If you'd like to use the exact syntax from your question then you could write a parser for the calculator:

```
#!/usr/bin/env python
from operator import add, div, mul, sub
from lepl import Any, Delayed, Digit, Drop, DroppedSpace, Eos
from sympy import Symbol, latex, pprint
def Power(tokens):
"""x**(y**z)"""
return reduce(lambda p, b: pow(b, p), reversed(tokens))
def Arithm(tokens):
"""(x op1 y) op2 z ..."""
OP = { '*': mul, '/': div, '+': add, '-': sub, }
tokens = iter(tokens)
a = next(tokens)
for op, b in zip(tokens, tokens):
a = OP[op](a, b)
return a
def makeparser():
expr = Delayed()
number = Digit()[1:,...] >> int # \d+
symbol = Any('xyz') >> (lambda x: Symbol(bytes(x))) # unicode -> str
muldiv_op = Any('*/')[:1] > (lambda x: x[0] if x else '*') # xy -> x*y
power_op = Drop('^') | Drop('**') # both stand for pow(x, y)
with DroppedSpace(): # ignore spaces
term = number | symbol | Drop('(') & expr & Drop(')')
power = term & (power_op & term)[:] > Power
factor = power & (muldiv_op & power)[:] > Arithm
expr += factor & (Any('-+') & factor)[:] > Arithm
line = expr & Eos()
return line.get_parse()
parse = makeparser()
[expr] = parse('(3x^(x+(5/x)+(x/33))+y)/(32 + 5)')
pprint(expr)
print(latex(expr))
```

### Output

```
34⋅x 5
──── + ─
33 x
y 3⋅x
── + ───────────
37 37
$\frac{1}{37} y + \frac{3}{37} x^{\frac{34}{33} x + \frac{5}{x}}$
```

In general it might be preferable to use syntax for an existing language such as Python.

`x`

in`(32 + 5)`

. – J.F. Sebastian Feb 9 '11 at 16:24