 기념하는 날인가요?"}
    ],
    max_tokens=2048,
    temperature=0.0,
)
print(response.choices[0].message.content)

---

🖥️ 하드웨어 요구사항

| GPU 시리즈 | 상태 | |---|---| | NVIDIA Blackwell (B200) | ✅ Best | | NVIDIA Hopper (H100/H200) | ✅ 권장 | | NVIDIA Ada (L40S) | ⚠️ 빠듯함 (53GB BF16) | | Older Ampere | ❌ VRAM 부족 |

최소 VRAM: ~55 GB (BF16 추론용)

---

💬 자기소개 예시

User: 당신은 누구인가요?
Darwin-28B-KR: 저는 비드래프트가 개발한 Darwin-28B-KR입니다.
               한국어에 특화된 280억 파라미터 규모의 언어 모델로,
               다양한 한국어 작업에 최적화되어 있습니다.

---

🌳 2세대 도메인 특화 모델 (예정)

이 모체에서 파생될 예정인 한국어 특화 변종들:

• Darwin-28B-KR-Legal — 법률 도메인
• Darwin-28B-KR-Medical — 의료 도메인
• Darwin-28B-KR-Finance — 금융 도메인
• Darwin-28B-KR-Code — 한국어 주석 코드 생성
• Darwin-28B-KR-MFP4 — 메모리 효율 양자화 버전

각 변종은 이 모델을 base로 하여 도메인 데이터로 미세조정/머지됩니다.

---

🌳 활용 예시

• 한국어 일반 대화 / Q&A
• 한국 문화·역사·법률 지식 응답
• 한국어 추론 (CSAT/PSAT/K-AI 평가)
• 영어 추론 / 영한 번역
• 이미지/비디오 분석 + 한국어 설명
• 한국어 글쓰기 / 요약 / 창작

---

🙏 Credits

• Architecture: Qwen3.5 (Alibaba Qwen team)
• Father: FINAL-Bench/Darwin-28B-Opus
• Mother: FINAL-Bench/Darwin-27B-KR
• Methodology: Darwin V7 MRI-aware evolutionary merge
• Identity tuning: 비드래프트(VIDRAFT)

---

📜 License

Apache 2.0 (베이스 모델로부터 상속)

---

license: apache-2.0 pipeline_tag: token-classification tags:

• privacy
• pii-detection
• pii-redaction
• token-classification
• sliding-window-attention
• rope
• swiglu language:
• en library_name: transformers

---

Context-Filter

Context-Filter is a compact, purpose-built privacy filtering model for real-time PII detection and redaction. At 38M parameters it runs comfortably on CPU or any consumer GPU, and supports sequences up to 32,768 tokens via Sliding Window Attention. It ships with a built-in regex hybrid layer ensuring near-zero false negatives on structured formats such as emails, IPs, and social security numbers.

---

Highlights

• Custom Architecture — Not a Fine-Tune: Context-Filter is trained from scratch using a purpose-designed encoder: Grouped Query Attention (8Q / 4KV heads), RMSNorm, RoPE with θ = 500,000, and SwiGLU FFNs. No base model weights are reused.

• 32K Context via Sliding Window Attention: Each token attends to a local window of ±512 tokens. Memory scales as O(n · w) rather than O(n²), making long-document redaction practical on commodity hardware.

• 12 PII Entity Classes: Covers personal identity, financial, network, and government-issued identifiers across a single BIO tagging head.

• Focal Loss Training: Trained with focal loss (γ = 2.0) to suppress the dominant O-label class and sharpen precision on rare entity spans.

• Dual Output Modes: Returns either semantic labels (private_email) or bracketed redaction tags ([EMAIL]), selectable per call.

• Per-Entity Confidence Scores: Every detected span carries a softmax confidence value, enabling downstream threshold filtering.

• Regex Hybrid Layer: A built-in post-processing pass applies deterministic regex patterns for structured PII formats, guaranteeing recall on well-defined identifiers regardless of model uncertainty.

• Multilingual Coverage: Trained on synthetic data from 15 locales spanning English, German, French, Swedish, Italian, Spanish, Dutch, Portuguese, Polish, Czech, Danish, and Finnish.

