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Documentation: hyperv: Add overview of Confidential Computing VM support
Add documentation topic for Confidential Computing (CoCo) VM support in Linux guests on Hyper-V. Signed-off-by: Michael Kelley <mhklinux@outlook.com> Reviewed-by: Easwar Hariharan <eahariha@linux.microsoft.com> Link: https://lore.kernel.org/r/20240618165059.10174-1-mhklinux@outlook.com Signed-off-by: Wei Liu <wei.liu@kernel.org> Message-ID: <20240618165059.10174-1-mhklinux@outlook.com>
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Documentation/virt/hyperv/coco.rst
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Documentation/virt/hyperv/coco.rst
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.. SPDX-License-Identifier: GPL-2.0
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Confidential Computing VMs
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==========================
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Hyper-V can create and run Linux guests that are Confidential Computing
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(CoCo) VMs. Such VMs cooperate with the physical processor to better protect
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the confidentiality and integrity of data in the VM's memory, even in the
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face of a hypervisor/VMM that has been compromised and may behave maliciously.
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CoCo VMs on Hyper-V share the generic CoCo VM threat model and security
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objectives described in Documentation/security/snp-tdx-threat-model.rst. Note
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that Hyper-V specific code in Linux refers to CoCo VMs as "isolated VMs" or
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"isolation VMs".
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A Linux CoCo VM on Hyper-V requires the cooperation and interaction of the
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following:
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* Physical hardware with a processor that supports CoCo VMs
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* The hardware runs a version of Windows/Hyper-V with support for CoCo VMs
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* The VM runs a version of Linux that supports being a CoCo VM
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The physical hardware requirements are as follows:
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* AMD processor with SEV-SNP. Hyper-V does not run guest VMs with AMD SME,
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SEV, or SEV-ES encryption, and such encryption is not sufficient for a CoCo
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VM on Hyper-V.
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* Intel processor with TDX
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To create a CoCo VM, the "Isolated VM" attribute must be specified to Hyper-V
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when the VM is created. A VM cannot be changed from a CoCo VM to a normal VM,
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or vice versa, after it is created.
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Operational Modes
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-----------------
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Hyper-V CoCo VMs can run in two modes. The mode is selected when the VM is
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created and cannot be changed during the life of the VM.
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* Fully-enlightened mode. In this mode, the guest operating system is
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enlightened to understand and manage all aspects of running as a CoCo VM.
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* Paravisor mode. In this mode, a paravisor layer between the guest and the
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host provides some operations needed to run as a CoCo VM. The guest operating
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system can have fewer CoCo enlightenments than is required in the
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fully-enlightened case.
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Conceptually, fully-enlightened mode and paravisor mode may be treated as
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points on a spectrum spanning the degree of guest enlightenment needed to run
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as a CoCo VM. Fully-enlightened mode is one end of the spectrum. A full
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implementation of paravisor mode is the other end of the spectrum, where all
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aspects of running as a CoCo VM are handled by the paravisor, and a normal
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guest OS with no knowledge of memory encryption or other aspects of CoCo VMs
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can run successfully. However, the Hyper-V implementation of paravisor mode
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does not go this far, and is somewhere in the middle of the spectrum. Some
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aspects of CoCo VMs are handled by the Hyper-V paravisor while the guest OS
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must be enlightened for other aspects. Unfortunately, there is no
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standardized enumeration of feature/functions that might be provided in the
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paravisor, and there is no standardized mechanism for a guest OS to query the
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paravisor for the feature/functions it provides. The understanding of what
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the paravisor provides is hard-coded in the guest OS.
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Paravisor mode has similarities to the `Coconut project`_, which aims to provide
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a limited paravisor to provide services to the guest such as a virtual TPM.
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However, the Hyper-V paravisor generally handles more aspects of CoCo VMs
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than is currently envisioned for Coconut, and so is further toward the "no
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guest enlightenments required" end of the spectrum.
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.. _Coconut project: https://github.com/coconut-svsm/svsm
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In the CoCo VM threat model, the paravisor is in the guest security domain
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and must be trusted by the guest OS. By implication, the hypervisor/VMM must
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protect itself against a potentially malicious paravisor just like it
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protects against a potentially malicious guest.
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The hardware architectural approach to fully-enlightened vs. paravisor mode
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varies depending on the underlying processor.
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* With AMD SEV-SNP processors, in fully-enlightened mode the guest OS runs in
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VMPL 0 and has full control of the guest context. In paravisor mode, the
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guest OS runs in VMPL 2 and the paravisor runs in VMPL 0. The paravisor
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running in VMPL 0 has privileges that the guest OS in VMPL 2 does not have.
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Certain operations require the guest to invoke the paravisor. Furthermore, in
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paravisor mode the guest OS operates in "virtual Top Of Memory" (vTOM) mode
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as defined by the SEV-SNP architecture. This mode simplifies guest management
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of memory encryption when a paravisor is used.
