# Scheduling Algorithm with limitations

Thanks to user3125280, D.W. and Evgeny Kluev the question is updated.

I have a list of webpages and I must download them frequently, each webpage got a different download frequency. Based on this frequency we group the webpages in 5 groups:

``````Items in group 1 are downloaded once per 1 hour
items in group 2 once per 2 hours
items in group 3 once per 4 hours
items in group 4 once per 12 hours
items in group 5 once per 24 hours
``````

This means, we must download all the group 1 webpages in 1 hour, all the group 2 in 2 hours etc.

I am trying to make an algorithm. As input, I have:

a) `DATA_ARR` = one array with 5 numbers. Each number represents the number of items in this group.

b) `TIME_ARR` = one array with 5 numbers (1, 2, 4, 12, 24) representing how often the items will be downloaded.

b) `X` = the total number of webpages to download per hour. This is calculated using items_in_group/download_frequently and rounded upwards. `If we have 15 items in group 5, and 3 items in group 4, this will be 15/24 + 3/12 = 0.875 and rounded is 1.`

Every hour my program must download at max `X` sites. I expect the algorithm to output something like:

``````Hour 1: A1 B0 C4 D5
Hour 2: A2 B1 C2 D2
...
``````

A1 = 2nd item of 1st group
C0 = 1st item of 3rd group

My algorithm must be as efficient as possible. This means:

a) the pattern must be extendable to at least 200+ hours
b) no need to create a repeatable pattern
c) spaces are needed when possible in order to use the absolute minimum bandwidth
d) never ever download an item more often than the update frequency, no exceptions

Example:

``````group 1: 0 items | once per 1 hour
group 2: 3 items | once per 2 hours
group 3: 4 items | once per 4 hours
group 4: 0 items | once per 12 hours
group 5: 0 items | once per 24 hours
``````

We calculate the number of items we can take per hour: `3/2+4/4 = 2.5. We round this upwards and it's 3.`

Using pencil and paper, we can found the following solution:

``````Hour 1: B0 C0 B1
Hour 2: B2 C1 c2
Hour 3: B0 C3 B1
Hour 4: B2
Hour 5: B0 C0 B1
Hour 6: B2 C1 c2
Hour 7: B0 C3 B1
Hour 8: B2
Hour 9: B0 C0 B1
Hour 10: B2 C1 c2
Hour 11: B0 C3 B1
Hour 12: B2
Hour 13: B0 C0 B1
Hour 14: B2 C1 c2
and continue the above.
``````

We take `C0`, `C1` `C2`, and `C3` once every 4 hours. We also take `B0`, `B1` and `B2` once every 2 hours.

Question: Please, explain to me, how to design an algorithm able to download the items, while using the absolute minimum number of downloads? Brute force is NOT a solution and the algorithm must be efficient CPU wise because the number of elements can be huge.

You may read the answer posted here: https://cs.stackexchange.com/a/19422/12497 as well as the answer posted bellow by user3125280.

• Better, lets call this a c++ question however and remove the tags for all the other languages. Dec 30, 2013 at 4:33
• What is your exact question? Dec 30, 2013 at 4:33
• @paqogomez I see no c++; I removed everything but 'c', gah, missed the std cout Dec 30, 2013 at 4:34
• You should not re-post a deleted question, you should make an effort to fix the previous post, only 10k+ user can actually view it though. Dec 30, 2013 at 4:34
• I added more tags in order to be viewed by more people as i understand and can write code in all languages I tagged. cout is c++ also. Anyway, I am new so I will listen to the seniors here. @Digital_Reality: In the given 'refresh time' we must take at least once each item from that group. you can run my code on codepad.org and see. This will help you understand more.
– Luka
Dec 30, 2013 at 4:36

You problem is a typical scheduling problem. These kinds of problems are well studied in computer science so there is a huge array of literature to consult.

The code is kind of like Deficit round robin, but with a few simplifications. First, we feed the queues ourself by adding to the `data_to_process` variable. Secondly, the queues just iterate through a list of values.

One difference is that this solution will get the optimal value you want, barring mathematical error.

Rough sketch: have not compiled (c++11) unix based, to spec code

``````#include <iostream>
#include <vector>
#include <numeric>
#include <unistd.h>
//#include <cmath> //for ceil

#define TIME_SCALE ((double)60.0) //1 for realtime speed

//Assuming you are not refreshing ints in the real case
template<typename T>
struct queue
{
const std::vector<T> data; //this will be filled with numbers
int position;

double refresh_rate; //must be refreshed ever ~ hours
double data_rate; //this many refreshes per hour
double credit; //amount of refreshes owed

queue(std::initializer_list<T> v, int r ) :
data(v), position(0), refresh_rate(r), credit(0) {
data_rate = data.size() / (double) refresh_rate;
}

int getNext() {
return data[position++ % data.size()];
}
};

double time_passed(){
static double total;
//if(total < 20){ //stop early
usleep(60000000 / TIME_SCALE); //sleep for a minute
total += 1.0 / 60.0; //add a minute
std::cout << "Time: " << total << std::endl;
return 1.0; //change to 1.0 / 60.0 for real time speed
//} else return 0;
}

int main()
{
//keep a list of the queues
std::vector<queue<int> > queues{
{{1, 2, 3}, 2},
{{1, 2, 3, 4}, 3}};

double total_data_rate = 0;
for(auto q : queues) total_data_rate += q.data_rate;

double data_to_process = 0; //how many refreshes we have to do
int queue_number = 0; //which queue we are processing

auto current_queue = &queues[0];

while(1) {
data_to_process += time_passed() * total_data_rate;
//data_to_process = ceil(data_to_process) //optional

while(data_to_process >= 1){
//data_to_process >= 0 will make the the scheduler more
//eager in the first time period (ie. everything will updated correctly
//in the first period and and following periods
if(current_queue->credit >= 1){
//don't change here though, since credit determines the weighting only,
//not how many refreshes are made
//refresh(current_queue.getNext();
std::cout << "From queue " << queue_number << " refreshed " <<
current_queue->getNext() << std::endl;
current_queue->credit -= 1;
data_to_process -= 1;
} else {
queue_number = (queue_number + 1) % queues.size();
current_queue = &queues[queue_number];
current_queue->credit += current_queue->data_rate;
}
}
}
return 0;
}
``````

