499 lines
16 KiB
ReStructuredText
499 lines
16 KiB
ReStructuredText
.. _memmgt-hld:
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Memory Management high-level design
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###################################
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This document describes memory management for the ACRN hypervisor.
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Overview
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********
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The hypervisor (HV) virtualizes real physical memory so an unmodified OS
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(such as Linux or Android) running in a virtual machine, has the view of
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managing its own contiguous physical memory. HV uses virtual-processor
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identifiers (VPIDs) and the extended page-table mechanism (EPT) to
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translate guest-physical address into host-physical address. HV enables
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EPT and VPID hardware virtualization features, establishes EPT page
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tables for SOS/UOS, and provides EPT page tables operation interfaces to
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others.
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In the ACRN hypervisor system, there are few different memory spaces to
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consider. From the hypervisor's point of view there are:
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- **Host Physical Address (HPA)**: the native physical address space, and
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- **Host Virtual Address (HVA)**: the native virtual address space based on
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a MMU. A page table is used to translate between HPA and HVA
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spaces.
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From the Guest OS running on a hypervisor there are:
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- **Guest Physical Address (GPA)**: the guest physical address space from a
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virtual machine. GPA to HPA transition is usually based on a
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MMU-like hardware module (EPT in X86), and associated with a page
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table
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- **Guest Virtual Address (GVA)**: the guest virtual address space from a
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virtual machine based on a vMMU
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.. figure:: images/mem-image2.png
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:align: center
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:width: 900px
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:name: mem-overview
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ACRN Memory Mapping Overview
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:numref:`mem-overview` provides an overview of the ACRN system memory
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mapping, showing:
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- GVA to GPA mapping based on vMMU on a VCPU in a VM
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- GPA to HPA mapping based on EPT for a VM in the hypervisor
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- HVA to HPA mapping based on MMU in the hypervisor
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This document illustrates the memory management infrastructure for the
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ACRN hypervisor and how it handles the different memory space views
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inside the hypervisor and from a VM:
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- How ACRN hypervisor manages host memory (HPA/HVA)
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- How ACRN hypervisor manages SOS guest memory (HPA/GPA)
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- How ACRN hypervisor & SOS DM manage UOS guest memory (HPA/GPA)
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Hypervisor Physical Memory Management
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*************************************
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In the ACRN, the HV initializes MMU page tables to manage all physical
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memory and then switches to the new MMU page tables. After MMU page
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tables are initialized at the platform initialization stage, no updates
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are made for MMU page tables.
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Hypervisor Physical Memory Layout - E820
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========================================
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The ACRN hypervisor is the primary owner to manage system memory.
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Typically the boot firmware (e.g., EFI) passes the platform physical
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memory layout - E820 table to the hypervisor. The ACRN hypervisor does
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its memory management based on this table using 4-level paging.
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The BIOS/bootloader firmware (e.g., EFI) passes the E820 table through a
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multiboot protocol. This table contains the original memory layout for
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the platform.
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.. figure:: images/mem-image1.png
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:align: center
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:width: 900px
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:name: mem-layout
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Physical Memory Layout Example
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:numref:`mem-layout` is an example of the physical memory layout based on a simple
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platform E820 table.
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Hypervisor Memory Initialization
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================================
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The ACRN hypervisor runs under paging mode. After the bootstrap
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processor (BSP) gets the platform E820 table, BSP creates its MMU page
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table based on it. This is done by the function *init_paging()* and
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*smep()*. After the application processor (AP) receives IPI CPU startup
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interrupt, it uses the MMU page tables created by BSP and enable SMEP.
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:numref:`hv-mem-init` describes the hypervisor memory initialization for BSP
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and APs.
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.. figure:: images/mem-image8.png
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:align: center
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:name: hv-mem-init
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Hypervisor Memory Initialization
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The memory mapping policy used is:
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- Identical mapping (ACRN hypervisor memory could be relocatable in
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the future)
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- Map all memory regions with UNCACHED type
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- Remap RAM regions to WRITE-BACK type
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.. figure:: images/mem-image69.png
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:align: center
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:name: hv-mem-vm-init
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Hypervisor Virtual Memory Layout
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:numref:`hv-mem-vm-init` above shows:
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- Hypervisor has a view of and can access all system memory
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- Hypervisor has UNCACHED MMIO/PCI hole reserved for devices such as
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LAPIC/IOAPIC accessing
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- Hypervisor has its own memory with WRITE-BACK cache type for its
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code/data (< 1M part is for secondary CPU reset code)
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The hypervisor should use minimum memory pages to map from virtual
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address space into physical address space.