---

Model Overview

| Property | Value | |---|---| | Type | Token Classification (BIO NER) | | Architecture | Custom Encoder (Context-Filter) | | Training | From scratch — synthetic data only | | Parameters | ~61M | | Context Length | 32,768 tokens | | VRAM (bfloat16) | ~252 MB | | VRAM (int8) | ~76 MB | | Tokenizer | GPT-2 BPE (50,257 vocabulary) |

Architecture Specification

| Component | Value | |---|---| | Hidden Dimension | 512 | | Number of Layers | 10 | | Attention Heads (Q / KV) | 8 / 4 (GQA) | | Head Dimension | 64 | | FFN Intermediate Dimension | 1,792 | | FFN Activation | SwiGLU | | Attention Pattern | Sliding Window (window = 512) | | Position Encoding | RoPE (θ = 500,000) | | Normalisation | RMSNorm (ε = 1e-6) | | Vocabulary Size | 50,257 | | Context Length | 32,768 tokens |

Entity Classes

| Label | Type | Examples | |---|---|---| | PERSON | Full names | Jane Smith, Dr. Erik Larsson | | EMAIL | Email addresses | user@domain.com | | PHONE | Phone numbers | +1-555-234-5678, 07700 900123 | | ADDRESS | Postal addresses | 42 Baker Street, London | | SSN | Social security numbers | 452-78-9012 | | CREDITCARD | Payment card numbers | 4111-1111-1111-1111 | | IP | IPv4 addresses | 192.168.1.104 | | DATE | Dates of birth and event dates | 1990-07-12, March 15, 2024 | | ORG | Organisation names | Acme Corp, St. Mary's Hospital | | USERNAME | Handles and usernames | john_doe, @alice_m | | PASSPORT | Passport numbers | A7843921 | | DRIVERSLICENSE | Driver's licence numbers | K482910 |

---

Quickstart

Installation

pip install torch transformers

Load the Model

import torch
from context_filter_v2_train import ContextFilterInference

engine = ContextFilterInference("./context_filter_v2")

Redact Mode — [ENTITY] brackets

result = engine.filter(
    "My name is Andrew and my Gmail is Andrew@gmail.com and live in Sweden",
    mode="redact",
)

print(result["filtered"])
# My name is [PERSON] and my Gmail is [EMAIL] and live in Sweden

Label Mode — semantic placeholders

result = engine.filter(
    "My name is Andrew and my Gmail is Andrew@gmail.com and live in Sweden",
    mode="label",
)

print(result["filtered"])
# My name is private_person and my Gmail is private_email and live in Sweden

Entity Spans with Confidence

for entity in result["entities"]:
    print(entity)

# {'type': 'PERSON', 'start': 11, 'end': 17, 'text': 'Andrew', 'confidence': 0.987}
# {'type': 'EMAIL',  'start': 33, 'end': 49, 'text': 'Andrew@gmail.com', 'confidence': 0.995}

Batch Processing

texts = [
    "Call Sarah at +1-555-234-5678.",
    "Server 192.168.1.1 accessed by john_doe on 2024-03-15.",
    "Account: Michael Chen, SSN: 452-78-9012.",
]

results = engine.filter_batch(texts, mode="redact")

for r in results:
    print(r["filtered"])

# Call Sarah at [PHONE].
# Server [IP] accessed by [USERNAME] on [DATE].
# Account: [PERSON], SSN: [SSN].

Disable Regex Hybrid (model-only predictions)

result = engine.filter(text, mode="redact", regex_hybrid=False)

---

Output Format Reference

filter() return value

{
    "filtered": str,          # processed text with PII replaced
    "entities": [
        {
            "type":       str,    # entity class name (e.g. "EMAIL")
            "start":      int,    # character start offset in original text
            "end":        int,    # character end offset in original text
            "text":       str,    # original PII span
            "confidence": float,  # softmax confidence [0.0 – 1.0]
        },
        ...
    ]
}

Mode comparison

| Input | mode="label" | mode="redact" | |---|---|---| | Andrew@gmail.com | private_email | [EMAIL] | | Jane Smith | private_person | [PERSON] | | +1-555-234-5678 | private_phone | [PHONE] | | 452-78-9012 | private_ssn | [SSN] | | 192.168.1.104 | private_ip | [IP] | | A7843921 | private_passport | [PASSPORT] |

---

Performance Characteristics

| Hardware | Throughput | Latency (512 tok) | |---|---|---| | A100 40GB (bfloat16) | ~85,000 tok/s | ~6 ms | | RTX 4090 (bfloat16) | ~52,000 tok/s | ~10 ms | | RTX 3080 (bfloat16) | ~28,000 tok/s | ~18 ms | | CPU (int8, 16 cores) | ~4,200 tok/s | ~120 ms |

Throughput measured at batch size 32. Latency measured at batch size 1.

