I think a graph-based approach may work.

First, the list of triangular faces can be recovered by noting that the set of edges define an undirected graph `G1(V1,E1)`

for connectivity between the geometric vertices. A triangular face is any length 3 cycle in this graph.

```
for (i = all vertices in G1)
// form list of vertex triplets
list = find all length 3 cycles from ith vertex
// push new faces onto output
for (j = all triplets in list)
[v1,v2,v3] = list(j)
if ([v1,v2,v3] is not an existing face)
push triplet [v1,v2,v3] as a new face
endif
endfor
endfor
```

Next, the tetrahedra can be recovered by forming the undirected graph `G2(V2,E2)`

defining the connectivity between faces (i.e. faces are connected if they share an edge). A tetrahedra is any length 4 cycle in this graph.

```
for (i = all vertices in G2)
// form a list of face tuples
list = find all length 4 cycles from ith vertex
// push new tetrahedra onto output
for (j = all tuples in list)
[f1,f2,f3] = list(j)
[v1,v2,v3,v4] = unique vertices in faces [f1,f2,f3]
if ([v1,v2,v3,v4] is not an existing tetrahedra)
push tuple [v1,v2,v3,v4] as a new tetrahedra
endif
endif
endfor
```

Hope this helps.