Documentation/driver-api/cxl/memory-devices.rst - linux/kernel/git/torvalds/linux - Git at Google

 .. SPDX-License-Identifier: GPL-2.0
 .. include:: <isonum.txt>

 ===================================
 Compute Express Link Memory Devices
 ===================================

 A Compute Express Link Memory Device is a CXL component that implements the
 CXL.mem protocol. It contains some amount of volatile memory, persistent memory,
 or both. It is enumerated as a PCI device for configuration and passing
 messages over an MMIO mailbox. Its contribution to the System Physical
 Address space is handled via HDM (Host Managed Device Memory) decoders
 that optionally define a device's contribution to an interleaved address
 range across multiple devices underneath a host-bridge or interleaved
 across host-bridges.

 CXL Bus: Theory of Operation
 ============================
 Similar to how a RAID driver takes disk objects and assembles them into a new
 logical device, the CXL subsystem is tasked to take PCIe and ACPI objects and
 assemble them into a CXL.mem decode topology. The need for runtime configuration
 of the CXL.mem topology is also similar to RAID in that different environments
 with the same hardware configuration may decide to assemble the topology in
 contrasting ways. One may choose performance (RAID0) striping memory across
 multiple Host Bridges and endpoints while another may opt for fault tolerance
 and disable any striping in the CXL.mem topology.

 Platform firmware enumerates a menu of interleave options at the "CXL root port"
 (Linux term for the top of the CXL decode topology). From there, PCIe topology
 dictates which endpoints can participate in which Host Bridge decode regimes.
 Each PCIe Switch in the path between the root and an endpoint introduces a point
 at which the interleave can be split. For example platform firmware may say at a
 given range only decodes to 1 one Host Bridge, but that Host Bridge may in turn
 interleave cycles across multiple Root Ports. An intervening Switch between a
 port and an endpoint may interleave cycles across multiple Downstream Switch
 Ports, etc.

 Here is a sample listing of a CXL topology defined by 'cxl_test'. The 'cxl_test'
 module generates an emulated CXL topology of 2 Host Bridges each with 2 Root
 Ports. Each of those Root Ports are connected to 2-way switches with endpoints
 connected to those downstream ports for a total of 8 endpoints::

     # cxl list -BEMPu -b cxl_test
     {
       "bus":"root3",
       "provider":"cxl_test",
       "ports:root3":[
         {
           "port":"port5",
           "host":"cxl_host_bridge.1",
           "ports:port5":[
             {
               "port":"port8",
               "host":"cxl_switch_uport.1",
               "endpoints:port8":[
                 {
                   "endpoint":"endpoint9",
                   "host":"mem2",
                   "memdev":{
                     "memdev":"mem2",
                     "pmem_size":"256.00 MiB (268.44 MB)",
                     "ram_size":"256.00 MiB (268.44 MB)",
                     "serial":"0x1",
                     "numa_node":1,
                     "host":"cxl_mem.1"
                   }
                 },
                 {
                   "endpoint":"endpoint15",
                   "host":"mem6",
                   "memdev":{
                     "memdev":"mem6",
                     "pmem_size":"256.00 MiB (268.44 MB)",
                     "ram_size":"256.00 MiB (268.44 MB)",
                     "serial":"0x5",
                     "numa_node":1,
                     "host":"cxl_mem.5"
                   }
                 }
               ]
             },
             {
               "port":"port12",
               "host":"cxl_switch_uport.3",
               "endpoints:port12":[
                 {
                   "endpoint":"endpoint17",
                   "host":"mem8",
                   "memdev":{
                     "memdev":"mem8",
                     "pmem_size":"256.00 MiB (268.44 MB)",
                     "ram_size":"256.00 MiB (268.44 MB)",
                     "serial":"0x7",
                     "numa_node":1,
                     "host":"cxl_mem.7"
                   }
                 },
                 {
                   "endpoint":"endpoint13",
                   "host":"mem4",
                   "memdev":{
                     "memdev":"mem4",
                     "pmem_size":"256.00 MiB (268.44 MB)",
                     "ram_size":"256.00 MiB (268.44 MB)",
                     "serial":"0x3",
                     "numa_node":1,
                     "host":"cxl_mem.3"
                   }
                 }
               ]
             }
           ]
         },
         {
           "port":"port4",
           "host":"cxl_host_bridge.0",
           "ports:port4":[
             {
               "port":"port6",
               "host":"cxl_switch_uport.0",
               "endpoints:port6":[
                 {
                   "endpoint":"endpoint7",
                   "host":"mem1",
                   "memdev":{
                     "memdev":"mem1",
                     "pmem_size":"256.00 MiB (268.44 MB)",
                     "ram_size":"256.00 MiB (268.44 MB)",
                     "serial":"0",
                     "numa_node":0,
                     "host":"cxl_mem.0"
                   }
                 },
                 {
                   "endpoint":"endpoint14",
                   "host":"mem5",
                   "memdev":{
                     "memdev":"mem5",
                     "pmem_size":"256.00 MiB (268.44 MB)",
                     "ram_size":"256.00 MiB (268.44 MB)",
                     "serial":"0x4",
                     "numa_node":0,
                     "host":"cxl_mem.4"
                   }
                 }
               ]
             },
             {
               "port":"port10",
               "host":"cxl_switch_uport.2",
               "endpoints:port10":[
                 {
                   "endpoint":"endpoint16",
                   "host":"mem7",
                   "memdev":{
                     "memdev":"mem7",
                     "pmem_size":"256.00 MiB (268.44 MB)",
                     "ram_size":"256.00 MiB (268.44 MB)",
                     "serial":"0x6",
                     "numa_node":0,
                     "host":"cxl_mem.6"
                   }
                 },
                 {
                   "endpoint":"endpoint11",
                   "host":"mem3",
                   "memdev":{
                     "memdev":"mem3",
                     "pmem_size":"256.00 MiB (268.44 MB)",
                     "ram_size":"256.00 MiB (268.44 MB)",
                     "serial":"0x2",
                     "numa_node":0,
                     "host":"cxl_mem.2"
                   }
                 }
               ]
             }
           ]
         }
       ]
     }

