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add process-concept spoc homework

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yuchen 9 年前
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共有 2 个文件被更改,包括 278 次插入0 次删除
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      related_info/lab4/process-concept-homework.md
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      related_info/lab4/process-concept-homework.py

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related_info/lab4/process-concept-homework.md 查看文件

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设计一个简化的进程管理子系统,可以管理并调度如下简化进程.给出了参考代码
### 进程的状态
- RUNNING - 进程正在使用CPU
- READY - 进程可使用CPU
- DONE - 进程结束
### 进程的行为
- 使用CPU,
- 发出YIELD请求,放弃使用CPU
### 进程调度
- 使用FIFO/FCFS:先来先服务
### 关键模拟变量
- 进程列表:描述了进程的行为特征:(1)使用CPU ;(2)等待I/O
```
-l PROCESS_LIST, --processlist= X1:Y1,X2:Y2,...
X 是进程的执行指令数;
Y是执行CPU的比例(0..100) ,如果是100,表示不会发出yield操作
```
- 进程切换行为:系统决定何时(when)切换进程:进程结束或进程发出yield请求
### 执行实例
#### 例1
```
$./process-simulation.py -l 5:50
Process 0
yld
yld
cpu
cpu
yld
Important behaviors:
System will switch when the current process is FINISHED or ISSUES AN YIELD
Time PID: 0
1 RUN:yld
2 RUN:yld
3 RUN:cpu
4 RUN:cpu
5 RUN:yld
```
#### 例2
```
$./process-simulation.py -l 5:50,5:50
Produce a trace of what would happen when you run these processes:
Process 0
yld
yld
cpu
cpu
yld
Process 1
cpu
yld
cpu
cpu
yld
Important behaviors:
System will switch when the current process is FINISHED or ISSUES AN YIELD
Time PID: 0 PID: 1
1 RUN:yld READY
2 READY RUN:cpu
3 READY RUN:yld
4 RUN:yld READY
5 READY RUN:cpu
6 READY RUN:cpu
7 READY RUN:yld
8 RUN:cpu READY
9 RUN:cpu READY
10 RUN:yld READY
11 RUNNING DONE
```

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related_info/lab4/process-concept-homework.py 查看文件

