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Is there a commonly accepted way of how to compare immutable objects that might contain long lists of values?

So far, my interfaces are as follows:

interface Formula : IEquatable<Formula> {
   IList<Symbol> Symbols {get;}
}

interface Symbol : IEquatable<Symbol> {
   String Value {get;}
}

Here, the immutable datatype Formula represents a sequence of Symbol's. So in a formula:

x -> y

symbols would be x,->,y.

I want to compare two Formulas based on their content (e.g. a list of symbols). So new Formula(symbols) would equal new Formula(symbols) for some arbitrary list of symbols.

However, I don't want to iteratively compare two lists all the time.

I was thinking, in implementation, of creating some kind of calculated value during the initialization of the Formula - and using that for comparison. However, that will require me to add a method of some sort to my interface. What would I call that method?

I am not sure if it is appropriate to use hash code for this, as it seems to be limited to integers.

Any help appreciated - and if something is not clear I will revise my question. Thank you!

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It is not so much the comparison of objects but more about how one formula can be identical to another one. Before comparing you need to normalize and simplify the formula to one common form. After that you can compare the elements one by one until you have nothing to compare (equal) or you have detected inequality. – Alois Kraus May 29 '12 at 20:38
    
But a+b does = a+b – Frisbee May 29 '12 at 20:38
    
Thanks, but I am not interested in "how" to compare formulas. Imagine they are already normalized. And comparing "one by one" is exactly what I am asking if I can avoid. – drozzy May 29 '12 at 20:39
    
Is your equality comparison supposed to return true when one formula is a + b and the other is b + a? – phoog May 29 '12 at 20:40
    
@phoog Nope. Perhaps I should have abstracted my question away from formulas. I'ts mostly a general practice type of question - about lists and comparisons by value. – drozzy May 29 '12 at 20:41
up vote 5 down vote accepted

You could definitely use a hash code for this. Don't forget that a hash code doesn't have to be unique - it just helps if it doesn't give collisions (two unequal sequences with the same hash code) terribly often. (At least, try to come up with an approach which avoids equal hash codes for obvious situations.)

So you could compute the hash code once on construction (by combining the hash codes of each symbol in turn), then return that from GetHashCode without recomputing it each time. That would mean that you'd only ever need to compare sequences with equal hash codes - which would rarely happen for non-equal sequences.

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Perhaps and true for the most part - but it is possible that two different sequences might return the same hashcode. The number of possibilities in a Formula FAR exceed the storage capacity of an int. This might result in subtle, non-reproducible errors at some point in the future. – ananthonline May 29 '12 at 20:42
    
Interesting... so if hash codes are equal I simply go on and compare them? That's cool - I never thought of that approach. – drozzy May 29 '12 at 20:43
    
@drozzy: Yes, exactly. And for things like HashSet<T>, this would be done automatically before you even got to Equals. – Jon Skeet May 29 '12 at 20:44
    
@ananthonline: Did you read my second sentence? "Don't forget that a hash code doesn't have to be unique" - you always need to assume that there can be hash collisions. They can still narrow down the field incredibly quickly. – Jon Skeet May 29 '12 at 20:44
    
This means that 99.999% of calls to Equals will be O(1) if the objects are actually not equal. If they really are equal, it will be O(n) and you will need to iterate through every single item in the collection. There is no way around that fact. You can only ever optimize the cases where Equals returns false. – Servy May 29 '12 at 20:48

No, you have to compare all of the elements. You can't use hash code or a similar approach, because the set of possible formulas is infinite, while the set of possible hash codes is finite.

As Jon Skeet notes, you could use hash codes to reduce the need to compare formulas element-by-element, but you cannot eliminate the need. When two formulas have unequal hash codes, you know the formulas are unequal, but when they have equal hash codes, you will need to do an element-by-element comparison to see whether they are equal.

