docs/pcie.txt - qemu - Git at Google

 PCI EXPRESS GUIDELINES
 ======================

 1. Introduction
 ================
 The doc proposes best practices on how to use PCI Express (PCIe) / PCI
 devices in PCI Express based machines and explains the reasoning behind
 them.

 Note that the PCIe features are available only when using the 'q35'
 machine type on x86 architecture and the 'virt' machine type on AArch64.
 Other machine types do not use PCIe at this time.

 The following presentations accompany this document:
  (1) Q35 overview.
      https://wiki.qemu.org/images/4/4e/Q35.pdf
  (2) A comparison between PCI and PCI Express technologies.
      https://wiki.qemu.org/images/f/f6/PCIvsPCIe.pdf

 Note: The usage examples are not intended to replace the full
 documentation, please use QEMU help to retrieve all options.

 2. Device placement strategy
 ============================
 QEMU does not have a clear socket-device matching mechanism
 and allows any PCI/PCI Express device to be plugged into any
 PCI/PCI Express slot.
 Plugging a PCI device into a PCI Express slot might not always work and
 is weird anyway since it cannot be done for "bare metal".
 Plugging a PCI Express device into a PCI slot will hide the Extended
 Configuration Space thus is also not recommended.

 The recommendation is to separate the PCI Express and PCI hierarchies.
 PCI Express devices should be plugged only into PCI Express Root Ports and
 PCI Express Downstream ports.

 2.1 Root Bus (pcie.0)
 =====================
 Place only the following kinds of devices directly on the Root Complex:
     (1) PCI Devices (e.g. network card, graphics card, IDE controller),
         not controllers. Place only legacy PCI devices on
         the Root Complex. These will be considered Integrated Endpoints.
         Note: Integrated Endpoints are not hot-pluggable.

         Although the PCI Express spec does not forbid PCI Express devices as
         Integrated Endpoints, existing hardware mostly integrates legacy PCI
         devices with the Root Complex. Guest OSes are suspected to behave
         strangely when PCI Express devices are integrated
         with the Root Complex.

     (2) PCI Express Root Ports (pcie-root-port), for starting exclusively
         PCI Express hierarchies.

     (3) PCI Express to PCI Bridge (pcie-pci-bridge), for starting legacy PCI
         hierarchies.

     (4) Extra Root Complexes (pxb-pcie), if multiple PCI Express Root Buses
         are needed.

    pcie.0 bus
    ----------------------------------------------------------------------------
         |                |                    |                  |
    -----------   ------------------   -------------------   --------------
    | PCI Dev |   | PCIe Root Port |   | PCIe-PCI Bridge |   |  pxb-pcie  |
    -----------   ------------------   -------------------   --------------

 2.1.1 To plug a device into pcie.0 as a Root Complex Integrated Endpoint use:
           -device <dev>[,bus=pcie.0]
 2.1.2 To expose a new PCI Express Root Bus use:
           -device pxb-pcie,id=pcie.1,bus_nr=x[,numa_node=y][,addr=z]
       PCI Express Root Ports and PCI Express to PCI bridges can be
       connected to the pcie.1 bus:
           -device pcie-root-port,id=root_port1[,bus=pcie.1][,chassis=x][,slot=y][,addr=z] \
           -device pcie-pci-bridge,id=pcie_pci_bridge1,bus=pcie.1


 2.2 PCI Express only hierarchy
 ==============================
 Always use PCI Express Root Ports to start PCI Express hierarchies.

 A PCI Express Root bus supports up to 32 devices. Since each
 PCI Express Root Port is a function and a multi-function
 device may support up to 8 functions, the maximum possible
 number of PCI Express Root Ports per PCI Express Root Bus is 256.

 Prefer grouping PCI Express Root Ports into multi-function devices
 to keep a simple flat hierarchy that is enough for most scenarios.
 Only use PCI Express Switches (x3130-upstream, xio3130-downstream)
 if there is no more room for PCI Express Root Ports.
 Please see section 4. for further justifications.