 In that listing each "root", "port", and "endpoint" object correspond a kernel
 'struct cxl_port' object. A 'cxl_port' is a device that can decode CXL.mem to
 its descendants. So "root" claims non-PCIe enumerable platform decode ranges and
 decodes them to "ports", "ports" decode to "endpoints", and "endpoints"
 represent the decode from SPA (System Physical Address) to DPA (Device Physical
 Address).

 Continuing the RAID analogy, disks have both topology metadata and on device
 metadata that determine RAID set assembly. CXL Port topology and CXL Port link
 status is metadata for CXL.mem set assembly. The CXL Port topology is enumerated
 by the arrival of a CXL.mem device. I.e. unless and until the PCIe core attaches
 the cxl_pci driver to a CXL Memory Expander there is no role for CXL Port
 objects. Conversely for hot-unplug / removal scenarios, there is no need for
 the Linux PCI core to tear down switch-level CXL resources because the endpoint
 ->remove() event cleans up the port data that was established to support that
 Memory Expander.

 The port metadata and potential decode schemes that a give memory device may
 participate can be determined via a command like::

     # cxl list -BDMu -d root -m mem3
     {
       "bus":"root3",
       "provider":"cxl_test",
       "decoders:root3":[
         {
           "decoder":"decoder3.1",
           "resource":"0x8030000000",
           "size":"512.00 MiB (536.87 MB)",
           "volatile_capable":true,
           "nr_targets":2
         },
         {
           "decoder":"decoder3.3",
           "resource":"0x8060000000",
           "size":"512.00 MiB (536.87 MB)",
           "pmem_capable":true,
           "nr_targets":2
         },
         {
           "decoder":"decoder3.0",
           "resource":"0x8020000000",
           "size":"256.00 MiB (268.44 MB)",
           "volatile_capable":true,
           "nr_targets":1
         },
         {
           "decoder":"decoder3.2",
           "resource":"0x8050000000",
           "size":"256.00 MiB (268.44 MB)",
           "pmem_capable":true,
           "nr_targets":1
         }
       ],
       "memdevs:root3":[
         {
           "memdev":"mem3",
           "pmem_size":"256.00 MiB (268.44 MB)",
           "ram_size":"256.00 MiB (268.44 MB)",
           "serial":"0x2",
           "numa_node":0,
           "host":"cxl_mem.2"
         }
       ]
     }

 ...which queries the CXL topology to ask "given CXL Memory Expander with a kernel
 device name of 'mem3' which platform level decode ranges may this device
 participate". A given expander can participate in multiple CXL.mem interleave
 sets simultaneously depending on how many decoder resource it has. In this
 example mem3 can participate in one or more of a PMEM interleave that spans to
 Host Bridges, a PMEM interleave that targets a single Host Bridge, a Volatile
 memory interleave that spans 2 Host Bridges, and a Volatile memory interleave
 that only targets a single Host Bridge.

