# OpenGL 3+ with orthographic projection of directional light

I'm currently having an issue with directional light shadow maps from a moving (sun-like) light source.

When I initially implemented, the light projection matrix was computed as 3D, and the shadow map appears beautifully. I then learned that for what I'm trying to do, an orthographic projection would work better, but I'm having a hard time substituting the proper projection matrix.

Each tick, the sun moves a certain amount along a circle, as one would expect. I use a homegrown "lookAt" method to determine the proper viewing matrix. So, for instance, daylight occurs from 6AM to 6PM. When the sun is at the 9AM position (45 degrees) it should look at the origin and render the shadow map to the framebuffer. What appears to be happening with the orthographic projection is that it doesn't "tilt down" toward the origin. It simply keeps looking straight down the Z axis instead. Things look fine at 6AM and 6PM, but 12 noon, for instance, show absolutely nothing.

Here's how I'm setting things up:

Original 3D projection matrix:

``````Matrix4f projectionMatrix = new Matrix4f();
float aspectRatio = (float) width / (float) height;

float y_scale = (float) (1 / cos(toRadians(fov / 2f)));
float x_scale = y_scale / aspectRatio;
float frustum_length = far_z - near_z;

projectionMatrix.m00 = x_scale;
projectionMatrix.m11 = y_scale;
projectionMatrix.m22 = (far_z + near_z) / (near_z - far_z);
projectionMatrix.m23 = -1;
projectionMatrix.m32 = -((2 * near_z * far_z) / frustum_length);
``````

LookAt method:

``````public Matrix4f lookAt( float x, float y, float z,
float center_x, float center_y, float center_z ) {
Vector3f forward = new Vector3f( center_x - x, center_y - y, center_z - z );
Vector3f up      = new Vector3f( 0, 1, 0 );

if ( center_x == x && center_z == z && center_y != y ) {
up.y = 0;
up.z = 1;
}

Vector3f side = new Vector3f();

forward.normalise();

Vector3f.cross(forward, up, side );
side.normalise();

Vector3f.cross(side, forward, up);
up.normalise();

Matrix4f multMatrix = new Matrix4f();
multMatrix.m00 = side.x;
multMatrix.m10 = side.y;
multMatrix.m20 = side.z;
multMatrix.m01 = up.x;
multMatrix.m11 = up.y;
multMatrix.m21 = up.z;
multMatrix.m02 = -forward.x;
multMatrix.m12 = -forward.y;
multMatrix.m22 = -forward.z;

Matrix4f translation = new Matrix4f();
translation.m30 = -x;
translation.m31 = -y;
translation.m32 = -z;

Matrix4f result = new Matrix4f();

Matrix4f.mul( multMatrix, translation, result );
return result;
}
``````

Orthographic projection (using width 100, height 75, near 1.0, far 100 ) I've tried this with many many different values:

``````Matrix4f projectionMatrix = new Matrix4f();

float r = width * 1.0f;
float l = -width;
float t = height * 1.0f;
float b = -height;

projectionMatrix.m00 = 2.0f / ( r - l );
projectionMatrix.m11 = 2.0f / ( t - b );
projectionMatrix.m22 = 2.0f / (far_z - near_z);
projectionMatrix.m30 = - ( r + l ) / ( r - l );
projectionMatrix.m31 = - ( t + b ) / ( t - b );
projectionMatrix.m32 = -(far_z + near_z) / (far_z - near_z);
projectionMatrix.m33 = 1;
``````

``````#version 150 core

uniform mat4 projectionMatrix;
uniform mat4 viewMatrix;
uniform mat4 modelMatrix;

in vec4 in_Position;

out float pass_Position;

void main(void) {
gl_Position = projectionMatrix * viewMatrix * modelMatrix * in_Position;
pass_Position = gl_Position.z;
}
``````

``````#version 150 core

in vec4 pass_Color;
in float pass_Position;

layout(location=0) out float fragmentdepth;

out vec4 out_Color;

void main(void) {
fragmentdepth = gl_FragCoord.z;
}
``````

I feel that I'm missing something very simple here. As I said, this works fine with a 3D projection matrix, but I want the shadows constant as the user travels across the world, which makes sense for directional lighting, and thus orthographic projection.

Actually, who told you that using an orthographic projection matrix would be a good idea for shadow maps? This might work for things like the sun, which are effectively infinitely far away, but for local lights perspective is very relevant. You have to be careful with perspective projection and shadow maps though, because the sample frequency varies with distance and you wind up getting a lot of precision at some distances and not enough at others unless you use things like cascading or perspective warping in general; this is probably more than you should be thinking about at the moment though :)

Also, orthographic projection matrices are no more or no less 3D than perspective, insofar as they work by projecting a 3D "image" onto a 2D viewing plane... the only difference between them and perspective is that parallel lines remain parallel. Put another way, (x,y,near) and (x,y,far) ideally project to the same position on screen in an orthographic projection.

Your use of `gl_FragCoord.z` in the fragment shader is unusual. Since this is the value that is written to the depth buffer, you might as well write NOTHING in your fragment shader and re-use the depth buffer. Unless your implementation does not support a floating-point depth buffer you are wasting memory bandwidth by writing the depth to two places. A depth-only pass with `glColorMask (GL_FALSE, GL_FALSE, GL_FALSE, GL_FALSE)` will usually get you much higher throughput when constructing shadow maps.

If you actually used the value of `pass_Position` (which is your non-perspective corrected Z coordinate in clip-space), I could see using a separate color attachment to write this, but you're writing the perspective-correct depth-range adjusted depth (`gl_FragDepth`) currently.

In any case, when the sun is directly overhead and you are using orthographic projection it is to be expected that no shadows are cast. This goes back to the property I explained earlier where parallel lines remain parallel. Since the distance an object is from the sun has no affect on where the object is projected (orthographically), if it is directly overhead you will not see any shadows. Try tracking the sun's position along a sphere instead of a circle to minimize this.

• From what I've seen (and since this is a sun-like light) the ortho perspective would fit more of what I want. I do understand that 3D perspective would be better for positioned lights. – Chris Sep 1 '13 at 3:33
• @Chris: Definitely, I am not saying that orthographic projection is inappropriate. Just that you will probably have to implement both types of shadow maps in the future. Point lights and positional spotlights should use perspective. Also, to fix the issue at noon I would suggest that your sun move across the sky in a spherical motion (e.g. x, y and z position would all be a function of time instead of just two of the three as you described in the question) – Andon M. Coleman Sep 1 '13 at 3:42
• The glFragCoord.z vs. pass_Position is something I've been switching between, because I lacked the understanding of the difference, but you've cleared that up for me. Finally, the explanation of overhead is spot on and is at least part of what I've been missing. The issue really starts earlier than that, though. It's like the shadow map "falls off" the buffer. I'll post some images to see if I can explain it better that way. – Chris Sep 1 '13 at 3:42
• I think I really need to revisit this more. The shadow coordinates aren't working like it was in projection. I see odd shadows in wrong places and then only until it gets to the origin. Negative x is fully lit. I will say that moving the light closer to the origin when doing the "lookAt" seemed to help this a lot. Although I'm not sure I can say why... I have a long way to go to start understanding these shadows, but I do appreciate the help. – Chris Sep 1 '13 at 4:52