208 lines
9.2 KiB
ReStructuredText
208 lines
9.2 KiB
ReStructuredText
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.. SPDX-License-Identifier: GPL-2.0
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Overview
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========
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The Linux kernel contains a variety of code for running as a fully
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enlightened guest on Microsoft's Hyper-V hypervisor. Hyper-V
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consists primarily of a bare-metal hypervisor plus a virtual machine
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management service running in the parent partition (roughly
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equivalent to KVM and QEMU, for example). Guest VMs run in child
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partitions. In this documentation, references to Hyper-V usually
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encompass both the hypervisor and the VMM service without making a
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distinction about which functionality is provided by which
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component.
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Hyper-V runs on x86/x64 and arm64 architectures, and Linux guests
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are supported on both. The functionality and behavior of Hyper-V is
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generally the same on both architectures unless noted otherwise.
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Linux Guest Communication with Hyper-V
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--------------------------------------
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Linux guests communicate with Hyper-V in four different ways:
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* Implicit traps: As defined by the x86/x64 or arm64 architecture,
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some guest actions trap to Hyper-V. Hyper-V emulates the action and
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returns control to the guest. This behavior is generally invisible
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to the Linux kernel.
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* Explicit hypercalls: Linux makes an explicit function call to
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Hyper-V, passing parameters. Hyper-V performs the requested action
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and returns control to the caller. Parameters are passed in
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processor registers or in memory shared between the Linux guest and
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Hyper-V. On x86/x64, hypercalls use a Hyper-V specific calling
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sequence. On arm64, hypercalls use the ARM standard SMCCC calling
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sequence.
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* Synthetic register access: Hyper-V implements a variety of
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synthetic registers. On x86/x64 these registers appear as MSRs in
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the guest, and the Linux kernel can read or write these MSRs using
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the normal mechanisms defined by the x86/x64 architecture. On
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arm64, these synthetic registers must be accessed using explicit
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hypercalls.
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* VMbus: VMbus is a higher-level software construct that is built on
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the other 3 mechanisms. It is a message passing interface between
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the Hyper-V host and the Linux guest. It uses memory that is shared
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between Hyper-V and the guest, along with various signaling
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mechanisms.
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The first three communication mechanisms are documented in the
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`Hyper-V Top Level Functional Spec (TLFS)`_. The TLFS describes
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general Hyper-V functionality and provides details on the hypercalls
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and synthetic registers. The TLFS is currently written for the
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x86/x64 architecture only.
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.. _Hyper-V Top Level Functional Spec (TLFS): https://docs.microsoft.com/en-us/virtualization/hyper-v-on-windows/tlfs/tlfs
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VMbus is not documented. This documentation provides a high-level
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overview of VMbus and how it works, but the details can be discerned
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only from the code.
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Sharing Memory
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--------------
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Many aspects are communication between Hyper-V and Linux are based
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on sharing memory. Such sharing is generally accomplished as
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follows:
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* Linux allocates memory from its physical address space using
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standard Linux mechanisms.
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* Linux tells Hyper-V the guest physical address (GPA) of the
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allocated memory. Many shared areas are kept to 1 page so that a
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single GPA is sufficient. Larger shared areas require a list of
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GPAs, which usually do not need to be contiguous in the guest
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physical address space. How Hyper-V is told about the GPA or list
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of GPAs varies. In some cases, a single GPA is written to a
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synthetic register. In other cases, a GPA or list of GPAs is sent
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in a VMbus message.
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* Hyper-V translates the GPAs into "real" physical memory addresses,
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and creates a virtual mapping that it can use to access the memory.
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* Linux can later revoke sharing it has previously established by
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telling Hyper-V to set the shared GPA to zero.
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Hyper-V operates with a page size of 4 Kbytes. GPAs communicated to
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Hyper-V may be in the form of page numbers, and always describe a
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range of 4 Kbytes. Since the Linux guest page size on x86/x64 is
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also 4 Kbytes, the mapping from guest page to Hyper-V page is 1-to-1.
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On arm64, Hyper-V supports guests with 4/16/64 Kbyte pages as
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defined by the arm64 architecture. If Linux is using 16 or 64
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Kbyte pages, Linux code must be careful to communicate with Hyper-V
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only in terms of 4 Kbyte pages. HV_HYP_PAGE_SIZE and related macros
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are used in code that communicates with Hyper-V so that it works
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correctly in all configurations.
