I want to track the mouse coordinates in my OpenGL scene on the ground surface of the world which is modeled as a height map. Currently there is no fancy stuff like hardware tessellation. Note that this question is not about object picking.
Currently I'm doing the following which is clearly dropping the performance because of a read-back operation:
- Render the world (the ground surface)
- Read back the depth value at the mouse coordinates
- Render the rest of the scene
- Swap buffers and render the next frame
The read back is between the two render steps because I want the depth value of the ground surface without any objects in front of it. It is done using the following command:
GLfloat depth; glReadPixels(x, y, 1, 1, GL_DEPTH_COMPONENT, GL_FLOAT, &depth);
My application limits the frame rate to 60 frames per second. When rendering the scene without the read back operation, I experience a CPU usage of less than 5%, but when doing the read back, it increases to about 75% although I'm not doing much to render the scene or update any game model or such things.
A temporary solution is to cache the depth value of the pixel under the mouse and update it only every 5th or 10th frame which causes the CPU usage going back down below 10%. But clearly can't be the best solution to the problem.
How can I implement picking (not object picking since I want the (floating point) coordinates on the surface) efficiently?
I already thought of reading back the depth value of the front buffer instead of the back buffer, but when googling on how to do so, I only find people complaining about glRead* methods to be best avoided at all. But how can I read something (do picking) without reading something (using glRead*)?
I'm confused. How do other people implement picking?
A totally different approach would be implementing the world surface picking in software. It should be no big deal to reconstruct a 3D ray from the camera "into the depth", representing the points in space which are rendered at the target pixel. Then I could implement an intersection algorithm to find the front-most point on the surface.