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I need to cap the number of events n permitted during a time period deltaT. Any approach I can think of, space is O(m), where m is the maximum number of eventrequests sent per deltaT, or O(deltaT/r), where r is an acceptable resolution.

Edit: deltaT is a sliding time window relative to the timestamp.

For instance: Keep a circular buffer of event timestamps. On event crop all earlier timestamps than t-deltaT. Deny event if the number of timestamps exceeds n. Add timestamp to the buffer.

Or, init a circular bucket buffer of integers of size deltaT/r indexed by time relative to the current with resolution r. Maintain pointer i. On event, increment i by time since last event divided by r. Zero the buffer between the original i and the new one. Increment at i. Deny, if the sum of the bugger exceeds n.

What's a better way?


I just implemented my second suggestion above in c# with a fixed deltaT of 1 s and a fixed resolution of 10 ms.

public class EventCap
{
    private const int RES = 10; //resolution in ms

    private int _max;
    private readonly int[] _tsBuffer;
    private int p = 0;
    private DateTime? _lastEventTime;
    private int _length = 1000 / RES;

    public EventCap(int max)
    {
        _max = max;

        _tsBuffer = new int[_length];
    }

    public EventCap()
    {
    }

    public bool Request(DateTime timeStamp)
    {
        if (_max <= 0)
            return true;

        if (!_lastEventTime.HasValue)
        {
            _lastEventTime = timeStamp;
            _tsBuffer[0] = 1;
            return true;
        }

        //A
        //Mutually redundant with B
        if (timeStamp - _lastEventTime >= TimeSpan.FromSeconds(1))
        {
            _lastEventTime = timeStamp;
            Array.Clear(_tsBuffer, 0, _length);
            _tsBuffer[0] = 1;
            p = 0;
            return true;
        }

        var newP = (timeStamp - _lastEventTime.Value).Milliseconds / RES + p;

        if (newP < _length)
            Array.Clear(_tsBuffer, p + 1, newP - p);

        else if (newP > p + _length)
        {
            //B
            //Mutually redundant with A
            Array.Clear(_tsBuffer, 0, _length);
        }
        else
        {
            Array.Clear(_tsBuffer, p + 1, _length - p - 1);
            Array.Clear(_tsBuffer, 0, newP % _length);
        }

        p = newP % _length;
        _tsBuffer[p]++;
        _lastEventTime = timeStamp;

        var sum = _tsBuffer.Sum();

        return sum <= 10;
    }
}
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i want that too..thanks for asking :) –  FUD Sep 21 '12 at 13:25
    
is deltaT a sliding window? meaning for every chosen deltaT you want a max of n events, or the deltaT is one after the other. –  Yarneo Sep 21 '12 at 13:30
    
yes, sliding. @FUD, till we get an answer, check below, might work for you. –  Martin Sep 21 '12 at 13:46
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3 Answers

up vote 5 down vote accepted

What about having these variables: num_events_allowed, time_before, time_now, time_passed

At init time you will do: time_before = system.timer(), num_events_allowed = n

When an event is received you do the following:

  time_now = system.timer()
  time_passed = time_now - time_before
  time_before = time_now

  num_events_allowed += time_passed * (n / deltaT);

  if num_events_allowed > n 
      num_events_allowed = n

  if num_events_allowed >= 1
      let event through, num_events_allowed -= 1
  else
      ignore event

Whats nice about this algorithm is the num_events_allowed is actually incremented by the time that has passed since the last event and the rate of which events can be received, that way you get an incrementation of the number of events you can send per that time_passed in order to stay in the limit of n. So if you get an event too soon, you will increment it by less than 1, if its after too much time you will increment it by more than one. Of course if the event goes through you decrement the allowance by 1 as you just got an event. If the allowance passes the max events which is n , you return it back to n as you cant allow more than n in any time phase. If the allowance is less than 1, you cant send a whole event, dont let it through!

share|improve this answer
    
In practice it'll work great, for most cases. It will be a bit too strict on bursty eventuell won't it? –  Martin Sep 22 '12 at 8:40
    
Hey @Martin, Well if you want exactly max of n events then it will be a good algorithm, if you want approximately n then it would be too strict as you could probably find something more loose, like having a function check periodically and not for every incoming event. But overall its good because its done in O(1) time and O(1) space. It is only important to keep the function synchronised because if 2 events accidentally enter at the same time the time_passed and num_events_allowed could be used by both events and cause problems –  Yarneo Sep 22 '12 at 10:27
    
Ah, I see now. This is actually very good. I'll try it. –  Martin Sep 23 '12 at 21:17
1  
Works charmingly! –  Martin Sep 23 '12 at 21:57
    
Found that I had solved this in almost exactly this way, two years ago. I was smarter then. :( –  Martin Sep 27 '12 at 6:26
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While reading about the various possible solutions to the problem. I came across token bucket algorithm ( http://en.wikipedia.org/wiki/Token_bucket ). If i understand your question completely you can implement a token bucket algorithm without actually having a bucket with N tokens by instead taking an counter which can be incremented and decremented accordingly. like

syncronized def get_token = 
    if count>0 
       { --count, return true }
    else return false

syncronized def add_token = 
    if count==N
       return;
    else ++count

Now the remaining part is to call the add_token in deltaT/r time repetadly.

To make it completely threadsafe we would need an atomic reference to count. But the above code is to show basic idea of doing it in O(1) memory.

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From what I can tell this is the same idea as Yarneo's except his implementation adds the appropriate number of tokens on event. –  Martin Sep 23 '12 at 21:16
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One way to keep the sliding window and still have it O(1) + very small O(n) for each incoming request is to make a suitable sized array of ints and keep it as a circular buffer and discretize incoming requests (the requests as integrated as with the sampled levels as in a A/D-converter, or as a histogram if you are a statistican) and keep track of the sum of the circular buffer, like this

assumptions: 
"there can be no more than 1000 request per minute" and 
"we discretize on every second"

int[] buffer = new zeroed int-array with 60 zeroes
int request-integrator = 0 (transactional)
int discretizer-integrator = 0 (transactional)

for each request:
    check if request-integrator < 1000 then
         // the following incs could be placed outside 
         // the if statement for saturation on to many
         // requests (punishment)
         request-integrator++                     // important
         discretizer-integrator++
         proceed with request

once every second:                    // in a transactional memory transaction, for God's saké 
    buffer-index++
    if (buffer-index = 60) then buffer-index=0    // for that circular buffer feeling!
    request-integrator -= buffer[buffer-index]    // clean for things happening one minute ago
    buffer[buffer-index] = discretizer-integrator // save this times value
    discretizer-integrator = 0                    // resetting for next sampling period

Note that the increase of the request-integrator "could" be done just once every second, but that leaves a hole open for saturating it with 1000 requests or worse in one second about once every minute depending on punishment behaviour.

share|improve this answer
    
and! you could of course have a second-based limit as well (ie 50 req/s), just add an or-block in the if-statement for request. –  claj Sep 26 '12 at 23:10
    
Interesting, it's a combination of my code above (discretization) and the token buffer suggested by FUD, isn't it? –  Martin Sep 27 '12 at 6:31
    
I guess, this one is inspired by the implementation of a digital low pass filter. I also guess you could make a 1/dT-summation as Yameo above, which is my solution but for events happening at special times - that one is actually the best, since it's smaller and as exact. Head for Yameos solution, mine is less elegant. –  claj Sep 27 '12 at 16:27
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