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- If 1GB hugepage can be used
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for virtual address space mapping, the corresponding PDPT entry shall be
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set for this 1GB hugepage.
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- If 1GB hugepage can't be used for virtual
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address space mapping and 2MB hugepage can be used, the corresponding
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PDT entry shall be set for this 2MB hugepage.
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- If both of 1GB hugepage
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and 2MB hugepage can't be used for virtual address space mapping, the
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corresponding PT entry shall be set.
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If memory type or access rights of a page is updated, or some virtual
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address space is deleted, it will lead to splitting of the corresponding
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page. The hypervisor will still keep using minimum memory pages to map from
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virtual address space into physical address space.
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Memory Pages Pool Functions
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===========================
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Memory pages pool functions provide dynamic management of multiple
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4KB page-size memory blocks, used by the hypervisor to store internal
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data. Through these functions, the hypervisor can allocate and
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deallocate pages.
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Data Flow Design
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================
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The physical memory management unit provides MMU 4-level page tables
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creating and updating services, MMU page tables switching service, SMEP
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enable service, and HPA/HVA retrieving service to other units.
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:numref:`mem-data-flow-physical` shows the data flow diagram
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of physical memory management.
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.. figure:: images/mem-image45.png
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:align: center
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:name: mem-data-flow-physical
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Data Flow of Hypervisor Physical Memory Management
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Interfaces Design
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=================
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MMU Initialization
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------------------
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.. doxygenfunction:: enable_smep
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:project: Project ACRN
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.. doxygenfunction:: enable_paging
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:project: Project ACRN
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.. doxygenfunction:: init_paging
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:project: Project ACRN
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Address Space Translation
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-------------------------
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.. doxygenfunction:: hpa2hva
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:project: Project ACRN
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.. doxygenfunction:: hva2hpa
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:project: Project ACRN
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Hypervisor Memory Virtualization
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********************************
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The hypervisor provides a contiguous region of physical memory for SOS
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and each UOS. It also guarantees that the SOS and UOS can not access
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code and internal data in the hypervisor, and each UOS can not access
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code and internal data of the SOS and other UOSs.
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The hypervisor:
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- enables EPT and VPID hardware virtualization features,
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- establishes EPT page tables for SOS/UOS,
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- provides EPT page tables operations services,
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- virtualizes MTRR for SOS/UOS,
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- provides VPID operations services,
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- provides services for address spaces translation between GPA and HPA, and
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- provides services for data transfer between hypervisor and virtual machine.
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Memory Virtualization Capability Checking
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=========================================
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In the hypervisor, memory virtualization provides EPT/VPID capability
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checking service and EPT hugepage supporting checking service. Before HV
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enables memory virtualization and uses EPT hugepage, these service need
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to be invoked by other units.
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Data Transfer between Different Address Spaces
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==============================================
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In ACRN, different memory space management is used in the hypervisor,
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Service OS, and User OS to achieve spatial isolation. Between memory
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spaces, there are different kinds of data transfer, such as a SOS/UOS
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may hypercall to request hypervisor services which includes data
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transferring, or when the hypervisor does instruction emulation: the HV
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needs to access the guest instruction pointer register to fetch guest
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instruction data.
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Access GPA from Hypervisor
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--------------------------
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When hypervisor need access GPA for data transfer, the caller from guest
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must make sure this memory range's GPA is continuous. But for HPA in
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hypervisor, it could be dis-continuous (especially for UOS under hugetlb
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allocation mechanism). For example, a 4M GPA range may map to 2
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different 2M huge host-physical pages. The ACRN hypervisor must take
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care of this kind of data transfer by doing EPT page walking based on
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its HPA.