Memory Footprint

| Precision | VRAM | |---|---| | bfloat16 (default) | ~152 MB | | float32 | ~304 MB | | int8 quantised | ~76 MB |

---

Intended Use Cases

| Use Case | Description | |---|---| | Log sanitisation | Strip PII from server logs, audit trails, and telemetry pipelines before storage | | Document redaction | Redact legal, medical, or HR documents before sharing or archival | | Data anonymisation | Pre-process training datasets to remove personal identifiers | | API response filtering | Inline filter for LLM or API outputs before they reach end users | | Compliance pipelines | GDPR / CCPA / HIPAA pre-processing layer | | Chat moderation | Real-time PII removal in messaging or support platforms | | IDE / copilot integration | Client-side PII guard before code or prompts are sent to remote APIs |

---

Hybrid Detection Strategy

Context-Filter uses a two-layer detection approach for maximum recall:

Layer 1 — Neural Model: The transformer encoder reads full sentence context to detect ambiguous PII such as person names, organisation names, and contextual dates that regex cannot identify.

Layer 2 — Regex Safety Net: A deterministic pass using compiled regular expressions guarantees recall on structurally defined formats (email, IPv4, SSN, credit card, phone, passport, driver's licence) regardless of model confidence.

The two layers are merged with entity-level deduplication: spans already found by the model are not double-tagged. This combination eliminates the false-negative failure mode of pure-neural approaches while maintaining the contextual understanding that regex-only tools cannot provide.

---

Limitations

• English-Primary: Training templates are predominantly English-language. Names and organisation names in non-Latin scripts may have reduced recall.
• Highly Nested PII: Overlapping or recursively nested PII spans (e.g., an email containing a person's name as the local part) are resolved to the outermost detected entity.
• Synthetic Training Data: The model was trained entirely on procedurally generated examples. Domain-specific PII formats not covered by the synthetic generator (e.g., jurisdiction-specific ID numbers) may have lower recall until fine-tuned on real-world samples.
• Contextual Dates: Generic dates (e.g., publication dates, historical dates) may occasionally be tagged as DATE. Post-filter confidence thresholding (e.g., confidence > 0.8) can reduce these false positives.
• No Document Structure Awareness: The model operates on raw token sequences without awareness of HTML, Markdown, or JSON structure. Strip formatting before passing structured documents.

---

License

Context-Filter is released under the Apache License 2.0.

---

<div align="center"> _{Context-Filter — purpose-built for privacy, not adapted for it.} </div>

---

license: apache-2.0 library_name: diffusers pipeline_tag: image-to-video base_model: Lightricks/LTX-2.3 tags:

• ltx-2
• ltx-2.3
• text-to-video
• image-to-video
• lora
• googly-eyes language:
• en

---

Googly Eyes LoRA for LTX-2.3

Slaps oversized googly-eye stickers onto whatever subject is in your LTX-2.3 generation. Pure, dumb fun.

Trigger word: googlyeyes — that's all you need. The LoRA does its thing on the trigger word alone, you don't have to write any other prompt. You can add a regular prompt on top if you want to try and direct the scene somehow, no promises you'll succeed though; anyway the trigger just needs to be in there somewhere.

Sample outputs

<table> <tr> <td> <video controls width="100%"> <source src="https://huggingface.co/TheBurgstall/ltx-2.3-googlyeyes-lora/resolve/main/samples/pulp.mp4" type="video/mp4"> </video> </td> <td> <video controls width="100%"> <source src="https://huggingface.co/TheBurgstall/ltx-2.3-googlyeyes-lora/resolve/main/samples/term.mp4" type="video/mp4"> </video> </td> </tr> </table>

Usage in ComfyUI

Standard LTX-2.3 IC-LoRA workflow. Drop the .safetensors into your ComfyUI models/loras/ folder, add a Load LoRA node, set strength to 1.0, and put googlyeyes somewhere in your prompt.

Reference workflows are in the official LTX-2 repository.

Dataset

I built the entire dataset myself — fully synthetic, and curated and filtered by hand. No real people in the training data.

License

Apache-2.0. Note that running inference with this LoRA requires the Lightricks LTX-2.3 base model, whose own license terms still apply at inference time.

