I know that shunting yard algorithm is a nice one when parsing simple infix expressions. I was able to figure out how to extend this algorithm for prefix and postfix operators too and also able to parse simple functions.
2+3*a(3,5)+b(3,5) turns into
2 3 <G> 3 5 a () * + <G> 3 5 b () +
<G> is a guard token that is pushed on the stack it will store the return address etc.
() is the call command that calls the function on the top of the stack that pops out the necessary amount of arguments and pushes back the result on return.)
If the function name is just one token I can simply mark it as function symbol if directly followed by a parenthesis. During the process if I encounter a function symbol I push it on the operator stack and pop it out when I finished converting the parameters.
This is working so far.
But if I add the option to have member functions, the
. operator. The things get more tricky. For example I want to convert the
a.b.c(12)+d.e.f(34) I can't mark c and f to be functions because
d.e.f are functions. If I start my parser on an expression like this the result will be
a b . <G> 12 c () . d e . <G> 34 f () . Which is obviously wrong. I want it to be
<G> 12 a b . c . () <G> 34 d e . f. () Which appears correct.
But of curse I can make the things more complicated if I add some parentheses:
(a.b.c)(). Or I make a function that returns a function which I call again:
Is there an easy way handle these tricky situations?