Re: [patch] CFS scheduler, -v14

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Ingo Molnar wrote:
* Li Yu <[email protected]> wrote:

Also, I have want to know what's real meaning of

   add_wait_runtime(rq, curr, delta_mine - delta_exec);

in update_curr(), IMHO, it should be

   add_wait_runtime(rq, curr, delta_mine - delta_fair);

Is this just another heuristics? or my opinion is wrong again? :-)

well, ->wait_runtime is in real time units. If a task executes delta_exec time on the CPU, we deduct "-delta_exec" 1:1. But during that time the task also got entitled to a bit more CPU time, that is +delta_mine. The calculation above expresses this. I'm not sure what sense '-delta_fair' would make - "delta_fair" is the amount of time a nice-0 task would be entitled to - but this task might not be a nice-0 task. Furthermore, even for a nice-0 task why deduct -delta_fair - it spent delta_exec on the CPU.


Eh, I wrong again~ I even took an experiment in last week end, this idea
is really bad! ;(

I think the most inner of source of my wrong again and again is
misunderstanding virtual time. For more better understanding this, I try to write one python script to simulate CFS behavior. However, It can not implement the fairness as I want. I really confuse here.

Would you like help me point out what's wrong in it? Any suggestion is welcome. Thanks in advanced.




I think use wait_runtime is more clear. so I modify this script.


#! /usr/bin/python

# htucfs.py - Hard-To-Understand-CFS.py ;)
# Wrote by Li Yu / 20070604

#
# only support static load / UP.
#


# Usage:
#	./htucfs.py nr_clock_ticks_to_run
#

import sys

class task_struct:
	def __init__(self, name, load_weight):
		self.name = name
		self.wait_runtime = 0
		self.fair_clock = 0
		self.load_weight = float(load_weight)
	def __repr__(self):
		return "%s/C%.2f" % (self.name, self.fair_clock)

idle_task = task_struct("idle", 0)

class run_queue:
	def __init__(self):
		self.raw_weighted_load = 0
		self.wall_clock = 0
		self.fair_clock = 0
		self.ready_queue = {}
		self.run_history = []
		self.task_list = []
		self.curr = None
		self.debug = 0
		
	def snapshot(self):
		if self.debug:
			print "%.2f" % self.fair_clock, self.ready_queue, self.curr

	def enqueue(self, task):
		if not self.ready_queue.get(task.wait_runtime):
			self.ready_queue[task.wait_runtime] = [task]
		else:
			# keep FIFO for same wait_runtime tasks.
			self.ready_queue[task.wait_runtime].append(task)
		self.raw_weighted_load += task.load_weight
		self.task_list.append(task)

	def dequeue(self, task):
		self.raw_weighted_load -= task.load_weight
		self.ready_queue[task.wait_runtime].remove(task)
		if not self.ready_queue[task.wait_runtime]:
			del self.ready_queue[task.wait_runtime]
		self.task_list.remove(task)
	
	def other_wait_runtime(self):
		task_list = self.task_list[:]
		for task in task_list:
			if task == self.curr:
				continue
			self.dequeue(task)
			task.wait_runtime += 1
			print task, "wait 1 sec"
			self.enqueue(task)
		
	def clock_tick(self):
		# clock_tick = 1.0
		self.fair_clock += 1.0/self.raw_weighted_load
		# delta_exec = 1.0
		delta_mine = self.curr.load_weight / self.raw_weighted_load
		self.dequeue(self.curr)
		self.other_wait_runtime()
		print self.curr, "run %.2f" % (delta_mine-1.0)
		self.curr.wait_runtime += (delta_mine-1.0)
		self.curr.fair_clock += 1.0/self.curr.load_weight
		self.enqueue(self.curr)
		self.pick_next_task()
	
	def pick_next_task(self):
		key_seq	= self.ready_queue.keys()
		if key_seq:
			key_seq.sort()
			self.curr = self.ready_queue[key_seq[-1]][0]
		else:
			self.curr = idle_task
		self.snapshot()
		self.record_run_history()

	def record_run_history(self):
		task = self.curr
		if not self.run_history:
			self.run_history.append([task, 1])
			return
		curr = self.run_history[-1]
		if curr[0] != task:
			self.run_history.append([task, 1])
		else:
			curr[1] += 1
	
	def show_history(self):
		stat = {}
		for entry in self.run_history:
			task = entry[0]
			nsec = entry[1]
			print "%s run %d sec" % (task, nsec)
			if task not in stat.keys():
				stat[task] = nsec
			else:
				stat[task] += nsec
		print "=============================="
		tasks = stat.keys()
		tasks.sort()
		for task in tasks:
			print task, "/", task.load_weight, ":", stat[task], "sec"
		print "=============================="

	def run(self, delta=0, debug=0):
		self.debug = debug
		until = self.wall_clock + delta
		print "-----------------------------"
		self.pick_next_task()
		while self.wall_clock < until:
			self.wall_clock += 1
			self.clock_tick()
		print "-----------------------------"

#
# To turn this, display verbose runtime information.
#
debug = True

if __name__ == "__main__":
	rq = run_queue()
	task1 = task_struct("TASK_1", 1)
	task2 = task_struct("TASK_2", 2)
	task3 = task_struct("TASK_3", 1)
	rq.enqueue(task1)
	rq.enqueue(task2)
	rq.enqueue(task3)
	rq.run(int(sys.argv[1]), debug)
	rq.show_history()

#EOF

Good luck

- Li Yu


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