The output of a vertex shader is a *four* component vector, `vec4 gl_Position`

. From Section 13.6 Coordinate Transformations of core GL 4.4 spec:

*Clip coordinates* for a vertex result from shader execution, which yields a vertex coordinate `gl_Position`

.

Perspective division on clip coordinates yields *normalized device coordinates*, followed by a *viewport* transformation (see section 13.6.1) to convert these coordinates into *window coordinates*.

OpenGL does the perspective divide as

```
device.xyz = gl_Position.xyz / gl_Position.w
```

But then keeps the `1 / gl_Position.w`

as the last component of `gl_FragCoord`

:

```
gl_FragCoord.xyz = device.xyz scaled to viewport
gl_FragCoord.w = 1 / gl_Position.w
```

This transform is bijective, so no depth information is lost. In fact as we see below, the `1 / gl_Position.w`

is crucial for perspective correct interpolation.

# Short introduction to barycentric coordinates

Given a triangle (P0, P1, P2) one way to parametrize the points inside the triangle is by choosing one vertex (here P0) and expressing each other point as:

```
P(u,v) = P0 + (P1 - P0)u + (P2 - P0)v
```

where u >= 0, v >= 0 and u + v <= 1. Given an attribute (f0, f1, f2) on the vertices of the triangle, we can use u, v to interpolate it over the triangle

```
f(u,v) = f0 + (f1 - f0)u + (f2 - f0)v
```

All math can be done using the above parametrization, and in fact is sometimes preferable due to faster calculations. However it is less convenient and has numerical issues (e.g. P(1,0) might not equal P1).

Instead *barycentric coordinates* are usually used. Every point inside the triangle is a weighted sum of the the vertices:

```
P(b0,b1,b2) = P0*b0 + P1*b1 + P2*b2
f(b0,b1,b2) = f0*b0 + f1*b1 + f2*b2
```

where b0 + b1 + b2 = 1, b0 >= 0, b1 >= 0, b2 >= 0 are the barycentric coordinates of the point in the triangle. Each bi can be thought as 'how much of Pi has to be mixed in'. So b = (1,0,0), (0,1,0) and (0,0,1) are the vertices of the triangle, (1/3, 1/3, 1/3) is the barycenter, and so on.

# Perspective correct interpolation

So let's say we fill a projected 2D triangle on the screen. For every fragment we have its window coordinates. First we calculate its barycentric coordinates by inverting the `P(b0,b1,b2)`

function, which is a linear function in window coordinates. This gives us the barycentric coordinates of the fragment on the **2D triangle projection**.

Perspective correct interpolation of an attribute would vary linearly in the *clip coordinates* (and by extension, world coordinates). For that we need to get the barycentric coordinates of the fragment in clip space.

As it happens (see [1] and [2]), the depth of the fragment is not linear in window coordinates, but the *depth inverse* (`1/gl_Position.w`

) is. Accordingly the attributes and the clip-space barycentric coordinates, when weighted by the depth inverse, vary linearly in window coordinates.

Therefore, we compute the perspective corrected barycentric by:

```
( b0 / gl_Position[0].w, b1 / gl_Position[1].w, b2 / gl_Position[2].w )
B = -------------------------------------------------------------------------
b0 / gl_Position[0].w + b1 / gl_Position[1].w + b2 / gl_Position[2].w
```

and then use it to interpolate the attributes from the vertices.

**Note:** GL_NV_fragment_shader_barycentric exposes the device-linear barycentric coordinates through `gl_BaryCoordNoPerspNV`

and the perspective corrected through `gl_BaryCoordNV`

.

