Difference between revisions of "Tutorial - Stereo rendering"
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+ | __NOTOC__ __NOEDITSECTION__{{ContentBlock|color=white|content={{!!}} | ||
'''In this tutorial I will describe how to perform quadbuffered stereo rendering with Horde3D. This explicitly requires a graphics card that supports quad-buffering, i.e. rendering to two different output devices(Nvidia Quadro or ATI/AMD FireGL). This has been tested with a stereo projection system and polarization glasses.''' | '''In this tutorial I will describe how to perform quadbuffered stereo rendering with Horde3D. This explicitly requires a graphics card that supports quad-buffering, i.e. rendering to two different output devices(Nvidia Quadro or ATI/AMD FireGL). This has been tested with a stereo projection system and polarization glasses.''' | ||
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[http://www.orthostereo.com/geometryopengl.html Stereoscopic Geometry in OpenGL] | [http://www.orthostereo.com/geometryopengl.html Stereoscopic Geometry in OpenGL] | ||
− | In this tutorial we will only use an | + | In this tutorial we will only use an symmetric frustum. |
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appWidth = fullscreen ? videoInfo->current_w : width; | appWidth = fullscreen ? videoInfo->current_w : width; | ||
appHeight = fullscreen ? videoInfo->current_h : height; | appHeight = fullscreen ? videoInfo->current_h : height; | ||
− | |||
− | |||
if(fullscreen) | if(fullscreen) | ||
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std::cerr << "STEREO initialization failed! Restarting..."<< std::endl; | std::cerr << "STEREO initialization failed! Restarting..."<< std::endl; | ||
SDL_GL_SetAttribute(SDL_GL_STEREO, 0); | SDL_GL_SetAttribute(SDL_GL_STEREO, 0); | ||
− | if (!SDL_SetVideoMode( | + | if (!(surface = SDL_SetVideoMode(appWidth, appHeight, 32, SDL_OPENGL | SDL_FULLSCREEN | SDL_HWSURFACE))) { |
std::cerr << "SDL_SetVideoMode failed: " << SDL_GetError() << std::endl; | std::cerr << "SDL_SetVideoMode failed: " << SDL_GetError() << std::endl; | ||
SDL_Quit(); | SDL_Quit(); | ||
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}} | }} | ||
− | This will also work with GLFW. | + | This will also work with GLFW. Just call this line before opening your GLFW window. |
{{CppSourceCode| | {{CppSourceCode| | ||
description= GLFW stereo flag| | description= GLFW stereo flag| | ||
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== Render the scene == | == Render the scene == | ||
− | Now we need to calculate the eye offset and render the scene twice for | + | Now we need to calculate the eye offset and render the scene twice (once for each eye). This is done by switching the Horde3D render buffer to the corresponding eye, moving the camera to the desired eye offset and render the scene to the specified buffer. Again, this will only be done if stereo rendering has been enabled successfully. |
− | We will calculate the eye offset by simply "strafing" the camera from its original position slightly to the left and right and rotating it inwards. This example has some keys assigned to adjust the eye offset and strabismus ("cross-eyedness") on the fly. In normal (non-stereo) mode we can switch between the eyes to check | + | We will calculate the eye offset by simply "strafing" the camera from its original position slightly to the left and right and rotating it inwards. This example has some keys assigned to adjust the eye offset and strabismus ("cross-eyedness") on the fly. In normal (non-stereo) mode we can switch between the eyes to check the camera position even if stereo rendering is not available. |
{{CppSourceCode| | {{CppSourceCode| | ||
description= Render the scene (app.cpp)| | description= Render the scene (app.cpp)| | ||
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Horde3D::setNodeTransform( _cam, _x-xEyeOffset, _y, _z-zEyeOffset, _rx ,_ry-strabismus, 0, 1, 1, 1 ); | Horde3D::setNodeTransform( _cam, _x-xEyeOffset, _y, _z-zEyeOffset, _rx ,_ry-strabismus, 0, 1, 1, 1 ); | ||
Horde3D::render( _cam ); | Horde3D::render( _cam ); | ||
− | |||
Horde3D::setNodeParami(_cam, CameraNodeParams::OutputBufferIndex, 1); | Horde3D::setNodeParami(_cam, CameraNodeParams::OutputBufferIndex, 1); | ||
Horde3D::setNodeTransform( _cam, _x+xEyeOffset, _y, _z+zEyeOffset, _rx ,_ry+strabismus, 0, 1, 1, 1 ); | Horde3D::setNodeTransform( _cam, _x+xEyeOffset, _y, _z+zEyeOffset, _rx ,_ry+strabismus, 0, 1, 1, 1 ); | ||
Horde3D::render( _cam ); | Horde3D::render( _cam ); | ||
− | |||
} | } | ||
else { // non stereo | else { // non stereo | ||
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Horde3D::setNodeTransform( _cam, _x, _y, _z, _rx ,_ry, 0, 1, 1, 1 ); | Horde3D::setNodeTransform( _cam, _x, _y, _z, _rx ,_ry, 0, 1, 1, 1 ); | ||
Horde3D::render( _cam ); | Horde3D::render( _cam ); | ||
− | |||
} | } | ||
// Remove all overlays | // Remove all overlays | ||
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// Write all mesages to log file | // Write all mesages to log file | ||
Horde3DUtils::dumpMessages(); | Horde3DUtils::dumpMessages(); | ||
+ | |||
+ | Horde3D::finalizeFrame(); // comment this line if you are using Horde3D 1.0.0 beta 2 | ||
SDL_GL_SwapBuffers(); | SDL_GL_SwapBuffers(); | ||
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</source> | </source> | ||
+ | }} | ||
+ | |||
+ | == TODO == | ||
+ | - calculate asymmetric frustum | ||
+ | |||
+ | - add a second camera node for easier camera movement | ||
}} | }} |
Latest revision as of 17:45, 3 January 2010
In this tutorial I will describe how to perform quadbuffered stereo rendering with Horde3D. This explicitly requires a graphics card that supports quad-buffering, i.e. rendering to two different output devices(Nvidia Quadro or ATI/AMD FireGL). This has been tested with a stereo projection system and polarization glasses. To do this we need to render our scene from two different points of view(left and right eye) and send each frame to the corresponding output device. Stereoscopic Geometry in OpenGL In this tutorial we will only use an symmetric frustum. Enable quadbufferingFirst of all we need to tell our graphics card to enable quadbuffering if available. The following code shows how to do this using SDL. We will try to enable stereo rendering by default but it will fall back to non-stereo if the graphics card does not have quadbuffering capabilities. We will enable stereo rendering only in fullscreen mode.
This will also work with GLFW. Just call this line before opening your GLFW window.
Render the sceneNow we need to calculate the eye offset and render the scene twice (once for each eye). This is done by switching the Horde3D render buffer to the corresponding eye, moving the camera to the desired eye offset and render the scene to the specified buffer. Again, this will only be done if stereo rendering has been enabled successfully. We will calculate the eye offset by simply "strafing" the camera from its original position slightly to the left and right and rotating it inwards. This example has some keys assigned to adjust the eye offset and strabismus ("cross-eyedness") on the fly. In normal (non-stereo) mode we can switch between the eyes to check the camera position even if stereo rendering is not available.
TODO- calculate asymmetric frustum - add a second camera node for easier camera movement |