Metadata-Version: 2.1
Name: q3dviewer
Version: 1.2.7
Summary: A library designed for quickly deploying a 3D viewer.
Author-email: Liu Yang <liu.yang@jp.panasonic.com>
License: MIT
Project-URL: Homepage, https://github.com/scomup/q3dviewer
Classifier: Programming Language :: Python :: 3
Classifier: License :: OSI Approved :: MIT License
Classifier: Operating System :: OS Independent
Requires-Python: >=3.8
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: numpy
Requires-Dist: pyside6
Requires-Dist: PyOpenGL
Requires-Dist: meshio
Requires-Dist: pypcd4
Requires-Dist: pye57
Requires-Dist: laspy
Requires-Dist: imageio
Requires-Dist: imageio[ffmpeg]
Requires-Dist: matplotlib
Requires-Dist: pyproj


![q3dviewer Logo](imgs/logo.png)

[![License: MIT](https://img.shields.io/badge/License-MIT-yellow.svg)](https://opensource.org/licenses/MIT)
[![PyPI version](https://badge.fury.io/py/q3dviewer.svg)](https://badge.fury.io/py/q3dviewer)

`q3dviewer` is a library designed for quickly deploying a 3D viewer. It is based on Qt and provides efficient OpenGL items for displaying 3D objects (e.g., point clouds, cameras, and 3D Gaussians). You can use it to visualize your 3D data or set up an efficient viewer application. It is inspired by PyQtGraph but focuses more on efficient 3D rendering.


To show how to use `q3dviewer` as a library, we also provide some [very useful tools](#tools).


## Installation

To install `q3dviewer`, execute the following command in your terminal on either Linux or Windows:

```bash
pip install q3dviewer
```

### Note for Windows Users

- Ensure that you have a Python 3 environment set up:
  - Download and install Python 3 from the [official Python website](https://www.python.org/downloads/).
  - During installation, make sure to check the "Add Python to PATH" option.

### Note for Linux Users

If you encounter an error related to loading the shared library `libxcb-cursor.so.0` on Ubuntu 20.04 or 22.04, please install `libxcb-cursor0`:

```bash
sudo apt-get install libxcb-cursor0
```

## Tools

Once installed, you can directly use the following tools:

### 1. Cloud Viewer

A tool for visualizing point cloud files (LAS, PCD, PLY, E57). Launch it by executing the following command in your terminal:

```sh
cloud_viewer
```

*Alternatively*, if the path is not set (though it's not recommended):

```sh
python3 -m q3dviewer.tools.cloud_viewer
```

**Basic Operations**

📁 **Load Files** - Drag and drop files into the viewer
* Point clouds: .pcd, .ply, .las, .e57
* Mesh files: .stl

📏 **Measure Distance** - Interactive point measurement
* `Ctrl + Left Click`: Add measurement point
* `Ctrl + Right Click`: Remove last point
* Total distance displayed automatically

🎥 **Camera Controls** - Navigate the 3D scene
* `Double Click`: Set camera center to point
* `Right Drag`: Rotate view
* `Left Drag`: Pan view
* `Mouse Wheel`: Zoom in/out

⚙️ **Settings** - Press `M` to open settings window
* Adjust visualization properties

For example, you can download and view point clouds of Tokyo in LAS format from the following link:

[Tokyo Point Clouds](https://www.geospatial.jp/ckan/dataset/tokyopc-23ku-2024/resource/7807d6d1-29f3-4b36-b0c8-f7aa0ea2cff3)

![Cloud Viewer Screenshot](imgs/tokyo.png)

**Mesh Support** - Starting from version 1.2.4, mesh files (.stl) are now supported.

![Screenshot from 2026-02-04 18-32-04.png](imgs/mesh.png)

### 2. ROS Viewer

A high-performance SLAM viewer compatible with ROS, serving as an alternative to RVIZ.

```sh
roscore &
ros_viewer
```

### 3. Film Maker

Would you like to create a video from point cloud data? With Film Maker, you can easily create videos with simple operations. Just edit keyframes using the user-friendly GUI, and the software will automatically interpolate the keyframes to generate the video.

```sh
film_maker
```

**Basic Operations**
* File loading & viewpoint movement: Same as Cloud_Viewer
* Space key to add a keyframe.
* Delete key to remove a keyframe.
* Play button: Automatically play the video (pressing again will stop playback)
* Record checkbox: When checked, actions will be automatically recorded during playback

Film Maker GUI: 

![film_maker_demo.gif](imgs/film_maker_demo.gif)

The demo video demonstrating how to use Film Maker utilizes the [cloud data of Kyobashi Station Area](https://www.geospatial.jp/ckan/dataset/kyoubasiekisyuuhen_las) located in Osaka, Japan.

