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I've got a small problem with left recursion in this grammar. I'm trying to write it in Prolog, but I don't know how to remove left recursion.

<expression> -> <simple_expression>
<simple_expression> -> <simple_expression> <binary_operator> <simple_expression>
<simple_expression> -> <function>
<function> -> <function> <atom>
<function> -> <atom>
<atom> -> <number> | <variable>

<binary_operator> -> + | - | * | /

expression(Expr) --> simple_expression(SExpr), { Expr = SExpr }.
simple_expression(SExpr) --> simple_expression(SExpr1), binary_operator(Op), simple_expression(SExpr2), { SExpr =.. [Op, SExpr1, SExpr2] }.
simple_expression(SExpr) --> function(Func), { SExpr = Func }.
function(Func) --> function(Func2), atom(At), { Func = [Func2, atom(At)] }.
function(Func) --> atom(At), { Func = At }.

I've written something like that, but it won't work at all. How to change it to get this program working?

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3 Answers

The problem with your program is indeed left recursion; it should be removed otherwise you'll get stuck in an infinite loop

To remove immediate left recursion you replace each rule of the form

A->A a1|A a2|....|b1|b2|....


A -> b1 A'|b2 A'|....
A' -> ε | a1 A'| a2 A'|....

so function would be

function -> atom, functionR.
funtionR -> [].

wiki page

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The problem only arises since you are using backward chaining. In forward chaining it is possible to deal with left recursive grammar rules directly. Provided the grammar rules of the form:

NT &&--> NT

Don't form a cycle. You can also use auxiliary computations, i.e. the {}/1, if you place them after the non-terminals of the body and if the non-terminals in the head don't have parameters exclusively going into the auxiliary computations.

Here is an example left recursive grammar that works perfectly this way in forward chaining:

:- forward expr/3.
:- forward term/3.
:- forward factor/3.

expr(C) &&--> expr(A), [+], term(B), {C is A+B}.
expr(C) &&--> expr(A), [-], term(B), {C is A-B}.
expr(A) &&--> term(A).

term(C) &&--> term(A), [*], factor(B), {C is A*B}.
term(C) &&--> term(A), [/], factor(B), {C is A/B}.
term(A) &&--> factor(A).

factor(A) &&--> [A], {integer(A)}.

Your forward chainer needs to be able to also directly deal with DCG. Here we assume that forward DCGs uses 'D'/3 for terminals. In the following an example session is shown:

% Parse and evaluate [1,+,2,*,3]
?- post('D'(1,0,1)), post('D'(+,1,2)),
   post('D'(2,2,3)), post('D'(*,3,4)),
   post('D'(3,4,5)), expr(X,0,5).
X = 7

The post/1 predicate here posts an event and keeps the propagator of the forward chainer running. How to write your forward rules depends on the Prolog systems respective library you are using.

Edit 12.02.2014:
I have replaced -->/2 by &&-->/2 and postulate/1 by post/1 so
that it matches the definitions of Jekejeke Minlog:

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The answer from @thanosQR is fairly good, but applies to a more general context than DCG, and requires a change in the Parse Tree. Effectively, the 'outcome' of parsing has been removed, that's not good.

If you are interested just in parsing expressions, I posted here something useful.

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