 Conversely the memory devices that can participate in a given platform level
 decode scheme can be determined via a command like the following::

     # cxl list -MDu -d 3.2
     [
       {
         "memdevs":[
           {
             "memdev":"mem1",
             "pmem_size":"256.00 MiB (268.44 MB)",
             "ram_size":"256.00 MiB (268.44 MB)",
             "serial":"0",
             "numa_node":0,
             "host":"cxl_mem.0"
           },
           {
             "memdev":"mem5",
             "pmem_size":"256.00 MiB (268.44 MB)",
             "ram_size":"256.00 MiB (268.44 MB)",
             "serial":"0x4",
             "numa_node":0,
             "host":"cxl_mem.4"
           },
           {
             "memdev":"mem7",
             "pmem_size":"256.00 MiB (268.44 MB)",
             "ram_size":"256.00 MiB (268.44 MB)",
             "serial":"0x6",
             "numa_node":0,
             "host":"cxl_mem.6"
           },
           {
             "memdev":"mem3",
             "pmem_size":"256.00 MiB (268.44 MB)",
             "ram_size":"256.00 MiB (268.44 MB)",
             "serial":"0x2",
             "numa_node":0,
             "host":"cxl_mem.2"
           }
         ]
       },
       {
         "root decoders":[
           {
             "decoder":"decoder3.2",
             "resource":"0x8050000000",
             "size":"256.00 MiB (268.44 MB)",
             "pmem_capable":true,
             "nr_targets":1
           }
         ]
       }
     ]

 ...where the naming scheme for decoders is "decoder<port_id>.<instance_id>".

 Driver Infrastructure
 =====================

 This section covers the driver infrastructure for a CXL memory device.

 CXL Memory Device
 -----------------

 .. kernel-doc:: drivers/cxl/pci.c
    :doc: cxl pci

 .. kernel-doc:: drivers/cxl/pci.c
    :internal:

 .. kernel-doc:: drivers/cxl/mem.c
    :doc: cxl mem

 CXL Port
 --------
 .. kernel-doc:: drivers/cxl/port.c
    :doc: cxl port

 CXL Core
 --------
 .. kernel-doc:: drivers/cxl/cxl.h
    :doc: cxl objects

 .. kernel-doc:: drivers/cxl/cxl.h
    :internal:

 .. kernel-doc:: drivers/cxl/core/port.c
    :doc: cxl core

 .. kernel-doc:: drivers/cxl/core/port.c
    :identifiers:

 .. kernel-doc:: drivers/cxl/core/pci.c
    :doc: cxl core pci

 .. kernel-doc:: drivers/cxl/core/pci.c
    :identifiers:

 .. kernel-doc:: drivers/cxl/core/pmem.c
    :doc: cxl pmem

 .. kernel-doc:: drivers/cxl/core/regs.c
    :doc: cxl registers

 .. kernel-doc:: drivers/cxl/core/mbox.c
    :doc: cxl mbox

 CXL Regions
 -----------
 .. kernel-doc:: drivers/cxl/core/region.c
    :doc: cxl core region

 .. kernel-doc:: drivers/cxl/core/region.c
    :identifiers:

 External Interfaces
 ===================

 CXL IOCTL Interface
 -------------------

 .. kernel-doc:: include/uapi/linux/cxl_mem.h
    :doc: UAPI

 .. kernel-doc:: include/uapi/linux/cxl_mem.h
    :internal:
	.. SPDX-License-Identifier: GPL-2.0
	.. include:: <isonum.txt>

	===================================
	Compute Express Link Memory Devices
	===================================

	A Compute Express Link Memory Device is a CXL component that implements the
	CXL.mem protocol. It contains some amount of volatile memory, persistent memory,
	or both. It is enumerated as a PCI device for configuration and passing
	messages over an MMIO mailbox. Its contribution to the System Physical
	Address space is handled via HDM (Host Managed Device Memory) decoders
	that optionally define a device's contribution to an interleaved address
	range across multiple devices underneath a host-bridge or interleaved
	across host-bridges.

	CXL Bus: Theory of Operation
	============================
	Similar to how a RAID driver takes disk objects and assembles them into a new
	logical device, the CXL subsystem is tasked to take PCIe and ACPI objects and
	assemble them into a CXL.mem decode topology. The need for runtime configuration
	of the CXL.mem topology is also similar to RAID in that different environments
	with the same hardware configuration may decide to assemble the topology in
	contrasting ways. One may choose performance (RAID0) striping memory across
	multiple Host Bridges and endpoints while another may opt for fault tolerance
	and disable any striping in the CXL.mem topology.