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Access GVA from Hypervisor
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--------------------------
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When hypervisor needs to access GVA for data transfer, it's likely both
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GPA and HPA could be address dis-continuous. The ACRN hypervisor must
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watch for this kind of data transfer, and handle it by doing page
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walking based on both its GPA and HPA.
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EPT Page Tables Operations
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==========================
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The hypervisor should use a minimum of memory pages to map from
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guest-physical address (GPA) space into host-physical address (HPA)
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space.
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- If 1GB hugepage can be used for GPA space mapping, the
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corresponding EPT PDPT entry shall be set for this 1GB hugepage.
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- If 1GB hugepage can't be used for GPA space mapping and 2MB hugepage can be
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used, the corresponding EPT PDT entry shall be set for this 2MB
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hugepage.
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- If both 1GB hugepage and 2MB hugepage can't be used for GPA
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space mapping, the corresponding EPT PT entry shall be set.
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If memory type or access rights of a page is updated or some GPA space
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is deleted, it will lead to the corresponding EPT page being split. The
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hypervisor should still keep to using minimum EPT pages to map from GPA
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space into HPA space.
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The hypervisor provides EPT guest-physical mappings adding service, EPT
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guest-physical mappings modifying/deleting service, EPT page tables
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deallocation, and EPT guest-physical mappings invalidation service.
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Virtual MTRR
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************
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In ACRN, the hypervisor only virtualizes MTRRs fixed range (0~1MB).
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The HV sets MTRRs of the fixed range as Write-Back for UOS, and the SOS reads
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native MTRRs of the fixed range set by BIOS.
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If the guest physical address is not in the fixed range (0~1MB), the
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hypervisor uses the default memory type in the MTRR (Write-Back).
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When the guest disables MTRRs, the HV sets the guest address memory type
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as UC.
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If the guest physical address is in fixed range (0~1MB), the HV sets
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memory type according to the fixed virtual MTRRs.
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When the guest enable MTRRs, MTRRs have no effect on the memory type
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used for access to GPA. The HV first intercepts MTRR MSR registers
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access through MSR access VM exit and updates EPT memory type field in EPT
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PTE according to the memory type selected by MTRRs. This combines with
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PAT entry in the PAT MSR (which is determined by PAT, PCD, and PWT bits
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from the guest paging structures) to determine the effective memory
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type.
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VPID operations
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===============
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Virtual-processor identifier (VPID) is a hardware feature to optimize
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TLB management. When VPID is enable, hardware will add a tag for TLB of
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a logical processor and cache information for multiple linear-address
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spaces. VMX transitions may retain cached information and the logical
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processor switches to a different address space, avoiding unnecessary
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TLB flushes.
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In ACRN, an unique VPID must be allocated for each virtual CPU
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when a virtual CPU is created. The logical processor invalidates linear
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mappings and combined mapping associated with all VPIDs (except VPID
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0000H), and with all PCIDs when the logical processor launches the virtual
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CPU. The logical processor invalidates all linear mapping and combined
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mappings associated with the specified VPID when the interrupt pending
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request handling needs to invalidate cached mapping of the specified
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VPID.
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Data Flow Design
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================
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The memory virtualization unit includes address space translation
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functions, data transferring functions, VM EPT operations functions,
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VPID operations functions, VM exit hanging about EPT violation and EPT
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misconfiguration, and MTRR virtualization functions. This unit handles
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guest-physical mapping updates by creating or updating related EPT page
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tables. It virtualizes MTRR for guest OS by updating related EPT page
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tables. It handles address translation from GPA to HPA by walking EPT
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page tables. It copies data from VM into the HV or from the HV to VM by
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walking guest MMU page tables and EPT page tables. It provides services
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to allocate VPID for each virtual CPU and TLB invalidation related VPID.
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It handles VM exit about EPT violation and EPT misconfiguration. The
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following :numref:`mem-flow-mem-virt` describes the data flow diagram of
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the memory virtualization unit.
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.. figure:: images/mem-image84.png
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:align: center
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:name: mem-flow-mem-virt
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Data Flow of Hypervisor Memory Virtualization
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Data Structure Design
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=====================
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EPT Memory Type Definition:
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.. doxygengroup:: ept_mem_type
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:project: Project ACRN
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:content-only:
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EPT Memory Access Right Definition:
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.. doxygengroup:: ept_mem_access_right
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:project: Project ACRN
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:content-only:
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Interfaces Design
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=================
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The memory virtualization unit interacts with external units through VM
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exit and APIs.
