Python bindings for the stable-diffusion.cpp library
Project description
🖼️ Python Bindings for stable-diffusion.cpp
Simple Python bindings for @leejet's stable-diffusion.cpp
library.
This package provides:
- Low-level access to C API via
ctypes
interface. - High-level Python API for Stable Diffusion and FLUX image generation.
Installation
Requirements:
- Python 3.8+
- C compiler
- Linux: gcc or clang
- Windows: Visual Studio or MinGW
- MacOS: Xcode
To install the package, run:
pip install stable-diffusion-cpp-python
This will also build stable-diffusion.cpp
from source and install it alongside this python package.
If this fails, add --verbose
to the pip install
to see the full cmake build log.
Installation Configuration
stable-diffusion.cpp
supports a number of hardware acceleration backends to speed up inference as well as backend specific options. See the stable-diffusion.cpp README for a full list.
All stable-diffusion.cpp
cmake build options can be set via the CMAKE_ARGS
environment variable or via the --config-settings / -C
cli flag during installation.
Environment Variables
# Linux and Mac
CMAKE_ARGS="-DSD_CUBLAS=ON" pip install stable-diffusion-cpp-python
# Windows
$env:CMAKE_ARGS="-DSD_CUBLAS=ON"
pip install stable-diffusion-cpp-python
CLI / requirements.txt
They can also be set via pip install -C / --config-settings
command and saved to a requirements.txt
file:
pip install --upgrade pip # ensure pip is up to date
pip install stable-diffusion-cpp-python -C cmake.args="-DSD_CUBLAS=ON"
# requirements.txt
stable-diffusion-cpp-python -C cmake.args="-DSD_CUBLAS=ON"
Supported Backends
Below are some common backends, their build commands and any additional environment variables required.
Using CUBLAS (CUDA)
This provides BLAS acceleration using the CUDA cores of your Nvidia GPU. Make sure you have the CUDA toolkit installed. You can download it from your Linux distro's package manager (e.g. apt install nvidia-cuda-toolkit
) or from here: CUDA Toolkit. You can check your installed CUDA toolkit version by running nvcc --version
.
- It is recommended you have at least 4 GB of VRAM.
CMAKE_ARGS="-DSD_CUBLAS=ON" pip install stable-diffusion-cpp-python
Using HIPBLAS (ROCm)
This provides BLAS acceleration using the ROCm cores of your AMD GPU. Make sure you have the ROCm toolkit installed. Windows users refer to docs/hipBLAS_on_Windows.md for a comprehensive guide.
CMAKE_ARGS="-G Ninja -DCMAKE_C_COMPILER=clang -DCMAKE_CXX_COMPILER=clang++ -DSD_HIPBLAS=ON -DCMAKE_BUILD_TYPE=Release -DAMDGPU_TARGETS=gfx1101" pip install stable-diffusion-cpp-python
Using Metal
Using Metal makes the computation run on the GPU. Currently, there are some issues with Metal when performing operations on very large matrices, making it highly inefficient at the moment. Performance improvements are expected in the near future.
CMAKE_ARGS="-DSD_METAL=ON" pip install stable-diffusion-cpp-python
Using Vulkan
Install Vulkan SDK from https://www.lunarg.com/vulkan-sdk/.CMAKE_ARGS="-DSD_VULKAN=ON" pip install stable-diffusion-cpp-python
Using SYCL
Using SYCL makes the computation run on the Intel GPU. Please make sure you have installed the related driver and Intel® oneAPI Base toolkit before start. More details and steps can refer to llama.cpp SYCL backend.
# Export relevant ENV variables
source /opt/intel/oneapi/setvars.sh
# Option 1: Use FP32 (recommended for better performance in most cases)
CMAKE_ARGS="-DSD_SYCL=ON -DCMAKE_C_COMPILER=icx -DCMAKE_CXX_COMPILER=icpx" pip install stable-diffusion-cpp-python
# Option 2: Use FP16
CMAKE_ARGS="-DSD_SYCL=ON -DCMAKE_C_COMPILER=icx -DCMAKE_CXX_COMPILER=icpx -DGGML_SYCL_F16=ON" pip install stable-diffusion-cpp-python
Using Flash Attention
Enabling flash attention reduces memory usage by at least 400 MB. At the moment, it is not supported when CUBLAS is enabled because the kernel implementation is missing.
