The built-in XNA FBX/model content importer and processor handle "faces" the same way that just about every modeling program out there does - as lists of vertices and indices. (As a side note, your GPU also natively supports this scheme, and modern games rely upon it for performance reasons.)

For instance, consider a simple, two-triangle quad. The vertices might be:

```
v0 (0,0,0)
v1 (1,0,0)
v2 (1,1,0)
v3 (0,1,0)
```

or,

```
v0--v1
| / |
| / |
v3--v2
```

To represent this in "face" form, you'd need a list of data equivalent to

triangle 1 (upper-left): (0,0,0),(1,0,0),(0,1,0) = (v0,v1,v3)

triangle 2 (lower-right): (1,0,0),(1,1,0),(0,1,0) = (v1,v2,v3)

which requires six vertex records.

Using XNA-native structures, a Vector3 has three elements, each of which are single-precision floats (4 bytes), so that's 3*4=12 bytes each, and you need six of them, so that 72 bytes.

Or, you can use indexing. In addition to the four vertices, you store a list of indices:

```
f1: 0,1,3
f2: 1,2,3
```

Indices can be stored using shorts (16-bit integers). So, let's examine the difference:

No indices: two faces * 3 vertices*3 components (xyz) * 4 bytes each = 2*3*3*4=72 bytes.

Indexed:

vertices: 4 vertices * 3 components each * 4 bytes per component = 48 bytes,

indices (3 shorts per triangle): 6 indices * 2 bytes each = 12 bytes.

48 + 12 = 60, which is slightly less than 72 bytes for the non-indexed model.

That 12 bytes might not seem like a lot until you consider an entire level with 100,000+ triangles. At that point, you're looking at a 1.2MB difference. Although your graphics card may about 2+GB of memory, moving that data back and forth between host RAM and GPU RAM is expensive.

So, how do you get that data?

Look at `Model.Meshes[].MeshParts[].VertexBuffer.GetData()`

and `Model.Meshes[].MeshParts[].IndexBuffer.GetData()`

. You can use those methods to extract the vertices and indexes, then cross-reference the two to get the triangle list.

*You can't just directly access the elements of *`VertexBuffer`

and `IndexBuffer`

because they are stored in the GPU's RAM - allowing random element access would drag performance to near-negative velocity.

Also, have a look at the `GraphicsDevice.DrawIndexedPrimitives()`

method.

I can post some example code later if necessary.