	Platform firmware enumerates a menu of interleave options at the "CXL root port"
	(Linux term for the top of the CXL decode topology). From there, PCIe topology
	dictates which endpoints can participate in which Host Bridge decode regimes.
	Each PCIe Switch in the path between the root and an endpoint introduces a point
	at which the interleave can be split. For example platform firmware may say at a
	given range only decodes to 1 one Host Bridge, but that Host Bridge may in turn
	interleave cycles across multiple Root Ports. An intervening Switch between a
	port and an endpoint may interleave cycles across multiple Downstream Switch
	Ports, etc.

	Here is a sample listing of a CXL topology defined by 'cxl_test'. The 'cxl_test'
	module generates an emulated CXL topology of 2 Host Bridges each with 2 Root
	Ports. Each of those Root Ports are connected to 2-way switches with endpoints
	connected to those downstream ports for a total of 8 endpoints::

	# cxl list -BEMPu -b cxl_test
	{
	"bus":"root3",
	"provider":"cxl_test",
	"ports:root3":[
	{
	"port":"port5",
	"host":"cxl_host_bridge.1",
	"ports:port5":[
	{
	"port":"port8",
	"host":"cxl_switch_uport.1",
	"endpoints:port8":[
	{
	"endpoint":"endpoint9",
	"host":"mem2",
	"memdev":{
	"memdev":"mem2",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x1",
	"numa_node":1,
	"host":"cxl_mem.1"
	}
	},
	{
	"endpoint":"endpoint15",
	"host":"mem6",
	"memdev":{
	"memdev":"mem6",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x5",
	"numa_node":1,
	"host":"cxl_mem.5"
	}
	}
	]
	},
	{
	"port":"port12",
	"host":"cxl_switch_uport.3",
	"endpoints:port12":[
	{
	"endpoint":"endpoint17",
	"host":"mem8",
	"memdev":{
	"memdev":"mem8",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x7",
	"numa_node":1,
	"host":"cxl_mem.7"
	}
	},
	{
	"endpoint":"endpoint13",
	"host":"mem4",
	"memdev":{
	"memdev":"mem4",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x3",
	"numa_node":1,
	"host":"cxl_mem.3"
	}
	}
	]
	}
	]
	},
	{
	"port":"port4",
	"host":"cxl_host_bridge.0",
	"ports:port4":[
	{
	"port":"port6",
	"host":"cxl_switch_uport.0",
	"endpoints:port6":[
	{
	"endpoint":"endpoint7",
	"host":"mem1",
	"memdev":{
	"memdev":"mem1",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0",
	"numa_node":0,
	"host":"cxl_mem.0"
	}
	},
	{
	"endpoint":"endpoint14",
	"host":"mem5",
	"memdev":{
	"memdev":"mem5",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x4",
	"numa_node":0,
	"host":"cxl_mem.4"
	}
	}
	]
	},
	{
	"port":"port10",
	"host":"cxl_switch_uport.2",
	"endpoints:port10":[
	{
	"endpoint":"endpoint16",
	"host":"mem7",
	"memdev":{
	"memdev":"mem7",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x6",
	"numa_node":0,
	"host":"cxl_mem.6"
	}
	},
	{
	"endpoint":"endpoint11",
	"host":"mem3",
	"memdev":{
	"memdev":"mem3",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x2",
	"numa_node":0,
	"host":"cxl_mem.2"
	}
	}
	]
	}
	]
	}
	]
	}

	In that listing each "root", "port", and "endpoint" object correspond a kernel
	'struct cxl_port' object. A 'cxl_port' is a device that can decode CXL.mem to
	its descendants. So "root" claims non-PCIe enumerable platform decode ranges and
	decodes them to "ports", "ports" decode to "endpoints", and "endpoints"
	represent the decode from SPA (System Physical Address) to DPA (Device Physical
	Address).

	Continuing the RAID analogy, disks have both topology metadata and on device
	metadata that determine RAID set assembly. CXL Port topology and CXL Port link
	status is metadata for CXL.mem set assembly. The CXL Port topology is enumerated
	by the arrival of a CXL.mem device. I.e. unless and until the PCIe core attaches
	the cxl_pci driver to a CXL Memory Expander there is no role for CXL Port
	objects. Conversely for hot-unplug / removal scenarios, there is no need for
	the Linux PCI core to tear down switch-level CXL resources because the endpoint
	->remove() event cleans up the port data that was established to support that
	Memory Expander.

