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Are there any good resources (books, websites) that give very good comparison of different scheduling algorithms for a Finite State Machine (FSM) in an embedded system without an OS?

I am designing a simple embedded web server without an OS. I would like to know what are the various methods used to schedule the processing of the different events that occur in the system.

For example,if two events arrived at the same time how are the events prioritized? If I assign different priorities to events, how do I ensure that the higher priority event gets processed first? If an even higher priority event comes in while an event is being processed, how can make sure that that event is processed immediately?

I'm planning on using a FSM to check various conditions upon an event's arrival and then to properly schedule the event for processing. Because the embedded web server does not have an OS, I am considering using a cyclic executive approach. But I would like to see a comparison of the pros and cons of different algorithms that could be used in this approach.

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Are you asking about a comparison of scheduling algorithms? Is there a specific reason you mention finite state machines? You state "with out OS" but tag this with "embedded-linux". So are you using an OS or not? Please clarify. –  embedded.kyle Aug 14 '12 at 13:56
    
@embedded.kyle I am not using OS. I am going to design a simple embeeded web server with out OS. No, I dont mean comparision of scheduling algorithm. I mean for example scheduling condion in like ,if two task arrived at the same time which task need to be prioritized and simillar other situations in embedded webserver. I need to have FSM for different task arrival conditions and task scheduling approach on them. Since the embeeded web-server is without OS , cyclic-exxecutive approach of scheduling need to be considered. –  josh Aug 14 '12 at 14:28
    
It is still not clear. The term "task" has a specific meaning that seems at odds with your usage, in conventional software engineering parlance, events or messages arrive and are processed by tasks, tasks themselves do not "arrive" - then become scheduled. The use of the apostrophe in "[...]scheduling condition's finite state machines [...]" implies the "FSMs belonging to the scheduling condition" which makes little sense to me - I have no idea what a "scheduling condition" is! –  Clifford Aug 14 '12 at 15:07
    
If you talk about different tasks you're implying you are using an operating system. A normal way to handle different 'tasks' without operating system is by simply super loop them. en.wikibooks.org/wiki/Embedded_Systems/Super_Loop_Architecture –  DipSwitch Aug 14 '12 at 15:15
    
If you're using an FSM to handle events, place the events in a queue (which is how they're usually handled anyway) and have the FSM pull from that queue for processing. The order that events arrive in the queue is the order they'll be 'scheduled'. Since adding events to the queue would have to be synchronized in some fashion, such as with a mutex, even events that arrive simultaneously would get processed serially. As far as your system is concerned, the events never arrive simultaneously; it would be arbitrary (and shouldn't matter) which simultaneous event 'wins' and gets processed first. –  Michael Burr Aug 14 '12 at 17:03

2 Answers 2

up vote 6 down vote accepted

You state: "I mean for example scheduling condion in like ,if two task arrived at the same time which task need to be prioritized and simillar other situations in embedded webserver."

Which I interpret as: "What is the set of rules used to determine which task gets executed first (scheduled) when multiple tasks arrive at the same time."

I used your terminology, "task" to illustrate the similarity. But Clifford is correct. The proper term should be "event" or "message".

And when you say "scheduling condition" I think you mean "set of rules that determines a schedule of events".

The definition of algorithm is: A process or set of rules to be followed in calculations or other problem-solving operations, esp. by a computer.

From a paper entitled Scheduling Algorithms:

Consider the central processing unit of a computer that must process a sequence of jobs that arrive over time. In what order should the jobs be processed in order to minimize, on average, the time that a job is in the system from arrival to completion?

Which again, sounds like what you're calling "scheduling conditions".

I bring this up because using the right words to describe what you are looking for will help us (the SO community) give you better answers. And will help you as you research further on your own.

If my interpretation of your question still isn't what you have in mind, please let me know what, in particular, I've said is wrong and I will try again. Maybe some more examples would help me better understand.

Some further reading on scheduling (which is what you asked for):

  1. A good starting point of course is the Wikipedia article on Scheduling Disciplines
  2. A bit lower level than you are looking for but still full of detailed information on scheduling is Scheduling Algorithms for High-Level Synthesis (NOTE: for whatever reason the PDF has the pages in reverse order, so start at the bottom)

An example of a priority interrupt scheduler:

Take an architecture where Priority Level 0 is the highest. Two events come in simultaneously. One with Priority 2 and another with Priority 3. The scheduling algorithm starts processing the one with Priority 2 because it has a higher priority.

While the event with Priority 2 is being processed, another event with Priority 0 comes in. The scheduler interrupts the event with Priority 2 and processes the event with Priority 0.

When it's finished processing the Priority 0 event, it returns to processing the Priority 2 event. When it's finished processing the Priority 2 event, it processes the Priority 3 event.

Finally, when it's done with processing all of the priority interrupts, it returns control to the main processing task which handles events where priority doesn't matter.