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* With Intel TDX processor, in fully-enlightened mode the guest OS runs in an
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L1 VM. In paravisor mode, TD partitioning is used. The paravisor runs in the
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L1 VM, and the guest OS runs in a nested L2 VM.
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Hyper-V exposes a synthetic MSR to guests that describes the CoCo mode. This
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MSR indicates if the underlying processor uses AMD SEV-SNP or Intel TDX, and
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whether a paravisor is being used. It is straightforward to build a single
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kernel image that can boot and run properly on either architecture, and in
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either mode.
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Paravisor Effects
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-----------------
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Running in paravisor mode affects the following areas of generic Linux kernel
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CoCo VM functionality:
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* Initial guest memory setup. When a new VM is created in paravisor mode, the
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paravisor runs first and sets up the guest physical memory as encrypted. The
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guest Linux does normal memory initialization, except for explicitly marking
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appropriate ranges as decrypted (shared). In paravisor mode, Linux does not
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perform the early boot memory setup steps that are particularly tricky with
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AMD SEV-SNP in fully-enlightened mode.
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* #VC/#VE exception handling. In paravisor mode, Hyper-V configures the guest
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CoCo VM to route #VC and #VE exceptions to VMPL 0 and the L1 VM,
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respectively, and not the guest Linux. Consequently, these exception handlers
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do not run in the guest Linux and are not a required enlightenment for a
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Linux guest in paravisor mode.
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* CPUID flags. Both AMD SEV-SNP and Intel TDX provide a CPUID flag in the
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guest indicating that the VM is operating with the respective hardware
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support. While these CPUID flags are visible in fully-enlightened CoCo VMs,
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the paravisor filters out these flags and the guest Linux does not see them.
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Throughout the Linux kernel, explicitly testing these flags has mostly been
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eliminated in favor of the cc_platform_has() function, with the goal of
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abstracting the differences between SEV-SNP and TDX. But the
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cc_platform_has() abstraction also allows the Hyper-V paravisor configuration
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to selectively enable aspects of CoCo VM functionality even when the CPUID
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flags are not set. The exception is early boot memory setup on SEV-SNP, which
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tests the CPUID SEV-SNP flag. But not having the flag in Hyper-V paravisor
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mode VM achieves the desired effect or not running SEV-SNP specific early
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boot memory setup.
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* Device emulation. In paravisor mode, the Hyper-V paravisor provides
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emulation of devices such as the IO-APIC and TPM. Because the emulation
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happens in the paravisor in the guest context (instead of the hypervisor/VMM
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context), MMIO accesses to these devices must be encrypted references instead
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of the decrypted references that would be used in a fully-enlightened CoCo
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VM. The __ioremap_caller() function has been enhanced to make a callback to
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check whether a particular address range should be treated as encrypted
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(private). See the "is_private_mmio" callback.
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* Encrypt/decrypt memory transitions. In a CoCo VM, transitioning guest
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memory between encrypted and decrypted requires coordinating with the
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hypervisor/VMM. This is done via callbacks invoked from
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__set_memory_enc_pgtable(). In fully-enlightened mode, the normal SEV-SNP and
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TDX implementations of these callbacks are used. In paravisor mode, a Hyper-V
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specific set of callbacks is used. These callbacks invoke the paravisor so
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that the paravisor can coordinate the transitions and inform the hypervisor
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as necessary. See hv_vtom_init() where these callback are set up.
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* Interrupt injection. In fully enlightened mode, a malicious hypervisor
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could inject interrupts into the guest OS at times that violate x86/x64
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architectural rules. For full protection, the guest OS should include
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enlightenments that use the interrupt injection management features provided
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by CoCo-capable processors. In paravisor mode, the paravisor mediates
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interrupt injection into the guest OS, and ensures that the guest OS only
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sees interrupts that are "legal". The paravisor uses the interrupt injection
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management features provided by the CoCo-capable physical processor, thereby
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masking these complexities from the guest OS.
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Hyper-V Hypercalls
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------------------
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When in fully-enlightened mode, hypercalls made by the Linux guest are routed
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directly to the hypervisor, just as in a non-CoCo VM. But in paravisor mode,
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normal hypercalls trap to the paravisor first, which may in turn invoke the
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hypervisor. But the paravisor is idiosyncratic in this regard, and a few
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hypercalls made by the Linux guest must always be routed directly to the
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hypervisor. These hypercall sites test for a paravisor being present, and use
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a special invocation sequence. See hv_post_message(), for example.
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Guest communication with Hyper-V
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--------------------------------
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Separate from the generic Linux kernel handling of memory encryption in Linux
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CoCo VMs, Hyper-V has VMBus and VMBus devices that communicate using memory
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shared between the Linux guest and the host. This shared memory must be
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marked decrypted to enable communication. Furthermore, since the threat model
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includes a compromised and potentially malicious host, the guest must guard
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against leaking any unintended data to the host through this shared memory.
