317 lines
16 KiB
ReStructuredText
317 lines
16 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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PCI pass-thru devices
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=========================
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In a Hyper-V guest VM, PCI pass-thru devices (also called
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virtual PCI devices, or vPCI devices) are physical PCI devices
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that are mapped directly into the VM's physical address space.
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Guest device drivers can interact directly with the hardware
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without intermediation by the host hypervisor. This approach
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provides higher bandwidth access to the device with lower
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latency, compared with devices that are virtualized by the
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hypervisor. The device should appear to the guest just as it
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would when running on bare metal, so no changes are required
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to the Linux device drivers for the device.
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Hyper-V terminology for vPCI devices is "Discrete Device
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Assignment" (DDA). Public documentation for Hyper-V DDA is
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available here: `DDA`_
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.. _DDA: https://learn.microsoft.com/en-us/windows-server/virtualization/hyper-v/plan/plan-for-deploying-devices-using-discrete-device-assignment
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DDA is typically used for storage controllers, such as NVMe,
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and for GPUs. A similar mechanism for NICs is called SR-IOV
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and produces the same benefits by allowing a guest device
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driver to interact directly with the hardware. See Hyper-V
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public documentation here: `SR-IOV`_
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.. _SR-IOV: https://learn.microsoft.com/en-us/windows-hardware/drivers/network/overview-of-single-root-i-o-virtualization--sr-iov-
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This discussion of vPCI devices includes DDA and SR-IOV
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devices.
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Device Presentation
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-------------------
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Hyper-V provides full PCI functionality for a vPCI device when
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it is operating, so the Linux device driver for the device can
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be used unchanged, provided it uses the correct Linux kernel
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APIs for accessing PCI config space and for other integration
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with Linux. But the initial detection of the PCI device and
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its integration with the Linux PCI subsystem must use Hyper-V
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specific mechanisms. Consequently, vPCI devices on Hyper-V
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have a dual identity. They are initially presented to Linux
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guests as VMBus devices via the standard VMBus "offer"
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mechanism, so they have a VMBus identity and appear under
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/sys/bus/vmbus/devices. The VMBus vPCI driver in Linux at
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drivers/pci/controller/pci-hyperv.c handles a newly introduced
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vPCI device by fabricating a PCI bus topology and creating all
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the normal PCI device data structures in Linux that would
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exist if the PCI device were discovered via ACPI on a bare-
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metal system. Once those data structures are set up, the
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device also has a normal PCI identity in Linux, and the normal
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Linux device driver for the vPCI device can function as if it
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were running in Linux on bare-metal. Because vPCI devices are
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presented dynamically through the VMBus offer mechanism, they
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do not appear in the Linux guest's ACPI tables. vPCI devices
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may be added to a VM or removed from a VM at any time during
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the life of the VM, and not just during initial boot.
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With this approach, the vPCI device is a VMBus device and a
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PCI device at the same time. In response to the VMBus offer
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message, the hv_pci_probe() function runs and establishes a
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VMBus connection to the vPCI VSP on the Hyper-V host. That
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connection has a single VMBus channel. The channel is used to
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exchange messages with the vPCI VSP for the purpose of setting
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up and configuring the vPCI device in Linux. Once the device
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is fully configured in Linux as a PCI device, the VMBus
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channel is used only if Linux changes the vCPU to be interrupted
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in the guest, or if the vPCI device is removed from
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the VM while the VM is running. The ongoing operation of the
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device happens directly between the Linux device driver for
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the device and the hardware, with VMBus and the VMBus channel
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playing no role.
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PCI Device Setup
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----------------
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PCI device setup follows a sequence that Hyper-V originally
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created for Windows guests, and that can be ill-suited for
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Linux guests due to differences in the overall structure of
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the Linux PCI subsystem compared with Windows. Nonetheless,
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with a bit of hackery in the Hyper-V virtual PCI driver for
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Linux, the virtual PCI device is setup in Linux so that
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generic Linux PCI subsystem code and the Linux driver for the
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device "just work".
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Each vPCI device is set up in Linux to be in its own PCI
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domain with a host bridge. The PCI domainID is derived from
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bytes 4 and 5 of the instance GUID assigned to the VMBus vPCI
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device. The Hyper-V host does not guarantee that these bytes
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are unique, so hv_pci_probe() has an algorithm to resolve
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collisions. The collision resolution is intended to be stable
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across reboots of the same VM so that the PCI domainIDs don't
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change, as the domainID appears in the user space
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configuration of some devices.
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hv_pci_probe() allocates a guest MMIO range to be used as PCI
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config space for the device. This MMIO range is communicated
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to the Hyper-V host over the VMBus channel as part of telling
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the host that the device is ready to enter d0. See
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hv_pci_enter_d0(). When the guest subsequently accesses this
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MMIO range, the Hyper-V host intercepts the accesses and maps
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them to the physical device PCI config space.
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hv_pci_probe() also gets BAR information for the device from
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the Hyper-V host, and uses this information to allocate MMIO
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space for the BARs. That MMIO space is then setup to be
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associated with the host bridge so that it works when generic
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PCI subsystem code in Linux processes the BARs.
