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	---
	license: apache-2.0
	tags:
	- rwkv
	---

	# RWKV-Reka-3.1-Flash



	<div align="center">
	<img src="./hxa079.png" style="border-radius: 15px; width: 60%; height: 60%; object-fit: cover; box-shadow: 10px 10px 20px rgba(0, 0, 0, 0.5); border: 2px solid white;" alt="PRWKV" />
	</div>

	> I'm simply exploring the possibility of linearizing existing Transformer models.
	> It's still far from perfect,
	> but I hope you'll bear with me as I continue this journey. :)

	### Model Description

	RWKV-Reka-3.1 Flash is an RNN hybrid architecture model that combines RWKV v7's linear attention mechanism with Group Query Attention (GQA) layers. Built upon the Reka-flash3.1 21B foundation, this model replaces most Transformer attention blocks with RWKV blocks while strategically maintaining some GQA layers to enhance performance on specific tasks.

	- Developed by: OpenMOSE
	- Model type: Hybrid Linear-Attention Language Model
	- Language(s): Multilingual (inherited from Reka-flash3.1 21B)
	- License: Apache-2.0
	- Base Model: Reka-flash3 21B(https://huggingface.co/RekaAI/reka-flash-3.1)
	- Year: 2025

	### Architecture Specifications

	- Architecture: RWKV v7 based "hxa079" Architecture + Group Query Attention Hybrid
	- Total Layers: 44 layers (L44D6114)
	- 38 RWKV layers (with Rope)
	- 6 GQA layers (No Rope, No Position Embeddings)
	- Hidden Dimension: 6144
	- Training Context Window: 8192 tokens
	- Inference Context Window 40000+
	- Training Strategy Following RADLADS method based knowledge distillation

	## Technical Innovation

	### RWKV "hxa079" Architecture

	The model implements several key improvements over original RWKV architectures:

	1. Token Shift Removal: In order to effectively inherit the teacher model weights, we removed the residual connection one token ago.
	2. GroupNorm Removal: Helps improve training stability issues
	3. k_first Introduction: Experimentally adopted the approach of residually connecting k layers in layer 0.

	### Hybrid Design Benefits

	- Linear Attention Inference: RWKV blocks enable O(1) memory complexity during inference, and the hybrid approach reduces the KVCache to 1/7 of full GQA.
	- Enhanced Needle Tasks: Strategic placement of GQA layers significantly improves performance on needle-in-haystack retrieval tasks, addressing a known limitation of pure linear attention models
	- Implicit Position Encoding: Interestingly, the model achieves better performance when RoPE (Rotary Position Embedding) is not applied to GQA layers, suggesting that RWKV blocks provide implicit positional encoding capabilities

	## Intended Use

	This is an experimental research model designed to explore hybrid architectures combining linear and quadratic attention mechanisms. It is intended for:

	- Research into efficient attention mechanisms
	- Benchmarking hybrid architecture performance
	- Exploring linear attention limitations and solutions
	- Academic and industrial R&D purposes

	## Limitations

	- Experimental Status: This model is in experimental stages and may exhibit unexpected behaviors
	- Context Window: Limited to 8192 tokens during training, though RWKV architecture theoretically supports longer sequences
	- Performance Variability: As a hybrid model, performance may vary significantly across different task types

	## Training Details

	- Training Context Window: 8192 tokens
	- Training GPU AMD Instinct MI300X (takes 290hrs) AMD Developer Cloud.(Thank you for credit support)
	- Training Strategy 8bit MLP Quant, frozen emb,mlp,head, Deepspeed Stage1, Stage1 100M, Stage2(ctx4096) 360M Stage3(ctx8192) 300M
	- Training Stage Stage3 - Reduced temperature stepped knowledge distillation.(stage3 final temp=0.7)
	- Base Model Initialization: Weights initialized from Reka-3.1-flash 21B
	- Architecture Conversion: Transformer attention blocks systematically replaced with RWKV blocks, except for 6 strategically placed GQA layers

	## Evaluation

	Performance evaluation is ongoing. The model shows promising results in:
	- Maintaining base model capabilities while achieving linear attention efficiency
	- Significantly improved needle-in-haystack task performance compared to pure RWKV architectures
	- Competitive performance on standard language modeling benchmarks

	## Usage with RWKV-Infer
	- RWKV-Infer Triton based Hybrid RWKV Inference engine, can be check at: [https://github.com/OpenMOSE/RWKV-Infer/wiki/How-to-Running-RWKV-hxa079-models%3F](https://github.com/OpenMOSE/RWKV-Infer/wiki/How-to-Running-RWKV-hxa079-models%3F)


	## Usage with Hugging Face Transformers

	Currently in development. stay tuned :)



	## Code Repositories

	- RADLADS Project Code: The main codebase for the RADLADS paper, including conversion scripts and model code, can be found at: [https://github.com/recursal/RADLADS](https://github.com/recursal/RADLADS)
	- ARWKV Project Code The ARWKV original training code, can be found at: [https://github.com/yynil/RWKVInside](https://github.com/yynil/RWKVInside)
	- Specific Training Code (OpenMOSE): The training code for this particular `RWKV-Reka-3.1-Flash` model is available at: [https://github.com/OpenMOSE/RWKVInside](https://github.com/OpenMOSE/RWKVInside) (Note: this repository is still under development and may contain bugs.)

	## Model Card Contact

	OpenMOSE - 2025