 Plug only PCI Express devices into PCI Express Ports.


    pcie.0 bus
    ----------------------------------------------------------------------------------
         |                 |                                    |
    -------------    -------------                        -------------
    | Root Port |    | Root Port |                        | Root Port |
    ------------     -------------                        -------------
          |                            -------------------------|------------------------
     ------------                      |                 -----------------              |
     | PCIe Dev |                      |    PCI Express  | Upstream Port |              |
     ------------                      |      Switch     -----------------              |
                                       |                  |            |                |
                                       |    -------------------    -------------------  |
                                       |    | Downstream Port |    | Downstream Port |  |
                                       |    -------------------    -------------------  |
                                       -------------|-----------------------|------------
                                              ------------
                                              | PCIe Dev |
                                              ------------

 2.2.1 Plugging a PCI Express device into a PCI Express Root Port:
           -device pcie-root-port,id=root_port1,chassis=x,slot=y[,bus=pcie.0][,addr=z]  \
           -device <dev>,bus=root_port1
 2.2.2 Using multi-function PCI Express Root Ports:
       -device pcie-root-port,id=root_port1,multifunction=on,chassis=x,addr=z.0[,slot=y][,bus=pcie.0] \
       -device pcie-root-port,id=root_port2,chassis=x1,addr=z.1[,slot=y1][,bus=pcie.0] \
       -device pcie-root-port,id=root_port3,chassis=x2,addr=z.2[,slot=y2][,bus=pcie.0] \
 2.2.3 Plugging a PCI Express device into a Switch:
       -device pcie-root-port,id=root_port1,chassis=x,slot=y[,bus=pcie.0][,addr=z]  \
       -device x3130-upstream,id=upstream_port1,bus=root_port1[,addr=x]          \
       -device xio3130-downstream,id=downstream_port1,bus=upstream_port1,chassis=x1,slot=y1[,addr=z1]] \
       -device <dev>,bus=downstream_port1

 Notes:
   - (slot, chassis) pair is mandatory and must be unique for each
     PCI Express Root Port. slot defaults to 0 when not specified.
   - 'addr' parameter can be 0 for all the examples above.


 2.3 PCI only hierarchy
 ======================
 Legacy PCI devices can be plugged into pcie.0 as Integrated Endpoints,
 but, as mentioned in section 5, doing so means the legacy PCI
 device in question will be incapable of hot-unplugging.
 Besides that use PCI Express to PCI Bridges (pcie-pci-bridge) in
 combination with PCI-PCI Bridges (pci-bridge) to start PCI hierarchies.

 Prefer flat hierarchies. For most scenarios a single PCI Express to PCI Bridge
 (having 32 slots) and several PCI-PCI Bridges attached to it
 (each supporting also 32 slots) will support hundreds of legacy devices.
 The recommendation is to populate one PCI-PCI Bridge under the
 PCI Express to PCI Bridge until is full and then plug a new PCI-PCI Bridge...

    pcie.0 bus
    ----------------------------------------------
         |                            |
    -----------               -------------------
    | PCI Dev |               | PCIe-PCI Bridge |
    -----------               -------------------
                                |            |
                   ------------------    ------------------
                   | PCI-PCI Bridge |    | PCI-PCI Bridge |
                   ------------------    ------------------
                                          |           |
                                   -----------     -----------
                                   | PCI Dev |     | PCI Dev |
                                   -----------     -----------

 2.3.1 To plug a PCI device into pcie.0 as an Integrated Endpoint use:
       -device <dev>[,bus=pcie.0]
 2.3.2 Plugging a PCI device into a PCI-PCI Bridge:
       -device pcie-pci-bridge,id=pcie_pci_bridge1[,bus=pcie.0] \
       -device pci-bridge,id=pci_bridge1,bus=pcie_pci_bridge1[,chassis_nr=x][,addr=y] \
       -device <dev>,bus=pci_bridge1[,addr=x]
       Note that 'addr' cannot be 0 unless shpc=off parameter is passed to
       the PCI Bridge/PCI Express to PCI Bridge.

 3. IO space issues
 ===================
 The PCI Express Root Ports and PCI Express Downstream ports are seen by
 Firmware/Guest OS as PCI-PCI Bridges. As required by the PCI spec, each
 such Port should be reserved a 4K IO range for, even though only one
 (multifunction) device can be plugged into each Port. This results in
 poor IO space utilization.

