175 lines
7.5 KiB
Markdown
175 lines
7.5 KiB
Markdown
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This program, mlfq.py, allows you to see how the MLFQ scheduler
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presented in this chapter behaves. As before, you can use this to generate
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problems for yourself using random seeds, or use it to construct a
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carefully-designed experiment to see how MLFQ works under different
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circumstances. To run the program, type:
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prompt> ./mlfq.py
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Use the help flag (-h) to see the options:
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Usage: mlfq.py [options]
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Options:
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-h, --help show this help message and exit
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-s SEED, --seed=SEED the random seed
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-n NUMQUEUES, --numQueues=NUMQUEUES
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number of queues in MLFQ (if not using -Q)
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-q QUANTUM, --quantum=QUANTUM
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length of time slice (if not using -Q)
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-Q QUANTUMLIST, --quantumList=QUANTUMLIST
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length of time slice per queue level,
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specified as x,y,z,... where x is the
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quantum length for the highest-priority
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queue, y the next highest, and so forth
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-j NUMJOBS, --numJobs=NUMJOBS
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number of jobs in the system
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-m MAXLEN, --maxlen=MAXLEN
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max run-time of a job (if random)
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-M MAXIO, --maxio=MAXIO
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max I/O frequency of a job (if random)
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-B BOOST, --boost=BOOST
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how often to boost the priority of all
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jobs back to high priority (0 means never)
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-i IOTIME, --iotime=IOTIME
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how long an I/O should last (fixed constant)
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-S, --stay reset and stay at same priority level
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when issuing I/O
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-l JLIST, --jlist=JLIST
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a comma-separated list of jobs to run,
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in the form x1,y1,z1:x2,y2,z2:... where
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x is start time, y is run time, and z
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is how often the job issues an I/O request
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-c compute answers for me
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]
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There are a few different ways to use the simulator. One way is to generate
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some random jobs and see if you can figure out how they will behave given the
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MLFQ scheduler. For example, if you wanted to create a randomly-generated
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three-job workload, you would simply type:
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prompt> ./mlfq.py -j 3
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What you would then see is the specific problem definition:
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Here is the list of inputs:
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OPTIONS jobs 3
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OPTIONS queues 3
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OPTIONS quantum length for queue 2 is 10
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OPTIONS quantum length for queue 1 is 10
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OPTIONS quantum length for queue 0 is 10
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OPTIONS boost 0
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OPTIONS ioTime 0
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OPTIONS stayAfterIO False
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For each job, three defining characteristics are given:
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startTime : at what time does the job enter the system
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runTime : the total CPU time needed by the job to finish
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ioFreq : every ioFreq time units, the job issues an I/O
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(the I/O takes ioTime units to complete)
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Job List:
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Job 0: startTime 0 - runTime 84 - ioFreq 7
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Job 1: startTime 0 - runTime 42 - ioFreq 2
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Job 2: startTime 0 - runTime 51 - ioFreq 4
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Compute the execution trace for the given workloads.
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If you would like, also compute the response and turnaround
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times for each of the jobs.
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Use the -c flag to get the exact results when you are finished.
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This generates a random workload of three jobs (as specified), on the default
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number of queues with a number of default settings. If you run again with the
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solve flag on (-c), you'll see the same print out as above, plus the
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following:
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Execution Trace:
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[time 0] JOB BEGINS by JOB 0
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[time 0] JOB BEGINS by JOB 1
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[time 0] JOB BEGINS by JOB 2
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[time 0] Run JOB 0 at PRI 2 [TICKSLEFT 9 RUNTIME 84 TIMELEFT 83]
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[time 1] Run JOB 0 at PRI 2 [TICKSLEFT 8 RUNTIME 84 TIMELEFT 82]
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[time 2] Run JOB 0 at PRI 2 [TICKSLEFT 7 RUNTIME 84 TIMELEFT 81]
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[time 3] Run JOB 0 at PRI 2 [TICKSLEFT 6 RUNTIME 84 TIMELEFT 80]
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[time 4] Run JOB 0 at PRI 2 [TICKSLEFT 5 RUNTIME 84 TIMELEFT 79]
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[time 5] Run JOB 0 at PRI 2 [TICKSLEFT 4 RUNTIME 84 TIMELEFT 78]
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[time 6] Run JOB 0 at PRI 2 [TICKSLEFT 3 RUNTIME 84 TIMELEFT 77]
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[time 7] IO_START by JOB 0
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[time 7] Run JOB 1 at PRI 2 [TICKSLEFT 9 RUNTIME 42 TIMELEFT 41]
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[time 8] Run JOB 1 at PRI 2 [TICKSLEFT 8 RUNTIME 42 TIMELEFT 40]
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[time 9] IO_START by JOB 1
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...
