Instructions to use shibatch/tinybpe1m with libraries, inference providers, notebooks, and local apps. Follow these links to get started.

Libraries

How to use shibatch/tinybpe1m with Transformers:

# Load model directly
from transformers import AutoModel
model = AutoModel.from_pretrained("shibatch/tinybpe1m", dtype="auto")

llama-cpp-python

How to use shibatch/tinybpe1m with llama-cpp-python:

# !pip install llama-cpp-python

from llama_cpp import Llama

llm = Llama.from_pretrained(
	repo_id="shibatch/tinybpe1m",
	filename="tinybpe1m.BF16.gguf",
)

output = llm(
	"Once upon a time,",
	max_tokens=512,
	echo=True
)
print(output)

Notebooks
Google Colab
Kaggle
Local Apps Settings

llama.cpp

How to use shibatch/tinybpe1m with llama.cpp:

Install from brew

brew install llama.cpp
# Start a local OpenAI-compatible server with a web UI:
llama-server -hf shibatch/tinybpe1m:Q4_K_M
# Run inference directly in the terminal:
llama-cli -hf shibatch/tinybpe1m:Q4_K_M

Install from WinGet (Windows)

winget install llama.cpp
# Start a local OpenAI-compatible server with a web UI:
llama-server -hf shibatch/tinybpe1m:Q4_K_M
# Run inference directly in the terminal:
llama-cli -hf shibatch/tinybpe1m:Q4_K_M

Use pre-built binary

# Download pre-built binary from:
# https://github.com/ggerganov/llama.cpp/releases
# Start a local OpenAI-compatible server with a web UI:
./llama-server -hf shibatch/tinybpe1m:Q4_K_M
# Run inference directly in the terminal:
./llama-cli -hf shibatch/tinybpe1m:Q4_K_M

Build from source code

git clone https://github.com/ggerganov/llama.cpp.git
cd llama.cpp
cmake -B build
cmake --build build -j --target llama-server llama-cli
# Start a local OpenAI-compatible server with a web UI:
./build/bin/llama-server -hf shibatch/tinybpe1m:Q4_K_M
# Run inference directly in the terminal:
./build/bin/llama-cli -hf shibatch/tinybpe1m:Q4_K_M

Use Docker

docker model run hf.co/shibatch/tinybpe1m:Q4_K_M

LM Studio
Jan
Ollama
How to use shibatch/tinybpe1m with Ollama:
```
ollama run hf.co/shibatch/tinybpe1m:Q4_K_M
```

Unsloth Studio

How to use shibatch/tinybpe1m with Unsloth Studio:

Install Unsloth Studio (macOS, Linux, WSL)

curl -fsSL https://unsloth.ai/install.sh | sh
# Run unsloth studio
unsloth studio -H 0.0.0.0 -p 8888
# Then open http://localhost:8888 in your browser
# Search for shibatch/tinybpe1m to start chatting

Install Unsloth Studio (Windows)

irm https://unsloth.ai/install.ps1 | iex
# Run unsloth studio
unsloth studio -H 0.0.0.0 -p 8888
# Then open http://localhost:8888 in your browser
# Search for shibatch/tinybpe1m to start chatting

Using HuggingFace Spaces for Unsloth

# No setup required
# Open https://huggingface.co/spaces/unsloth/studio in your browser
# Search for shibatch/tinybpe1m to start chatting

Docker Model Runner
How to use shibatch/tinybpe1m with Docker Model Runner:
```
docker model run hf.co/shibatch/tinybpe1m:Q4_K_M
```

Lemonade

How to use shibatch/tinybpe1m with Lemonade:

Pull the model

# Download Lemonade from https://lemonade-server.ai/
lemonade pull shibatch/tinybpe1m:Q4_K_M

Run and chat with the model

lemonade run user.tinybpe1m-Q4_K_M

List all available models

lemonade list

TinyStories Llama2 1M (tinybpe1m) GGUF & HF Validation Suite

This repository provides ultra-lightweight Llama2 model files across various formats (both GGUF and Hugging Face / Safetensors), trained on the TinyStories dataset and optimized for testing and validation.

Why this repository exists

When developing a custom LLM inference engine, debugging with a full-sized model is slow. This suite offers a true 1M parameter scale model (~0.5MB to ~4MB depending on the quantization format), allowing developers to validate their loaders, serialization, quantization kernels, and inference logic step-by-step with maximum efficiency.

Difference from `tiny1m`

This is a BPE-based model variant. Unlike the standard tiny1m model, this model is NOT compatible with llama2.c. The custom SentencePiece BPE tokenizer utilized here relies on the byte_fallback mechanism to handle unknown characters. Because llama2.c's simplified native C loader/tokenizer cannot interpret or process byte_fallback routines, text generation will fail or corrupt in that environment. This suite is strictly designed and optimized for llama.cpp (GGUF) and Hugging Face transformers (Python) execution.

