audk/ArmPkg/ArmPkg.dec

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#/** @file
# ARM processor package.
#
# Copyright (c) 2009 - 2010, Apple Inc. All rights reserved.<BR>
# Copyright (c) 2011 - 2018, ARM Limited. All rights reserved.
#
# This program and the accompanying materials
# are licensed and made available under the terms and conditions of the BSD License
# which accompanies this distribution. The full text of the license may be found at
# http://opensource.org/licenses/bsd-license.php
#
# THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
# WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
#
#**/
[Defines]
DEC_SPECIFICATION = 0x00010005
PACKAGE_NAME = ArmPkg
PACKAGE_GUID = 5CFBD99E-3C43-4E7F-8054-9CDEAFF7710F
PACKAGE_VERSION = 0.1
################################################################################
#
# Include Section - list of Include Paths that are provided by this package.
# Comments are used for Keywords and Module Types.
#
# Supported Module Types:
# BASE SEC PEI_CORE PEIM DXE_CORE DXE_DRIVER DXE_RUNTIME_DRIVER DXE_SMM_DRIVER DXE_SAL_DRIVER UEFI_DRIVER UEFI_APPLICATION
#
################################################################################
[Includes.common]
Include # Root include for the package
[LibraryClasses.common]
ArmLib|Include/Library/ArmLib.h
ArmMmuLib|Include/Library/ArmMmuLib.h
SemihostLib|Include/Library/Semihosting.h
DefaultExceptionHandlerLib|Include/Library/DefaultExceptionHandlerLib.h
ArmDisassemblerLib|Include/Library/ArmDisassemblerLib.h
ArmGicArchLib|Include/Library/ArmGicArchLib.h
ArmMtlLib|ArmPlatformPkg/Include/Library/ArmMtlLib.h
ArmSvcLib|Include/Library/ArmSvcLib.h
OpteeLib|Include/Library/OpteeLib.h
[Guids.common]
gArmTokenSpaceGuid = { 0xBB11ECFE, 0x820F, 0x4968, { 0xBB, 0xA6, 0xF7, 0x6A, 0xFE, 0x30, 0x25, 0x96 } }
## ARM MPCore table
# Include/Guid/ArmMpCoreInfo.h
gArmMpCoreInfoGuid = { 0xa4ee0728, 0xe5d7, 0x4ac5, {0xb2, 0x1e, 0x65, 0x8e, 0xd8, 0x57, 0xe8, 0x34} }
[Protocols.common]
## Arm System Control and Management Interface(SCMI) Base protocol
## ArmPkg/Include/Protocol/ArmScmiBaseProtocol.h
gArmScmiBaseProtocolGuid = { 0xd7e5abe9, 0x33ab, 0x418e, { 0x9f, 0x91, 0x72, 0xda, 0xe2, 0xba, 0x8e, 0x2f } }
## Arm System Control and Management Interface(SCMI) Clock management protocol
## ArmPkg/Include/Protocol/ArmScmiClockProtocol.h
gArmScmiClockProtocolGuid = { 0x91ce67a8, 0xe0aa, 0x4012, { 0xb9, 0x9f, 0xb6, 0xfc, 0xf3, 0x4, 0x8e, 0xaa } }
## Arm System Control and Management Interface(SCMI) Clock management protocol
## ArmPkg/Include/Protocol/ArmScmiPerformanceProtocol.h
gArmScmiPerformanceProtocolGuid = { 0x9b8ba84, 0x3dd3, 0x49a6, { 0xa0, 0x5a, 0x31, 0x34, 0xa5, 0xf0, 0x7b, 0xad } }
[Ppis]
## Include/Ppi/ArmMpCoreInfo.h
gArmMpCoreInfoPpiGuid = { 0x6847cc74, 0xe9ec, 0x4f8f, {0xa2, 0x9d, 0xab, 0x44, 0xe7, 0x54, 0xa8, 0xfc} }
[PcdsFeatureFlag.common]
