I'm reading Concepts of Programming Languages (Sebesta 10th edition) and within the text it defines Orthogonality as meaning "that a relatively small set of primitive constructs can be combined in a relatively small number of ways to build the control and data structures of the language". But I'm confused as to what makes a certain language feature orthogonal. Because I probably won't explain the text in all its glory :), I've included below the appropriate text.
We can illustrate the use of orthogonality as a design concept by comparing one aspect of the assembly languages of the IBM mainframe computers and the VAX series of minicomputers. We consider a single simple situation: adding two 32-bit integer values that reside in either memory or registers and replacing one of the two values with the sum. The IBM mainframes have two instructions for this purpose, which have the forms A Reg1, memory_cell AR Reg1, Reg2 where Reg1 and Reg2 represent registers. The semantics of these are: Reg1 ← contents(Reg1) + contents(memory_cell) Reg1 ← contents(Reg1) + contents(Reg2) The VAX addition instruction for 32-bit integer values is ADDL operand_1, operand_2 whose semantics is operand_2 ← contents(operand_1) + contents(operand_2) In this case, either operand can be a register or a memory cell. The VAX instruction design is orthogonal in that a single instruction can use either registers or memory cells as the operands. There are two ways to specify operands, which can be combined in all possible ways. The IBM design is not orthogonal. Only two out of four operand combinations possibilities are legal, and the two require different instructions, A and AR.>
So my main question is why is it that the VAX instruction is orthogonal. Is it just because it's construct takes less instructions and everything can be completed in a single line? What if the VAX series computers took two instructions and the IBM took three, would the VAX language be more orthogonal? Any help would be appreciated.