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stringExp = "2^4"
intVal = int(stringExp)      # Expected value: 16

This returns the following error:

Traceback (most recent call last):  
File "<stdin>", line 1, in <module>
ValueError: invalid literal for int()
with base 10: '2^4'

I know that eval can work around this, but isn't there a better and - more importantly - safer method to evaluate a mathematical expression that is being stored in a string?

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2  
^ is the XOR operator. Expected value is 6. You probably want pow(2,4). –  kgiannakakis Mar 3 '10 at 13:12
7  
or more pythonically 2**4 –  fortran Mar 3 '10 at 13:14
3  
    
Not exactly a duplicate. I'm just parsing math without introducing unknowns. –  Pieter Mar 3 '10 at 13:41

11 Answers 11

up vote 22 down vote accepted

Pyparsing can be used to parse mathematical expressions. In particular, fourFn.py shows how to parse basic arithmetic expressions. Below, I've rewrapped fourFn into a numeric parser class for easier reuse.

from __future__ import division
from pyparsing import (Literal,CaselessLiteral,Word,Combine,Group,Optional,
                       ZeroOrMore,Forward,nums,alphas,oneOf)
import math
import operator

__author__='Paul McGuire'
__version__ = '$Revision: 0.0 $'
__date__ = '$Date: 2009-03-20 $'
__source__='''http://pyparsing.wikispaces.com/file/view/fourFn.py
http://pyparsing.wikispaces.com/message/view/home/15549426
'''
__note__='''
All I've done is rewrap Paul McGuire's fourFn.py as a class, so I can use it
more easily in other places.
'''

class NumericStringParser(object):
    '''
    Most of this code comes from the fourFn.py pyparsing example

    '''
    def pushFirst(self, strg, loc, toks ):
        self.exprStack.append( toks[0] )
    def pushUMinus(self, strg, loc, toks ):
        if toks and toks[0]=='-': 
            self.exprStack.append( 'unary -' )
    def __init__(self):
        """
        expop   :: '^'
        multop  :: '*' | '/'
        addop   :: '+' | '-'
        integer :: ['+' | '-'] '0'..'9'+
        atom    :: PI | E | real | fn '(' expr ')' | '(' expr ')'
        factor  :: atom [ expop factor ]*
        term    :: factor [ multop factor ]*
        expr    :: term [ addop term ]*
        """
        point = Literal( "." )
        e     = CaselessLiteral( "E" )
        fnumber = Combine( Word( "+-"+nums, nums ) + 
                           Optional( point + Optional( Word( nums ) ) ) +
                           Optional( e + Word( "+-"+nums, nums ) ) )
        ident = Word(alphas, alphas+nums+"_$")       
        plus  = Literal( "+" )
        minus = Literal( "-" )
        mult  = Literal( "*" )
        div   = Literal( "/" )
        lpar  = Literal( "(" ).suppress()
        rpar  = Literal( ")" ).suppress()
        addop  = plus | minus
        multop = mult | div
        expop = Literal( "^" )
        pi    = CaselessLiteral( "PI" )
        expr = Forward()
        atom = ((Optional(oneOf("- +")) +
                 (pi|e|fnumber|ident+lpar+expr+rpar).setParseAction(self.pushFirst))
                | Optional(oneOf("- +")) + Group(lpar+expr+rpar)
                ).setParseAction(self.pushUMinus)       
        # by defining exponentiation as "atom [ ^ factor ]..." instead of 
        # "atom [ ^ atom ]...", we get right-to-left exponents, instead of left-to-right
        # that is, 2^3^2 = 2^(3^2), not (2^3)^2.
        factor = Forward()
        factor << atom + ZeroOrMore( ( expop + factor ).setParseAction( self.pushFirst ) )
        term = factor + ZeroOrMore( ( multop + factor ).setParseAction( self.pushFirst ) )
        expr << term + ZeroOrMore( ( addop + term ).setParseAction( self.pushFirst ) )
        # addop_term = ( addop + term ).setParseAction( self.pushFirst )
        # general_term = term + ZeroOrMore( addop_term ) | OneOrMore( addop_term)
        # expr <<  general_term       
        self.bnf = expr
        # map operator symbols to corresponding arithmetic operations
        epsilon = 1e-12
        self.opn = { "+" : operator.add,
                "-" : operator.sub,
                "*" : operator.mul,
                "/" : operator.truediv,
                "^" : operator.pow }
        self.fn  = { "sin" : math.sin,
                "cos" : math.cos,
                "tan" : math.tan,
                "abs" : abs,
                "trunc" : lambda a: int(a),
                "round" : round,
                "sgn" : lambda a: abs(a)>epsilon and cmp(a,0) or 0}
    def evaluateStack(self, s ):
        op = s.pop()
        if op == 'unary -':
            return -self.evaluateStack( s )
        if op in "+-*/^":
            op2 = self.evaluateStack( s )
            op1 = self.evaluateStack( s )
            return self.opn[op]( op1, op2 )
        elif op == "PI":
            return math.pi # 3.1415926535
        elif op == "E":
            return math.e  # 2.718281828
        elif op in self.fn:
            return self.fn[op]( self.evaluateStack( s ) )
        elif op[0].isalpha():
            return 0
        else:
            return float( op )
    def eval(self,num_string,parseAll=True):
        self.exprStack=[]
        results=self.bnf.parseString(num_string,parseAll)
        val=self.evaluateStack( self.exprStack[:] )
        return val