 The firmware used by QEMU (SeaBIOS/OVMF) may try further optimizations
 by not allocating IO space for each PCI Express Root / PCI Express
 Downstream port if:
     (1) the port is empty, or
     (2) the device behind the port has no IO BARs.

 The IO space is very limited, to 65536 byte-wide IO ports, and may even be
 fragmented by fixed IO ports owned by platform devices resulting in at most
 10 PCI Express Root Ports or PCI Express Downstream Ports per system
 if devices with IO BARs are used in the PCI Express hierarchy. Using the
 proposed device placing strategy solves this issue by using only
 PCI Express devices within PCI Express hierarchy.

 The PCI Express spec requires that PCI Express devices work properly
 without using IO ports. The PCI hierarchy has no such limitations.


 4. Bus numbers issues
 ======================
 Each PCI domain can have up to only 256 buses and the QEMU PCI Express
 machines do not support multiple PCI domains even if extra Root
 Complexes (pxb-pcie) are used.

 Each element of the PCI Express hierarchy (Root Complexes,
 PCI Express Root Ports, PCI Express Downstream/Upstream ports)
 uses one bus number. Since only one (multifunction) device
 can be attached to a PCI Express Root Port or PCI Express Downstream
 Port it is advised to plan in advance for the expected number of
 devices to prevent bus number starvation.

 Avoiding PCI Express Switches (and thereby striving for a 'flatter' PCI
 Express hierarchy) enables the hierarchy to not spend bus numbers on
 Upstream Ports.

 The bus_nr properties of the pxb-pcie devices partition the 0..255 bus
 number space. All bus numbers assigned to the buses recursively behind a
 given pxb-pcie device's root bus must fit between the bus_nr property of
 that pxb-pcie device, and the lowest of the higher bus_nr properties
 that the command line sets for other pxb-pcie devices.


 5. Hot-plug
 ============
 The PCI Express root buses (pcie.0 and the buses exposed by pxb-pcie devices)
 do not support hot-plug, so any devices plugged into Root Complexes
 cannot be hot-plugged/hot-unplugged:
     (1) PCI Express Integrated Endpoints
     (2) PCI Express Root Ports
     (3) PCI Express to PCI Bridges
     (4) pxb-pcie

 Be aware that PCI Express Downstream Ports can't be hot-plugged into
 an existing PCI Express Upstream Port.

 PCI devices can be hot-plugged into PCI Express to PCI and PCI-PCI Bridges.
 The PCI hot-plug into PCI-PCI bridge is ACPI based, whereas hot-plug into
 PCI Express to PCI bridges is SHPC-based. They both can work side by side with
 the PCI Express native hot-plug.

 PCI Express devices can be natively hot-plugged/hot-unplugged into/from
 PCI Express Root Ports (and PCI Express Downstream Ports).

 5.1 Planning for hot-plug:
     (1) PCI hierarchy
         Leave enough PCI-PCI Bridge slots empty or add one
         or more empty PCI-PCI Bridges to the PCI Express to PCI Bridge.

         For each such PCI-PCI Bridge the Guest Firmware is expected to reserve
         4K IO space and 2M MMIO range to be used for all devices behind it.
         Appropriate PCI capability is designed, see pcie_pci_bridge.txt.

         Because of the hard IO limit of around 10 PCI Bridges (~ 40K space)
         per system don't use more than 9 PCI-PCI Bridges, leaving 4K for the
         Integrated Endpoints. (The PCI Express Hierarchy needs no IO space).

     (2) PCI Express hierarchy:
         Leave enough PCI Express Root Ports empty. Use multifunction
         PCI Express Root Ports (up to 8 ports per pcie.0 slot)
         on the Root Complex(es), for keeping the
         hierarchy as flat as possible, thereby saving PCI bus numbers.
         Don't use PCI Express Switches if you don't have
         to, each one of those uses an extra PCI bus (for its Upstream Port)
         that could be put to better use with another Root Port or Downstream
         Port, which may come handy for hot-plugging another device.


 5.3 Hot-plug example:
 Using HMP: (add -monitor stdio to QEMU command line)
   device_add <dev>,id=<id>,bus=<PCI Express Root Port Id/PCI Express Downstream Port Id/PCI-PCI Bridge Id/>


 6. Device assignment
 ====================
 Host devices are mostly PCI Express and should be plugged only into
 PCI Express Root Ports or PCI Express Downstream Ports.
 PCI-PCI Bridge slots can be used for legacy PCI host devices.

