parsing a complex logical expression in pyparsing in a binary tree fashion

I am trying to parse complex logical expression like the one below;

``````x > 7 AND x < 8 OR x = 4
``````

and get the parsed string as a binary tree. For the above expression the expected parsed expression should look like

``````[['x', '>', 7], 'AND', [['x', '<', 8], 'OR', ['x', '=', 4]]]
``````

'OR' logical operator has higher precedence than 'AND' operator. Parenthesis can override the default precedence. To be more general, the parsed expression should look like;

``````<left_expr> <logical_operator> <right_expr>
``````

Another example would be

``````input_string = x > 7 AND x < 8 AND x = 4
parsed_expr  = [[['x', '>', 7], 'AND', ['x', ',', 8]], 'AND', ['x', '=', 4]]
``````

So far i came up with this simple solution which sadly cannot generate parsed expression in binary tree fashion. operatorPrecedence doesn't seem to have help me here where there is same logical operator consecutively as in previous example.

``````import pyparsing as pp
complex_expr = pp.Forward()
operator = pp.Regex(">=|<=|!=|>|<|=").setName("operator")
logical = (pp.Keyword("AND") | pp.Keyword("OR")).setName("logical")
vars = pp.Word(pp.alphas, pp.alphanums + "_") | pp.Regex(r"[+-]?\d+(:?\.\d*)?(:?[eE][+-]?\d+)?")
condition = (vars + operator + vars)
clause = pp.Group(condition ^ (pp.Suppress("(") + complex_expr + pp.Suppress(")") ))

expr = pp.operatorPrecedence(clause,[
("OR", 2, pp.opAssoc.LEFT, ),
("AND", 2, pp.opAssoc.LEFT, ),])

complex_expr << expr
print complex_expr.parseString("x > 7 AND x < 8 AND x = 4")
``````

Any suggestions or guidance is well appreciated.

`BNF` for the expression (without parenthesis) could be

``````<expr>       -> <expr> | <expr> <logical> <expr>
<expr>       -> <opnd> <relational> <opnd>
<opnd>       -> <variable> | <numeric>
<relational> -> <'>'> | <'='> | <'>='> | <'<='> | <'!='>
``````
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Your code is a bit hard to follow, could you post the grammar in BNF? –  gdbdmdb Jun 21 '12 at 7:29
just added the BNF ... i am not sure if it's unambiguous or not. –  consumer Jun 21 '12 at 8:08
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2 Answers

Try changing:

``````expr = pp.operatorPrecedence(clause,[
("OR", 2, pp.opAssoc.LEFT, ),
("AND", 2, pp.opAssoc.LEFT, ),])
``````

to:

``````expr = pp.operatorPrecedence(condition,[
("OR", 2, pp.opAssoc.LEFT, ),
("AND", 2, pp.opAssoc.LEFT, ),])
``````

The first argument to operatorPrecedence is the primitive operand to be used with the operators - there is no need to include your complexExpr in parentheses - operatorPrecedence will do that for you. Since your operand is actually another deeper comparison, you might consider changing:

``````condition = (expr + operator + expr)
``````

to:

``````condition = pp.Group(expr + operator + expr)
``````

so that the output of operatorPrecedence is easier to process. With these changes, parsing `x > 7 AND x < 8 OR x = 4` gives:

``````[[['x', '>', '7'], 'AND', [['x', '<', '8'], 'OR', ['x', '=', '4']]]]
``````

which recognizes OR's higher precedence and groups it first. (Are you sure you want this order of AND and OR precedence? I think the traditional ordering is the reverse, as shown in this wikipedia entry.)

I think you are also asking why pyparsing and operatorPrecedence does not return the results in nested binary pairs, that is, you expect parsing "A and B and C" would return:

``````[['A', 'and', 'B'] 'and', 'C']
``````

but what you get is:

``````['A', 'and', 'B', 'and', 'C']
``````

That is because operatorPrecedence parses repeated operations at the same precedence level using repetition, not recursion. See this question which is very similar to yours, and whose answer includes a parse action to convert your repetitive parse tree to the more traditional binary parse tree. You can also find a sample boolean expression parser implemented using operatorPrecedence on the pyparsing wiki page.

EDIT: To clarify, this is what I recommend you reduce your parser to:

``````import pyparsing as pp

operator = pp.Regex(">=|<=|!=|>|<|=").setName("operator")
number = pp.Regex(r"[+-]?\d+(:?\.\d*)?(:?[eE][+-]?\d+)?")
identifier = pp.Word(pp.alphas, pp.alphanums + "_")
comparison_term = identifier | number
condition = pp.Group(comparison_term + operator + comparison_term)

expr = pp.operatorPrecedence(condition,[
("AND", 2, pp.opAssoc.LEFT, ),
("OR", 2, pp.opAssoc.LEFT, ),
])

print expr.parseString("x > 7 AND x < 8 OR x = 4")
``````

If support for NOT might also be something you want to add, then this would look like:

``````expr = pp.operatorPrecedence(condition,[
("NOT", 1, pp.opAssoc.RIGHT, ),
("AND", 2, pp.opAssoc.LEFT, ),
("OR", 2, pp.opAssoc.LEFT, ),
])
``````

At some point, you may want to expand the definition of `comparison_term` with a more complete arithmetic expression, defined with its own `operatorPrecedence` definition. I would suggest doing it this way, rather than creating one monster `opPrec` definition, as you have already alluded to some of the performance downsides to `opPrec`. If you still get performance issues, look into `ParserElement.enablePackrat`.

