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@ -1,7 +1,5 @@ |
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FOR VERSION 0.2 |
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- move authentication from communication layer to application layer. |
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- add a first simple session persistence stuff. |
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This could store informations like the username and the last login |
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date and present these to the user. |
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@ -20,6 +18,48 @@ FOR VERSION 0.2 |
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- IPV6 support (optional) |
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- optimize session handling. Right now session handling slows down |
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everything incredibly...especially if there would be some clients |
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that don't use cookies... |
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The reason is that for every request all sessions are checked if they |
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could be closed. If the session amount increases this slows down everything. |
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TODO: |
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* add an additional storage layer, an ordered list indexed by lifetime |
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each element of this list is an array of session ids that have this |
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lifetime. This would have been a classical queue, if there wasn't the |
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need to update them in between. |
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So three cases: |
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* delete: the element is on the beginning of the list. |
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* insert: always put to the end of the list. |
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* update: the lifetime could be get in O(log n) from the |
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session hash. If the list is no list but an array |
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I could get to the element in O(log n) via successive |
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approximation. But this would involve a memmov afterwords. |
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Additionally it will make memory menagement more difficult. |
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We need a large enough array that may grow in time. |
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With the optimizes memory management this leaves us with |
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large memory segments that might be never used... |
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so this would involve splitting again. |
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So a better alternative might be again a tree... |
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Workflow to handle sessions updates would be: |
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* lookup session in session hash O(log n) |
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* remove session from session time tree O(log n) |
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* if session it timeout |
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* remove session from session hash O(log n) |
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* else |
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* update timeout O(1) |
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* insert session again in session timeout tree O(log n) |
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So I end up with a complexity of 3*O(log n) not to bad. |
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But each lifetime might hold sevaral session ids, so |
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with an update this again has to be looked up. |
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Anyway it will be faster than walking through a maybe very |
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large monster list of sessions. |
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Also one should keep in mind that the timeout list has |
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a maximum of timeout second entries. |
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* store the lowest lifetime (ideally it could be retrieved by the key of |
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the first element of the previous list. |
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* try to delete sessions only if the lowest lifetime is expired. |
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* store the sessions in a hash indexed by id again. |
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FOR VERSION 1.0 |
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