An illustration:

priority interrupt timing

In the above image, the "task" is the super loop which DipSwitch mentioned or the infinite loop in main() that occurs in a cyclic executive which you mentioned. The "events" are the various routines that are run in the super loop or interrupts as seen above if they require prioritization.

Terms to search for are Priority Interrupt and Control Flow. Some good reading material is the Toppers Kernel Spec (where I got the image from), the ARM Interrupt Architecture, and a paper on the 80196 Interrupt Architecture.

I mention the Toppers Kernel Spec just because that's where I got the image from. But at the heart of any real-time OS is it's scheduling algorithm and interrupt architecture.

The "on event" processing you ask about would be handled by the microprocessor/microcontroller interrupt subsystem. How you structure the priority levels and how you handle non-priority events is what makes up the totality of your scheduling algorithm.

An example of a cooperative scheduler:

typedef struct {
    void   (*task)(void); // Pointer to the task function.
    uint32_t period;      // Period to execute with.
    uint32_t delay;       // Delay before first call.
} task_type;

volatile uint32_t elapsed_ticks = 0;
task_type tasks[NUM_TASKS];

void Dispatch_Tasks(void)
{
    Disable_Interrupts();
    while (elapsed_ticks > 0) { // TRUE only if the ISR ran.
        for (uint32_t i = 0; i < NUM_TASKS; i++) {
            if (--tasks[i].delay == 0) {
                tasks[i].delay = tasks[i].period;

                Enable_Interrupts();
                tasks[i].task(); // Execute the task!
                Disable_Interrupts();
            }
        }
        --elapsed_ticks;
    }
    Enable_Interrupts();
}

// Count the number of ticks yet to be processed.
void Timer_ISR(void)
{
    ++elapsed_ticks;
}

The above example was take from a blog post entitled "Simple Co-Operative Scheduling".

A cooperative scheduler is a combination of a super loop and a timer interrupt. From Section 2.4 in NON-BLOCKING HARDWARE CODING FOR EMBEDDED SYSTEMS:

A Cooperative scheduler is essentially a combination of the two previously discussed schedulers. One timer is set to interrupt at a regular interval, which will be the minimum time resolution for the different tasks. Each task is then assigned a period that is a multiple of the minimum resolution of the interrupt interval. A function is then constantly called to update the interrupt count for each task and run tasks that have reached their interrupt period. This results in a scheduler that has the scalability of the Superloop with the timing reliability of the Time Triggered scheduler. This is a commonly used scheduler for sensor systems. However, this type of scheduler is not without its limitations. It is still important that the task calls in a cooperative scheduler are short. If one task blocks longer than one timer interrupt period, a time-critical task might be missed.

And for a more in depth analysis, here is a paper from the International Journal of Electrical & Computer Sciences.

Preemptive versus Cooperative:

A cooperative scheduler cannot handle asynchronous events without some sort of a preemption algorithm running on top of it. An example of this would be a multilevel queue architecture. Some discussion on this can be found in this paper on CPU Scheduling. There are, of course, pros and cons to each. A few of which are described in this short article on the RTKernel-32.

As for "any specific type preemptive scheduling scheduling process that can satisfy priority based task scheduling (like in the graph)", any priority based interrupt controller is inherently preemptive. If you schedule one task per interrupt, it will execute as shown in the graph.

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@embedded.kayle yes, your interpretation is right. yes I realized that task in terms of event. Since there is no OS in the system, on event processing is not possible. So how to handle those events in mutiple cases? Like multiple event can arrive simultaneously at the same time in the system or another highest priority event arrived but the first event is still on processing and so on.And what about the cyclic-executive and super loop? are the event scheduler and task schedule two different things or they are the same things?I am a newbie can you make clear on these things?Thanks!! –  josh Aug 15 '12 at 9:09
    
See my edit for more information that should address your comment –  embedded.kyle Aug 15 '12 at 13:35
    
embedded.kayle Thank you so much for the informations. What about the Time-triggered co-operative-Super Loop scheduler? Since the required scheduling mechanism is simpler. –  josh Aug 15 '12 at 18:05
    
See new edit for cooperative scheduler example –  embedded.kyle Aug 15 '12 at 18:52
    
@embedded.kayle thank you for the quick response. Now I come to idea that to implement the graph mentioned above (according to task priority), through time driven scheduler is not possible (like above mentioned cooperative scheduler) . So to implement such kind of priority based activities, I need to go through the pre-emptive scheduling process. Is there any specific type pre-emptive scheduling scheduling process that can satisfy priority based task scheduling ( like in the graph). Does the asynchronous events can handle by Co-operative-SL scheduler? Cheers !!! –  josh Aug 16 '12 at 8:21

If I knew what the question meant the answer would still probably be Miro Samek's Practical UML Statecharts in C/C++, Second Edition: Event-Driven Programming for Embedded Systems

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+1 for the 'If I know what the question meant' –  DipSwitch Aug 14 '12 at 15:18

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