Talk:COMP 3000 Essay 1 2010 Question 5: Difference between revisions

From Soma-notes
Sschnei1 (talk | contribs)
Sschnei1 (talk | contribs)
Line 101: Line 101:


In Linux 1.2 a scheduler operated with a round robin policy using a circular queue, allowing the scheduler to be  
In Linux 1.2 a scheduler operated with a round robin policy using a circular queue, allowing the scheduler to be  
efficient in adding and removing processes.[http://www.ibm.com/developerworks/linux/library/l-completely-fair-scheduler/index.html] When Linux 2.2 was introduced, the scheduler was changed. It now used the idea  
efficient in adding and removing processes. When Linux 2.2 was introduced, the scheduler was changed. It now used the idea  
of scheduling classes, thus allowing it to schedule real-time tasks, non real-time tasks, and non-preemptible tasks. It was  
of scheduling classes, thus allowing it to schedule real-time tasks, non real-time tasks, and non-preemptible tasks. It was  
the first scheduler which supported SMP.
the first scheduler which supported SMP.


With the introduction of Linux 2.4, the scheduler was changed again. The scheduler started to be more complex than its  
With the introduction of Linux 2.4, the scheduler was changed again. The scheduler started to be more complex than its  
predecessors, but it also has more features.[http://www.ibm.com/developerworks/linux/library/l-completely-fair-scheduler/index.html] The running time was O(n) because it iterated over each task during a  
predecessors, but it also has more features. The running time was O(n) because it iterated over each task during a  
scheduling event. The scheduler divided tasks into epochs, allowing each tasks to execute up to its time slice. If a task  
scheduling event. The scheduler divided tasks into epochs, allowing each tasks to execute up to its time slice. If a task  
did not use up all of its time slice, the remaining time was added to the next time slice to allow the task to execute  
did not use up all of its time slice, the remaining time was added to the next time slice to allow the task to execute  
Line 114: Line 114:


Linux-2.6 introduced another scheduler up to Linux 2.6.23. Before Linux 2.6.23 an O(1) scheduler was used. It needed the  
Linux-2.6 introduced another scheduler up to Linux 2.6.23. Before Linux 2.6.23 an O(1) scheduler was used. It needed the  
same amount of time for each task to execute, independent of how big the tasks were.[http://www.ibm.com/developerworks/linux/library/l-completely-fair-scheduler/index.html] It kept track of the tasks in a  
same amount of time for each task to execute, independent of how big the tasks were.It kept track of the tasks in a  
running queue. The scheduler offered much more scalability. To determine if a task was I/O bound or processor bound the  
running queue. The scheduler offered much more scalability. To determine if a task was I/O bound or processor bound the  
scheduler used interactive metrics with numerous heuristics. Because the code was difficult to manage and the most part of  
scheduler used interactive metrics with numerous heuristics. Because the code was difficult to manage and the most part of  
Line 132: Line 132:
scheduler then accounts execution time at the CPU and adds it to the virtual runtime. If runnable the task then is inserted  
scheduler then accounts execution time at the CPU and adds it to the virtual runtime. If runnable the task then is inserted  
into the red-black tree. This means  tasks on the left side are given time to execute, while the contents on the right side  
into the red-black tree. This means  tasks on the left side are given time to execute, while the contents on the right side  
of the tree are migrated to the left side to maintain fairness.  
of the tree are migrated to the left side to maintain fairness. [http://www.ibm.com/developerworks/linux/library/l-completely-fair-scheduler/index.html]





Revision as of 14:34, 13 October 2010

Discussion

From what I have been reading the early versions of the Linux scheduler had a very hard time managing high numbers of tasks at the same time. Although I do not how it ran, the scheduler algorithm operated at O(n) time. As a result as more tasks were added, the scheduler would become slower. In addition to this, a single data structure was used to manage all processors of a system which created a problem with managing cached memory between processors. The Linux 2.6 scheduler was built to resolve the task management issues in O(1), constant, time as well as addressing the multiprocessing issues.

It appears as though BSD also had issues with task management however for BSD this was due to a locking mechanism that only allowed one process at a time to operate in kernel mode. FreeBSD 5 changed this locking mechanism to allow multiple processes the ability to run in kernel mode at the same time advancing the success of symmetric multiprocessing.

--Mike Preston 18:38, 3 October 2010 (UTC)


Hi Mike, Can you give any names for the schedulers you are talking about? I think it is easier to distinguish by names and not by the algorithm. It is just a suggestion!

The O(1) scheduler was replaced in the linux kernel 2.6.23 with the CFS (completly fair scheduler) which runs in O(log n). Also, the schedulers before CFS were based on a Multilevel feedback queue algorithm, which was changed in 2.6.23. It is not based on a queue as most schedulers, but on a red-black-tree to implement a timeline to make future predictions. The aim of CFS is to maximize CPU utilization and maximizing the performance at the same time.