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#! /usr/bin/env python
import sys
from optparse import OptionParser
import random
# process states
STATE_RUNNING = 'RUNNING'
STATE_READY = 'READY'
STATE_DONE = 'DONE'
# members of process structure
PROC_CODE = 'code_'
PROC_PC = 'pc_'
PROC_ID = 'pid_'
PROC_STATE = 'proc_state_'
# things a process can do
DO_COMPUTE = 'cpu'
DO_YIELD = 'yld'
class scheduler:
def __init__(self):
# keep set of instructions for each of the processes
self.proc_info = {}
return
def new_process(self):
proc_id = len(self.proc_info)
self.proc_info[proc_id] = {}
self.proc_info[proc_id][PROC_PC] = 0
self.proc_info[proc_id][PROC_ID] = proc_id
self.proc_info[proc_id][PROC_CODE] = []
self.proc_info[proc_id][PROC_STATE] = STATE_READY
return proc_id
def load(self, program_description):
proc_id = self.new_process()
tmp = program_description.split(':')
if len(tmp) != 2:
print 'Bad description (%s): Must be number <x:y>'
print ' where X is the number of instructions'
print ' and Y is the percent change that an instruction is CPU not YIELD'
exit(1)
num_instructions, chance_cpu = int(tmp[0]), float(tmp[1])/100.0
for i in range(num_instructions):
if random.random() < chance_cpu:
self.proc_info[proc_id][PROC_CODE].append(DO_COMPUTE)
else:
self.proc_info[proc_id][PROC_CODE].append(DO_YIELD)
return
#change to READY STATE, the current proc's state should be expected
#if pid==-1, then pid=self.curr_proc
def move_to_ready(self, expected, pid=-1):
#YOUR CODE
return
#change to RUNNING STATE, the current proc's state should be expected
def move_to_running(self, expected):
#YOUR CODE
return
#change to DONE STATE, the current proc's state should be expected
def move_to_done(self, expected):
#YOUR CODE
return
#choose next proc using FIFO/FCFS scheduling, If pid==-1, then pid=self.curr_proc
def next_proc(self, pid=-1):
#YOUR CODE
return
def get_num_processes(self):
return len(self.proc_info)
def get_num_instructions(self, pid):
return len(self.proc_info[pid][PROC_CODE])
def get_instruction(self, pid, index):
return self.proc_info[pid][PROC_CODE][index]
def get_num_active(self):
num_active = 0
for pid in range(len(self.proc_info)):
if self.proc_info[pid][PROC_STATE] != STATE_DONE:
num_active += 1
return num_active
def get_num_runnable(self):
num_active = 0
for pid in range(len(self.proc_info)):
if self.proc_info[pid][PROC_STATE] == STATE_READY or \
self.proc_info[pid][PROC_STATE] == STATE_RUNNING:
num_active += 1
return num_active
def space(self, num_columns):
for i in range(num_columns):
print '%10s' % ' ',
def check_if_done(self):
if len(self.proc_info[self.curr_proc][PROC_CODE]) == 0:
if self.proc_info[self.curr_proc][PROC_STATE] == STATE_RUNNING:
self.move_to_done(STATE_RUNNING)
self.next_proc()
return
def run(self):
clock_tick = 0
if len(self.proc_info) == 0:
return
# make first one active
self.curr_proc = 0
self.move_to_running(STATE_READY)
# OUTPUT: heade`[rs for each column
print '%s' % 'Time',
for pid in range(len(self.proc_info)):
print '%10s' % ('PID:%2d' % (pid)),
print ''
# init statistics
cpu_busy = 0
while self.get_num_active() > 0:
clock_tick += 1
# if current proc is RUNNING and has an instruction, execute it
# statistics clock_tick
instruction_to_execute = ''
if self.proc_info[self.curr_proc][PROC_STATE] == STATE_RUNNING and \
len(self.proc_info[self.curr_proc][PROC_CODE]) > 0:
#YOUR CODE
# OUTPUT: print what everyone is up to
print '%3d ' % clock_tick,
for pid in range(len(self.proc_info)):
if pid == self.curr_proc and instruction_to_execute != '':
print '%10s' % ('RUN:'+instruction_to_execute),
else:
print '%10s' % (self.proc_info[pid][PROC_STATE]),
print ''
# if this is an YIELD instruction, switch to ready state
# and add an io completion in the future
if instruction_to_execute == DO_YIELD:
#YOUR CODE
# ENDCASE: check if currently running thing is out of instructions
self.check_if_done()
return (clock_tick)
#
# PARSE ARGUMENTS
#
parser = OptionParser()
parser.add_option('-s', '--seed', default=0, help='the random seed', action='store', type='int', dest='seed')
parser.add_option('-l', '--processlist', default='',
help='a comma-separated list of processes to run, in the form X1:Y1,X2:Y2,... where X is the number of instructions that process should run, and Y the chances (from 0 to 100) that an instruction will use the CPU or issue an YIELD',
action='store', type='string', dest='process_list')
parser.add_option('-p', '--printstats', help='print statistics at end; only useful with -c flag (otherwise stats are not printed)', action='store_true', default=False, dest='print_stats')
(options, args) = parser.parse_args()
random.seed(options.seed)
s = scheduler()
# example process description (10:100,10:100)
for p in options.process_list.split(','):
s.load(p)
print 'Produce a trace of what would happen when you run these processes:'
for pid in range(s.get_num_processes()):
print 'Process %d' % pid
for inst in range(s.get_num_instructions(pid)):
print ' %s' % s.get_instruction(pid, inst)
print ''
print 'Important behaviors:'
print ' System will switch when the current process is FINISHED or ISSUES AN YIELD'
(clock_tick) = s.run()
if options.print_stats:
print ''
print 'Stats: Total Time %d' % clock_tick
print ''

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