tl;dr - You shouldn't care for ARM CPUs. This is a micro optimization.
Let the compiler place registers by making functions static.
All CPUs are limited in registers. ARM is mainly a RISC architecture and one fact that guided its development was implementing compiled code. You may pass as many arguments as you like. The only trade off is efficiency.
It is always good to group related parameters together in a structure. Especially, if the parameters pass-through a function to a sub-function. On the ARM, the first four parameters are slightly more optimal if placed first. Consider the following example,
int bar(int a, int b) { return a+b; }
int baz(int a, int b, int c) { return a+bar(b,c); }
int foo(int a, int b, int c, int d, int e, int f) { return a+b+baz(d,e,f); }
The calculations are non-sensical. It is only meant to provide a reference for different types of functions. bar
is a leaf function, baz
is an intermediate and foo
is a top level or higher level function. It makes a lot of sense to package the 'e' and 'f' parameters to foo
in a structure and to pass a pointer to the structure around. In fact, this is perhaps a hallmark of Object-oriented design. The structure will pass through baz
to be used by bar
. When the ARM call list exceeds four, passing a structure is much the same as putting things on the stack. The same addressing modes are available via the pointer. Also, by grouping the variables together you get cache and memory pipeline optimizations.
If a function will use an argument, then passing it in the first four parameters is beneficial. If a function does not use an argument, it can actually be beneficial to pass them later on. So, if you have the latitude to choice, it is better to put frequently used parameters first.
Another issue is that it beneficial to keep arguments the same between calls. Here is another example of the above where the foo()
caller reverses the order.
int bar(int a, int b) { return a+b; }
int baz(int a, int b, int c) { return c+bar(a,b); }
int foo(int a, int b, int c, int d, int e, int f) { return e+f+baz(a,b,c); }
Here is a third example with the data packaging,
struct bar_data {int a; int b;};
int bar(struct bar_data *p) { return p->a+p->b; }
int baz(struct bar_data *p, int a) { return a+bar(p); }
int foo(struct bar_data *p, int a, int b, int c) { return b+c+baz(p,a); }
I choose the -O1
option as compilers will not be able to inline if the functions are in separate source files. They will probably all be the same at a higher level as the compiler will re-order the arguments as it best sees fit.
So, you can see that this really only matters for extern functions; follow the links and add the -O3
option.
That said, clear understandable code is always beneficial. No one should prematurely optimize. Frankly, I wouldn't worry about it. The ARM is generally designed to be quite efficient at handling compiled code. Most compiler are quite good at re-ordering and analyzing code. You are better off writing Object Oriented static functions and doing higher level design for a great many reasons. It will also naturally result in better code.
See the Arm Procedure calling standard for the register use; all extern
functions should follow these rules on the ARM. Depending on the machine, some floating point arguments may also be passed in registers. So four is not a hard and fast rule; even if performance is your ultimate goal.