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Final statistics:
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Job 0: startTime 0 - response 0 - turnaround 175
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Job 1: startTime 0 - response 7 - turnaround 191
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Job 2: startTime 0 - response 9 - turnaround 168
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Avg 2: startTime n/a - response 5.33 - turnaround 178.00
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]
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The trace shows exactly, on a millisecond-by-millisecond time scale, what the
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scheduler decided to do. In this example, it begins by running Job 0 for 7 ms
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until Job 0 issues an I/O; this is entirely predictable, as Job 0's I/O
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frequency is set to 7 ms, meaning that every 7 ms it runs, it will issue an
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I/O and wait for it to complete before continuing. At that point, the
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scheduler switches to Job 1, which only runs 2 ms before issuing an I/O.
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The scheduler prints the entire execution trace in this manner, and
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finally also computes the response and turnaround times for each job
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as well as an average.
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You can also control various other aspects of the simulation. For example, you
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can specify how many queues you'd like to have in the system (-n) and what the
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quantum length should be for all of those queues (-q); if you want even more
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control and varied quanta length per queue, you can instead specify the length
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of the quantum for each queue with -Q, e.g., -Q 10,20,30] simulates a
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scheduler with three queues, with the highest-priority queue having a 10-ms
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time slice, the next-highest a 20-ms time-slice, and the low-priority queue a
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30-ms time slice.
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If you are randomly generating jobs, you can also control how long they might
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run for (-m), or how often they generate I/O (-M). If you, however, want more
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control over the exact characteristics of the jobs running in the system, you
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can use -l (lower-case L) or --jlist, which allows you to specify the exact
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set of jobs you wish to simulate. The list is of the form:
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x1,y1,z1:x2,y2,z2:... where x is the start time of the job, y is the run time
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(i.e., how much CPU time it needs), and z the I/O frequency (i.e., after
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running z ms, the job issues an I/O; if z is 0, no I/Os are issued).
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For example, if you wanted to recreate the example in Figure 8.3
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you would specify a job list as follows:
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prompt> ./mlfq.py --jlist 0,180,0:100,20,0 -Q 10,10,10
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Running the simulator in this way creates a three-level MLFQ, with each level
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having a 10-ms time slice. Two jobs are created: Job 0 which starts at time 0,
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runs for 180 ms total, and never issues an I/O; Job 1 starts at 100 ms, needs
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only 20 ms of CPU time to complete, and also never issues I/Os.
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Finally, there are three more parameters of interest. The -B flag, if set to a
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non-zero value, boosts all jobs to the highest-priority queue every N
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milliseconds, when invoked as such:
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prompt> ./mlfq.py -B N
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The scheduler uses this feature to avoid starvation as discussed in the
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chapter. However, it is off by default.
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The -S flag invokes older Rules 4a and 4b, which means that if a job issues an
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I/O before completing its time slice, it will return to that same priority
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queue when it resumes execution, with its full time-slice intact. This
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enables gaming of the scheduler.
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Finally, you can easily change how long an I/O lasts by using the -i flag. By
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default in this simplistic model, each I/O takes a fixed amount of time of 5
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milliseconds or whatever you set it to with this flag.
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You can also play around with whether jobs that just complete an I/O are moved
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to the head of the queue they are in or to the back, with the -I flag. Check
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it out.
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