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As described in the TLFS, a few memory pages shared between Hyper-V
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and the Linux guest are "overlay" pages. With overlay pages, Linux
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uses the usual approach of allocating guest memory and telling
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Hyper-V the GPA of the allocated memory. But Hyper-V then replaces
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that physical memory page with a page it has allocated, and the
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original physical memory page is no longer accessible in the guest
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VM. Linux may access the memory normally as if it were the memory
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that it originally allocated. The "overlay" behavior is visible
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only because the contents of the page (as seen by Linux) change at
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the time that Linux originally establishes the sharing and the
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overlay page is inserted. Similarly, the contents change if Linux
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revokes the sharing, in which case Hyper-V removes the overlay page,
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and the guest page originally allocated by Linux becomes visible
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again.
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Before Linux does a kexec to a kdump kernel or any other kernel,
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memory shared with Hyper-V should be revoked. Hyper-V could modify
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a shared page or remove an overlay page after the new kernel is
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using the page for a different purpose, corrupting the new kernel.
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Hyper-V does not provide a single "set everything" operation to
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guest VMs, so Linux code must individually revoke all sharing before
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doing kexec. See hv_kexec_handler() and hv_crash_handler(). But
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the crash/panic path still has holes in cleanup because some shared
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pages are set using per-CPU synthetic registers and there's no
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mechanism to revoke the shared pages for CPUs other than the CPU
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running the panic path.
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CPU Management
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--------------
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Hyper-V does not have a ability to hot-add or hot-remove a CPU
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from a running VM. However, Windows Server 2019 Hyper-V and
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earlier versions may provide guests with ACPI tables that indicate
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more CPUs than are actually present in the VM. As is normal, Linux
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treats these additional CPUs as potential hot-add CPUs, and reports
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them as such even though Hyper-V will never actually hot-add them.
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Starting in Windows Server 2022 Hyper-V, the ACPI tables reflect
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only the CPUs actually present in the VM, so Linux does not report
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any hot-add CPUs.
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A Linux guest CPU may be taken offline using the normal Linux
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mechanisms, provided no VMbus channel interrupts are assigned to
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the CPU. See the section on VMbus Interrupts for more details
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on how VMbus channel interrupts can be re-assigned to permit
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taking a CPU offline.
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32-bit and 64-bit
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-----------------
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On x86/x64, Hyper-V supports 32-bit and 64-bit guests, and Linux
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will build and run in either version. While the 32-bit version is
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expected to work, it is used rarely and may suffer from undetected
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regressions.
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On arm64, Hyper-V supports only 64-bit guests.
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Endian-ness
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-----------
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All communication between Hyper-V and guest VMs uses Little-Endian
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format on both x86/x64 and arm64. Big-endian format on arm64 is not
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supported by Hyper-V, and Linux code does not use endian-ness macros
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when accessing data shared with Hyper-V.
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Versioning
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----------
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Current Linux kernels operate correctly with older versions of
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Hyper-V back to Windows Server 2012 Hyper-V. Support for running
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on the original Hyper-V release in Windows Server 2008/2008 R2
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has been removed.
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A Linux guest on Hyper-V outputs in dmesg the version of Hyper-V
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it is running on. This version is in the form of a Windows build
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number and is for display purposes only. Linux code does not
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test this version number at runtime to determine available features
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and functionality. Hyper-V indicates feature/function availability
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via flags in synthetic MSRs that Hyper-V provides to the guest,
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and the guest code tests these flags.
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VMbus has its own protocol version that is negotiated during the
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initial VMbus connection from the guest to Hyper-V. This version
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number is also output to dmesg during boot. This version number
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is checked in a few places in the code to determine if specific
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functionality is present.
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Furthermore, each synthetic device on VMbus also has a protocol
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version that is separate from the VMbus protocol version. Device
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drivers for these synthetic devices typically negotiate the device
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protocol version, and may test that protocol version to determine
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if specific device functionality is present.
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Code Packaging
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--------------
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Hyper-V related code appears in the Linux kernel code tree in three
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main areas:
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1. drivers/hv
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2. arch/x86/hyperv and arch/arm64/hyperv
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3. individual device driver areas such as drivers/scsi, drivers/net,
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drivers/clocksource, etc.
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A few miscellaneous files appear elsewhere. See the full list under
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"Hyper-V/Azure CORE AND DRIVERS" and "DRM DRIVER FOR HYPERV
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SYNTHETIC VIDEO DEVICE" in the MAINTAINERS file.
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The code in #1 and #2 is built only when CONFIG_HYPERV is set.
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Similarly, the code for most Hyper-V related drivers is built only
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when CONFIG_HYPERV is set.
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Most Hyper-V related code in #1 and #3 can be built as a module.
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The architecture specific code in #2 must be built-in. Also,
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drivers/hv/hv_common.c is low-level code that is common across
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architectures and must be built-in.
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