214 lines
7.5 KiB
Markdown
214 lines
7.5 KiB
Markdown
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This program, called process-run.py, allows you to see how the state of a
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process state changes as it runs on a CPU. As described in the chapter,
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processes can be in a few different states:
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RUNNING - the process is using the CPU right now
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READY - the process could be using the CPU right now
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but (alas) some other process is
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WAITING - the process is waiting on I/O
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(e.g., it issued a request to a disk)
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DONE - the process is finished executing
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In this homework, we'll see how these process states change as a program
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runs, and thus learn a little bit better how these things work.
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To run the program and get its options, do this:
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prompt> ./process-run.py -h
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If this doesn't work, type "python" before the command, like this:
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prompt> python process-run.py -h
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What you should see is this:
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Usage: process-run.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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-l PROCESS_LIST, --processlist=PROCESS_LIST
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a comma-separated list of processes to run, in the
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form X1:Y1,X2:Y2,... where X is the number of
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instructions that process should run, and Y the
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chances (from 0 to 100) that an instruction will use
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the CPU or issue an IO
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-L IO_LENGTH, --iolength=IO_LENGTH
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how long an IO takes
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-S PROCESS_SWITCH_BEHAVIOR, --switch=PROCESS_SWITCH_BEHAVIOR
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when to switch between processes: SWITCH_ON_IO,
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SWITCH_ON_END
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-I IO_DONE_BEHAVIOR, --iodone=IO_DONE_BEHAVIOR
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type of behavior when IO ends: IO_RUN_LATER,
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IO_RUN_IMMEDIATE
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-c compute answers for me
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-p, --printstats print statistics at end; only useful with -c flag
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(otherwise stats are not printed)
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The most important option to understand is the PROCESS_LIST (as specified by
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the -l or --processlist flags) which specifies exactly what each running
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program (or "process") will do. A process consist of instructions, and each
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instruction can just do one of two things:
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- use the CPU
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- issue an IO (and wait for it to complete)
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When a process uses the CPU (and does no IO at all), it should simply
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alternate between RUNNING on the CPU or being READY to run. For example, here
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is a simple run that just has one program being run, and that program only
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uses the CPU (it does no IO).
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prompt> ./process-run.py -l 5:100 -p
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Produce a trace of what would happen when you run these processes:
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Process 0
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cpu
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cpu
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cpu
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cpu
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cpu
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Important behaviors:
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System will switch when the current process is FINISHED or ISSUES AN IO
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After IOs, the process issuing the IO will run LATER (when it is its turn)
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prompt>
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Here, the process we specified is "5:100" which means it should consist of 5
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instructions, and the chances that each instruction is a CPU instruction are
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100%.
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You can see what happens to the process by using the -c flag, which computes the
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answers for you:
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prompt> ./process-run.py -l 5:100 -c
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Time PID: 0 CPU IOs
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1 RUN:cpu 1
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2 RUN:cpu 1
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3 RUN:cpu 1
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4 RUN:cpu 1
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5 RUN:cpu 1
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This result is not too interesting: the process is simple in the RUN state and
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then finishes, using the CPU the whole time and thus keeping the CPU busy the
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entire run, and not doing any I/Os.
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Let's make it slightly more complex by running two processes:
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prompt> ./process-run.py -l 5:100,5:100
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Produce a trace of what would happen when you run these processes:
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Process 0
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cpu
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cpu
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cpu
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cpu
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cpu
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Process 1
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cpu
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cpu
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cpu
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cpu
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cpu
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Important behaviors:
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Scheduler will switch when the current process is FINISHED or ISSUES AN IO
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After IOs, the process issuing the IO will run LATER (when it is its turn)
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In this case, two different processes run, each again just using the CPU. What
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happens when the operating system runs them? Let's find out:
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prompt> ./process-run.py -l 5:100,5:100 -c
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Time PID: 0 PID: 1 CPU IOs
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1 RUN:cpu READY 1
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2 RUN:cpu READY 1
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3 RUN:cpu READY 1
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4 RUN:cpu READY 1
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5 RUN:cpu READY 1
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6 DONE RUN:cpu 1
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7 DONE RUN:cpu 1
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8 DONE RUN:cpu 1
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9 DONE RUN:cpu 1
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10 DONE RUN:cpu 1
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As you can see above, first the process with "process ID" (or "PID") 0 runs,
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while process 1 is READY to run but just waits until 0 is done. When 0 is
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finished, it moves to the DONE state, while 1 runs. When 1 finishes, the trace
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is done.
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Let's look at one more example before getting to some questions. In this
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example, the process just issues I/O requests.
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prompt> ./process-run.py -l 3:0
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Produce a trace of what would happen when you run these processes:
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Process 0
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io-start
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io-start
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io-start
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Important behaviors:
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System will switch when the current process is FINISHED or ISSUES AN IO
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After IOs, the process issuing the IO will run LATER (when it is its turn)
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What do you think the execution trace will look like? Let's find out:
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prompt> ./process-run.py -l 3:0 -c
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Time PID: 0 CPU IOs
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1 RUN:io-start 1
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2 WAITING 1
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3 WAITING 1
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4 WAITING 1
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5 WAITING 1
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6* RUN:io-start 1
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7 WAITING 1
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8 WAITING 1
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9 WAITING 1
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10 WAITING 1
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11* RUN:io-start 1
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12 WAITING 1
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13 WAITING 1
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14 WAITING 1
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15 WAITING 1
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16* DONE
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As you can see, the program just issues three I/Os. When each I/O is issued,
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the process moves to a WAITING state, and while the device is busy servicing
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the I/O, the CPU is idle.
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Let's print some stats (run the same command as above, but with the -p flag)
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to see some overall behaviors:
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Stats: Total Time 16
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Stats: CPU Busy 3 (18.75%)
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Stats: IO Busy 12 (75.00%)
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As you can see, the trace took 16 clock ticks to run, but the CPU was only
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busy less than 20% of the time. The IO device, on the other hand, was quite
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busy. In general, we'd like to keep all the devices busy, as that is a better
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use of resources.
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There are a few other important flags:
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-s SEED, --seed=SEED the random seed
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this gives you way to create a bunch of different jobs randomly
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-L IO_LENGTH, --iolength=IO_LENGTH
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this determines how long IOs take to complete (default is 5 ticks)
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-S PROCESS_SWITCH_BEHAVIOR, --switch=PROCESS_SWITCH_BEHAVIOR
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when to switch between processes: SWITCH_ON_IO, SWITCH_ON_END
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this determines when we switch to another process:
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- SWITCH_ON_IO, the system will switch when a process issues an IO
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- SWITCH_ON_END, the system will only switch when the current process is done
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-I IO_DONE_BEHAVIOR, --iodone=IO_DONE_BEHAVIOR
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type of behavior when IO ends: IO_RUN_LATER, IO_RUN_IMMEDIATE
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this determines when a process runs after it issues an IO:
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- IO_RUN_IMMEDIATE: switch to this process right now
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- IO_RUN_LATER: switch to this process when it is natural to
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(e.g., depending on process-switching behavior)
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Now go answer the questions at the back of the chapter to learn more.
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