# How Do I Create Cheap Shadows In OpenGL?

I have two models, A and B, and one light, L. I would like model A to cast a shadow on model B. I don't want to bother with shadow volumes or proper shadows for the moment, just a simple circle shadow will suffice. The effect is that model A is treated as a sphere for shadow casting purposes.

Here is how I envision the algorithm:

For each triangle in model B, draw the triangle. Project a circle onto the triangle along the line from L to A, increasing the size of the circle depending on how far away the triangle is. Ensure the circle is clipped to the triangle's boundaries (using the stencil buffer in some way, I imagine).

I'm working with OpenGL and plain C.

Any pointers on some reference documentation I can read? Or implmentation ideas?

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I think it is actually easier to implement correct shadows because OpenGL can do the work for you.

I found a working shadow code with lots of documentation here: http://www.opengl.org/resources/code/samples/mjktips/TexShadowReflectLight.html

The code above renders the object twice: first normally then with a special matrix. It does a lot of unrelated things such as control with mouse and reflections. So here are the interesting parts.

``````/* Create a matrix that will project the desired shadow. */
void
GLfloat groundplane[4],
GLfloat lightpos[4])
{
GLfloat dot;

/* Find dot product between light position vector and ground plane normal. */
dot = groundplane[X] * lightpos[X] +
groundplane[Y] * lightpos[Y] +
groundplane[Z] * lightpos[Z] +
groundplane[W] * lightpos[W];

shadowMat[0][0] = dot - lightpos[X] * groundplane[X];
shadowMat[1][0] = 0.f - lightpos[X] * groundplane[Y];
shadowMat[2][0] = 0.f - lightpos[X] * groundplane[Z];
shadowMat[3][0] = 0.f - lightpos[X] * groundplane[W];

shadowMat[X][1] = 0.f - lightpos[Y] * groundplane[X];
shadowMat[1][1] = dot - lightpos[Y] * groundplane[Y];
shadowMat[2][1] = 0.f - lightpos[Y] * groundplane[Z];
shadowMat[3][1] = 0.f - lightpos[Y] * groundplane[W];

shadowMat[X][2] = 0.f - lightpos[Z] * groundplane[X];
shadowMat[1][2] = 0.f - lightpos[Z] * groundplane[Y];
shadowMat[2][2] = dot - lightpos[Z] * groundplane[Z];
shadowMat[3][2] = 0.f - lightpos[Z] * groundplane[W];

shadowMat[X][3] = 0.f - lightpos[W] * groundplane[X];
shadowMat[1][3] = 0.f - lightpos[W] * groundplane[Y];
shadowMat[2][3] = 0.f - lightpos[W] * groundplane[Z];
shadowMat[3][3] = dot - lightpos[W] * groundplane[W];

}
``````

I do not pretend to understand this completely. lightpos is the position of the light source. The first 3 coordinates of groundplane are the normal vector of the ground surface. The fourth is the offset (how far is it from 0,0,0).

And this part actually renders the shadow:

``````glPushMatrix();
drawDinosaur();
glPopMatrix();
``````

There are some things you need to glEnable/glDisable first for this to work so look at the link.

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This just "flattens" the model onto a plane.. good for projecting a shadow onto a flat surface. The OP wants to render the shadow onto an arbitrarily-shaped 3d object. – Jim Buck Jul 12 '09 at 0:14
This one can supposedly do that: nehe.gamedev.net/data/lessons/lesson.asp?lesson=27 Unfortunately I can not compile it with gcc. – stribika Jul 12 '09 at 0:37
This method seems good, but the cost of drawing the source model once for each face in B seems high. Is there a way to reduce the complexity of this method? – Martin Jul 12 '09 at 15:26
I have settled (for the moment) for this method, iterated once for each triangle of model B, it seems to work, but the speed leaves something to be desired. Thank you! – Martin Jul 12 '09 at 22:48
Here's a working link to at least the full code: cs.uiuc.edu/class/sp05/cs419/accum/softshadow.c – andy Jun 1 '12 at 7:20

This paper seems to cover your requirements, using OpenGL and hardware acceleration to create a detailed shadow map.

If I were trying to accomplish this, I would be tempted to use ray casting. For each triangle in B, create a vector from the triangle to the light. If it hits anything along the way, it is in shadow. This would be kind of slow unless you were using a decent acceleration structure and a fast triangle hit test. I like bounding volume hierarchies; many programs use them for collision detection as well.

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