In FreeBSD 5, the ULE Scheduler was introduced but disabled by default in the early versions, which eventually changed later on. ULE has better support for SMP and SMT, thus allowing it to improve overall performance in uniprocessors and multiprocessors. And it has a constant execution time, regardless of the amount of threads.

More information can be found here:
http://lwn.net/Articles/230574/
http://lwn.net/Articles/240474/

Sschnei1 16:33, 3 October 2010 (UTC) or Sebastian


Here is another article which essentially backs up what you are saying Sebastian: http://delivery.acm.org/10.1145/1040000/1035622/p58-mckusick.pdf?key1=1035622&key2=8828216821&coll=GUIDE&dl=GUIDE&CFID=104236685&CFTOKEN=84340156

Here are the highlights from the article:

General FreeBSD knowledge:

     1. requires a scheduler to be selected at the time the kernel is built.
     2. all calls to scheduling code are resolved at compile time...this means that the overhead of indirect function calls for scheduling decisions is eliminated.
     3. kernels up to FreeBSD 5.1 used this scheduler, but from 5.2 onward the ULE scheduler used.

Original FreeBSD Scheduler:

     1.  threads assigned a scheduling priority which determines which 'run queue' the thread is placed in.
     2.  the system scans the run queues in order of highest priority to lowest priority and executes the first thread of the first non-empty run queue it finds.
     3.  once a non-empty queue is found the system spends an equal time slice on each thread in the run queue. This time slice is 0.1 seconds and this value has not changed in over 20 years. A shorter time slice would cause overhead due to switching between threads too often thus reducing productivity.
     4.  the article then provides detailed formulae on how to determine thread priority which is out of our scope for this project.

ULE Scheduler - overhaul of Original BSD scheduler to:

      1. support symmetric multiprocessing (SMP)
      2. support symmetric multithreading (SMT) on multi-core systems
      3. improve the scheduler algorithm to ensure execution is no longer limited by the number of threads in the system.



Here is another article which gives some great overview of a bunch of versions/the evolution of different schedulers: https://www.usenix.org/events/bsdcon03/tech/full_papers/roberson/roberson.pdf
Some interesting pieces about the Linux scheduler include:

     1. The Jan 2002 version included O(1) algorithm as well as additions for SMP.
     2. Scheduler uses 2 priority queue arrays to achieve fairness. Does this by giving each thread a time slice and a priority and executes each thread in order of highest priority to lowest. Threads that exhaust their time slice are moved to the exhausted queue and threads with remaining time slices are kept in the active queue.
     3. Time slices are DYNAMIC, larger time slices are given to higher priority tasks, smaller slices to lower priority tasks.


I thought the dynamic time slice piece was of particular interest as you would think this would lead to starvation situations if the priority was high enough on one or multiple threads. --Mike Preston 18:38, 3 October 2010 (UTC)

This is essentially a summarized version of the aforementioned information regarding CFS (http://www.ibm.com/developerworks/linux/library/l-scheduler/). --AbsMechanik 02:32, 4 October 2010 (UTC)


I have seen this website and thought it is useful. Do you think this is enough on research to write an essay or are we going to do some more research? --Sschnei1 09:38, 5 October 2010 (UTC)

I also stumbled upon this website: http://my.opera.com/blu3c4t/blog/show.dml/1531517. It explains a lot of stuff in layman's terms (I had a lot of trouble finding more info on the default BSD scheduler, but this link has some brief description included in it). I think we have enough resources/research done. We should start to formulate these results into an answer now. --AbsMechanik 20:08, 4 October 2010 (UTC)


So I thought I would take a first crack at an intro for our article, please tell me what you think of the following. Note that I have included the resource used as a footnote, the placement of which I indicate with the number 1, and I just tacked the details of the footnote on at the bottom:

See Essay preview section!

--Mike Preston 02:54, 6 October 2010 (UTC)

I added a part to introduce the several schedulers for LINUX. We might need to change the reference, since I got it all from http://www.ibm.com/developerworks/linux/library/l-completely-fair-scheduler/index.html

-- Sschnei1 19:27, 9 October 2010 (UTC)

Maybe we should write down our contact emails and names to write down who would like to write what part.

Sebastian Schneider - sebastian@gamersblog.ca

Essay Preview

So just a small, quick question. Are we going to follow a certain standard for citing resources (bibliography & footnotes) to maintain consistency, or do we just stick with what Mike's presented?--AbsMechanik 12:53, 7 October 2010 (UTC)

Maybe we should write the essay templates/prototypes here, to keep overview of the discussion part.

Just relocating previous post with suggested intro paragraph:

One of the most difficult problems that operating systems must handle is process management. In order to ensure that a system will run efficiently, processes must be maintained, prioritized, categorized and communicated with all without experiencing critical errors such as race conditions or process starvation. A critical component in the management of such issues is the operating system’s scheduler. The goal of a scheduler is to ensure that all processes of a computer system get access to the system resources they require as efficiently as possible while maintaining fairness for each process, limiting CPU wait times, and maximizing the throughput of the system.1 As computer hardware has increased in complexity, for example multiple core CPUs, schedulers of operating systems have similarly evolved to handle these additional challenges. In this article we will compare and contrast the evolution of two such schedulers; the default BSD/FreeBSD and Linux schedulers.