You can use it like this:

nsp=NumericStringParser()
result=nsp.eval('2^4')
print(result)
# 16.0
share|improve this answer
1  
Now, that's probably more than what the OP had in mind, but +1 for the relatively compact pyparsing application! Thanks. –  mjv Mar 3 '10 at 14:59

eval is evil

eval("__import__('os').remove('important file')") # arbitrary commands
eval("9**9**9**9**9**9**9**9", {'__builtins__': None}) # CPU, memory

Note: even if you use set __builtins__ to None it still might be possible to break out using introspection:

eval('(1).__class__.__bases__[0].__subclasses__()', {'__builtins__': None})

Evaluate arithmetic expression using ast

import ast
import operator as op

# supported operators
operators = {ast.Add: op.add, ast.Sub: op.sub, ast.Mult: op.mul,
             ast.Div: op.truediv, ast.Pow: op.pow, ast.BitXor: op.xor,
             ast.USub: op.neg}

def eval_expr(expr):
    """
    >>> eval_expr('2^6')
    4
    >>> eval_expr('2**6')
    64
    >>> eval_expr('1 + 2*3**(4^5) / (6 + -7)')
    -5.0
    """
    return eval_(ast.parse(expr, mode='eval').body)

def eval_(node):
    if isinstance(node, ast.Num): # <number>
        return node.n
    elif isinstance(node, ast.BinOp): # <left> <operator> <right>
        return operators[type(node.op)](eval_(node.left), eval_(node.right))
    elif isinstance(node, ast.UnaryOp): # <operator> <operand> e.g., -1
        return operators[type(node.op)](eval_(node.operand))
    else:
        raise TypeError(node)

You can easily limit allowed range for each operation or any intermediate result, e.g., to limit input arguments for a**b:

def power(a, b):
    if any(abs(n) > 100 for n in [a, b]):
        raise ValueError((a,b))
    return op.pow(a, b)
operators[ast.Pow] = power

Or to limit magnitude of intermediate results:

import functools

def limit(max_=None):
    """Return decorator that limits allowed returned values."""
    def decorator(func):
        @functools.wraps(func)
        def wrapper(*args, **kwargs):
            ret = func(*args, **kwargs)
            try:
                mag = abs(ret)
            except TypeError:
                pass # not applicable
            else:
                if mag > max_:
                    raise ValueError(ret)
            return ret
        return wrapper
    return decorator

eval_ = limit(max_=10**100)(eval_)