CMAKE_ARGS="-DSD_FLASH_ATTN=ON" pip install stable-diffusion-cpp-python
Using OpenBLAS
CMAKE_ARGS="-DGGML_OPENBLAS=ON" pip install stable-diffusion-cpp-python
Upgrading and Reinstalling
To upgrade and rebuild stable-diffusion-cpp-python
add --upgrade --force-reinstall --no-cache-dir
flags to the pip install
command to ensure the package is rebuilt from source.
High-level API
The high-level API provides a simple managed interface through the StableDiffusion
class.
Below is a short example demonstrating how to use the high-level API to generate a simple image:
Text to Image
from stable_diffusion_cpp import StableDiffusion
def callback(step: int, steps: int, time: float):
print("Completed step: {} of {}".format(step, steps))
stable_diffusion = StableDiffusion(
model_path="../models/v1-5-pruned-emaonly.safetensors",
wtype="default", # Weight type (default: automatically determines weight type of model file)
)
output = stable_diffusion.txt_to_img(
prompt="a lovely cat",
width=512, # Must be a multiple of 64
height=512, # Must be a multiple of 64
progress_callback=callback,
# seed=1337, # Uncomment to set a specific seed
)
output[0].save("output.png") # Image returned as list of PIL Images
With LoRA (Stable Diffusion)
You can specify the directory where the lora weights are stored via lora_model_dir
. If not specified, the default is the current working directory.
- LoRA is specified via prompt, just like stable-diffusion-webui. (e.g.
<lora:marblesh:1>
) - LoRAs will not work when using quantized models. You must instead use a full precision
.safetensors
model.
Here's a simple example:
from stable_diffusion_cpp import StableDiffusion
stable_diffusion = StableDiffusion(
model_path="../models/v1-5-pruned-emaonly.safetensors",
lora_model_dir="../models/", # This should point to folder where LoRA weights are stored (not an individual file)
)
output = stable_diffusion.txt_to_img(
prompt="a lovely cat<lora:marblesh:1>",
)
- The
lora_model_dir
argument is used in the same way for FLUX image generation.
FLUX Image Generation
FLUX models should be run using the same implementation as the stable-diffusion.cpp FLUX documentation where the diffusion_model_path
argument is used in place of the model_path
. The clip_l_path
, t5xxl_path
, and vae_path
arguments are also required for inference to function.
Download the weights from the links below:
- Preconverted gguf weights from FLUX.1-dev-gguf or FLUX.1-schnell, this way you don't have to do the conversion yourself.
- Download
vae
from https://huggingface.co/black-forest-labs/FLUX.1-dev/blob/main/ae.safetensors - Download
clip_l
from https://huggingface.co/comfyanonymous/flux_text_encoders/blob/main/clip_l.safetensors - Download
t5xxl
from https://huggingface.co/comfyanonymous/flux_text_encoders/blob/main/t5xxl_fp16.safetensors
from stable_diffusion_cpp import StableDiffusion
stable_diffusion = StableDiffusion(
diffusion_model_path="../models/flux1-schnell-q3_k.gguf", # In place of model_path
clip_l_path="../models/clip_l.safetensors",
t5xxl_path="../models/t5xxl_fp16.safetensors",
vae_path="../models/ae.safetensors",
)
output = stable_diffusion.txt_to_img(
prompt="a lovely cat holding a sign says 'flux.cpp'",
sample_steps=4,
cfg_scale=1.0, # a cfg_scale of 1 is recommended for FLUX
sample_method="euler", # euler is recommended for FLUX
)
With LoRA (FLUX)
LoRAs can be used with FLUX models in the same way as Stable Diffusion models (as shown above).
Note that:
- It is recommended to use LoRA with naming formats compatible with ComfyUI.
