Well, let's first think about Turing machines.

A Turing machine consists of an unbounded tape which contains symbols, a head and a small control unit which is a *finite* state automata that controls how the machine reads, moves and modifies the symbols on the tape.

**Fact:** there exist universal Turing machines, i.e. machines that read from the tape the description of an other Turing machine and execute it on some given input. In other words: even with just a finite number of states in the control unit such machines can simulate *every* possible other Turing machine.

Reading the description of a Turing machine is the same as reading a software program stored in memory.

In this sense **if** you count as the number of states of the hardware the number of states in the control unit, and if software is the description of a Turing machine written on the tape, then *yes* a finite hardware can simulate infinite softwares, yet the softwares surely contains Turing machines with more states than the one simulating it.

If you however consider as state the whole *state of the computation*, i.e. including the state of the tape, then you are right: every simulation corresponds to specific possible states in this sense and there are many states that are not valid, or are unreachable.

In the same way modern computers consists of a set of hardware that implements this control unit, and then memory which is our tape. If you do *not* consider the state of the memory as part of the state of the hardware, the same applies: a finite computer, given enough memory, could execute every possible program on every possible input, yet its controlling parts are only finite.

This said I wouldn't take such assertions too literally or too seriously...
The point is simply: software systems's number of states grows extremely rapidly.