 6.1 How to detect if a device is PCI Express:
   > lspci -s 03:00.0 -v (as root)

     03:00.0 Network controller: Intel Corporation Wireless 7260 (rev 83)
     Subsystem: Intel Corporation Dual Band Wireless-AC 7260
     Flags: bus master, fast devsel, latency 0, IRQ 50
     Memory at f0400000 (64-bit, non-prefetchable) [size=8K]
     Capabilities: [c8] Power Management version 3
     Capabilities: [d0] MSI: Enable+ Count=1/1 Maskable- 64bit+
     Capabilities: [40] Express Endpoint, MSI 00
     ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
     Capabilities: [100] Advanced Error Reporting
     Capabilities: [140] Device Serial Number 7c-7a-91-ff-ff-90-db-20
     Capabilities: [14c] Latency Tolerance Reporting
     Capabilities: [154] Vendor Specific Information: ID=cafe Rev=1 Len=014

 If you can see the "Express Endpoint" capability in the
 output, then the device is indeed PCI Express.


 7. Virtio devices
 =================
 Virtio devices plugged into the PCI hierarchy or as Integrated Endpoints
 will remain PCI and have transitional behaviour as default.
 Transitional virtio devices work in both IO and MMIO modes depending on
 the guest support. The Guest firmware will assign both IO and MMIO resources
 to transitional virtio devices.

 Virtio devices plugged into PCI Express ports are PCI Express devices and
 have "1.0" behavior by default without IO support.
 In both cases disable-legacy and disable-modern properties can be used
 to override the behaviour.

 Note that setting disable-legacy=off will enable legacy mode (enabling
 legacy behavior) for PCI Express virtio devices causing them to
 require IO space, which, given the limited available IO space, may quickly
 lead to resource exhaustion, and is therefore strongly discouraged.


 8. Conclusion
 ==============
 The proposal offers a usage model that is easy to understand and follow
 and at the same time overcomes the PCI Express architecture limitations.
	PCI EXPRESS GUIDELINES
	======================

	1. Introduction
	================
	The doc proposes best practices on how to use PCI Express (PCIe) / PCI
	devices in PCI Express based machines and explains the reasoning behind
	them.

	Note that the PCIe features are available only when using the 'q35'
	machine type on x86 architecture and the 'virt' machine type on AArch64.
	Other machine types do not use PCIe at this time.

	The following presentations accompany this document:
	(1) Q35 overview.
	https://wiki.qemu.org/images/4/4e/Q35.pdf
	(2) A comparison between PCI and PCI Express technologies.
	https://wiki.qemu.org/images/f/f6/PCIvsPCIe.pdf

	Note: The usage examples are not intended to replace the full
	documentation, please use QEMU help to retrieve all options.

	2. Device placement strategy
	============================
	QEMU does not have a clear socket-device matching mechanism
	and allows any PCI/PCI Express device to be plugged into any
	PCI/PCI Express slot.
	Plugging a PCI device into a PCI Express slot might not always work and
	is weird anyway since it cannot be done for "bare metal".
	Plugging a PCI Express device into a PCI slot will hide the Extended
	Configuration Space thus is also not recommended.

	The recommendation is to separate the PCI Express and PCI hierarchies.
	PCI Express devices should be plugged only into PCI Express Root Ports and
	PCI Express Downstream ports.

	2.1 Root Bus (pcie.0)
	=====================
	Place only the following kinds of devices directly on the Root Complex:
	(1) PCI Devices (e.g. network card, graphics card, IDE controller),
	not controllers. Place only legacy PCI devices on
	the Root Complex. These will be considered Integrated Endpoints.
	Note: Integrated Endpoints are not hot-pluggable.

	Although the PCI Express spec does not forbid PCI Express devices as
	Integrated Endpoints, existing hardware mostly integrates legacy PCI
	devices with the Root Complex. Guest OSes are suspected to behave
	strangely when PCI Express devices are integrated
	with the Root Complex.

