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5d57686605
- Fixes and code refactoring for stage2 kvm MMU unmap_range - Support unmapping IPAs on deleting memslots for arm and arm64 - Support MMIO mappings in stage2 faults - KVM VGIC v2 emulation on GICv3 hardware - Big-Endian support for arm/arm64 (guest and host) - Debug Architecture support for arm64 (arm32 is on Christoffer's todo list) - Detect non page-aligned GICV regions and bail out (plugs guest-can-crash host bug) -----BEGIN PGP SIGNATURE----- Version: GnuPG v1 iQEcBAABAgAGBQJT3oZTAAoJEEtpOizt6ddyKQIH/1Bj/cZYSkkSf3IJfQhHRbWN jS37IBsvcHwjHkRJxCNmQuKP/Ho5XEusluPGrVY25PAgBMl+ouPqAuKzUk+GEab6 snjJjDFqw0zs0x0h3tg6UwfZdF+eyyIkmFGn8/IATD5P3PPd8kWBVtYnSnZmYK+R KJNVcp6RPDrt9kvUDY8Ln9fW99Jl+7CdgQAnc3QkHcXUlanLyrfq+fE1lSzyrbhZ ETzyMFAX4kCdc8tflgyyBS4A7+RvfQ6ZIQummxoAMFHIoSk90dtK7ovX68rd9U3e yL+mpe130+dTIFpUMbxCnIdE7C0eud3vcgXC6MuWtFjUrxQoaEgsVE+ffGC5tX0= =axkp -----END PGP SIGNATURE----- Merge tag 'kvm-arm-for-3.17' of git://git.kernel.org/pub/scm/linux/kernel/git/kvmarm/kvmarm into kvm KVM/ARM New features for 3.17 include: - Fixes and code refactoring for stage2 kvm MMU unmap_range - Support unmapping IPAs on deleting memslots for arm and arm64 - Support MMIO mappings in stage2 faults - KVM VGIC v2 emulation on GICv3 hardware - Big-Endian support for arm/arm64 (guest and host) - Debug Architecture support for arm64 (arm32 is on Christoffer's todo list) Conflicts: virt/kvm/arm/vgic.c [last minute cherry-pick from 3.17 to 3.16]
225 lines
9.0 KiB
Plaintext
225 lines
9.0 KiB
Plaintext
Booting AArch64 Linux
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=====================
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Author: Will Deacon <will.deacon@arm.com>
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Date : 07 September 2012
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This document is based on the ARM booting document by Russell King and
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is relevant to all public releases of the AArch64 Linux kernel.
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The AArch64 exception model is made up of a number of exception levels
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(EL0 - EL3), with EL0 and EL1 having a secure and a non-secure
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counterpart. EL2 is the hypervisor level and exists only in non-secure
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mode. EL3 is the highest priority level and exists only in secure mode.
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For the purposes of this document, we will use the term `boot loader'
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simply to define all software that executes on the CPU(s) before control
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is passed to the Linux kernel. This may include secure monitor and
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hypervisor code, or it may just be a handful of instructions for
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preparing a minimal boot environment.
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Essentially, the boot loader should provide (as a minimum) the
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following:
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1. Setup and initialise the RAM
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2. Setup the device tree
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3. Decompress the kernel image
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4. Call the kernel image
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1. Setup and initialise RAM
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---------------------------
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Requirement: MANDATORY
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The boot loader is expected to find and initialise all RAM that the
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kernel will use for volatile data storage in the system. It performs
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this in a machine dependent manner. (It may use internal algorithms
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to automatically locate and size all RAM, or it may use knowledge of
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the RAM in the machine, or any other method the boot loader designer
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sees fit.)
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2. Setup the device tree
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-------------------------
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Requirement: MANDATORY
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The device tree blob (dtb) must be placed on an 8-byte boundary within
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the first 512 megabytes from the start of the kernel image and must not
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cross a 2-megabyte boundary. This is to allow the kernel to map the
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blob using a single section mapping in the initial page tables.
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3. Decompress the kernel image
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------------------------------
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Requirement: OPTIONAL
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The AArch64 kernel does not currently provide a decompressor and
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therefore requires decompression (gzip etc.) to be performed by the boot
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loader if a compressed Image target (e.g. Image.gz) is used. For
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bootloaders that do not implement this requirement, the uncompressed
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Image target is available instead.
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4. Call the kernel image
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------------------------
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Requirement: MANDATORY
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The decompressed kernel image contains a 64-byte header as follows:
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u32 code0; /* Executable code */
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u32 code1; /* Executable code */
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u64 text_offset; /* Image load offset, little endian */
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u64 image_size; /* Effective Image size, little endian */
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u64 flags; /* kernel flags, little endian */
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u64 res2 = 0; /* reserved */
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u64 res3 = 0; /* reserved */
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u64 res4 = 0; /* reserved */
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u32 magic = 0x644d5241; /* Magic number, little endian, "ARM\x64" */
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u32 res5; /* reserved (used for PE COFF offset) */
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Header notes:
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- As of v3.17, all fields are little endian unless stated otherwise.
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- code0/code1 are responsible for branching to stext.
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- when booting through EFI, code0/code1 are initially skipped.
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res5 is an offset to the PE header and the PE header has the EFI
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entry point (efi_stub_entry). When the stub has done its work, it
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jumps to code0 to resume the normal boot process.