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Lists are finite... – drozzy May 29 '12 at 20:42
1  
If the lists were infinite, how would you expect to compare them anyway? If they were infinite but equal, you'd have to keep going forever. – Jon Skeet May 29 '12 at 20:43
    
@JonSkeet Strings have finite length, but there is an infinite number of possible strings. – phoog May 29 '12 at 20:44
1  
@drozzy I don't mean that a single formula could be infinite, rather, that there is an infinite number of possible formulas. – phoog May 29 '12 at 20:45
    
@phoog: Your claim that you "can't use hash code" suggests missing the point of hash codes. No-one ever said that they would eliminate the need for element-by-element comparisons. – Jon Skeet May 29 '12 at 20:51

I do believe that is not all you need to do...

a+b = (a+b)

would result in false with your approach.

I believe you have to construct AST (abstract syntax trees) for the expressions on both sides and then compare the expressions. The AST would do away the parnthesis since they are expressed as hierarchies in the AST.

hth

Mario

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1  
Based on the OP's comments on my answer he may not care about this but I do agree! – Jay May 29 '12 at 21:31

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.

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Obviously the algorithm OpCode for chars would be something like: if(char.IsLetterOrDigit(c)) return c.GetHashCode() else { /*Determine equality and position in hash via shifting inter alia*/ } – Jay May 29 '12 at 21:07
    
Um... thanks, but I really don't want a+b to be the same as b+a. Perhaps I used a bad example, but think of it more as a->b and b->a - which are different. You approach is interesting though. – drozzy May 29 '12 at 21:15
    
Since you example was not clear and based on your reply my answer very well may not apply... however it still is better than what was suggested as the given answers neglected to cache the value/hashcode of signs which do not change the equation such as (, ), or = and also required you to maintain their value separately... With the given example the hashCode not only is unique but tells you things about the equation in advance and allows you to mix and match equality when ever you would like and which ever way while maintaining efficiency over the others. – Jay May 29 '12 at 21:25
    
Your comment is baseless.... You could abstract the type limitations away with many techniques... once of such techniques is to use a larger hashCode as I have indicated.... last but not least the amount of formulas is not relevant with this implementation as the code depends on the symbols contained their-in and furthermore duplicate symbols will not effect the masked value on the entire value. If you had a requirement to stay within int limited You could always utilize a OpCode.From(Guid) where you allowed a Guid to represent a known qualified formula... – Jay May 29 '12 at 21:59
1  
The technique int hashCode |= c will guarantee that two bytes of the hash code are always zero. In addition, consider this: "A$" gives the same hash code as "D!": "A$" is { 65, 36 } and "D!" is { 68, 33 }; both sets of values yield 101 when combined with bitwise or. You might get better results with the xor operator (^). – phoog May 30 '12 at 14:45

First of all, I would advise against implementing IEquatable<T> for any non-sealed type T. The only safe way to implement IEquatable<T>.Equals on an unsealed type is generally to call the virtual method Object.Equals. Otherwise, there is a possibility that a class whose parent class implements IEquatable<T> for one or more types T will override Object.Equals and Object.GetHashCode without re-implementing all of its IEquatable<T> interfaces; any such interfaces that aren't re-implemented will thus be broken.

Secondly, if while comparing the lists in two Formula instances, one finds a pair of corresponding Symbol references that are equivalent but refer to distinct instances, it may be helpful to call System.Runtime.CompilerServices.RuntimeHelpers.GetHashCode() on each instance. If one compares larger than the other, replace the reference with the larger RunTimeHelpers.GetHashCode() value with the one from the other list. This will accelerate any future comparisons of those lists. Further, if one repeatedly compares multiple lists that have the same items, all of the lists will "gravitate" toward having the same Symbol instances.

Finally, if one finds that the lists are equal, and if the lists are supposed to be "semantically" immutable, one can use the same RuntimeHelpers.GetHashCode() trick to pick a List instance. This will then expedite future comparisons.

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