===============
RDMA Controller
===============

.. Contents

   1. Overview
     1-1. What is RDMA controller?
     1-2. Why RDMA controller needed?
     1-3. How is RDMA controller implemented?
   2. Usage Examples
   3. RDMA Interface Files

1. Overview
===========

1-1. What is RDMA controller?
-----------------------------

RDMA controller allows user to limit RDMA/IB specific resources that a given
set of processes can use. These processes are grouped using RDMA controller.

RDMA controller defines two resources which can be limited for processes of a
cgroup.

1-2. Why RDMA controller needed?
--------------------------------

Currently user space applications can easily take away all the rdma verb
specific resources such as AH, CQ, QP, MR etc. Due to which other applications
in other cgroup or kernel space ULPs may not even get chance to allocate any
rdma resources. This can lead to service unavailability.

Therefore RDMA controller is needed through which resource consumption
of processes can be limited. Through this controller different rdma
resources can be accounted.

1-3. How is RDMA controller implemented?
----------------------------------------

RDMA cgroup allows limit configuration of resources. Rdma cgroup maintains
resource accounting per cgroup, per device using resource pool structure.
Each such resource pool is limited up to 64 resources in given resource pool
by rdma cgroup, which can be extended later if required.

This resource pool object is linked to the cgroup css. Typically there
are 0 to 4 resource pool instances per cgroup, per device in most use cases.
But nothing limits to have it more. At present hundreds of RDMA devices per
single cgroup may not be handled optimally, however there is no
known use case or requirement for such configuration either.

Since RDMA resources can be allocated from any process and can be freed by any
of the child processes which shares the address space, rdma resources are
always owned by the creator cgroup css. This allows process migration from one
to other cgroup without major complexity of transferring resource ownership;
because such ownership is not really present due to shared nature of
rdma resources. Linking resources around css also ensures that cgroups can be
deleted after processes migrated. This allow progress migration as well with
active resources, even though that is not a primary use case.

Whenever RDMA resource charging occurs, owner rdma cgroup is returned to
the caller. Same rdma cgroup should be passed while uncharging the resource.
This also allows process migrated with active RDMA resource to charge
to new owner cgroup for new resource. It also allows to uncharge resource of
a process from previously charged cgroup which is migrated to new cgroup,
even though that is not a primary use case.

Resource pool object is created in following situations.
(a) User sets the limit and no previous resource pool exist for the device
of interest for the cgroup.
(b) No resource limits were configured, but IB/RDMA stack tries to
charge the resource. So that it correctly uncharge them when applications are
running without limits and later on when limits are enforced during uncharging,
otherwise usage count will drop to negative.

Resource pool is destroyed if all the resource limits are set to max and
it is the last resource getting deallocated.

User should set all the limit to max value if it intents to remove/unconfigure
the resource pool for a particular device.

IB stack honors limits enforced by the rdma controller. When application
query about maximum resource limits of IB device, it returns minimum of
what is configured by user for a given cgroup and what is supported by
IB device.

Following resources can be accounted by rdma controller.

  ==========    =============================
  hca_handle	Maximum number of HCA Handles
  hca_object 	Maximum number of HCA Objects
  ==========    =============================

2. Usage Examples
=================

(a) Configure resource limit::

	echo mlx4_0 hca_handle=2 hca_object=2000 > /sys/fs/cgroup/rdma/1/rdma.max
	echo ocrdma1 hca_handle=3 > /sys/fs/cgroup/rdma/2/rdma.max

(b) Query resource limit::

	cat /sys/fs/cgroup/rdma/2/rdma.max
	#Output:
	mlx4_0 hca_handle=2 hca_object=2000
	ocrdma1 hca_handle=3 hca_object=max

(c) Query current usage::

	cat /sys/fs/cgroup/rdma/2/rdma.current
	#Output:
	mlx4_0 hca_handle=1 hca_object=20
	ocrdma1 hca_handle=1 hca_object=23

(d) Delete resource limit::

	echo mlx4_0 hca_handle=max hca_object=max > /sys/fs/cgroup/rdma/1/rdma.max

3. RDMA Interface Files
========================

The following interface files are available in each non-root RDMA cgroup.

  rdma.max
	A read-write file which describes the configured resource limit
	for an RDMA/IB device.  See the Usage Examples above.

  rdma.current
	A read-only file which describes the current resource usage.

  rdma.peak
	A read-only nested-keyed file which shows the historical high
	watermark of resource usage per device since the cgroup was created.

	An example for mlx4 and ocrdma device follows::

	  mlx4_0 hca_handle=1 hca_object=20
	  ocrdma1 hca_handle=0 hca_object=23

  rdma.events
	A read-only nested-keyed file which exists on non-root cgroups
	and contains the following keys:

	  max
		The number of times a process in this cgroup or its
		descendants attempted an RDMA resource allocation that
		was rejected because a rdma.max limit in the subtree
		was reached.  This is a hierarchical counter propagated
		upward to all ancestor cgroups.  A value change in this
		file generates a file modified event.

	  alloc_fail
		The number of RDMA resource allocation attempts that
		originated in this cgroup or its descendants and failed
		due to a rdma.max limit being reached.  This is a
		hierarchical counter propagated upward.

	An example for mlx4 device follows::

	  mlx4_0 hca_handle.max=5 hca_handle.alloc_fail=3 hca_object.max=0 hca_object.alloc_fail=0

  rdma.events.local
	Similar to rdma.events but the fields are local to the cgroup,
	i.e. not hierarchical.  The file modified event generated on this
	file reflects only the local events.

	The following nested keys are defined.

	  max
		The number of times a process in this cgroup or its
		descendants attempted an RDMA resource allocation that
		was rejected because this cgroup's own rdma.max limit
		was reached.

	  alloc_fail
		The number of RDMA resource allocation attempts
		originating from this cgroup that failed due to this
		cgroup's or an ancestor's rdma.max limit.

	An example for mlx4 device follows::

	  mlx4_0 hca_handle.max=5 hca_handle.alloc_fail=0 hca_object.max=0 hca_object.alloc_fail=0