# Implementation

Here is a C++ code that rasterizes and shades a triangle on the CPU, in a manner similar to OpenGL. I encourage you to compare it with the shaders listed below:

```
struct Renderbuffer {
int w, h, ys;
void *data;
};
struct Vert {
vec4f position;
vec4f texcoord;
vec4f color;
};
struct Varying {
vec4f texcoord;
vec4f color;
};
void vertex_shader(const Vert &in, vec4f &gl_Position, Varying &out)
{
out.texcoord = in.texcoord;
out.color = in.color;
gl_Position = { in.position[0], in.position[1], -2*in.position[2] - 2*in.position[3], -in.position[2] };
}
void fragment_shader(vec4f &gl_FragCoord, const Varying &in, vec4f &out)
{
out = in.color;
vec2f wrapped = vec2f(in.texcoord - floor(in.texcoord));
bool brighter = (wrapped[0] < 0.5) != (wrapped[1] < 0.5);
if(!brighter)
(vec3f&)out = 0.5f*(vec3f&)out;
}
void store_color(Renderbuffer &buf, int x, int y, const vec4f &c)
{
// can do alpha composition here
uint8_t *p = (uint8_t*)buf.data + buf.ys*(buf.h - y - 1) + 4*x;
p[0] = linear_to_srgb8(c[0]);
p[1] = linear_to_srgb8(c[1]);
p[2] = linear_to_srgb8(c[2]);
p[3] = lrint(c[3]*255);
}
void draw_triangle(Renderbuffer &color_attachment, const box2f &viewport, const Vert *verts)
{
Varying perVertex[3];
vec4f gl_Position[3];
box2f aabbf = { viewport.hi, viewport.lo };
for(int i = 0; i < 3; ++i)
{
// invoke the vertex shader
vertex_shader(verts[i], gl_Position[i], perVertex[i]);
// convert to device coordinates by perspective division
gl_Position[i][3] = 1/gl_Position[i][3];
gl_Position[i][0] *= gl_Position[i][3];
gl_Position[i][1] *= gl_Position[i][3];
gl_Position[i][2] *= gl_Position[i][3];
// convert to window coordinates
auto &pos2 = (vec2f&)gl_Position[i];
pos2 = mix(viewport.lo, viewport.hi, 0.5f*(pos2 + vec2f(1)));
aabbf = join(aabbf, (const vec2f&)gl_Position[i]);
}
// precompute the affine transform from fragment coordinates to barycentric coordinates
const float denom = 1/((gl_Position[0][0] - gl_Position[2][0])*(gl_Position[1][1] - gl_Position[0][1]) - (gl_Position[0][0] - gl_Position[1][0])*(gl_Position[2][1] - gl_Position[0][1]));
const vec3f barycentric_d0 = denom*vec3f( gl_Position[1][1] - gl_Position[2][1], gl_Position[2][1] - gl_Position[0][1], gl_Position[0][1] - gl_Position[1][1] );
const vec3f barycentric_d1 = denom*vec3f( gl_Position[2][0] - gl_Position[1][0], gl_Position[0][0] - gl_Position[2][0], gl_Position[1][0] - gl_Position[0][0] );
const vec3f barycentric_0 = denom*vec3f(
gl_Position[1][0]*gl_Position[2][1] - gl_Position[2][0]*gl_Position[1][1],
gl_Position[2][0]*gl_Position[0][1] - gl_Position[0][0]*gl_Position[2][1],
gl_Position[0][0]*gl_Position[1][1] - gl_Position[1][0]*gl_Position[0][1]
);
// loop over all pixels in the rectangle bounding the triangle
const box2i aabb = lrint(aabbf);
for(int y = aabb.lo[1]; y < aabb.hi[1]; ++y)
for(int x = aabb.lo[0]; x < aabb.hi[0]; ++x)
{
vec4f gl_FragCoord;
gl_FragCoord[0] = x + 0.5;
gl_FragCoord[1] = y + 0.5;
// fragment barycentric coordinates in window coordinates
const vec3f barycentric = gl_FragCoord[0]*barycentric_d0 + gl_FragCoord[1]*barycentric_d1 + barycentric_0;
// discard fragment outside the triangle. this doesn't handle edges correctly.
if(barycentric[0] < 0 || barycentric[1] < 0 || barycentric[2] < 0)
continue;
// interpolate inverse depth linearly
gl_FragCoord[2] = dot(barycentric, vec3f(gl_Position[0][2], gl_Position[1][2], gl_Position[2][2]));
gl_FragCoord[3] = dot(barycentric, vec3f(gl_Position[0][3], gl_Position[1][3], gl_Position[2][3]));
// clip fragments to the near/far planes (as if by GL_ZERO_TO_ONE)
if(gl_FragCoord[2] < 0 || gl_FragCoord[2] > 1)
continue;
// convert to perspective correct (clip-space) barycentric
const vec3f perspective = 1/gl_FragCoord[3]*barycentric*vec3f(gl_Position[0][3], gl_Position[1][3], gl_Position[2][3]);
// interpolate the attributes using the perspective correct barycentric
Varying varying;
for(int i = 0; i < sizeof(Varying)/sizeof(float); ++i)
((float*)&varying)[i] = dot(perspective, vec3f(
((const float*)&perVertex[0])[i],
((const float*)&perVertex[1])[i],
((const float*)&perVertex[2])[i]
));
// invoke the fragment shader and store the result
vec4f color;
fragment_shader(gl_FragCoord, varying, color);
store_color(color_attachment, x, y, color);
}
}
int main()
{
Renderbuffer buffer = { 512, 512, 512*4 };
buffer.data = malloc(buffer.ys * buffer.h);
memset(buffer.data, 0, buffer.ys * buffer.h);
// interleaved attributes buffer
Vert verts[] = {
{ { -1, -1, -2, 1 }, { 0, 0, 0, 1 }, { 0, 0, 1, 1 } },
{ { 1, -1, -1, 1 }, { 10, 0, 0, 1 }, { 1, 0, 0, 1 } },
{ { 0, 1, -1, 1 }, { 0, 10, 0, 1 }, { 0, 1, 0, 1 } },
};
box2f viewport = { 0, 0, buffer.w, buffer.h };
draw_triangle(buffer, viewport, verts);
lodepng_encode32_file("out.png", (unsigned char*)buffer.data, buffer.w, buffer.h);
}
```

# OpenGL shaders

Here are the OpenGL shaders used to generate the reference image.

**Vertex shader:**

```
#version 450 core
layout(location = 0) in vec4 position;
layout(location = 1) in vec4 texcoord;
layout(location = 2) in vec4 color;
out gl_PerVertex {
vec4 gl_Position;
};
layout(location = 0) out PerVertex {
vec4 texcoord;
vec4 color;
} OUT;
void main() {
OUT.texcoord = texcoord;
OUT.color = color;
gl_Position = vec4(position[0], position[1], -2*position[2] - 2*position[3], -position[2]);
}
```

**Fragment shader:**

```
#version 450 core
layout(location = 0) in PerVertex {
vec4 texcoord;
vec4 color;
} IN;
layout(location = 0) out vec4 OUT;
void main() {
OUT = IN.color;
vec2 wrapped = fract(IN.texcoord.xy);
bool brighter = (wrapped[0] < 0.5) != (wrapped[1] < 0.5);
if(!brighter)
OUT.rgb *= 0.5;
}
```

# Results

Here are the almost identical images generated by the C++ (left) and OpenGL (right) code:

The differences are caused by different precision and rounding modes.

For comparison, here is one that is not perspective correct (uses `barycentric`

instead of `perspective`

for the interpolation in the code above):