Because then a
POP uses the same addressing mode that is commonly used to scan through strings and arrays
An instruction that pops a value off of a stack needs to do two things: read the value out of memory, and adjust the stack pointer. There are four possible design choices for this operation:
Preincrement the stack pointer first, then read the value. This implies that the stack will grow "downwards" (towards lower memory addresses).
Predecrement the stack pointer first, then read the value. This implies that the stack will grow "upwards" (towards higher memory addresses).
Read the value first, then postincrement the stack pointer. This implies that the stack will grow downwards.
Read the value first, then postdecrement the stack pointer. This implies that the stack will grow upwards.
In many computer languages (particularly C), strings and arrays are passed to functions as pointers to their first element. A very common operation is to read the elements of the string or array in order, starting with the first element. Such an operation needs only the postincrement addressing mode described above.
Furthermore, reading the elements of a string or array is more common than writing the elements. Indeed, there are many standard library functions that perform no writing at all (e.g.
Therefore, if you have a limited number of addressing modes in your instruction set design, the most useful addressing mode would be a read that postincrements. This results in not only the most useful string and array operations, but also a
POP instruction that grows the stack downward.
The second-most-useful addressing mode would then be a post-decrement write, which can be used for the matching
Indeed, the PDP-11 had postincrement and predecrement addressing modes, which produced a downward-growing stack. Even the VAX did not have preincrement or postdecrement.