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Finally, hv_pci_probe() creates the root PCI bus. At this
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point the Hyper-V virtual PCI driver hackery is done, and the
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normal Linux PCI machinery for scanning the root bus works to
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detect the device, to perform driver matching, and to
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initialize the driver and device.
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PCI Device Removal
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------------------
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A Hyper-V host may initiate removal of a vPCI device from a
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guest VM at any time during the life of the VM. The removal
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is instigated by an admin action taken on the Hyper-V host and
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is not under the control of the guest OS.
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A guest VM is notified of the removal by an unsolicited
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"Eject" message sent from the host to the guest over the VMBus
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channel associated with the vPCI device. Upon receipt of such
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a message, the Hyper-V virtual PCI driver in Linux
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asynchronously invokes Linux kernel PCI subsystem calls to
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shutdown and remove the device. When those calls are
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complete, an "Ejection Complete" message is sent back to
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Hyper-V over the VMBus channel indicating that the device has
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been removed. At this point, Hyper-V sends a VMBus rescind
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message to the Linux guest, which the VMBus driver in Linux
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processes by removing the VMBus identity for the device. Once
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that processing is complete, all vestiges of the device having
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been present are gone from the Linux kernel. The rescind
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message also indicates to the guest that Hyper-V has stopped
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providing support for the vPCI device in the guest. If the
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guest were to attempt to access that device's MMIO space, it
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would be an invalid reference. Hypercalls affecting the device
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return errors, and any further messages sent in the VMBus
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channel are ignored.
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After sending the Eject message, Hyper-V allows the guest VM
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60 seconds to cleanly shutdown the device and respond with
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Ejection Complete before sending the VMBus rescind
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message. If for any reason the Eject steps don't complete
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within the allowed 60 seconds, the Hyper-V host forcibly
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performs the rescind steps, which will likely result in
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cascading errors in the guest because the device is now no
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longer present from the guest standpoint and accessing the
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device MMIO space will fail.
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Because ejection is asynchronous and can happen at any point
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during the guest VM lifecycle, proper synchronization in the
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Hyper-V virtual PCI driver is very tricky. Ejection has been
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observed even before a newly offered vPCI device has been
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fully setup. The Hyper-V virtual PCI driver has been updated
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several times over the years to fix race conditions when
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ejections happen at inopportune times. Care must be taken when
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modifying this code to prevent re-introducing such problems.
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See comments in the code.
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Interrupt Assignment
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--------------------
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The Hyper-V virtual PCI driver supports vPCI devices using
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MSI, multi-MSI, or MSI-X. Assigning the guest vCPU that will
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receive the interrupt for a particular MSI or MSI-X message is
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complex because of the way the Linux setup of IRQs maps onto
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the Hyper-V interfaces. For the single-MSI and MSI-X cases,
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Linux calls hv_compse_msi_msg() twice, with the first call
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containing a dummy vCPU and the second call containing the
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real vCPU. Furthermore, hv_irq_unmask() is finally called
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(on x86) or the GICD registers are set (on arm64) to specify
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the real vCPU again. Each of these three calls interact
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with Hyper-V, which must decide which physical CPU should
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receive the interrupt before it is forwarded to the guest VM.
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Unfortunately, the Hyper-V decision-making process is a bit
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limited, and can result in concentrating the physical
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interrupts on a single CPU, causing a performance bottleneck.
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See details about how this is resolved in the extensive
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comment above the function hv_compose_msi_req_get_cpu().
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The Hyper-V virtual PCI driver implements the
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irq_chip.irq_compose_msi_msg function as hv_compose_msi_msg().
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Unfortunately, on Hyper-V the implementation requires sending
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a VMBus message to the Hyper-V host and awaiting an interrupt
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indicating receipt of a reply message. Since
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irq_chip.irq_compose_msi_msg can be called with IRQ locks
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held, it doesn't work to do the normal sleep until awakened by
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the interrupt. Instead hv_compose_msi_msg() must send the
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VMBus message, and then poll for the completion message. As
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further complexity, the vPCI device could be ejected/rescinded
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while the polling is in progress, so this scenario must be
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detected as well. See comments in the code regarding this
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very tricky area.
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Most of the code in the Hyper-V virtual PCI driver (pci-
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hyperv.c) applies to Hyper-V and Linux guests running on x86
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and on arm64 architectures. But there are differences in how
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interrupt assignments are managed. On x86, the Hyper-V
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virtual PCI driver in the guest must make a hypercall to tell
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Hyper-V which guest vCPU should be interrupted by each
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MSI/MSI-X interrupt, and the x86 interrupt vector number that
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the x86_vector IRQ domain has picked for the interrupt. This
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hypercall is made by hv_arch_irq_unmask(). On arm64, the
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Hyper-V virtual PCI driver manages the allocation of an SPI
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for each MSI/MSI-X interrupt. The Hyper-V virtual PCI driver
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stores the allocated SPI in the architectural GICD registers,
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which Hyper-V emulates, so no hypercall is necessary as with
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x86. Hyper-V does not support using LPIs for vPCI devices in
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arm64 guest VMs because it does not emulate a GICv3 ITS.
