In the order in which your code hits it...
== is overridden. This means that rather than
"abc" == "ab" + "c" calling the default
== for reference types (which compares references and not values) it calls into
Now, this does the following:
- If the two are indeed the same reference, return true.
- If either are null, return false (we would have already returned true above if they were both null).
- if the two are different length, return false;
- Do an optimised cycle through one string, comparing it char-for-char with the rest (actually int-for-int as viewed as two blocks of ints in memory, which is one of the optimisations involved). If it reaches the end without a mismatch, then return true, otherwise return false.
In other words, it starts with something like:
public static bool ==(string x, string y)
if(ReferenceEquals(x, null) || ReferenceEquals(y, null))
int len = x.Length;
if(len != y.Length)
for(int i = 0; i != len; ++i)
if(x[i] != y[i])
Except that step 4 is a pointer-based version with an unrolled loop that should hence ideally be faster. I won't show that because I want to talk about the overall logic.
There are significant short-cuts. The first is in step 1. Since equality is reflexive (identity entails equality,
a == a) then we can return true in nanoseconds for even a string several MB in size, if compared with itself.
Step 2 isn't a short-cut, because its a condition that must be tested for, but note that because we'll have already have returned true for
(string)null == (string)null we don't need another branch. So the order of calling is geared to a quick result.
Step 3 allows two things. It both short-cuts on strings of different length (always false) and means that one cannot accidentally shoot past the end of one of the strings being compared in step 4.
Note that this is not the case for other string comparisons, since e.g.
weißbier are different lengths but the same word in different capitalisation, so case-insensitive comparison cannot use step 3. All equality comparisons can do step 1 and 2 as the rules used always hold, so you should use them in your own, only some can do step 3.
Hence, while you are wrong in suggesting that it is references rather than values that are compared, it is true that references are compared first as a very significant short-cut. Note also that interned strings (strings placed in the intern pool by compilation or by
string.Intern called) will hence trigger this short-cut often. This would be the case in the code in your example, as the compiler will have used the same reference in each case.
If you know that a string was interned you can depend upon this (just do reference equality test), but even if you don't know for sure you can benefit from it (reference equality test will short-cut at least some of the time).
If you have a bunch of strings where you will want to test some of them against each other often, but you don't want to extend their lifetime in memory as much as interning does, then you could use an XmlNameTable or LockFreeAtomizer (soon to be renamed ThreadSafeAtomizer and the doc moved to http://hackcraft.github.com/Ariadne/documentation/html/T_Ariadne_ThreadSafeAtomizer_1.htm - should have been named for function rather than implementation details in the first place).
The former is used internally by
XmlTextReader and hence by a lot of the rest of
System.Xml and can be used by other code too. The latter I wrote because I wanted a similar idea, that was safe for concurrent calls, for different types, and where I could override the equality comparison.
In either case, if you put 50 different strings that are all "abc" into it, you'll get a single "abc" reference back allowing the others to be garbage collected. If you know this has happened you can depend upon
ReferenceEquals alone, and if you're not sure, you'll still benefit from the short-cut when it is the case.