One solution would be using shunting yard algorithm to convert the expression to RPN, and then evaluate it as RPN (because RPN is much easier to evaluate than infix). The first part, conversion to RPN (in pseudocode):

```
while (tokens left) {
t = read_token();
if (t is number) {
output(t);
} else if (t is unary operator) {
push(t);
} else if (t is binary operator) {
r = pop();
if (r is operator and precedence(t)<=precedence(r)) {
output(r);
} else {
push(r);
}
push(t);
} else if (t is left parenthesis) {
push(t);
} else if (r is right parenthesis) {
while ((r = pop()) is not left parenthesis) {
output(r);
if (stack is empty) {
mismatched parenthesis!
}
}
if (top() is unary operator) {
output(pop());
}
}
}
while (stack is not empty) {
if (top() is parenthesis) {
mismatched parenthesis!
}
output(pop());
}
```

`read_token`

reads a token from input queue
`output`

inserts a value into output queue
`push`

pushes a value into the stack (you only need one)
`pop`

pops a value out of a stack
`top`

peeks the value at the top of the stack without popping

The RPN evaluation is simpler:

```
while (tokens left) {
t = read_token();
if (t is number) {
push(t);
} else if (t is unary operator) {
push(eval(t, pop()));
} else if (t is binary operator) {
val1 = pop();
val2 = pop();
push(eval(t, val1, val2));
}
}
result = pop();
```

`read_token()`

reads values from the RPN queue generated in previous step
`eval(t, val)`

evaluates unary operator `t`

with operand `val`

`eval(t, val1, val2)`

evaluates binary operator `t`

with operands `val1`

and `val2`

`result`

is the final value of the expression

This simplified algorithm should work if all your operators are left-associative and no functions are used. Note that no recursion is necessary, because we use our own stack implementation.
For examples and more information, see Rosetta Code on Shunting-yard and Rosetta Code on RPN

evalmethod, for security reasons, and I'd like to be able to customise the syntax too. – tomturton Jun 27 '12 at 12:03