This is kinda like the other answer for overriding GetHashCode but I have a different approach....
Since the formula appears to have a string representation....

Can't you override GetHashCode and in the override do a

```
foreach(char c in ToString().ToCharArray()){
int hashCode |= c;
}
```

The result of this would yield a 4 byte code which was a packed representation of the symbols in the equation...

This could be taken further if each symbol has specific OpCode which could be looked up in a HashTable.

I would build the HashTable up with alias's of each OpCode so each Symbol would not have to declare a property OpCode.

I would then make an Extension ToOpCode on the Symbol class which did the look-up in the HashTable described above.

I would then utilize the Extension method in the GetHashCode such as

Formula....

```
public override int GetHashCode(){
foreach(Symbol c in Symbols){
int hashCode |= c.ToOpCode();
}
}
```

Symbol....

```
public override int GetHashCode(){
retuurn Extensions.ToOpCode(this);
}
```

This implementation would yield the same hash for a + b and b + a which is very important per your question...

Additionally if you specified the OpCode in correct succession you would technically be able to compare equations in the form of:

`(a) + (b)`

== `(a+b)`

This would be achieved by ensuring the Parenthesis OpCodes were given a value in the HashCode in a different place than the numbers...

E.g. If you have 4 bytes (an integer) the scope depth could be kept in the first byte, the index to the previous or next equation / symbol in the stack would be next and the next two bytes would be reserved for sign data and the value / continuations or number of variables in the equation (exclusive).

This allows you to tell certain things such as how many nesting levels etc so you can essentially override Equals as well to ensure you can differentiate between `a + b`

and `b + a`

and `((a) + (b))`

if required.

For instance you may want to know if the equation is exactly the same with a certain method but in another you may want to know if the equations are doing the same thing but not written the same exact way.

This would also allow you to determine equality in different ways such as checking if the scope depths match and if there are exactly the same amount of steps in the equation rather than just assuming so based on the hash code..

e.g. you could then shift as follows to determine things such as :

hash << 8 would be the dept of parens
hash << 16 would be the previous or next equation pointer for the stack
hash << 24 would be the sign or code value continuation or number of variables in the equation (exclusive)

you could also just do hash == anotherHash but this way gives you much more flexibility with literally no overhead.

If you need more room in the Hash then create a new Method GetExtendedHashCode which returns long and then shift / downcast or reformat the ExtendedHashCode in GetHashCode to match the int format required by the CLR.

You also have the benefit of the symbols being able to represent variables and values in this way by leaving them as they are on the stack and using them just like the CLR.

`true`

when one formula is`a + b`

and the other is`b + a`

? – phoog May 29 '12 at 20:40