gArmTokenSpaceGuid.PcdCpuDxeProduceDebugSupport|FALSE|BOOLEAN|0x00000001
# On ARM Architecture with the Security Extension, the address for the
# Vector Table can be mapped anywhere in the memory map. It means we can
# point the Exception Vector Table to its location in CpuDxe.
# By default we copy the Vector Table at PcdGet64(PcdCpuVectorBaseAddress)
gArmTokenSpaceGuid.PcdRelocateVectorTable|TRUE|BOOLEAN|0x00000022
# Set this PCD to TRUE if the Exception Vector is changed to add debugger support before
# it has been configured by the CPU DXE
gArmTokenSpaceGuid.PcdDebuggerExceptionSupport|FALSE|BOOLEAN|0x00000032
# Define if the spin-table mechanism is used by the secondary cores when booting
# Linux (instead of PSCI)
gArmTokenSpaceGuid.PcdArmLinuxSpinTable|FALSE|BOOLEAN|0x00000033
# Define if the GICv3 controller should use the GICv2 legacy
gArmTokenSpaceGuid.PcdArmGicV3WithV2Legacy|FALSE|BOOLEAN|0x00000042
# Whether to implement warm reboot for capsule update using a jump back to the
# PEI entry point with caches and interrupts disabled.
gArmTokenSpaceGuid.PcdArmReenterPeiForCapsuleWarmReboot|FALSE|BOOLEAN|0x0000001F
[PcdsFeatureFlag.ARM]
# Whether to map normal memory as non-shareable. FALSE is the safe choice, but
# TRUE may be appropriate to fix performance problems if you don't care about
# hardware coherency (i.e., no virtualization or cache coherent DMA)
gArmTokenSpaceGuid.PcdNormalMemoryNonshareableOverride|FALSE|BOOLEAN|0x00000043
[PcdsFixedAtBuild.common]
