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Question: Design a system for showing quotes on the web. For example, when the user is looking at page A, part of which is reproduced in page B, the system could highlight part of page A present the user with a link to page B. This is an open-ended system design question.

What constitutes a quote? How do you find quotes? How do you make it scale to the web? How do you handle updates? How would you arrange the servers? What data structures would you use? How much storage would you need? How would the user agent present information about quotes?

So I was rejected at an interview because I wasn't able to give all expected pointers for designing a large scale system. I'm appearing for another interview and have tried a lot to improve my system design skills. This is a sample response for the question given above.

I know this question might be too localized or something but it'll be very very helpful for me if you could help me out here. Please help me work on the flaws so I can crack my next interview.

My approach:

1) Data Model I'll have 2 hash maps:

  • Based on source page address as key
  • Destination page as key.
  • For both maps value will be position in a vector which will contain pointer to struct.

    struct quote { string src; // Links string dest; // Links string src_element; // We can have div, p etc int src_id; // Id of element on source page i.e. to be quoted string dest_element; // We can have div, p etc int dest_id; // Id of element on source page i.e. to be quoted };

    unordered_map srcMap; unordered_map destMap;

2) Operations supported will be:

- void insertQuote(string src, string dest ...)    // properties to be added to our struct
- string fetchQuotedString(string dest, string element, int id); 
- string fetchDestPage(string src, string element, int id);

Hash can be calculated on complete web address which might look like: "http://www.blah.com&type=id"

3) Execution

  • Client sends insertquote request to server.
  • Insertion can be an asynchronous event, which returns with a success error code and lazily updates the data structures.

4) Complexity

  • Since we're using hash maps and simply appending a new node to end of a STL list, our time complexity for each operation will be O(1).

5) Write to Disks We can keep a threshold for time or for size of data in memory after which contents can be dumped to the disk. (These will basically be serial writes)

6) Concurrency

  • Read operation

    • For displaying page A, whose text is quoted we'll have to invoke fetchDestPage(...) and for displaying page B, we'll invoke fetchQuotedString(...)
    • For read, we can use reader-writer locking mechanism on the maps. If no writer is updating the corresponding entry, reader process can fetch node value based on the type of page being displayed (hashing source or destination web address).
  • Write operation

    • As mentioned earlier, insertion can be asynchronous in nature. Once a client invokes insertQuote(...), preforked server process can record the invocation and return a success code to the caller.
    • Each process update the List of nodes and receive an iterator. In order to insert entry to the maps, the process has to wait to acquire locks on the hashed positions and once received can insert a new entry to each map.

7) Scalability We can distribute our hash maps to different nodes with a DHT based setup. (Caching most frequently used data). Therefore, when a server will receive request for fetching/ inserting an entry it'll:

  • Return 2xx to client
  • Hash the "web-address" and accordingly find the destination host
  • Route the message to the destination
  • Recipient node will have it's own segment of hash tables and list. We basically import all the features of DHT to share resources between number of hosts and provide better performance to the user.

9) Replication for availability

Data can be replicated on many DHT nodes, with DHT based bootstrapping and division of labor. For every write operation once a node receives a request it can be considered at the co-ordinator who'll take care of the successful commit to each replica using 2-phase commit protocol. In case of aborted transaction failure code can be returned to the client. Client is responsible for retrying.

10) Fault Tolerance

  • Again we're importing fault tolerance features from DHT. In case of faulty destination hosts, its replicas should be able to service the request.
  • If none of the replica's is able to respond we'll assume it's a cache miss and fetch data from disk.

11) Load Balancing


12) Monitoring and Alert


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closed as off topic by Michael Petrotta, Tonny Madsen, Nesim Razon, PearsonArtPhoto, stealthyninja Nov 17 '12 at 23:52

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