- Only the Flux-dev q8_0 will work with LoRAs.
- You can download FLUX LoRA models from https://huggingface.co/XLabs-AI/flux-lora-collection/tree/main (you must use a comfy converted version!!!).
SD3.5 Image Generation
Download the weights from the links below:
- Download sd3.5_large from https://huggingface.co/stabilityai/stable-diffusion-3.5-large/blob/main/sd3.5_large.safetensors
- Download clip_g from https://huggingface.co/Comfy-Org/stable-diffusion-3.5-fp8/blob/main/text_encoders/clip_g.safetensors
- Download clip_l from https://huggingface.co/Comfy-Org/stable-diffusion-3.5-fp8/blob/main/text_encoders/clip_l.safetensors
- Download t5xxl from https://huggingface.co/Comfy-Org/stable-diffusion-3.5-fp8/blob/main/text_encoders/t5xxl_fp16.safetensors
from stable_diffusion_cpp import StableDiffusion
stable_diffusion = StableDiffusion(
model_path="../models/sd3.5_large.safetensors",
clip_l_path="../models/clip_l.safetensors",
clip_g_path="../models/clip_g.safetensors",
t5xxl_path="../models/t5xxl_fp16.safetensors",
)
output = stable_diffusion.txt_to_img(
prompt="a lovely cat holding a sign says 'Stable diffusion 3.5 Large'",
height=1024,
width=1024,
cfg_scale=4.5,
sample_method="euler",
)
Other High-level API Examples
Other examples for the high-level API (such as image to image, upscaling and model conversion) can be found in the tests directory.
Low-level API
The low-level API is a direct ctypes
binding to the C API provided by stable-diffusion.cpp
.
The entire low-level API can be found in stable_diffusion_cpp/stable_diffusion_cpp.py and directly mirrors the C API in stable-diffusion.h.
Below is a short example demonstrating how to use the low-level API:
import stable_diffusion_cpp as sd_cpp
import ctypes
from PIL import Image
img = Image.open("path/to/image.png")
img_bytes = img.tobytes()
c_image = sd_cpp.sd_image_t(
width=img.width,
height=img.height,
channel=channel,
data=ctypes.cast(
(ctypes.c_byte * len(img_bytes))(*img_bytes),
ctypes.POINTER(ctypes.c_uint8),
),
) # Create a new C sd_image_t
img = sd_cpp.upscale(
self.upscaler,
image_bytes,
upscale_factor,
) # Upscale the image
Development
To get started, clone the repository and install the package in editable / development mode.
git clone --recurse-submodules https://github.com/william-murray1204/stable-diffusion-cpp-python.git
cd stable-diffusion-cpp-python
# Upgrade pip (required for editable mode)
pip install --upgrade pip
# Install with pip
pip install -e .
Now you can make changes to the code within the stable_diffusion_cpp
directory and test them in your python environment.
Cleanup
To clear the cache.
make clean
References
- stable-diffusion.cpp
- llama-cpp-python
- llama.cpp
- whisper-cpp-python
- Golang stable-diffusion
- StableDiffusion.NET
License
This project is licensed under the terms of the MIT license. See LICENSE for details.
Project details
Release history Release notifications | RSS feed
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.
Source Distribution
File details
Details for the file stable_diffusion_cpp_python-0.1.9.tar.gz
.
File metadata
- Download URL: stable_diffusion_cpp_python-0.1.9.tar.gz
- Upload date:
- Size: 46.7 MB
- Tags: Source
- Uploaded using Trusted Publishing? No
- Uploaded via: twine/5.1.1 CPython/3.12.7
File hashes
Algorithm | Hash digest | |
---|---|---|
SHA256 | 6cd62f6c2f5b0c699f64c34c7323bc3861e8c9f041169eff542786aa3207ed2a |
|
MD5 | 05e16851e29e84732179655c35e29459 |
|
BLAKE2b-256 | e5d5443ca93d0bb7692792f24f2b626c3a099694ea13b124153c7c0e496249ee |