A good approach to solving this problem is to first write the code required to get one result, then incorporate threading code to parallelize the application.
In a perfect world this would simply mean simultaneously starting 100,000 threads which output their results into a dictionary or list for later processing, but in practice you are limited in how many parallel HTTP requests you can issue in this fashion. Locally, you have limits in how many sockets you can open concurrently, how many threads of execution your Python interpreter will allow. Remotely, you may be limited in the number of simultaneous connections if all the requests are against one server, or many. These limitations will probably necessitate that you write the script in such a way as to only poll a small fraction of the URLs at any one time (100, as another poster mentioned, is probably a decent thread pool size, although you may find that you can successfully deploy many more).
You can follow this design pattern to resolve the above issue:
- Start a thread which launches new request threads until the number of currently running threads (you can track them via threading.active_count() or by pushing the thread objects into a data structure) is >= your maximum number of simultaneous requests (say 100), then sleeps for a short timeout. This thread should terminate when there is are no more URLs to process. Thus, the thread will keep waking up, launching new threads, and sleeping until your are finished.
- Have the request threads store their results in some data structure for later retrieval and output. If the structure you are storing the results in is a
dict in CPython, you can safely append or insert unique items from your threads without locks, but if you write to a file or require in more complex cross-thread data interaction you should use a mutual exclusion lock to protect this state from corruption.
I would suggest you use the threading module. You can use it to launch and track running threads. Python's threading support is bare, but the description of your problem suggests that it is completely sufficient for your needs.
Finally, if you'd like to see a pretty straightforward application of a parallel network application written in Python, check out ssh.py. It's a small library which uses Python threading to parallelize many SSH connections. The design is close enough to your requirements that you may find it to be a good resource.