This thread is long-dead, I realize. But I post this answer in hopes that it will be useful for someone in the future. If you can extend the equations into the right SVG markup, then we've done it. I developed this particular solution for cocoa, but the math is entirely relevant.

The approach involves a little matrix math to find the triangle's gradient vector, which gives the (x,y) direction of steepest ascent with respect to z -- this is the direction of the color-gradient. The start/end points of the color-gradient are determined by the intersection of the gradient vector slope (constrained through the x,y origin) with the iso-lines on the triangle's plane describing zmin and zmax.

To begin, the plane intersecting three points `{p1, p2, p3}`

of a triangle can be described by the equation:

```
A1(x) + A2(y) + A3(z) - A = 0
```

where A is the determinant:

```
|p1x p1y p1z|
A = |p2x p2y p2z|
|p3x p3y p3z|
```

and `Ai`

is the same determinant, but replace column `i`

with the column vector:

```
1 |p1x 1 p1z|
column(i) = 1 e.g., A2 = |p2x 1 p2z|
1 |p3x 1 p3z|
```

The gradient vector `grad(z)`

describes the direction of steepest ascent, which is also the trajectory of the color-gradient:

```
grad(z) = [-A1/A3 (i), -A2/A3 (j)]
```

so in the x,y plane, this gradient vector lies along a line:

```
y = x * A2/A1 + b,
```

where b can be anything, but let's set `b = 0`

. this constrains the color-gradient trajectory to a line intersecting the origin:

```
y = x * A2/A1 [eqn 1]
```

This line describes the color-gradient direction. The start and end points will be determined by the intersection of this line with the zmax and zmin iso-lines.

now, for any defined values `zmax`

and `zmin`

, we can describe parallel lines on the plane defined by our triangle thus:

```
A1(x) + A2(y) + A3(zmax) - A = 0 [eqn 2]
and
A1(x) + A2(y) + A3(zmin) - A = 0 [eqn 3]
```

Using equations 1-3 from above, we can solve for `G1`

and `G2`

, the color-gradient start and end points, respectively.

```
G1 = (xmin,ymin)
G2 = (xmax,ymax)
```

where

```
xmin = (A - A3*zmin) / (A1 + A2^2 / A1)
ymin = xmin * A2/A1
xmax = (A - A3*zmax) / (A1 + A2^2 / A1)
ymax = xmax * A2/A1
```

Notice the special case where `A1 = 0`

, corresponding to a perfectly vertical color-gradient path. In this case:

```
for A1 == 0:
G1 = (0,ymin)
G2 = (0,ymax),
where
ymin = (A - A3*zmin) / A2
ymax = (A - A3*zmax) / A2
```

The only other special case is when `p1z = p2z = p3z`

. This would try to stretch the gradient path to be infinitely long. In this special case, the triangle should just be colored solidly, rather than going through all the math.

All that's left is to set the triangle as a clipping region and draw the gradient from `G1`

to `G2`

. I'm including a diagram of the problem domain with associated linear equations. Notice also that the color-gradient varies linearly along each triangle edge, so the OP's question about delaunay triangulation is right on target. I developed this approach for just that reason - to color the faces of a triangulated mesh. The image below shows a case where `zmax == p3z > p1z > p2z > zmin`

.