	The port metadata and potential decode schemes that a give memory device may
	participate can be determined via a command like::

	# cxl list -BDMu -d root -m mem3
	{
	"bus":"root3",
	"provider":"cxl_test",
	"decoders:root3":[
	{
	"decoder":"decoder3.1",
	"resource":"0x8030000000",
	"size":"512.00 MiB (536.87 MB)",
	"volatile_capable":true,
	"nr_targets":2
	},
	{
	"decoder":"decoder3.3",
	"resource":"0x8060000000",
	"size":"512.00 MiB (536.87 MB)",
	"pmem_capable":true,
	"nr_targets":2
	},
	{
	"decoder":"decoder3.0",
	"resource":"0x8020000000",
	"size":"256.00 MiB (268.44 MB)",
	"volatile_capable":true,
	"nr_targets":1
	},
	{
	"decoder":"decoder3.2",
	"resource":"0x8050000000",
	"size":"256.00 MiB (268.44 MB)",
	"pmem_capable":true,
	"nr_targets":1
	}
	],
	"memdevs:root3":[
	{
	"memdev":"mem3",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x2",
	"numa_node":0,
	"host":"cxl_mem.2"
	}
	]
	}

	...which queries the CXL topology to ask "given CXL Memory Expander with a kernel
	device name of 'mem3' which platform level decode ranges may this device
	participate". A given expander can participate in multiple CXL.mem interleave
	sets simultaneously depending on how many decoder resource it has. In this
	example mem3 can participate in one or more of a PMEM interleave that spans to
	Host Bridges, a PMEM interleave that targets a single Host Bridge, a Volatile
	memory interleave that spans 2 Host Bridges, and a Volatile memory interleave
	that only targets a single Host Bridge.

	Conversely the memory devices that can participate in a given platform level
	decode scheme can be determined via a command like the following::

	# cxl list -MDu -d 3.2
	[
	{
	"memdevs":[
	{
	"memdev":"mem1",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0",
	"numa_node":0,
	"host":"cxl_mem.0"
	},
	{
	"memdev":"mem5",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x4",
	"numa_node":0,
	"host":"cxl_mem.4"
	},
	{
	"memdev":"mem7",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x6",
	"numa_node":0,
	"host":"cxl_mem.6"
	},
	{
	"memdev":"mem3",
	"pmem_size":"256.00 MiB (268.44 MB)",
	"ram_size":"256.00 MiB (268.44 MB)",
	"serial":"0x2",
	"numa_node":0,
	"host":"cxl_mem.2"
	}
	]
	},
	{
	"root decoders":[
	{
	"decoder":"decoder3.2",
	"resource":"0x8050000000",
	"size":"256.00 MiB (268.44 MB)",
	"pmem_capable":true,
	"nr_targets":1
	}
	]
	}
	]

	...where the naming scheme for decoders is "decoder<port_id>.<instance_id>".

	Driver Infrastructure
	=====================

	This section covers the driver infrastructure for a CXL memory device.

	CXL Memory Device
	-----------------

	.. kernel-doc:: drivers/cxl/pci.c
	:doc: cxl pci

	.. kernel-doc:: drivers/cxl/pci.c
	:internal:

	.. kernel-doc:: drivers/cxl/mem.c
	:doc: cxl mem

	CXL Port
	--------
	.. kernel-doc:: drivers/cxl/port.c
	:doc: cxl port

	CXL Core
	--------
	.. kernel-doc:: drivers/cxl/cxl.h
	:doc: cxl objects

	.. kernel-doc:: drivers/cxl/cxl.h
	:internal:

	.. kernel-doc:: drivers/cxl/core/port.c
	:doc: cxl core

	.. kernel-doc:: drivers/cxl/core/port.c
	:identifiers:

	.. kernel-doc:: drivers/cxl/core/pci.c
	:doc: cxl core pci

	.. kernel-doc:: drivers/cxl/core/pci.c
	:identifiers:

	.. kernel-doc:: drivers/cxl/core/pmem.c
	:doc: cxl pmem

	.. kernel-doc:: drivers/cxl/core/regs.c
	:doc: cxl registers

	.. kernel-doc:: drivers/cxl/core/mbox.c
	:doc: cxl mbox

	CXL Regions
	-----------
	.. kernel-doc:: drivers/cxl/core/region.c
	:doc: cxl core region

	.. kernel-doc:: drivers/cxl/core/region.c
	:identifiers:

	External Interfaces
	===================

	CXL IOCTL Interface
	-------------------

	.. kernel-doc:: include/uapi/linux/cxl_mem.h
	:doc: UAPI

	.. kernel-doc:: include/uapi/linux/cxl_mem.h
	:internal: