π Model Description
license: mit license_link: https://huggingface.co/microsoft/bitnet-b1.58-2B-4T/blob/main/LICENSE language:
- en
- chat
- bitnet
- text-generation
- large-language-model
BitNet b1.58 2B4T - Scaling Native 1-bit LLM
This repository contains the weights for BitNet b1.58 2B4T, the first open-source, native 1-bit Large Language Model (LLM) at the 2-billion parameter scale, developed by Microsoft Research.
Trained on a corpus of 4 trillion tokens, this model demonstrates that native 1-bit LLMs can achieve performance comparable to leading open-weight, full-precision models of similar size, while offering substantial advantages in computational efficiency (memory, energy, latency).
β‘οΈ Technical Report: BitNet b1.58 2B4T Technical Report
β‘οΈ Official Inference Code: microsoft/BitNet (bitnet.cpp)
Model Variants
Several versions of the model weights are available on Hugging Face:
microsoft/bitnet-b1.58-2B-4T: Contains the packed 1.58-bit weights optimized for efficient inference. Use this for deployment.microsoft/bitnet-b1.58-2B-4T-bf16: Contains the master weights in BF16 format. Use this only for training or fine-tuning purposes.microsoft/bitnet-b1.58-2B-4T-gguf(This repository): Contains the model weights in GGUF format, compatible with thebitnet.cpplibrary for CPU inference.
Model Details
- Architecture: Transformer-based, modified with
BitLinearlayers (BitNet framework).
subln normalization.
* No bias terms in linear or normalization layers.
- Quantization: Native 1.58-bit weights and 8-bit activations (W1.58A8).
- Parameters: ~2 Billion
- Training Tokens: 4 Trillion
- Context Length: Maximum sequence length of 4096 tokens.
- Training Stages:
- Tokenizer: LLaMA 3 Tokenizer (vocab size: 128,256).
How to Use (with transformers)
VERY IMPORTANT NOTE ON EFFICIENCY
>Please do NOT expect performance efficiency gains (in terms of speed, latency, or energy consumption) when using this model with the standard transformers library, even with the required fork.
>The current execution paths within transformers do not contain the specialized, highly optimized computational kernels required to leverage the advantages of the BitNet architecture. Running the model via transformers will likely result in inference speeds and energy usage comparable to, or potentially worse than, standard full-precision models within this framework on both CPU and GPU.
>While you might observe reduced memory usage due to the quantized weights, the primary computational efficiency benefits are not accessible through this standard transformers usage path.
For achieving the efficiency benefits demonstrated in the technical paper, you MUST use the dedicated C++ implementation: bitnet.cpp.
Requirements
pip install git+https://github.com/huggingface/transformers.git@096f25ae1f501a084d8ff2dcaf25fbc2bd60eba4Example
import torch
from transformers import AutoModelForCausalLM, AutoTokenizer
model_id = "microsoft/bitnet-b1.58-2B-4T"
Load tokenizer and model
tokenizer = AutoTokenizer.frompretrained(modelid)
model = AutoModelForCausalLM.from_pretrained(
model_id,
torch_dtype=torch.bfloat16
)
Apply the chat template
messages = [
{"role": "system", "content": "You are a helpful AI assistant."},
{"role": "user", "content": "How are you?"},
]
prompt = tokenizer.applychattemplate(messages, tokenize=False, addgenerationprompt=True)
chatinput = tokenizer(prompt, returntensors="pt").to(model.device)
Generate response
chatoutputs = model.generate(chatinput, maxnewtokens=50)
response = tokenizer.decode(chatoutputs[0][chatinput['inputids'].shape[-1]:], skipspecial_tokens=True) # Decode only the response part
print("\nAssistant Response:", response)How to Use (with bitnet.cpp)
Please refer to the bitnet.cpp GitHub repository for detailed compilation steps, usage examples, and command-line options.
Evaluation
BitNet b1.58 2B4T was evaluated against leading open-weight full-precision LLMs of similar size. Below are the key results (all models are instruction-tuned versions):
| Benchmark | LLaMA 3.2 1B | Gemma-3 1B | Qwen2.5 1.5B | SmolLM2 1.7B | MiniCPM 2B | BitNet b1.58 2B |
|---|---|---|---|---|---|---|
| Memory (Non-emb) | 2GB | 1.4GB | 2.6GB | 3.2GB | 4.8GB | 0.4GB |
| Latency (CPU Decoding) | 48ms | 41ms | 65ms | 67ms | 124ms | 29ms |
| Energy (Estimated) | 0.258J | 0.186J | 0.347J | 0.425J | 0.649J | 0.028J |
| Training Tokens (Pre-train) | 9T | 2T* | 18T | 11T | 1.1T | 4T |
| ARC-Challenge | 37.80 | 38.40 | 46.67 | 43.52 | 44.80 | 49.91 |
| ARC-Easy | 63.17 | 63.13 | 76.01 | 62.92 | 72.14 | 74.79 |
| OpenbookQA | 34.80 | 38.80 | 40.80 | 46.00 | 40.20 | 41.60 |
| BoolQ | 64.65 | 74.22 | 78.04 | 75.78 | 80.67 | 80.18 |
| HellaSwag | 60.80 | 57.69 | 68.28 | 71.71 | 70.81 | 68.44 |
| PIQA | 74.21 | 71.93 | 76.12 | 76.12 | 76.66 | 77.09 |
| WinoGrande | 59.51 | 58.48 | 62.83 | 68.98 | 61.80 | 71.90 |
| CommonsenseQA | 58.48 | 42.10 | 76.41 | 63.55 | 71.74 | 71.58 |
| TruthfulQA | 43.80 | 38.66 | 46.67 | 39.90 | 41.41 | 45.31 |
| TriviaQA | 37.60 | 23.49 | 38.37 | 45.97 | 34.13 | 33.57 |
| MMLU | 45.58 | 39.91 | 60.25 | 49.24 | 51.82 | 53.17 |
| HumanEval+ | 31.10 | 37.20 | 50.60 | 28.00 | 43.90 | 38.40 |
| GSM8K | 38.21 | 31.16 | 56.79 | 45.11 | 4.40 | 58.38 |
| MATH-500 | 23.00 | 42.00 | 53.00 | 17.60 | 14.80 | 43.40 |
| IFEval | 62.71 | 66.67 | 50.12 | 57.91 | 36.81 | 53.48 |
| MT-bench | 5.43 | 6.40 | 6.12 | 5.50 | 6.57 | 5.85 |
| Average | 44.90 | 43.74 | 55.23 | 48.70 | 42.05 | 54.19 |
Gemma-3 1B uses distillation.
License
The model weights and code are released under the MIT License.Disclaimer
This model is intended for research and development purposes. While efforts have been made to align it using SFT and DPO, it may still produce outputs that are unexpected, biased, or inaccurate. Please use responsibly.π GGUF File List
| π Filename | π¦ Size | β‘ Download |
|---|---|---|
|
ggml-model-i2_s.gguf
Recommended
LFS
|
1.11 GB | Download |