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 can parametrize all the points inside the triangle by the linear combinations of the vertices:

```
P(b0,b1,b2) = P0*b0 + P1*b1 + P2*b2
```

where b0 + b1 + b2 = 1 and b0 ≥ 0, b1 ≥ 0, b2 ≥ 0.

Given a point P inside the triangle, the coefficients (b0, b1, b2) that satisfy the equation above are called the *barycentric coordinates* of that point. For non-degenerate triangles they are unique, and can be calculated as quotients of the areas of the following triangles:

```
b0(P) = area(P, P1, P2) / area(P0, P1, P2)
b1(P) = area(P0, P, P2) / area(P0, P1, P2)
b2(P) = area(P0, P1, P) / area(P0, P1, P2)
```

Each bi can be thought of 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.

Given an attribute (f0, f1, f2) on the vertices of the triangle, we can now interpolate it over the interior:

```
f(P) = f0*b0(P) + f1*b1(P) + f2*b2(P)
```

This is a linear function of P, therefore it is the unique linear interpolant over the given triangle. The math also works in either 2D or 3D.

# 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] = lround(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 = lround(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 = calloc(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);
stbi_write_png("out.png", buffer.w, buffer.h, 4, buffer.data, buffer.ys);
}
```

# 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):