The example should now compile on gcc with --std=c++11 and give you what you want.

and here is test case output: (for non-time scaled earlier code)

``````Time: 0
From queue 1 refreshed 1
From queue 0 refreshed 1
From queue 1 refreshed 2
Time: 1
From queue 0 refreshed 2
From queue 0 refreshed 3
From queue 1 refreshed 3
Time: 2
From queue 0 refreshed 1
From queue 1 refreshed 4
From queue 1 refreshed 1
Time: 3
From queue 0 refreshed 2
From queue 0 refreshed 3
From queue 1 refreshed 2
Time: 4
From queue 0 refreshed 1
From queue 1 refreshed 3
From queue 0 refreshed 2
Time: 5
From queue 0 refreshed 3
From queue 1 refreshed 4
From queue 1 refreshed 1
``````

As an extension, to answer the repeating pattern problem by allowing this scheduler to complete only the first lcm(update_rate * lcm(...refresh rates...), ceil(update_rate)) steps, and then repeating the pattern.

ALSO: this will, indeed, be unsolvable sometimes because of the requirement on hour boundaries. When I use your unsolvable example, and modify time_passed to return 0.1, the schedule is solved with updates every 1.1 hours (just not at the hour boundaries!).

• Hey, thanks for pointing this out. It's close to my problem. Can you find any source explaining how this works?
– Luka
Dec 30, 2013 at 5:16
• in this case, it's probably easy enough to work out how many must be extracted from each list per unit time, and then do the extracting at the start of each time unit (hour/second/whatever). I suggested the scheduling analogy since things seemed a little simplified and scheduling could help with more complicated cases Dec 30, 2013 at 5:20
• What you say is correct but really not enough to solve the puzzle.
– Luka
Dec 30, 2013 at 7:55
• My algorithm shares a few things with weighted fair queuing but there are differences also. All in all, reading those very few sites in the web regarding the subject doesn't help me solve this.
– Luka
Dec 30, 2013 at 13:12
• @Luka i wrote some code before, i'll post it in a couple of minutes Dec 30, 2013 at 13:14

It seems your constraints are all over the place. To quickly summarise my other answer:

• It meets the refresh rates only on average
• It does the least number of downloads at hour intervals required to fulfil the above

It was based on these (sometimes unfulfillable) constraints

1. Update at discrete, 1 hour intervals
2. Update the fewest items each time
3. Update each item at fixed intervals

and broke 3.

Since both the hourly interval and least-each-time constraints are not really necessary, I will give a simpler, better answer here, which breaks 2.

``````#include <iostream>
#include <vector>
#include <numeric>
#include <unistd.h>

#define TIME_SCALE ((double)60.0)

//Assuming you are not refreshing ints in the real case
template<typename T>
struct queue
{
const std::vector<T> data; //this is the data to refresh
int position; //this is the data we are up to
double refresh_rate; //must be refreshed every this many hours
double data_rate; //this many refreshes per hour
double credit; //is owed this many refreshes
const char* name;//a name for each queue

queue(std::initializer_list<T> v, int r, const char* n ) :
data(v), position(0), refresh_rate(r), credit(0), name(n) {
data_rate = data.size() / (double) refresh_rate;
}

void refresh() {
std::cout << "From queue " << name << " refreshed " << data[position++ % data.size()] << "\n";
}
};

double time_passed(){
static double total;
usleep(60000000 / TIME_SCALE); //sleep for a minute
total += 1.0; //add a minute
std::cout << "Time: " << total << std::endl;
return 1.0; //change to 1.0 / 60.0 for real time speed
}

int main()
{
//keep a list of the queues
std::vector<queue<int> > queues{
{{1}, 1, "A"},
{{1}, 2, "B"}};

while(1) {
auto t = time_passed();
for(queue<int>& q : queues) {
q.credit += q.data_rate * t;
while(q.credit >= 1){
q.refresh();
q.credit -= 1.0;
}
}
}
return 0;
}
``````

It has the potential, however, to schedule many refreshes on the same hour. There is a third option as well, which breaks the hour-interval rule and updates only one at a time.

I think this is the easiest and requires the minimal number of updates (like the previous answer) but doesn't break rule 3.