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- Prior to v3.17, the endianness of text_offset was not specified. In
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these cases image_size is zero and text_offset is 0x80000 in the
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endianness of the kernel. Where image_size is non-zero image_size is
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little-endian and must be respected. Where image_size is zero,
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text_offset can be assumed to be 0x80000.
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- The flags field (introduced in v3.17) is a little-endian 64-bit field
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composed as follows:
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Bit 0: Kernel endianness. 1 if BE, 0 if LE.
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Bits 1-63: Reserved.
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- When image_size is zero, a bootloader should attempt to keep as much
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memory as possible free for use by the kernel immediately after the
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end of the kernel image. The amount of space required will vary
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depending on selected features, and is effectively unbound.
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The Image must be placed text_offset bytes from a 2MB aligned base
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address near the start of usable system RAM and called there. Memory
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below that base address is currently unusable by Linux, and therefore it
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is strongly recommended that this location is the start of system RAM.
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At least image_size bytes from the start of the image must be free for
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use by the kernel.
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Any memory described to the kernel (even that below the 2MB aligned base
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address) which is not marked as reserved from the kernel e.g. with a
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memreserve region in the device tree) will be considered as available to
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the kernel.
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Before jumping into the kernel, the following conditions must be met:
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- Quiesce all DMA capable devices so that memory does not get
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corrupted by bogus network packets or disk data. This will save
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you many hours of debug.
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- Primary CPU general-purpose register settings
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x0 = physical address of device tree blob (dtb) in system RAM.
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x1 = 0 (reserved for future use)
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x2 = 0 (reserved for future use)
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x3 = 0 (reserved for future use)
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- CPU mode
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All forms of interrupts must be masked in PSTATE.DAIF (Debug, SError,
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IRQ and FIQ).
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The CPU must be in either EL2 (RECOMMENDED in order to have access to
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the virtualisation extensions) or non-secure EL1.
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- Caches, MMUs
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The MMU must be off.
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Instruction cache may be on or off.
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The address range corresponding to the loaded kernel image must be
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cleaned to the PoC. In the presence of a system cache or other
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coherent masters with caches enabled, this will typically require
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cache maintenance by VA rather than set/way operations.
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System caches which respect the architected cache maintenance by VA
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operations must be configured and may be enabled.
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System caches which do not respect architected cache maintenance by VA
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operations (not recommended) must be configured and disabled.
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- Architected timers
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CNTFRQ must be programmed with the timer frequency and CNTVOFF must
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be programmed with a consistent value on all CPUs. If entering the
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kernel at EL1, CNTHCTL_EL2 must have EL1PCTEN (bit 0) set where
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available.
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- Coherency
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All CPUs to be booted by the kernel must be part of the same coherency
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domain on entry to the kernel. This may require IMPLEMENTATION DEFINED
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initialisation to enable the receiving of maintenance operations on
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each CPU.
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- System registers
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All writable architected system registers at the exception level where
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the kernel image will be entered must be initialised by software at a
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higher exception level to prevent execution in an UNKNOWN state.
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For systems with a GICv3 interrupt controller:
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- If EL3 is present:
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ICC_SRE_EL3.Enable (bit 3) must be initialiased to 0b1.
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ICC_SRE_EL3.SRE (bit 0) must be initialised to 0b1.
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- If the kernel is entered at EL1:
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ICC.SRE_EL2.Enable (bit 3) must be initialised to 0b1
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ICC_SRE_EL2.SRE (bit 0) must be initialised to 0b1.
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The requirements described above for CPU mode, caches, MMUs, architected
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timers, coherency and system registers apply to all CPUs. All CPUs must
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enter the kernel in the same exception level.
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The boot loader is expected to enter the kernel on each CPU in the
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following manner:
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- The primary CPU must jump directly to the first instruction of the
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kernel image. The device tree blob passed by this CPU must contain
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an 'enable-method' property for each cpu node. The supported
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enable-methods are described below.
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It is expected that the bootloader will generate these device tree
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properties and insert them into the blob prior to kernel entry.
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- CPUs with a "spin-table" enable-method must have a 'cpu-release-addr'
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property in their cpu node. This property identifies a
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naturally-aligned 64-bit zero-initalised memory location.
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These CPUs should spin outside of the kernel in a reserved area of
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memory (communicated to the kernel by a /memreserve/ region in the
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device tree) polling their cpu-release-addr location, which must be
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contained in the reserved region. A wfe instruction may be inserted
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to reduce the overhead of the busy-loop and a sev will be issued by
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the primary CPU. When a read of the location pointed to by the
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cpu-release-addr returns a non-zero value, the CPU must jump to this
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value. The value will be written as a single 64-bit little-endian
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value, so CPUs must convert the read value to their native endianness
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before jumping to it.
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- CPUs with a "psci" enable method should remain outside of
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the kernel (i.e. outside of the regions of memory described to the
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kernel in the memory node, or in a reserved area of memory described
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to the kernel by a /memreserve/ region in the device tree). The
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kernel will issue CPU_ON calls as described in ARM document number ARM
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DEN 0022A ("Power State Coordination Interface System Software on ARM
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processors") to bring CPUs into the kernel.
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The device tree should contain a 'psci' node, as described in
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Documentation/devicetree/bindings/arm/psci.txt.
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- Secondary CPU general-purpose register settings
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x0 = 0 (reserved for future use)
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x1 = 0 (reserved for future use)
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x2 = 0 (reserved for future use)
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x3 = 0 (reserved for future use)
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