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These Hyper-V and VMBus memory pages are marked as decrypted:
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* VMBus monitor pages
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* Synthetic interrupt controller (synic) related pages (unless supplied by
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the paravisor)
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* Per-cpu hypercall input and output pages (unless running with a paravisor)
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* VMBus ring buffers. The direct mapping is marked decrypted in
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__vmbus_establish_gpadl(). The secondary mapping created in
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hv_ringbuffer_init() must also include the "decrypted" attribute.
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When the guest writes data to memory that is shared with the host, it must
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ensure that only the intended data is written. Padding or unused fields must
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be initialized to zeros before copying into the shared memory so that random
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kernel data is not inadvertently given to the host.
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Similarly, when the guest reads memory that is shared with the host, it must
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validate the data before acting on it so that a malicious host cannot induce
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the guest to expose unintended data. Doing such validation can be tricky
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because the host can modify the shared memory areas even while or after
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validation is performed. For messages passed from the host to the guest in a
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VMBus ring buffer, the length of the message is validated, and the message is
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copied into a temporary (encrypted) buffer for further validation and
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processing. The copying adds a small amount of overhead, but is the only way
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to protect against a malicious host. See hv_pkt_iter_first().
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Many drivers for VMBus devices have been "hardened" by adding code to fully
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validate messages received over VMBus, instead of assuming that Hyper-V is
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acting cooperatively. Such drivers are marked as "allowed_in_isolated" in the
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vmbus_devs[] table. Other drivers for VMBus devices that are not needed in a
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CoCo VM have not been hardened, and they are not allowed to load in a CoCo
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VM. See vmbus_is_valid_offer() where such devices are excluded.
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Two VMBus devices depend on the Hyper-V host to do DMA data transfers:
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storvsc for disk I/O and netvsc for network I/O. storvsc uses the normal
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Linux kernel DMA APIs, and so bounce buffering through decrypted swiotlb
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memory is done implicitly. netvsc has two modes for data transfers. The first
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mode goes through send and receive buffer space that is explicitly allocated
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by the netvsc driver, and is used for most smaller packets. These send and
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receive buffers are marked decrypted by __vmbus_establish_gpadl(). Because
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the netvsc driver explicitly copies packets to/from these buffers, the
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equivalent of bounce buffering between encrypted and decrypted memory is
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already part of the data path. The second mode uses the normal Linux kernel
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DMA APIs, and is bounce buffered through swiotlb memory implicitly like in
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storvsc.
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Finally, the VMBus virtual PCI driver needs special handling in a CoCo VM.
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Linux PCI device drivers access PCI config space using standard APIs provided
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by the Linux PCI subsystem. On Hyper-V, these functions directly access MMIO
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space, and the access traps to Hyper-V for emulation. But in CoCo VMs, memory
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encryption prevents Hyper-V from reading the guest instruction stream to
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emulate the access. So in a CoCo VM, these functions must make a hypercall
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with arguments explicitly describing the access. See
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_hv_pcifront_read_config() and _hv_pcifront_write_config() and the
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"use_calls" flag indicating to use hypercalls.
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load_unaligned_zeropad()
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------------------------
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When transitioning memory between encrypted and decrypted, the caller of
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set_memory_encrypted() or set_memory_decrypted() is responsible for ensuring
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the memory isn't in use and isn't referenced while the transition is in
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progress. The transition has multiple steps, and includes interaction with
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the Hyper-V host. The memory is in an inconsistent state until all steps are
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complete. A reference while the state is inconsistent could result in an
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exception that can't be cleanly fixed up.
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However, the kernel load_unaligned_zeropad() mechanism may make stray
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references that can't be prevented by the caller of set_memory_encrypted() or
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set_memory_decrypted(), so there's specific code in the #VC or #VE exception
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handler to fixup this case. But a CoCo VM running on Hyper-V may be
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configured to run with a paravisor, with the #VC or #VE exception routed to
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the paravisor. There's no architectural way to forward the exceptions back to
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the guest kernel, and in such a case, the load_unaligned_zeropad() fixup code
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in the #VC/#VE handlers doesn't run.
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To avoid this problem, the Hyper-V specific functions for notifying the
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hypervisor of the transition mark pages as "not present" while a transition
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is in progress. If load_unaligned_zeropad() causes a stray reference, a
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normal page fault is generated instead of #VC or #VE, and the page-fault-
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based handlers for load_unaligned_zeropad() fixup the reference. When the
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encrypted/decrypted transition is complete, the pages are marked as "present"
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again. See hv_vtom_clear_present() and hv_vtom_set_host_visibility().
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vmbus
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clocks
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vpci
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coco
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