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The Hyper-V virtual PCI driver in Linux supports vPCI devices
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whose drivers create managed or unmanaged Linux IRQs. If the
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smp_affinity for an unmanaged IRQ is updated via the /proc/irq
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interface, the Hyper-V virtual PCI driver is called to tell
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the Hyper-V host to change the interrupt targeting and
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everything works properly. However, on x86 if the x86_vector
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IRQ domain needs to reassign an interrupt vector due to
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running out of vectors on a CPU, there's no path to inform the
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Hyper-V host of the change, and things break. Fortunately,
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guest VMs operate in a constrained device environment where
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using all the vectors on a CPU doesn't happen. Since such a
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problem is only a theoretical concern rather than a practical
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concern, it has been left unaddressed.
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DMA
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---
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By default, Hyper-V pins all guest VM memory in the host
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when the VM is created, and programs the physical IOMMU to
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allow the VM to have DMA access to all its memory. Hence
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it is safe to assign PCI devices to the VM, and allow the
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guest operating system to program the DMA transfers. The
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physical IOMMU prevents a malicious guest from initiating
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DMA to memory belonging to the host or to other VMs on the
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host. From the Linux guest standpoint, such DMA transfers
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are in "direct" mode since Hyper-V does not provide a virtual
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IOMMU in the guest.
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Hyper-V assumes that physical PCI devices always perform
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cache-coherent DMA. When running on x86, this behavior is
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required by the architecture. When running on arm64, the
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architecture allows for both cache-coherent and
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non-cache-coherent devices, with the behavior of each device
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specified in the ACPI DSDT. But when a PCI device is assigned
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to a guest VM, that device does not appear in the DSDT, so the
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Hyper-V VMBus driver propagates cache-coherency information
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from the VMBus node in the ACPI DSDT to all VMBus devices,
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including vPCI devices (since they have a dual identity as a VMBus
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device and as a PCI device). See vmbus_dma_configure().
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Current Hyper-V versions always indicate that the VMBus is
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cache coherent, so vPCI devices on arm64 always get marked as
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cache coherent and the CPU does not perform any sync
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operations as part of dma_map/unmap_*() calls.
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vPCI protocol versions
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----------------------
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As previously described, during vPCI device setup and teardown
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messages are passed over a VMBus channel between the Hyper-V
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host and the Hyper-v vPCI driver in the Linux guest. Some
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messages have been revised in newer versions of Hyper-V, so
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the guest and host must agree on the vPCI protocol version to
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be used. The version is negotiated when communication over
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the VMBus channel is first established. See
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hv_pci_protocol_negotiation(). Newer versions of the protocol
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extend support to VMs with more than 64 vCPUs, and provide
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additional information about the vPCI device, such as the
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guest virtual NUMA node to which it is most closely affined in
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the underlying hardware.
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Guest NUMA node affinity
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------------------------
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When the vPCI protocol version provides it, the guest NUMA
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node affinity of the vPCI device is stored as part of the Linux
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device information for subsequent use by the Linux driver. See
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hv_pci_assign_numa_node(). If the negotiated protocol version
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does not support the host providing NUMA affinity information,
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the Linux guest defaults the device NUMA node to 0. But even
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when the negotiated protocol version includes NUMA affinity
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information, the ability of the host to provide such
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information depends on certain host configuration options. If
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the guest receives NUMA node value "0", it could mean NUMA
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node 0, or it could mean "no information is available".
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Unfortunately it is not possible to distinguish the two cases
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from the guest side.
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PCI config space access in a CoCo VM
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------------------------------------
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Linux PCI device drivers access PCI config space using a
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standard set of functions provided by the Linux PCI subsystem.
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In Hyper-V guests these standard functions map to functions
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hv_pcifront_read_config() and hv_pcifront_write_config()
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in the Hyper-V virtual PCI driver. In normal VMs,
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these hv_pcifront_*() functions directly access the PCI config
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space, and the accesses trap to Hyper-V to be handled.
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But in CoCo VMs, memory encryption prevents Hyper-V
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from reading the guest instruction stream to emulate the
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access, so the hv_pcifront_*() functions must invoke
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hypercalls with explicit arguments describing the access to be
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made.
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Config Block back-channel
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-------------------------
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The Hyper-V host and Hyper-V virtual PCI driver in Linux
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together implement a non-standard back-channel communication
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path between the host and guest. The back-channel path uses
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messages sent over the VMBus channel associated with the vPCI
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device. The functions hyperv_read_cfg_blk() and
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hyperv_write_cfg_blk() are the primary interfaces provided to
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other parts of the Linux kernel. As of this writing, these
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interfaces are used only by the Mellanox mlx5 driver to pass
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diagnostic data to a Hyper-V host running in the Azure public
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cloud. The functions hyperv_read_cfg_blk() and
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hyperv_write_cfg_blk() are implemented in a separate module
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(pci-hyperv-intf.c, under CONFIG_PCI_HYPERV_INTERFACE) that
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effectively stubs them out when running in non-Hyper-V
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environments.
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