Example

>>> evil = "__import__('os').remove('important file')"
>>> eval_expr(evil) #doctest:+IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
TypeError:
>>> eval_expr("9**9")
387420489
>>> eval_expr("9**9**9**9**9**9**9**9") #doctest:+IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
ValueError:
share|improve this answer
1  
Very cool post, Thanks. I've taken that concept, and tried to make a library which should be easy to use: github.com/danthedeckie/simpleeval –  Daniel Fairhead Dec 3 '13 at 21:51
    
Thank you, that's an extremely elegant solution. I can see adding simple constants, managed variables and commands very easily! –  Jotaf Feb 18 at 5:20
    
This also works in Python 3, except for negative numbers: eval_expr('1 + 2*3**(4^5) / (6 + -7)') fails with a TypeError: ast.UnaryOp - any idea why? –  Tim Pietzcker Jul 30 at 10:12
1  
@TimPietzcker: I've updated the code to support both Python 2 and 3. –  J.F. Sebastian Jul 30 at 12:00
    
Great! Unfortunately I can only upvote you once :( –  Tim Pietzcker Jul 30 at 12:38

Use eval in a clean namespace:

>>> ns = {'__builtins__': None}
>>> eval('2 ** 4', ns)
16

The clean namespace should prevent injection. For instance:

>>> eval('__builtins__.__import__("os").system("echo got through")', ns)
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
  File "<string>", line 1, in <module>
AttributeError: 'NoneType' object has no attribute '__import__'

Otherwise you would get:

>>> eval('__builtins__.__import__("os").system("echo got through")')
got through
0

You might want to give access to the math module:

>>> import math
>>> ns = vars(math).copy()
>>> ns['__builtins__'] = None
>>> eval('cos(pi/3)', ns)
0.50000000000000011
share|improve this answer
1  
+1 for limiting the namespace. Just like in normal code, using __builtins__.* is unnecessary. –  u0b34a0f6ae Mar 3 '10 at 14:54
2  
eval("(1).__class__.__bases__[0].__subclasses__()[81]('echo got through'.split())",{'builtins':None}) #escapes your sandbox –  Perkins Aug 21 at 23:21

You need to use the eval() function, as in

#btw that's probably what you meant, 2 to the 4th power, not the XOR operation
>>>stringExp = "2**4"  
>>>print(eval(stringExp))
16

Beware that eval(), and its cousin exec() are dangerous tools in the Python's "workshop" because, depending on the origin of the string to be evaluated, the expression could at best simply generate an exception, and at worse, well..., take over the computer or something like that ;-)

Therefore you typically need to

  • parse (if only roughly) the string for "dangerous" keywords etc.; For simple expressions, a simple regex which checks for the absence of letters may just suffice.
  • run the eval in the context of a try-except construct

Better yet, to check the input string against erroneous syntax and malicious code, you could use functions from the ast module (Abstract Syntax Tree)
For example, after ast.parse()ing the expression use ast.walk() to check that the tree only contains an ast.Expr, void of ast.Assign and such.

share|improve this answer
    
I've implemented eval_expr() using ast module –  J.F. Sebastian Mar 4 '12 at 19:21

This is a massively late reply, but I think useful for future reference. Rather that write your own math parser (although the pyparsing example above is great) you could use SymPy. I don't have a lot of experience with it, but it contains a much more powerful math engine than anyone is likely to write for a specific application and the basic expression evaluation is very easy:

>>> import sympy
>>> x, y, z = sympy.symbols('x y z')
>>> sympy.sympify("x**3 + sin(y)").evalf(subs={x:1, y:-3})
0.858879991940133

Very cool indeed! A from sympy import * brings in a lot more function support, such as trig functions, special functions, etc., but I've avoided that here to show what's coming from where.