-
Hi Paul, Thank you for guiding me. I have another question here though. Using three level of precedence as you suggested has increased the parsing time and also the grammar validation time has also grown drastically. Do you see any possibility to improve the query performance? –  consumer Jun 22 '12 at 5:14
??? I'm a little confused on what the 3rd level was that I suggested. I was actually suggesting you remove the addition of `complex_expr` and `clause`, and just use 'expr'. I was not suggesting that you add anything to your list of operators. I did recommend that you revisit the order of the operators, as traditional math evaluates AND ahead of OR, not the other way around as you currently have it. –  Paul McGuire Jun 22 '12 at 6:30
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Let me suggest this parsing approach, coming directly from Peter Norvig's class in design of computer programs at udacity (and tweaked for your needs).

``````from functools import update_wrapper
from string import split
import re

def grammar(description, whitespace=r'\s*'):
"""Convert a description to a grammar.  Each line is a rule for a
non-terminal symbol; it looks like this:
Symbol =>  A1 A2 ... | B1 B2 ... | C1 C2 ...
where the right-hand side is one or more alternatives, separated by
the '|' sign.  Each alternative is a sequence of atoms, separated by
spaces.  An atom is either a symbol on some left-hand side, or it is
a regular expression that will be passed to re.match to match a token.

Notation for *, +, or ? not allowed in a rule alternative (but ok
within a token). Use '\' to continue long lines.  You must include spaces
or tabs around '=>' and '|'. That's within the grammar description itself.
The grammar that gets defined allows whitespace between tokens by default;
specify '' as the second argument to grammar() to disallow this (or supply
any regular expression to describe allowable whitespace between tokens)."""
G = {' ': whitespace}
description = description.replace('\t', ' ') # no tabs!
for line in split(description, '\n'):
lhs, rhs = split(line, ' => ', 1)
alternatives = split(rhs, ' | ')
G[lhs] = tuple(map(split, alternatives))
return G

def decorator(d):
def _d(fn):
return update_wrapper(d(fn), fn)
update_wrapper(_d, d)
return _d

@decorator
def memo(f):
cache = {}
def _f(*args):
try:
return cache[args]
except KeyError:
cache[args] = result = f(*args)
return result
except TypeError:
# some element of args can't be a dict key
return f(args)
return _f

def parse(start_symbol, text, grammar):
"""Example call: parse('Exp', '3*x + b', G).
Returns a (tree, remainder) pair. If remainder is '', it parsed the whole
string. Failure iff remainder is None. This is a deterministic PEG parser,
so rule order (left-to-right) matters. Do 'E => T op E | T', putting the
longest parse first; don't do 'E => T | T op E'
Also, no left recursion allowed: don't do 'E => E op T'"""

tokenizer = grammar[' '] + '(%s)'

def parse_sequence(sequence, text):
result = []
for atom in sequence:
tree, text = parse_atom(atom, text)
if text is None: return Fail
result.append(tree)
return result, text

@memo
def parse_atom(atom, text):
if atom in grammar:  # Non-Terminal: tuple of alternatives
for alternative in grammar[atom]:
tree, rem = parse_sequence(alternative, text)
if rem is not None: return [atom]+tree, rem
return Fail
else:  # Terminal: match characters against start of text
m = re.match(tokenizer % atom, text)
return Fail if (not m) else (m.group(1), text[m.end():])

# Body of parse:
return parse_atom(start_symbol, text)

Fail = (None, None)

MyLang = grammar("""expression => block logicalop expression | block
block => variable operator number
variable => [a-z]+
operator => <=|>=|>|<|=
number => [-+]?[0-9]+
logicalop => AND|OR""", whitespace='\s*')

def parse_it(text):
return parse('expression', text, MyLang)

print parse_it("x > 7 AND x < 8 AND x = 4")
``````

Outputs:

``````(['expression', ['block', ['variable', 'x'], ['operator', '>'], ['number', '7']], ['logicalop', 'AND'], ['expression', ['block', ['variable', 'x'], ['operator', '<'], ['number', '8']], ['logicalop', 'AND'], ['expression', ['block', ['variable', 'x'], ['operator', '='], ['number', '4']]]]], '')
``````
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Thanks luke for suggesting ... but the solution suggested by Paul was the one i was looking for. THanks for taking your time :) –  consumer Jun 22 '12 at 5:29
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