1 Jensen, Douglas E., C. Douglass Locke and Hideyuki Tokuda, A Time-Driven Scheduling Model for Real-Time Operating Systems, Carnegie-Mellon University, 1985.

--Mike Preston 03:48, 7 October 2010 (UTC)


In Linux 1.2 a scheduler operated with a round robin policy using a circular queue, allowing the scheduler to be efficient in adding and removing processes. When Linux 2.2 was introduced, the scheduler was changed. It now used the idea of scheduling classes, thus allowing it to schedule real-time tasks, non real-time tasks, and non-preemptible tasks. It was the first scheduler which supported SMP.

With the introduction of Linux 2.4, the scheduler was changed again. The scheduler started to be more complex than its predecessors, but it also has more features. The running time was O(n) because it iterated over each task during a scheduling event. The scheduler divided tasks into epochs, allowing each tasks to execute up to its time slice. If a task did not use up all of its time slice, the remaining time was added to the next time slice to allow the task to execute longer in its next epoch. The scheduler simply iterated over all tasks, which made it inefficient, low in scalability and did not have a useful support for real-time systems. On top of that, it did not have features to exploit new hardware architectures, such as multi-core processors.

Linux-2.6 introduced another scheduler up to Linux 2.6.23. Before Linux 2.6.23 an O(1) scheduler was used. It needed the same amount of time for each task to execute, independent of how big the tasks were.It kept track of the tasks in a running queue. The scheduler offered much more scalability. To determine if a task was I/O bound or processor bound the scheduler used interactive metrics with numerous heuristics. Because the code was difficult to manage and the most part of the code was to calculate heuristics, it was replaced in Linux 2.6.23 with the CFS scheduler, which is the current scheduler in the actual Linux versions.

As of the Linux 2.6.23 introduction the CFS scheduler took its place in the kernel. CFS uses the idea of maintaining fairness in providing processor time to tasks, which means each tasks gets a fair amount of time to run on the processor. When the time task is out of balance, it means the tasks has to be given more time because the scheduler has to keep fairness. To determine the balance, the CFS maintains the amount of time given to a task, which is called a virtual runtime.

The model how the CFS executes has changed, too. The scheduler now runs a time-ordered red-black tree. It is self-balancing and runs in O(log n) where n is the amount of nodes in the tree, allowing the scheduler to add and erase tasks efficiently. Tasks with the most need of processor are stored in the left side of the tree. Therefore, tasks with a lower need of cpu are stored in the right side of the tree. To keep fairness the scheduler takes the left most node from the tree. The scheduler then accounts execution time at the CPU and adds it to the virtual runtime. If runnable the task then is inserted into the red-black tree. This means tasks on the left side are given time to execute, while the contents on the right side of the tree are migrated to the left side to maintain fairness. [1]


-- Sschnei1 19:26, 9 October 2010 (UTC)



I've started writing a bit about the Linux O(1) scheduler:

Under a Linux system, scheduling can be handled manually by the user by assigning programs different priority levels, called "nice levels." Put simply, the higher a program's nice level is, the nicer it will be about sharing system resources. A program with a lower nice level will be more greedy, and a program with a higher nice level will more readily give up its CPU time to other, more important programs. This spectrum is not linear; programs with high negative nice levels run significantly faster than those with high positive nice levels. The Linux scheduler accomplishes this by sharing CPU usage in terms of time slices (also called quanta), which refer to the length of time a program can use the CPU before being forced to give it up. High-priority programs get much larger time slices, allowing them to use the CPU more often and for longer periods of time than programs with lower priority. Users can adjust the niceness of a program using the shell command nice( ). Nice values can range from -20 to +19.

In previous versions of Linux, the scheduler was dependent on the clock speed of the processor. While this dependency was an effective way of dividing up time slices, it made it impossible for the Linux developers to fine-tune their scheduler to perfection. In recent releases, specific nice levels are assigned fixed-size time slices instead. This keeps nice programs from trying to muscle in on the CPU time of less nice programs, and also stops the less nice programs from stealing more time than they deserve.[2]

In addition to this fixed style of time slice allocation, Linux schedulers also have a more dynamic feature which causes them to monitor all active programs. If a program has been waiting an abnormally long time to use the processor, it will be given a temporary increase in priority to compensate. Similarly, if a program has been hogging CPU time, it will temporarily be given a lower priority rating.[3]

-- Austin Bondio Last edit: 14:39, 12 October 2010

Sources

[1] http://www.mjmwired.net/kernel/Documentation/scheduler/sched-nice-design.txt

[2] http://oreilly.com/catalog/linuxkernel/chapter/ch10.html#94726