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1  
Is sympy "safe"? There seem to be numerous posts that suggest it is a wrapper around eval() that could be exploited in the same way. Also evalf doesn't take numpy ndarrays. –  Mark Mikofski Aug 6 '13 at 23:22
4  
No sympy is not safe for untrusted input. Try sympy.sympify("""[].__class__.__base__.__subclasses__()[158]('ls')""") this calls subprocess.Popen() which I passed ls instead of rm -rf /. The index will probably be different on other computers. This is a variant of the Ned Batchelder exploit –  Mark Mikofski Aug 7 '13 at 8:49

Try asteval or possibly numexpr for possibly safer alternatives to eval() and Sympy.sympify().evalf().

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What is wrong with eval? If you have some expression as a string, then eval is the way to go.

Just run:

try:
  result = eval('2**4')
except SyntaxError:
  result = 0

Or something like this.

If you want to sanitaze your code, you can use compiler package and parse the given code. If you notice anything but mathematical expressions, just refuse to evaluate the code.

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1  
The problem is that the string might really be coming from user input, and eval can execute arbitrary commands. –  Tim Goodman Mar 3 '10 at 13:16
    
Although in that case he should probably validate that the input has the form of a mathematical expression before passing it to eval() –  Tim Goodman Mar 3 '10 at 13:17
1  
Then he needs a math syntax parser and validate the code. This is easy in Python, though. –  gruszczy Mar 3 '10 at 13:20

I think I would use eval(), but would first check to make sure the string is a valid mathematical expression, as opposed to something malicious. You could use a regex for the validation.

eval() also takes additional arguments which you can use to restrict the namespace it operates in for greater security.

share|improve this answer
    
You seem to mean "opposed", not "supposed". –  Svante Mar 3 '10 at 14:13
3  
But, of course, don't rely on regular expressions to validate arbitrary mathematical expressions. –  High Performance Mark Mar 3 '10 at 14:23
    
@Svante: Right, that was a typo ... fixed now, thanks –  Tim Goodman Mar 3 '10 at 15:45
    
@High-Performance Mark: Yes, I guess it depends on what sort of mathematical expressions he has in mind . . . e.g., just simple arithmetic with numbers and +,-,*,/,**,(,) or something more complicated –  Tim Goodman Mar 3 '10 at 15:56
    
@Tim -- it's the () I'm worried about, or rather the (((((())))))). In truth, I think OP should worry about them, my brow is unfurrowed by OP's problems. –  High Performance Mark Mar 3 '10 at 17:35

If you don't want to use eval, then the only solution is to implement the appropriate grammar parser. Have a look at pyparsing.

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Python already has a function for safely evaluating strings containing literal expressions:

http://docs.python.org/2/library/ast.html#ast.literal_eval

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3  
have you tried it? ast.literal_eval("2^4") fails. It is an arithmetic (not literal) expression. Though it might be evaluated into a constant during compilation. –  J.F. Sebastian May 4 '13 at 13:35
    
Oops, fair point! –  lost May 7 '13 at 15:34

Okay, so the problem with eval is that it can escape its sandbox too easily, even if you get rid of __builtins__. All the methods for escaping the sandbox come down to using getattr or object.__getattribute__ (via the . operator) to obtain a reference to some dangerous object via some allowed object (''.__class__.__bases__[0].__subclasses__ or similar). getattr is eliminated by setting __builtins__ to None. object.__getattribute__ is the difficult one, since it cannot simply be removed, both because object is immutable and because removing it would break everything. However, __getattribute__ is only accessible via the . operator, so purging that from your input is sufficient to ensure eval cannot escape its sandbox.
In processing formulas, the only valid use of a decimal is when it is preceded or followed by [0-9], so we just remove all other instances of ..

import re
inp = re.sub(r"\.(?![0-9])","", inp)
val = eval(inp, {'__builtins__':None})

Note that while python normally treats 1 + 1. as 1 + 1.0, this will remove the trailing . and leave you with 1 + 1. You could add ),, and EOF to the list of things allowed to follow ., but why bother?

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