	(2) PCI Express Root Ports (pcie-root-port), for starting exclusively
	PCI Express hierarchies.

	(3) PCI Express to PCI Bridge (pcie-pci-bridge), for starting legacy PCI
	hierarchies.

	(4) Extra Root Complexes (pxb-pcie), if multiple PCI Express Root Buses
	are needed.

	pcie.0 bus
	----------------------------------------------------------------------------
	\| \| \| \|
	----------- ------------------ ------------------- --------------
	\| PCI Dev \| \| PCIe Root Port \| \| PCIe-PCI Bridge \| \| pxb-pcie \|
	----------- ------------------ ------------------- --------------

	2.1.1 To plug a device into pcie.0 as a Root Complex Integrated Endpoint use:
	-device <dev>[,bus=pcie.0]
	2.1.2 To expose a new PCI Express Root Bus use:
	-device pxb-pcie,id=pcie.1,bus_nr=x[,numa_node=y][,addr=z]
	PCI Express Root Ports and PCI Express to PCI bridges can be
	connected to the pcie.1 bus:
	-device pcie-root-port,id=root_port1[,bus=pcie.1][,chassis=x][,slot=y][,addr=z] \
	-device pcie-pci-bridge,id=pcie_pci_bridge1,bus=pcie.1


	2.2 PCI Express only hierarchy
	==============================
	Always use PCI Express Root Ports to start PCI Express hierarchies.

	A PCI Express Root bus supports up to 32 devices. Since each
	PCI Express Root Port is a function and a multi-function
	device may support up to 8 functions, the maximum possible
	number of PCI Express Root Ports per PCI Express Root Bus is 256.

	Prefer grouping PCI Express Root Ports into multi-function devices
	to keep a simple flat hierarchy that is enough for most scenarios.
	Only use PCI Express Switches (x3130-upstream, xio3130-downstream)
	if there is no more room for PCI Express Root Ports.
	Please see section 4. for further justifications.

	Plug only PCI Express devices into PCI Express Ports.


	pcie.0 bus
	----------------------------------------------------------------------------------
	\| \| \|
	------------- ------------- -------------
	\| Root Port \| \| Root Port \| \| Root Port \|
	------------ ------------- -------------
	\| -------------------------\|------------------------
	------------ \| ----------------- \|
	\| PCIe Dev \| \| PCI Express \| Upstream Port \| \|
	------------ \| Switch ----------------- \|
	\| \| \| \|
	\| ------------------- ------------------- \|
	\| \| Downstream Port \| \| Downstream Port \| \|
	\| ------------------- ------------------- \|
	-------------\|-----------------------\|------------
	------------
	\| PCIe Dev \|
	------------

	2.2.1 Plugging a PCI Express device into a PCI Express Root Port:
	-device pcie-root-port,id=root_port1,chassis=x,slot=y[,bus=pcie.0][,addr=z] \
	-device <dev>,bus=root_port1
	2.2.2 Using multi-function PCI Express Root Ports:
	-device pcie-root-port,id=root_port1,multifunction=on,chassis=x,addr=z.0[,slot=y][,bus=pcie.0] \
	-device pcie-root-port,id=root_port2,chassis=x1,addr=z.1[,slot=y1][,bus=pcie.0] \
	-device pcie-root-port,id=root_port3,chassis=x2,addr=z.2[,slot=y2][,bus=pcie.0] \
	2.2.3 Plugging a PCI Express device into a Switch:
	-device pcie-root-port,id=root_port1,chassis=x,slot=y[,bus=pcie.0][,addr=z] \
	-device x3130-upstream,id=upstream_port1,bus=root_port1[,addr=x] \
	-device xio3130-downstream,id=downstream_port1,bus=upstream_port1,chassis=x1,slot=y1[,addr=z1]] \
	-device <dev>,bus=downstream_port1

	Notes:
	- (slot, chassis) pair is mandatory and must be unique for each
	PCI Express Root Port. slot defaults to 0 when not specified.
	- 'addr' parameter can be 0 for all the examples above.


	2.3 PCI only hierarchy
	======================
	Legacy PCI devices can be plugged into pcie.0 as Integrated Endpoints,
	but, as mentioned in section 5, doing so means the legacy PCI
	device in question will be incapable of hot-unplugging.
	Besides that use PCI Express to PCI Bridges (pcie-pci-bridge) in
	combination with PCI-PCI Bridges (pci-bridge) to start PCI hierarchies.