📂 Repository Structure & File Descriptions

1. GGUF Formats (Root Directory `./`)

A comprehensive validation suite converted for llama.cpp and compatible engines. The tokenizer vocabulary and special tokens are fully embedded within each GGUF binary. Every compiled quantization variant available in the root directory is explicitly covered below:

Filename(s) / Wildcard Pattern	Type	Size	Purpose / Validation Target
`tinybpe1m.F32.gguf`	`F32`	~4.0 MB	Baseline Test. Validates GGUF parsing, tensor layout, matrix multiplication, RoPE, and Attention logic without dequantization overhead.
`tinybpe1m.F16.gguf` `tinybpe1m.BF16.gguf`	`F16` `BF16`	~2.0 MB	Half-Precision Test. Validates 16-bit floating point loading, type casting, and inference stability.
`tinybpe1m.Q8_0.gguf`	`Q8_0`	~1.1 MB	Quantization Level 1. Validates block-based uniform scaling with 32 elements.
`tinybpe1m.Q4_0.gguf` `tinybpe1m.Q4_1.gguf`	`Q4_0` `Q4_1`	~0.7 MB	Quantization Level 2. Validates classic 4-bit linear quantization and bit-unpacking logic.
`tinybpe1m.Q2_K.gguf`	`Q2_K`	~0.5 MB	Standard K-Quant (2-bit). Validates 2-bit super-block quantization parsing.
*`tinybpe1m.Q3_K_.gguf`** ↳ `tinybpe1m.Q3_K_S.gguf` ↳ `tinybpe1m.Q3_K_M.gguf` ↳ `tinybpe1m.Q3_K_L.gguf`	`Q3_K`	~0.6 MB	Standard K-Quant (3-bit). Validates Small, Medium, and Large sub-variants of 3-bit multi-block structures.
*`tinybpe1m.Q4_K_.gguf`** ↳ `tinybpe1m.Q4_K_S.gguf` ↳ `tinybpe1m.Q4_K_M.gguf`	`Q4_K`	~0.7 MB	Standard K-Quant (4-bit). Validates Small and Medium sub-variants of modern 4-bit super-block structural parsing.
*`tinybpe1m.Q5_K_.gguf`** ↳ `tinybpe1m.Q5_K_S.gguf` ↳ `tinybpe1m.Q5_K_M.gguf`	`Q5_K`	~0.8 MB	Standard K-Quant (5-bit). Validates Small and Medium sub-variants of 5-bit mixed precision super-blocks.
`tinybpe1m.Q6_K.gguf`	`Q6_K`	~0.9 MB	Standard K-Quant (6-bit). Validates 6-bit high-fidelity super-block quantization.
*`tinybpe1m.IQ3_.gguf`** ↳ `tinybpe1m.IQ3_XXS.gguf` ↳ `tinybpe1m.IQ3_S.gguf`	`I-Quants`	~0.5 MB	Importance Quants (3-bit). Non-linear 3-bit importance quantization targeting lookup table (codebook) decoding logic.
*`tinybpe1m.IQ4_.gguf`** ↳ `tinybpe1m.IQ4_NL.gguf` ↳ `tinybpe1m.IQ4_XS.gguf`	`I-Quants`	~0.6 MB	Importance Quants (4-bit). Non-linear 4-bit importance quantization variants (Non-Linear and Extra Small).
`tinybpe1m.TQ1_0.gguf` `tinybpe1m.TQ2_0.gguf`	`Ternary`	~0.4 MB	Experimental. Ternary (-1, 0, 1) state quantization for cutting-edge engine testing.

2. Hugging Face Native Format (`./hf/`)

This directory contains the standard files required to load the model using the PyTorch transformers library:

hf/model.safetensors: The raw, unquantized model weights stored securely in Safetensors format.
hf/config.json: The architectural configuration file defining hyperparameters (layers, heads, dimensions).
hf/generation_config.json: Default parameters optimized for text generation.
hf/tokenizer_config.json: Tokenizer behavior layout enabling automatic BOS token injection and padding setup.
hf/special_tokens_map.json: Architectural mappings tying token strings to exact internal special token IDs.
hf/tokenizer.model: The custom 512-vocab SentencePiece tokenizer model file.

🚀 Usage Examples

A. Running GGUF via llama.cpp

To verify your local setup or test custom execution backends using the official native utilities:

./llama-cli -m tinybpe1m.Q4_K_M.gguf -p "Tom and Jerry are " -n 64 --temp 0.0

B. Loading Hugging Face Formats via Python

You can import the Hugging Face variant directly into Python using the transformers library.

import torch
from transformers import AutoTokenizer, AutoModelForCausalLM

repo_id = "shibatch/tinybpe1m"

# The library automatically loads from the hf/ subfolder
tokenizer = AutoTokenizer.from_pretrained(repo_id, subfolder="hf")
model = AutoModelForCausalLM.from_pretrained(repo_id, subfolder="hf")

prompt = "Tom and Jerry are "
inputs = tokenizer(prompt, return_tensors="pt")

with torch.no_grad():
    outputs = model.generate(
        **inputs, 
        max_new_tokens=64, 
        do_sample=False,
        pad_token_id=tokenizer.eos_token_id
    )

print(tokenizer.decode(outputs[0], skip_special_tokens=True))

📝 Model Specifications

The network architecture features an unshared output layer (lm_head) to keep memory structures consistent with standard Llama 2 definitions. Thanks to the highly optimized 512 vocabulary size, the token embedding and output layers remain extremely lightweight.

Architecture: Llama 2 (Scaled-down variant)
Dataset: TinyStories
Total Parameters: ~1M (Exactly 896,256 parameters)
Vocabulary Size: 512 (Custom SentencePiece BPE Tokenizer with byte_fallback enabled)
Hidden Size (hidden_size): 128
Number of Hidden Layers (num_hidden_layers): 4
Number of Attention Heads (num_heads): 2
Number of Key-Value Heads (num_kv_heads): 2
Intermediate Size (intermediate_size): 352
Max Position Embeddings (max_position_embeddings): 256

📜 Acknowledgments & License

Original Implementation: Inspired by Andrej Karpathy's llama2.c project.
Dataset: TinyStories dataset.
License: MIT License. You are free to use, modify, and distribute these assets for any purpose.

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