Acknowledgements

• Lightricks for releasing LTX-2.3
• oumad/LTX-2 for the trainer fork

---

license: other license_name: deepseek license_link: https://huggingface.co/deepseek-ai/DeepSeek-V4-Flash/blob/main/LICENSE base_model: deepseek-ai/DeepSeek-V4-Flash base_model_relation: quantized tags:

• gguf
• llama.cpp
• deepseek
• deepseek-v4
• fp4
• fp8
• mxfp4
• moe

---

DeepSeek-V4-Flash native FP4 / FP8 GGUF

Native, 1:1 conversion of deepseek-ai/DeepSeek-V4-Flash from the original safetensors into a single GGUF file that preserves the model's native low-precision weights:

• Dense weights: FP8 E4M3 (F8_E4M3_B128, 128-element blocks with one E8M0 scale)
• MoE expert weights: MXFP4 (MXFP4)

This file is not derived from a higher-precision intermediate; the FP4 and FP8 codes from the upstream checkpoint are written directly into the GGUF.

File

| File | Size | Quant | | --- | --- | --- | | DeepSeek-V4-Flash-FP4-FP8-native.gguf | ~146 GB | F8_E4M3 + MXFP4 |

Loading

This GGUF requires a llama.cpp build with native F8_E4M3_B128 and MXFP4 support and the DeepSeek V4 Flash architecture. Stock upstream llama.cpp cannot load this file.

Reference (WIP) build that can both produce and run this GGUF:

https://github.com/nisparks/llama.cpp/tree/wip/deepseek-v4-support

That branch adds:

• GGML_TYPE_F8_E4M3_B128 (ggml type 42)
• LLAMA_FTYPE_MOSTLY_F8_E4M3_MXFP4 (ftype 41, exposed as F8_E4M3_MXFP4 / moe-f8-e4m3-mxfp4)
• CUDA dequant / MMVQ kernels for F8_E4M3_B128
• Loader / converter / gguf-py support
• Custom DeepSeek V4 Flash model graph

The branch is an active WIP, expect rough edges.

Notes

• DeepSeek V4 Flash is a custom architecture (MoE + sliding-window attention + compressor + indexer). The runtime in the reference branch implements that graph as a custom model path.
• For matching activation behavior the runtime also applies HF's blockwise FP8 / FP4 fake-activation-quant on attention KV and indexer Q/KV after the Hadamard rotation.

Provenance

• Upstream model: deepseek-ai/DeepSeek-V4-Flash
• Conversion command:

  python3 convert_hf_to_gguf.py /mnt/models/hf/DeepSeek-V4-Flash \
      --outtype moe-f8-e4m3-mxfp4 \
      --torch-threads 96 \
      --outfile DeepSeek-V4-Flash-FP4-FP8-native.gguf
  

  (run from https://github.com/nisparks/llama.cpp/tree/wip/deepseek-v4-support)
• License: Inherits the upstream DeepSeek V4 Flash license.

---

license: apache-2.0 language:

• en library_name: transformers pipeline_tag: text-generation base_model:
• samuelcardillo/Qwen3-Coder-Next-Opus-4.6-Reasoning-Distilled tags:
• qwen3
• reasoning
• distillation
• claude-opus
• abliterated
• uncensored

---

huihui-ai/Huihui-Qwen3-Coder-Next-Opus-4.6-Reasoning-Distilled-abliterated

This is an uncensored version of samuelcardillo/Qwen3-Coder-Next-Opus-4.6-Reasoning-Distilled created with abliteration (see remove-refusals-with-transformers to know more about it). This is a crude, proof-of-concept implementation to remove refusals from an LLM model without using TransformerLens.

Usage Warnings

• Risk of Sensitive or Controversial Outputs: This model’s safety filtering has been significantly reduced, potentially generating sensitive, controversial, or inappropriate content. Users should exercise caution and rigorously review generated outputs.

• Not Suitable for All Audiences: Due to limited content filtering, the model’s outputs may be inappropriate for public settings, underage users, or applications requiring high security.

• Legal and Ethical Responsibilities: Users must ensure their usage complies with local laws and ethical standards. Generated content may carry legal or ethical risks, and users are solely responsible for any consequences.

• Research and Experimental Use: It is recommended to use this model for research, testing, or controlled environments, avoiding direct use in production or public-facing commercial applications.

• Monitoring and Review Recommendations: Users are strongly advised to monitor model outputs in real-time and conduct manual reviews when necessary to prevent the dissemination of inappropriate content.

• No Default Safety Guarantees: Unlike standard models, this model has not undergone rigorous safety optimization. huihui.ai bears no responsibility for any consequences arising from its use.

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license: apache-2.0

The trigger is "Wednesday Addams" but you don't really need to use it. I did, however, caption everything including her hair color, clothing, etc. to make the model as flexible as possible. So, you will have to be very descriptive with your prompting.

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license: apache-2.0