# Yacc - Equation Parser with function support

i'm trying to write an equation parser for equations like: `4*sin(1+cos(10/2))` I use `lex` to get the tokens and `yacc` as the parser module.

My actual problem now is that i dont know how to define the grammar for functions. A function is usually constructed like this `FunctionName( Expression)` so for the parser grammar it would be `function : FUNCTION LPAREN expression RPAREN` (i hope).

But how im going to treat functions that are build like that `sin(3+cos(0)*10)`. This woulde a function within a function, not forgetting to care about `3+` and `*10`. Hope i've pointed out my problem good enough.

Here's my code:

``````import ply.lex as lex
import ply.yacc as yacc
import math

tokens = (
'DIV',
'TIMES',
'MINUS',
'PLUS',
'FUNCTION',
'NUMBER',
'LPAREN',
'RPAREN',
)

t_PLUS = r'\+'
t_MINUS = r'-'
t_TIMES = r'\*'
t_DIV = r'/'
t_LPAREN = r'\('
t_RPAREN = r'\)'

t_ignore = ' '

def t_NUMBER(t):
r'([0-9]*\.[0-9]+|[0-9]+)'
t.value = float(t.value)
return t

def t_FUNCTION(t):
r'sin|cos|tan'
return t

def t_error(t):
print("Illegal character '%s'" % t.value[0])
t.lexer.skip(1)

# Parser
'''
Here i need some help
'''
def p_function_exp(p):
'function : expression PLUS function'
p[0] = p[1] + p[3]

def p_function(p):
'function : FUNCTION LPAREN expression RPAREN'
if p[1] == 'sin':
p[0] = math.sin(p[3])

def p_expression_minus(p):
'expression : expression MINUS term'
p[0] = p[1] - p[3]

def p_expression_plus(p):
'expression : expression PLUS term'
p[0] = p[1] + p[3]

def p_expression_term(p):
'expression : term'
p[0] = p[1]

def p_term_div(p):
'term : term DIV factor'
p[0] = p[1] / p[3]

def p_term_times(p):
'term : term TIMES factor'
p[0] = p[1] * p[3]

def p_term_factor(p):
'term : factor'
p[0] = p[1]

def p_factor(p):
'factor : NUMBER'
p[0] = p[1]

def p_factor_exp(p):
'factor : LPAREN expression RPAREN'
p[0] = p[2]

# Error rule for syntax errors
def p_error(p):
print("Syntax error in input!")

# Build the parser
parser = yacc.yacc()

while True:
try:
s = input('>> ')
equation = lex.lex()
equation.input(s)
while True:
tok = equation.token()
if not tok: break
print(tok)
except EOFError:
break
if not s: continue
result = parser.parse(s)
print(result)
``````

-
If you re-arrange the parser so that a function call is just a part of the expression then it will solve itself. –  Joachim Pileborg Sep 1 '12 at 12:15
You mean like this? `def p_expression_func(p): 'expression : FUNCTION LPAREN expression RPAREN'` –  Sean M. Sep 1 '12 at 12:20

A traditional Yacc-grammar for simple expressions usually looks something like this:

``````expression
;

: mul_div_expr
;

mul_div_expr
: funcall_expr
| funcall_expr '*' mul_div_expr
| funcall_expr '/' mul_div_expr
;

funcall_expr
: prim_expr
| FUNCTION_NAME '(' expression_list ')'
;

prim_expr
: NUMBER
| '(' expression ')'
;

expression_list
: expression
| expression ','  expression_list
;
``````

The above grammar will make function calls a direct part of the expression, with higher precedence than multiplication and division.

For `FUNCTION_NAME` you can either have one line each for each function (if you list of functions is short) or a non-terminal that contains a list of the function identifiers, or a special terminal (like in my grammar) or just a generic identifier terminal.

-
Okay, thanks! I'll give it a try now. What does the `comma in the expression_list` stand for? –  Sean M. Sep 1 '12 at 12:41
@JohnSmith Just comma... :) So you can have functions with multiple arguments. –  Joachim Pileborg Sep 1 '12 at 12:46
Awesome, works just great! –  Sean M. Sep 1 '12 at 13:03