A really useful next step would be to construct a parse tree:

You'd make one of these by writing an infix parser. You could either do this by writing a simple recursive descent parser, or by bringing in the big guns and using a parser generator. In either case, it helps to construct a formal grammar:

```
expression: additive
additive: multiplicative ([+-] multiplicative)*
multiplicative: primary ('*' primary)*
primary: variable
| number
| '(' expression ')'
```

Note that this grammar does not handle the `2x`

syntax, but it should be easy to add.

Notice the clever use of recursion in the grammar rules. `primary`

only captures variables, numbers, and parenthesized expressions, and stops when it runs into an operator. `multiplicative`

parses one or more `primary`

expressions delimited by `*`

signs, but stops when it runs into a `+`

or `-`

sign. `additive`

parses one or more `multiplicative`

expressions delimited by `+`

and `-`

, but stops when it runs into a `)`

. Hence, the recursion scheme determines operator precedence.

It isn't too terribly difficult to implement a predictive parser by hand, as I've done below (see full example at ideone.com):

```
function parse()
{
global $tokens;
reset($tokens);
$ret = parseExpression();
if (current($tokens) !== FALSE)
die("Stray token at end of expression\n");
return $ret;
}
function popToken()
{
global $tokens;
$ret = current($tokens);
if ($ret !== FALSE)
next($tokens);
return $ret;
}
function parseExpression()
{
return parseAdditive();
}
function parseAdditive()
{
global $tokens;
$expr = parseMultiplicative();
for (;;) {
$next = current($tokens);
if ($next !== FALSE && $next->type == "operator" &&
($next->op == "+" || $next->op == "-"))
{
next($tokens);
$left = $expr;
$right = parseMultiplicative();
$expr = mkOperatorExpr($next->op, $left, $right);
} else {
return $expr;
}
}
}
function parseMultiplicative()
{
global $tokens;
$expr = parsePrimary();
for (;;) {
$next = current($tokens);
if ($next !== FALSE && $next->type == "operator" &&
$next->op == "*")
{
next($tokens);
$left = $expr;
$right = parsePrimary();
$expr = mkOperatorExpr($next->op, $left, $right);
} else {
return $expr;
}
}
}
function parsePrimary()
{
$tok = popToken();
if ($tok === FALSE)
die("Unexpected end of token list\n");
if ($tok->type == "variable")
return mkVariableExpr($tok->name);
if ($tok->type == "number")
return mkNumberExpr($tok->value);
if ($tok->type == "operator" && $tok->op == "(") {
$ret = parseExpression();
$tok = popToken();
if ($tok->type == "operator" && $tok->op == ")")
return $ret;
else
die("Missing end parenthesis\n");
}
die("Unexpected $tok->type token\n");
}
```

Okay, so now you have this lovely parse tree, and even a pretty picture to go with it. Now what? Your goal (for now) might be to simply combine terms to get a result of the form:

```
n1*a + n2*b + n3*c + n4*d + ...
```

I'll leave that part to you. Having a parse tree should make things much more straightforward.

`$operator`

and`$var`

without having to worry about conflicting with keywords in the programming language. – Joey Adams Mar 23 '11 at 23:04