Let's say there is a grid terrain for a game composed of tiles made of two triangles - made from four vertices. How would we find the Y (up) position of a point between the four vertices?

I have tried this:

```
float diffZ1 = lerp(heights[0], heights[2], zOffset);
float diffZ2 = lerp(heights[1], heights[3], zOffset);
float yPosition = lerp(diffZ1, diffZ2, xOffset);
```

Where z/yOffset is the z/y offset from the first vertex of the tile in percent / 100. This works for flat surfaces but not so well on bumpy terrain.

I expect this has something to do with the terrain being made from triangles where the above may work on flat planes. I'm not sure, but does anybody know what's going wrong?

This may better explain what's going on here:

In the code above "heights[]" is an array of the Y coordinate of surrounding vertices v0-3. Triangle 1 is made of vertex 0, 2 and 1. Triangle 2 is made of vertex 1, 2 and 3.

I wish to find coordinate Y of p1 when its x,y coordinates lay between v0-3.

So I have tried determining which triangle the point is between through this function:

```
bool PointInTriangle(float3 pt, float3 pa, float3 pb, float3 pc)
{
// Compute vectors
float2 v0 = pc.xz - pa.xz;
float2 v1 = pb.xz - pa.xz;
float2 v2 = pt.xz - pa.xz;
// Compute dot products
float dot00 = dot(v0, v0);
float dot01 = dot(v0, v1);
float dot02 = dot(v0, v2);
float dot11 = dot(v1, v1);
float dot12 = dot(v1, v2);
// Compute barycentric coordinates
float invDenom = 1.0f / (dot00 * dot11 - dot01 * dot01);
float u = (dot11 * dot02 - dot01 * dot12) * invDenom;
float v = (dot00 * dot12 - dot01 * dot02) * invDenom;
// Check if point is in triangle
return (u >= 0.0f) && (v >= 0.0f) && (u + v <= 1.0f);
}
```

This isn't giving me the results I expected

I am then trying to find the y coordinate of point p1 inside each triangle:

```
// Position of point p1
float3 pos = input[0].PosI;
// Calculate point and normal for triangles
float3 p1 = tile[0];
float3 n1 = (tile[2] - p1) * (tile[1] - p1); // <-- Error, cross needed
// = cross(tile[2] - p1, tile[1] - p1);
float3 p2 = tile[3];
float3 n2 = (tile[2] - p2) * (tile[1] - p2); // <-- Error
// = cross(tile[2] - p2, tile[1] - p2);
float newY = 0.0f;
// Determine triangle & get y coordinate inside correct triangle
if(PointInTriangle(pos, tile[0], tile[1], tile[2]))
{
newY = p1.y - ((pos.x - p1.x) * n1.x + (pos.z - p1.z) * n1.z) / n1.y;
}
else if(PointInTriangle(input[0].PosI, tile[3], tile[2], tile[1]))
{
newY = p2.y - ((pos.x - p2.x) * n2.x + (pos.z - p2.z) * n2.z) / n2.y;
}
```

Using the following to find the correct triangle:

```
if((1.0f - xOffset) <= zOffset)
inTri1 = true;
```

And correcting the code above to use the correct cross function seems to have solved the problem.

`xOffset`

. In particular, how do you make two triangles from only four vertices? Are two of the vertices shared between the two triangles? – aecolley Aug 31 at 22:31