### 4. Gaussian Viewer

A simple viewer for 3D Gaussians. See [EasyGaussianSplatting](https://github.com/scomup/EasyGaussianSplatting) for more information.

```sh
gaussian_viewer  # Drag and drop your Gaussian file onto the window
```

![Gaussian Viewer GIF](https://qiita-image-store.s3.ap-northeast-1.amazonaws.com/0/149168/441e6f5a-214d-f7c1-11bf-5fa79e63b38e.gif)

### 5. LiDAR-LiDAR Calibration Tools

A tool to compute the relative pose between two LiDARs. It allows for both manual adjustment in the settings screen and automatic calibration.

```sh
lidar_calib --lidar0=/YOUR_LIDAR0_TOPIC --lidar1=/YOUR_LIDAR1_TOPIC
```

![LiDAR Calibration](https://qiita-image-store.s3.ap-northeast-1.amazonaws.com/0/149168/5a8a9903-a42a-8322-1d23-0cbecd3fa99a.png)

### 6. LiDAR-Camera Calibration Tools

A tool for calculating the relative pose between a LiDAR and a camera. It allows for manual adjustment in the settings screen and real-time verification of LiDAR point projection onto images.

```sh
lidar_cam_calib --lidar=/YOUR_LIDAR_TOPIC --camera=/YOUR_CAMERA_TOPIC --camera_info=/YOUR_CAMERA_INFO_TOPIC
```

![LiDAR-Camera Calibration](https://qiita-image-store.s3.ap-northeast-1.amazonaws.com/0/149168/f8359820-2ae7-aa37-6577-0fa035f4dd95.png)

## Using as a Library

Using the examples above, you can easily customize and develop your own 3D viewer with `q3dviewer`. Below is a coding example.

### Custom 3D Viewer

```python
#!/usr/bin/env python3

import q3dviewer as q3d  # Import q3dviewer

def main():
    # Create a Qt application
    app = q3d.QApplication([])

    # Create various 3D items
    axis_item = q3d.AxisItem(size=0.5, width=5)
    grid_item = q3d.GridItem(size=10, spacing=1)

    # Create a viewer
    viewer = q3d.Viewer(name='example')
    
    # Add items to the viewer
    viewer.add_items({
        'grid': grid_item,
        'axis': axis_item,
    })

    # Show the viewer & run the Qt application
    viewer.show()
    app.exec()

if __name__ == '__main__':
    main()
```

`q3dviewer` provides the following 3D items:

- **AxisItem**: Displays coordinate axes or the origin position.
- **CloudItem**: Displays point clouds.
- **CloudIOItem**: Displays point clouds with input/output capabilities.
- **GaussianItem**: Displays 3D Gaussians.
- **GridItem**: Displays grids.
- **ImageItem**: Displays 2D images.
- **Text2DItem**: Displays 2D text.
- **Text3DItem**: Displays 3D test and mark.
- **LineItem**: Displays lines or trajectories.

### Developing Custom Items

In addition to the standard 3D items provided, you can visualize custom 3D items with simple coding. Below is a sample:

```python
from OpenGL.GL import *
import numpy as np
import q3dviewer as q3d
from q3dviewer.Qt.QtWidgets import QLabel, QSpinBox

class YourItem(q3d.BaseItem):
    def __init__(self):
        super(YourItem, self).__init__()
        # Necessary initialization

    def add_setting(self, layout):
        # Initialize the settings screen
        label = QLabel("Add your setting:")
        layout.addWidget(label)
        box = QSpinBox()
        layout.addWidget(box)

    def set_data(self, data):
        # Obtain the data you want to visualize
        pass

    def initialize_gl(self):
        # OpenGL initialization settings (if needed)
        pass

    def paint(self):
        # Visualize 3D objects using OpenGL
        pass
```

Enjoy using `q3dviewer`!
