Note: this is a more detailed version of Recursive Descent precedence parsing missing prefix expression
I'm building a simple language parser, and having an issue with lower precedence prefix expressions. Here's an example grammar:
E = E8 E8 = E7 'OR' E8 | E7 E7 = E6 'XOR' E7 | E6 E6 = E5 'AND' E6 | E5 E5 = 'NOT' E5 | E4 E4 = E3 '==' E4 | E3 '!=' E4 | E3 E3 = E2 '<' E3 | E2 '>' E3 | E2 E2 = E1 '+' E2 | E1 '-' E2 | E1 '*' E2 | E1 '+' E2 | E1 E1 = '(' E ')' | 'true' | 'false' | '0'..'9'
However, this grammar doesn't work correctly for the NOT, if it's used as the RHS of a higher precedence infix operator, i.e.:
true == NOT false
This is due to the == operator requiring
E3 on the RHS, which cannot be a 'NOT' operation.
I'm unsure the correct way to express this grammar? Is it still possible using this simplistic recursive descent approach, or will I need to move to a more featured algorithm (shunting yard or precedence climbing).
Here are some examples that would need to parse correctly:
true == 1 < 2, output
==(true, <(1, 2))
1 < 2 == true, output
==(<(1, 2), true)
NOT true == false, output
true == NOT false, output
==(true, NOT(false))** doesn't work
true < NOT false, output
<(true, NOT(false))** doesn't work
I have attempted to alter the levels
E2 to use
E5 on the RHS of the infix expression, as suggested in Recursive Descent precedence parsing missing prefix expression (i.e.
E3 '==' E5,
E3 '<' E5, etc). However this breaks the precedence between these levels, i.e.
true == 1 < 2 would be incorrectly
parsed as<(==(true, 1), 2)`.