gArmTokenSpaceGuid.PcdTrustzoneSupport|FALSE|BOOLEAN|0x00000006
# This PCD should be a FeaturePcd. But we used this PCD as an '#if' in an ASM file.
# Using a FeaturePcd make a '(BOOLEAN) casting for its value which is not understood by the preprocessor.
gArmTokenSpaceGuid.PcdVFPEnabled|0|UINT32|0x00000024
gArmTokenSpaceGuid.PcdCpuVectorBaseAddress|0xffff0000|UINT64|0x00000004
gArmTokenSpaceGuid.PcdCpuResetAddress|0x00000000|UINT32|0x00000005
#
# ARM Secure Firmware PCDs
#
gArmTokenSpaceGuid.PcdSecureFdBaseAddress|0|UINT64|0x00000015
gArmTokenSpaceGuid.PcdSecureFdSize|0|UINT32|0x00000016
gArmTokenSpaceGuid.PcdSecureFvBaseAddress|0x0|UINT64|0x0000002F
gArmTokenSpaceGuid.PcdSecureFvSize|0x0|UINT32|0x00000030
#
# ARM Hypervisor Firmware PCDs
#
gArmTokenSpaceGuid.PcdHypFdBaseAddress|0|UINT32|0x0000003A
gArmTokenSpaceGuid.PcdHypFdSize|0|UINT32|0x0000003B
gArmTokenSpaceGuid.PcdHypFvBaseAddress|0|UINT32|0x0000003C
gArmTokenSpaceGuid.PcdHypFvSize|0|UINT32|0x0000003D
# Use ClusterId + CoreId to identify the PrimaryCore
gArmTokenSpaceGuid.PcdArmPrimaryCoreMask|0xF03|UINT32|0x00000031
# The Primary Core is ClusterId[0] & CoreId[0]
gArmTokenSpaceGuid.PcdArmPrimaryCore|0|UINT32|0x00000037
#
# ARM L2x0 PCDs
#
gArmTokenSpaceGuid.PcdL2x0ControllerBase|0|UINT32|0x0000001B
#
# ARM Normal (or Non Secure) Firmware PCDs
#
gArmTokenSpaceGuid.PcdFdSize|0|UINT32|0x0000002C
gArmTokenSpaceGuid.PcdFvSize|0|UINT32|0x0000002E
#
# Value to add to a host address to obtain a device address, using
# unsigned 64-bit integer arithmetic on both ARM and AArch64. This
# means we can rely on truncation on overflow to specify negative
# offsets.
#
gArmTokenSpaceGuid.PcdArmDmaDeviceOffset|0x0|UINT64|0x0000044
[PcdsFixedAtBuild.common, PcdsPatchableInModule.common]
gArmTokenSpaceGuid.PcdFdBaseAddress|0|UINT64|0x0000002B
gArmTokenSpaceGuid.PcdFvBaseAddress|0|UINT64|0x0000002D
[PcdsFixedAtBuild.ARM]
#
# ARM Security Extension
#
# Secure Configuration Register
# - BIT0 : NS - Non Secure bit
# - BIT1 : IRQ Handler
# - BIT2 : FIQ Handler
# - BIT3 : EA - External Abort
# - BIT4 : FW - F bit writable
# - BIT5 : AW - A bit writable
# - BIT6 : nET - Not Early Termination
# - BIT7 : SCD - Secure Monitor Call Disable
# - BIT8 : HCE - Hyp Call enable
# - BIT9 : SIF - Secure Instruction Fetch
# 0x31 = NS | EA | FW
gArmTokenSpaceGuid.PcdArmScr|0x31|UINT32|0x00000038
# By default we do not do a transition to non-secure mode
gArmTokenSpaceGuid.PcdArmNonSecModeTransition|0x0|UINT32|0x0000003E
# The Linux ATAGs are expected to be under 0x4000 (16KB) from the beginning of the System Memory
gArmTokenSpaceGuid.PcdArmLinuxAtagMaxOffset|0x4000|UINT32|0x00000020
# If the fixed FDT address is not available, then it should be loaded below the kernel.
# The recommendation from the Linux kernel is to have the FDT below 16KB.
# (see the kernel doc: Documentation/arm/Booting)
gArmTokenSpaceGuid.PcdArmLinuxFdtMaxOffset|0x4000|UINT32|0x00000023
# The FDT blob must be loaded at a 64bit aligned address.
gArmTokenSpaceGuid.PcdArmLinuxFdtAlignment|0x8|UINT32|0x00000026
# Non Secure Access Control Register
# - BIT15 : NSASEDIS - Disable Non-secure Advanced SIMD functionality
# - BIT14 : NSD32DIS - Disable Non-secure use of D16-D31
# - BIT11 : cp11 - Non-secure access to coprocessor 11 enable
# - BIT10 : cp10 - Non-secure access to coprocessor 10 enable
# 0xC00 = cp10 | cp11
gArmTokenSpaceGuid.PcdArmNsacr|0xC00|UINT32|0x00000039
[PcdsFixedAtBuild.AARCH64]
