I am trying to create a very simple 3D modelling application in C++. During the course of this, I have decided to implement a class for halfedge data structure solid boundary representations.

A book I am reading (Introduction to Computational Geometry) goes into detail regarding the Euler's Polyhedron Formula written as V-E+F=2 and how it is true for all topologically valid convex polyhedra (ignoring for a moment stuff like facial holes and genus).

For the purpose of maintaining the truth of this formula, the book describes how solids can be generated using Euler Operators. For example, I might begin generating a new solid using **mvfs**, meaning "make vertex face solid", which creates a new solid with a vertex and a face such that V-E+F=1-0+1=2. Every other operation if it adds to V or F adds also to E or if it takes from V or F also takes from E etc. so that this formula is always true. As the wikipedia page says: "Euler operators modify the mesh's graph creating or removing faces, edges and vertices according to simple rules while preserving the overall topology thus maintaining a valid boundary (i.e. not introducing holes)."

My question is twofold.

First of all, how can I possibly say that the Euler Formula being true for my particular halfedge data structure implies I have a valid boundary, when I can have stuff like dangling faces without any edges or adjacent vertices (remember mvfs creates a single vertex and a single face). A mesh with a single vertex and a single face does not sound to me like a valid boundary.

Even is true that solids such as those with a single vertex and a single boundary are sensible and valid boundaries, what is the point of going through such effort to maintain the truth of the Euler formula? What if I want it to be possible to create a halfedge data structure mesh with a hole it in? The point of the HEDS representation seems to be that it is easily manipulated (which is perfect for my small modeler) but I seem to be deterred from allowing the user to delete a face for example on the basis that maintaining a valid topology is so important these somewhat awkward Euler Operators exist. Operators which require always creating or deleting two of a vector/edge/face at a time instead of just creating or deleting them one at a time independently.