	Prefer flat hierarchies. For most scenarios a single PCI Express to PCI Bridge
	(having 32 slots) and several PCI-PCI Bridges attached to it
	(each supporting also 32 slots) will support hundreds of legacy devices.
	The recommendation is to populate one PCI-PCI Bridge under the
	PCI Express to PCI Bridge until is full and then plug a new PCI-PCI Bridge...

	pcie.0 bus
	----------------------------------------------
	\| \|
	----------- -------------------
	\| PCI Dev \| \| PCIe-PCI Bridge \|
	----------- -------------------
	\| \|
	------------------ ------------------
	\| PCI-PCI Bridge \| \| PCI-PCI Bridge \|
	------------------ ------------------
	\| \|
	----------- -----------
	\| PCI Dev \| \| PCI Dev \|
	----------- -----------

	2.3.1 To plug a PCI device into pcie.0 as an Integrated Endpoint use:
	-device <dev>[,bus=pcie.0]
	2.3.2 Plugging a PCI device into a PCI-PCI Bridge:
	-device pcie-pci-bridge,id=pcie_pci_bridge1[,bus=pcie.0] \
	-device pci-bridge,id=pci_bridge1,bus=pcie_pci_bridge1[,chassis_nr=x][,addr=y] \
	-device <dev>,bus=pci_bridge1[,addr=x]
	Note that 'addr' cannot be 0 unless shpc=off parameter is passed to
	the PCI Bridge/PCI Express to PCI Bridge.

	3. IO space issues
	===================
	The PCI Express Root Ports and PCI Express Downstream ports are seen by
	Firmware/Guest OS as PCI-PCI Bridges. As required by the PCI spec, each
	such Port should be reserved a 4K IO range for, even though only one
	(multifunction) device can be plugged into each Port. This results in
	poor IO space utilization.

	The firmware used by QEMU (SeaBIOS/OVMF) may try further optimizations
	by not allocating IO space for each PCI Express Root / PCI Express
	Downstream port if:
	(1) the port is empty, or
	(2) the device behind the port has no IO BARs.

	The IO space is very limited, to 65536 byte-wide IO ports, and may even be
	fragmented by fixed IO ports owned by platform devices resulting in at most
	10 PCI Express Root Ports or PCI Express Downstream Ports per system
	if devices with IO BARs are used in the PCI Express hierarchy. Using the
	proposed device placing strategy solves this issue by using only
	PCI Express devices within PCI Express hierarchy.

	The PCI Express spec requires that PCI Express devices work properly
	without using IO ports. The PCI hierarchy has no such limitations.


	4. Bus numbers issues
	======================
	Each PCI domain can have up to only 256 buses and the QEMU PCI Express
	machines do not support multiple PCI domains even if extra Root
	Complexes (pxb-pcie) are used.

	Each element of the PCI Express hierarchy (Root Complexes,
	PCI Express Root Ports, PCI Express Downstream/Upstream ports)
	uses one bus number. Since only one (multifunction) device
	can be attached to a PCI Express Root Port or PCI Express Downstream
	Port it is advised to plan in advance for the expected number of
	devices to prevent bus number starvation.

	Avoiding PCI Express Switches (and thereby striving for a 'flatter' PCI
	Express hierarchy) enables the hierarchy to not spend bus numbers on
	Upstream Ports.

	The bus_nr properties of the pxb-pcie devices partition the 0..255 bus
	number space. All bus numbers assigned to the buses recursively behind a
	given pxb-pcie device's root bus must fit between the bus_nr property of
	that pxb-pcie device, and the lowest of the higher bus_nr properties
	that the command line sets for other pxb-pcie devices.


	5. Hot-plug
	============
	The PCI Express root buses (pcie.0 and the buses exposed by pxb-pcie devices)
	do not support hot-plug, so any devices plugged into Root Complexes
	cannot be hot-plugged/hot-unplugged:
	(1) PCI Express Integrated Endpoints
	(2) PCI Express Root Ports
	(3) PCI Express to PCI Bridges
	(4) pxb-pcie

	Be aware that PCI Express Downstream Ports can't be hot-plugged into
	an existing PCI Express Upstream Port.