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VM Exit about EPT
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=================
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There are two VM exit handlers for EPT violation and EPT
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misconfiguration in the hypervisor. EPT page tables are
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always configured correctly for SOS and UOS. If EPT misconfiguration is
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detected, a fatal error is reported by HV. The hypervisor
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uses EPT violation to intercept MMIO access to do device emulation. EPT
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violation handling data flow is described in the
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:ref:`instruction-emulation`.
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Memory Virtualization APIs
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==========================
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Here is a list of major memory related APIs in HV:
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EPT/VPID Capability Checking
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----------------------------
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Data Transferring between hypervisor and VM
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-------------------------------------------
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.. doxygenfunction:: copy_from_gpa
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:project: Project ACRN
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.. doxygenfunction:: copy_to_gpa
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:project: Project ACRN
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.. doxygenfunction:: copy_from_gva
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:project: Project ACRN
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Address Space Translation
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-------------------------
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.. doxygenfunction:: gpa2hpa
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:project: Project ACRN
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.. doxygenfunction:: sos_vm_hpa2gpa
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:project: Project ACRN
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EPT
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---
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.. doxygenfunction:: ept_add_mr
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:project: Project ACRN
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.. doxygenfunction:: ept_del_mr
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:project: Project ACRN
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.. doxygenfunction:: ept_modify_mr
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:project: Project ACRN
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.. doxygenfunction:: destroy_ept
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:project: Project ACRN
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.. doxygenfunction:: invept
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:project: Project ACRN
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.. doxygenfunction:: ept_misconfig_vmexit_handler
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:project: Project ACRN
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Virtual MTRR
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------------
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.. doxygenfunction:: init_vmtrr
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:project: Project ACRN
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.. doxygenfunction:: write_vmtrr
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:project: Project ACRN
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.. doxygenfunction:: read_vmtrr
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:project: Project ACRN
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VPID
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----
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.. doxygenfunction:: flush_vpid_single
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:project: Project ACRN
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.. doxygenfunction:: flush_vpid_global
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:project: Project ACRN
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Service OS Memory Management
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****************************
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After the ACRN hypervisor starts, it creates the Service OS as its first
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VM. The Service OS runs all the native device drivers, manage the
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hardware devices, and provides I/O mediation to guest VMs. The Service
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OS is in charge of the memory allocation for Guest VMs as well.
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ACRN hypervisor passes the whole system memory access (except its own
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part) to the Service OS. The Service OS must be able to access all of
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the system memory except the hypervisor part.
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Guest Physical Memory Layout - E820
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===================================
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The ACRN hypervisor passes the original E820 table to the Service OS
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after filtering out its own part. So from Service OS's view, it sees
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almost all the system memory as shown here:
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.. figure:: images/mem-image3.png
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:align: center
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:width: 900px
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:name: sos-mem-layout
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SOS Physical Memory Layout
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Host to Guest Mapping
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=====================
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ACRN hypervisor creates Service OS's host (HPA) to guest (GPA) mapping
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(EPT mapping) through the function ``prepare_sos_vm_memmap()``
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when it creates the SOS VM. It follows these rules:
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- Identical mapping
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- Map all memory range with UNCACHED type
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- Remap RAM entries in E820 (revised) with WRITE-BACK type
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- Unmap ACRN hypervisor memory range
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- Unmap ACRN hypervisor emulated vLAPIC/vIOAPIC MMIO range
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The host to guest mapping is static for the Service OS; it will not
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change after the Service OS begins running. Each native device driver
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can access its MMIO through this static mapping. EPT violation is only
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serving for vLAPIC/vIOAPIC's emulation in the hypervisor for Service OS
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VM.
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Trusty
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******
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For an Android User OS, there is a secure world named trusty world
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support, whose memory must be secured by the ACRN hypervisor and
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must not be accessible by SOS and UOS normal world.
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.. figure:: images/mem-image18.png
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:align: center
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UOS Physical Memory Layout with Trusty
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