For starters, you don't have a circular loop.
A circular loop is when you have a linked list that points back to itself. You merely have a queue that as you step through it might have another thread add repeated elements to the end of the queue.
The way to detect a circular loop is to use a
hashtable, before each
Ping() you check if the connection already exists in the connection, if it does then you just move on to the next element, if it doesn't exist then you add it to the
hashtable and then you call your
Ping operation to the server.
Or you can just have your initial
ping operation make a snapshot of the queue at that exact time and not step over it.
With that said, something is very wrong with your queue if you can have two different callers get the same
A result off the queue.
The correct way to do this code is to have two separate lists, one is a queue of connections for requests such as
externalClass.getConnection() and the other is the list of connections for
Ping. Whatever your
Ping operation is doing it really shouldn't impact anything that any external class is doing with it's connection, For example assuming
connection is a
sql connection then
Ping should execute something like this:
SELECT TOP 1 1
And nothing more, that will then mean your connection remains alive. as you are likely implementing this because the connections are being idle too long and closing themselves.. which in that case you really shouldn't because pretty much any flavor of sql dbms supports connection pooling which does exactly what you're trying to do. Unless you want to prevent more than Queue.Count concurrent connections at once by having the other executions wait (which in itself can be done much better ways that keeping a pool of open connections, such as a simple
Unless your keeping connections to different servers and trying to do some adhoc load balancing by rotating requests across several servers, then use my above solution with a list of all connections and a queue of available connections. The major benefit from this solution is that you can terminate all connections when the application closes even if they're currently processing requests.
But, for completeness in answering your question:
If you did have a circular loop it would look like this:
A -> B -> C -> A where each element would point to the next in the list and not just be elements in a
queue. A good example is you Ping server
A which pings server
B which pings server
C which then pings
A and you would detect it as follows:
The simple way to detect circular loops is to run two (or multiple) iterations through it at once, we'll call them X and Y.
For every second time you step (or
.Ping() in your context) X, you step Y once. You might want to make a new method such as
Visit rather than calling your
Ping so that ping isn't called many times within the loop.
Assuming the queue looks like
A, B, C, A, B...
After a few steps X will look like:
A, B, C, A while Y will look like
A, B. What you do is you don't store the entire history, you only look at the current values, so when you step in X you check if the new value matches the current value of Y, thus we will eventually always get to a collision.
This isn't the fastest or most efficient way to detect cyclic loops, but it is the most simple and if your loops will generally be small it is easier than storing a historical list of past routes (which in some cases requires significant changes to code). There are much more efficient algorithms that can be used for when your loops are more than 20 steps long (they're designed to deal with complex branching trees and the like). It is important to recognize that the worst case for this implementation will be a prime number of looping elements.
But you can improve performance on average by just expanding this further to have a
Z iterator which steps once for every three
X steps, at this point it's not really worth adding an additional one that steps every 5
X steps or 7 and so on (visiting the next incremental prime number with the creation of each new iterator).