==============================================================================
NUMA binding description.
==============================================================================

==============================================================================
1 - Introduction
==============================================================================

Systems employing a Non Uniform Memory Access (NUMA) architecture contain
collections of hardware resources including processors, memory, and I/O buses,
that comprise what is commonly known as a NUMA node.
Processor accesses to memory within the local NUMA node is generally faster
than processor accesses to memory outside of the local NUMA node.
DT defines interfaces that allow the platform to convey NUMA node
topology information to OS.

==============================================================================
2 - numa-node-id
==============================================================================

For the purpose of identification, each NUMA node is associated with a unique
token known as a node id. For the purpose of this binding
a node id is a 32-bit integer.

A device node is associated with a NUMA node by the presence of a
numa-node-id property which contains the node id of the device.

Example:
	/* numa node 0 */
	numa-node-id = <0>;

	/* numa node 1 */
	numa-node-id = <1>;

==============================================================================
3 - distance-map
==============================================================================

The device tree node distance-map describes the relative
distance(memory latency) between all numa nodes.

- compatible : Should at least contain "numa-distance-map-v1".

- distance-matrix
  This property defines a matrix to describe the relative distances
  between all numa nodes.
  It is represented as a list of node pairs and their relative distance.

  Note:
	1. Each entry represents distance from first node to second node.
	The distance are equal in either direction.
	2. The distance from a node to self(local distance) is represented
	with value 10 and all inter node distance should be represented with
	value greater than 10.
	3. distance-matrix shold have entries in lexicographical ascending
	order of nodes.
	4. There must be only one Device node distance-map and must reside in the root node.

Example:
	4 nodes connected in mesh/ring topology as below,

		0_______20______1
		|               |
		|               |
		20             20
		|               |
		|               |
		|_______________|
		3       20      2

	if relative distance for each hop is 20,
	then inter node distance would be,
	      0 -> 1 = 20
	      1 -> 2 = 20
	      2 -> 3 = 20
	      3 -> 0 = 20
	      0 -> 2 = 40
	      1 -> 3 = 40

     and dt presentation for this distance matrix is,

		distance-map {
			 compatible = "numa-distance-map-v1";
			 distance-matrix = <0 0  10>,
					   <0 1  20>,
					   <0 2  40>,
					   <0 3  20>,
					   <1 0  20>,
					   <1 1  10>,
					   <1 2  20>,
					   <1 3  40>,
					   <2 0  40>,
					   <2 1  20>,
					   <2 2  10>,
					   <2 3  20>,
					   <3 0  20>,
					   <3 1  40>,
					   <3 2  20>,
					   <3 3  10>;
		};

==============================================================================
4 - Example dts
==============================================================================

2 sockets system consists of 2 boards connected through ccn bus and
each board having one socket/soc of 8 cpus, memory and pci bus.

	memory@00c00000 {
		device_type = "memory";
		reg = <0x0 0x00c00000 0x0 0x80000000>;
		/* node 0 */
		numa-node-id = <0>;
	};

	memory@10000000000 {
		device_type = "memory";
		reg = <0x100 0x00000000 0x0 0x80000000>;
		/* node 1 */
		numa-node-id = <1>;
	};

	cpus {
		#address-cells = <2>;
		#size-cells = <0>;

		cpu@000 {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x000>;
			enable-method = "psci";
			/* node 0 */
			numa-node-id = <0>;
		};
		cpu@001 {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x001>;
			enable-method = "psci";
			numa-node-id = <0>;
		};
		cpu@002 {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x002>;
			enable-method = "psci";
			numa-node-id = <0>;
		};
		cpu@003 {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x003>;
			enable-method = "psci";
			numa-node-id = <0>;
		};
		cpu@004 {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x004>;
			enable-method = "psci";
			numa-node-id = <0>;
		};
		cpu@005 {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x005>;
			enable-method = "psci";
			numa-node-id = <0>;
		};
		cpu@006 {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x006>;
			enable-method = "psci";
			numa-node-id = <0>;
		};
		cpu@007 {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x007>;
			enable-method = "psci";
			numa-node-id = <0>;
		};
		cpu@008 {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x008>;
			enable-method = "psci";
			/* node 1 */
			numa-node-id = <1>;
		};
		cpu@009 {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x009>;
			enable-method = "psci";
			numa-node-id = <1>;
		};
		cpu@00a {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x00a>;
			enable-method = "psci";
			numa-node-id = <1>;
		};
		cpu@00b {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x00b>;
			enable-method = "psci";
			numa-node-id = <1>;
		};
		cpu@00c {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x00c>;
			enable-method = "psci";
			numa-node-id = <1>;
		};
		cpu@00d {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x00d>;
			enable-method = "psci";
			numa-node-id = <1>;
		};
		cpu@00e {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x00e>;
			enable-method = "psci";
			numa-node-id = <1>;
		};
		cpu@00f {
			device_type = "cpu";
			compatible =  "arm,armv8";
			reg = <0x0 0x00f>;
			enable-method = "psci";
			numa-node-id = <1>;
		};
	};

	pcie0: pcie0@0x8480,00000000 {
		compatible = "arm,armv8";
		device_type = "pci";
		bus-range = <0 255>;
		#size-cells = <2>;
		#address-cells = <3>;
		reg = <0x8480 0x00000000 0 0x10000000>;  /* Configuration space */
		ranges = <0x03000000 0x8010 0x00000000 0x8010 0x00000000 0x70 0x00000000>;
		/* node 0 */
		numa-node-id = <0>;
        };

	pcie1: pcie1@0x9480,00000000 {
		compatible = "arm,armv8";
		device_type = "pci";
		bus-range = <0 255>;
		#size-cells = <2>;
		#address-cells = <3>;
		reg = <0x9480 0x00000000 0 0x10000000>;  /* Configuration space */
		ranges = <0x03000000 0x9010 0x00000000 0x9010 0x00000000 0x70 0x00000000>;
		/* node 1 */
		numa-node-id = <1>;
        };

	distance-map {
		compatible = "numa-distance-map-v1";
		distance-matrix = <0 0 10>,
				  <0 1 20>,
				  <1 1 10>;
	};
