Documentation/x86/x86_64/fake-numa-for-cpusets - linux - Git at Google

 Using numa=fake and CPUSets for Resource Management
 Written by David Rientjes <rientjes@cs.washington.edu>

 This document describes how the numa=fake x86_64 command-line option can be used
 in conjunction with cpusets for coarse memory management.  Using this feature,
 you can create fake NUMA nodes that represent contiguous chunks of memory and
 assign them to cpusets and their attached tasks.  This is a way of limiting the
 amount of system memory that are available to a certain class of tasks.

 For more information on the features of cpusets, see
 Documentation/cgroups/cpusets.txt.
 There are a number of different configurations you can use for your needs.  For
 more information on the numa=fake command line option and its various ways of
 configuring fake nodes, see Documentation/x86/x86_64/boot-options.txt.

 For the purposes of this introduction, we'll assume a very primitive NUMA
 emulation setup of "numa=fake=4*512,".  This will split our system memory into
 four equal chunks of 512M each that we can now use to assign to cpusets.  As
 you become more familiar with using this combination for resource control,
 you'll determine a better setup to minimize the number of nodes you have to deal
 with.

 A machine may be split as follows with "numa=fake=4*512," as reported by dmesg:

 	Faking node 0 at 0000000000000000-0000000020000000 (512MB)
 	Faking node 1 at 0000000020000000-0000000040000000 (512MB)
 	Faking node 2 at 0000000040000000-0000000060000000 (512MB)
 	Faking node 3 at 0000000060000000-0000000080000000 (512MB)
 	...
 	On node 0 totalpages: 130975
 	On node 1 totalpages: 131072
 	On node 2 totalpages: 131072
 	On node 3 totalpages: 131072

 Now following the instructions for mounting the cpusets filesystem from
 Documentation/cgroups/cpusets.txt, you can assign fake nodes (i.e. contiguous memory
 address spaces) to individual cpusets:

 	[root@xroads /]# mkdir exampleset
 	[root@xroads /]# mount -t cpuset none exampleset
 	[root@xroads /]# mkdir exampleset/ddset
 	[root@xroads /]# cd exampleset/ddset
 	[root@xroads /exampleset/ddset]# echo 0-1 > cpus
 	[root@xroads /exampleset/ddset]# echo 0-1 > mems

 Now this cpuset, 'ddset', will only allowed access to fake nodes 0 and 1 for
 memory allocations (1G).

 You can now assign tasks to these cpusets to limit the memory resources
 available to them according to the fake nodes assigned as mems:

 	[root@xroads /exampleset/ddset]# echo $$ > tasks
 	[root@xroads /exampleset/ddset]# dd if=/dev/zero of=tmp bs=1024 count=1G
 	[1] 13425

 Notice the difference between the system memory usage as reported by
 /proc/meminfo between the restricted cpuset case above and the unrestricted
 case (i.e. running the same 'dd' command without assigning it to a fake NUMA
 cpuset):
 				Unrestricted	Restricted
 	MemTotal:		3091900 kB	3091900 kB
 	MemFree:		  42113 kB	1513236 kB

 This allows for coarse memory management for the tasks you assign to particular
 cpusets.  Since cpusets can form a hierarchy, you can create some pretty
 interesting combinations of use-cases for various classes of tasks for your
 memory management needs.
	Using numa=fake and CPUSets for Resource Management
	Written by David Rientjes <rientjes@cs.washington.edu>

	This document describes how the numa=fake x86_64 command-line option can be used
	in conjunction with cpusets for coarse memory management. Using this feature,
	you can create fake NUMA nodes that represent contiguous chunks of memory and
	assign them to cpusets and their attached tasks. This is a way of limiting the
	amount of system memory that are available to a certain class of tasks.

	For more information on the features of cpusets, see
	Documentation/cgroups/cpusets.txt.
	There are a number of different configurations you can use for your needs. For
	more information on the numa=fake command line option and its various ways of
	configuring fake nodes, see Documentation/x86/x86_64/boot-options.txt.

	For the purposes of this introduction, we'll assume a very primitive NUMA
	emulation setup of "numa=fake=4*512,". This will split our system memory into
	four equal chunks of 512M each that we can now use to assign to cpusets. As
	you become more familiar with using this combination for resource control,
	you'll determine a better setup to minimize the number of nodes you have to deal
	with.

	A machine may be split as follows with "numa=fake=4*512," as reported by dmesg:

	Faking node 0 at 0000000000000000-0000000020000000 (512MB)
	Faking node 1 at 0000000020000000-0000000040000000 (512MB)
	Faking node 2 at 0000000040000000-0000000060000000 (512MB)
	Faking node 3 at 0000000060000000-0000000080000000 (512MB)
	...
	On node 0 totalpages: 130975
	On node 1 totalpages: 131072
	On node 2 totalpages: 131072
	On node 3 totalpages: 131072

	Now following the instructions for mounting the cpusets filesystem from
	Documentation/cgroups/cpusets.txt, you can assign fake nodes (i.e. contiguous memory
	address spaces) to individual cpusets:

	[root@xroads /]# mkdir exampleset
	[root@xroads /]# mount -t cpuset none exampleset
	[root@xroads /]# mkdir exampleset/ddset
	[root@xroads /]# cd exampleset/ddset
	[root@xroads /exampleset/ddset]# echo 0-1 > cpus
	[root@xroads /exampleset/ddset]# echo 0-1 > mems

	Now this cpuset, 'ddset', will only allowed access to fake nodes 0 and 1 for
	memory allocations (1G).

	You can now assign tasks to these cpusets to limit the memory resources
	available to them according to the fake nodes assigned as mems:

	[root@xroads /exampleset/ddset]# echo $$ > tasks
	[root@xroads /exampleset/ddset]# dd if=/dev/zero of=tmp bs=1024 count=1G
	[1] 13425

	Notice the difference between the system memory usage as reported by
	/proc/meminfo between the restricted cpuset case above and the unrestricted
	case (i.e. running the same 'dd' command without assigning it to a fake NUMA
	cpuset):
	Unrestricted Restricted
	MemTotal: 3091900 kB 3091900 kB
	MemFree: 42113 kB 1513236 kB

	This allows for coarse memory management for the tasks you assign to particular
	cpusets. Since cpusets can form a hierarchy, you can create some pretty
	interesting combinations of use-cases for various classes of tasks for your
	memory management needs.