	PCI devices can be hot-plugged into PCI Express to PCI and PCI-PCI Bridges.
	The PCI hot-plug into PCI-PCI bridge is ACPI based, whereas hot-plug into
	PCI Express to PCI bridges is SHPC-based. They both can work side by side with
	the PCI Express native hot-plug.

	PCI Express devices can be natively hot-plugged/hot-unplugged into/from
	PCI Express Root Ports (and PCI Express Downstream Ports).

	5.1 Planning for hot-plug:
	(1) PCI hierarchy
	Leave enough PCI-PCI Bridge slots empty or add one
	or more empty PCI-PCI Bridges to the PCI Express to PCI Bridge.

	For each such PCI-PCI Bridge the Guest Firmware is expected to reserve
	4K IO space and 2M MMIO range to be used for all devices behind it.
	Appropriate PCI capability is designed, see pcie_pci_bridge.txt.

	Because of the hard IO limit of around 10 PCI Bridges (~ 40K space)
	per system don't use more than 9 PCI-PCI Bridges, leaving 4K for the
	Integrated Endpoints. (The PCI Express Hierarchy needs no IO space).

	(2) PCI Express hierarchy:
	Leave enough PCI Express Root Ports empty. Use multifunction
	PCI Express Root Ports (up to 8 ports per pcie.0 slot)
	on the Root Complex(es), for keeping the
	hierarchy as flat as possible, thereby saving PCI bus numbers.
	Don't use PCI Express Switches if you don't have
	to, each one of those uses an extra PCI bus (for its Upstream Port)
	that could be put to better use with another Root Port or Downstream
	Port, which may come handy for hot-plugging another device.


	5.3 Hot-plug example:
	Using HMP: (add -monitor stdio to QEMU command line)
	device_add <dev>,id=<id>,bus=<PCI Express Root Port Id/PCI Express Downstream Port Id/PCI-PCI Bridge Id/>


	6. Device assignment
	====================
	Host devices are mostly PCI Express and should be plugged only into
	PCI Express Root Ports or PCI Express Downstream Ports.
	PCI-PCI Bridge slots can be used for legacy PCI host devices.

	6.1 How to detect if a device is PCI Express:
	> lspci -s 03:00.0 -v (as root)

	03:00.0 Network controller: Intel Corporation Wireless 7260 (rev 83)
	Subsystem: Intel Corporation Dual Band Wireless-AC 7260
	Flags: bus master, fast devsel, latency 0, IRQ 50
	Memory at f0400000 (64-bit, non-prefetchable) [size=8K]
	Capabilities: [c8] Power Management version 3
	Capabilities: [d0] MSI: Enable+ Count=1/1 Maskable- 64bit+
	Capabilities: [40] Express Endpoint, MSI 00
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
	Capabilities: [100] Advanced Error Reporting
	Capabilities: [140] Device Serial Number 7c-7a-91-ff-ff-90-db-20
	Capabilities: [14c] Latency Tolerance Reporting
	Capabilities: [154] Vendor Specific Information: ID=cafe Rev=1 Len=014

	If you can see the "Express Endpoint" capability in the
	output, then the device is indeed PCI Express.


	7. Virtio devices
	=================
	Virtio devices plugged into the PCI hierarchy or as Integrated Endpoints
	will remain PCI and have transitional behaviour as default.
	Transitional virtio devices work in both IO and MMIO modes depending on
	the guest support. The Guest firmware will assign both IO and MMIO resources
	to transitional virtio devices.

	Virtio devices plugged into PCI Express ports are PCI Express devices and
	have "1.0" behavior by default without IO support.
	In both cases disable-legacy and disable-modern properties can be used
	to override the behaviour.

	Note that setting disable-legacy=off will enable legacy mode (enabling
	legacy behavior) for PCI Express virtio devices causing them to
	require IO space, which, given the limited available IO space, may quickly
	lead to resource exhaustion, and is therefore strongly discouraged.


	8. Conclusion
	==============
	The proposal offers a usage model that is easy to understand and follow
	and at the same time overcomes the PCI Express architecture limitations.