#
# AArch64 Security Extension
#
# Secure Configuration Register
# - BIT0 : NS - Non Secure bit
# - BIT1 : IRQ Handler
# - BIT2 : FIQ Handler
# - BIT3 : EA - External Abort
# - BIT4 : FW - F bit writable
# - BIT5 : AW - A bit writable
# - BIT6 : nET - Not Early Termination
# - BIT7 : SCD - Secure Monitor Call Disable
# - BIT8 : HCE - Hyp Call enable
# - BIT9 : SIF - Secure Instruction Fetch
# - BIT10: RW - Register width control for lower exception levels
# - BIT11: SIF - Enables Secure EL1 access to EL1 Architectural Timer
# - BIT12: TWI - Trap WFI
# - BIT13: TWE - Trap WFE
# 0x501 = NS | HCE | RW
gArmTokenSpaceGuid.PcdArmScr|0x501|UINT32|0x00000038
# By default we do transition to EL2 non-secure mode with Stack for EL2.
# Mode Description Bits
# NS EL2 SP2 all interrupts disabled = 0x3c9
# NS EL1 SP1 all interrupts disabled = 0x3c5
# Other modes include using SP0 or switching to Aarch32, but these are
# not currently supported.
gArmTokenSpaceGuid.PcdArmNonSecModeTransition|0x3c9|UINT32|0x0000003E
# If the fixed FDT address is not available, then it should be loaded above the kernel.
# The recommendation from the AArch64 Linux kernel is to have the FDT below 512MB.
# (see the kernel doc: Documentation/arm64/booting.txt)
gArmTokenSpaceGuid.PcdArmLinuxFdtMaxOffset|0x20000000|UINT32|0x00000023
# The FDT blob must be loaded at a 2MB aligned address.
gArmTokenSpaceGuid.PcdArmLinuxFdtAlignment|0x00200000|UINT32|0x00000026
#
# These PCDs are also defined as 'PcdsDynamic' or 'PcdsPatchableInModule' to be
# redefined when using UEFI in a context of virtual machine.
#
[PcdsFixedAtBuild.common, PcdsDynamic.common, PcdsPatchableInModule.common]
# System Memory (DRAM): These PCDs define the region of in-built system memory
# Some platforms can get DRAM extensions, these additional regions may be
# declared to UEFI using separate resource descriptor HOBs
gArmTokenSpaceGuid.PcdSystemMemoryBase|0|UINT64|0x00000029
gArmTokenSpaceGuid.PcdSystemMemorySize|0|UINT64|0x0000002A
[PcdsFixedAtBuild.common, PcdsDynamic.common]
#
# ARM Architectural Timer
#
gArmTokenSpaceGuid.PcdArmArchTimerFreqInHz|0|UINT32|0x00000034
# ARM Architectural Timer Interrupt(GIC PPI) numbers
gArmTokenSpaceGuid.PcdArmArchTimerSecIntrNum|29|UINT32|0x00000035
gArmTokenSpaceGuid.PcdArmArchTimerIntrNum|30|UINT32|0x00000036
gArmTokenSpaceGuid.PcdArmArchTimerHypIntrNum|26|UINT32|0x00000040
gArmTokenSpaceGuid.PcdArmArchTimerVirtIntrNum|27|UINT32|0x00000041
#
# ARM Generic Watchdog
#
gArmTokenSpaceGuid.PcdGenericWatchdogControlBase|0x2A440000|UINT64|0x00000007
gArmTokenSpaceGuid.PcdGenericWatchdogRefreshBase|0x2A450000|UINT64|0x00000008
gArmTokenSpaceGuid.PcdGenericWatchdogEl2IntrNum|93|UINT32|0x00000009
#
# ARM Generic Interrupt Controller
#
gArmTokenSpaceGuid.PcdGicDistributorBase|0|UINT64|0x0000000C
# Base address for the GIC Redistributor region that contains the boot CPU
gArmTokenSpaceGuid.PcdGicRedistributorsBase|0|UINT64|0x0000000E
gArmTokenSpaceGuid.PcdGicInterruptInterfaceBase|0|UINT64|0x0000000D
gArmTokenSpaceGuid.PcdGicSgiIntId|0|UINT32|0x00000025
#
# Bases, sizes and translation offsets of IO and MMIO spaces, respectively.
# Note that "IO" is just another MMIO range that simulates IO space; there
# are no special instructions to access it.
#
# The base addresses PcdPciIoBase, PcdPciMmio32Base and PcdPciMmio64Base are
# specific to their containing address spaces. In order to get the physical
# address for the CPU, for a given access, the respective translation value
# has to be added.
#
# The translations always have to be initialized like this, using UINT64:
#
# UINT64 IoCpuBase; // mapping target in 64-bit cpu-physical space
# UINT64 Mmio32CpuBase; // mapping target in 64-bit cpu-physical space
# UINT64 Mmio64CpuBase; // mapping target in 64-bit cpu-physical space
#
# PcdPciIoTranslation = IoCpuBase - PcdPciIoBase;
# PcdPciMmio32Translation = Mmio32CpuBase - (UINT64)PcdPciMmio32Base;
# PcdPciMmio64Translation = Mmio64CpuBase - PcdPciMmio64Base;
#
# because (a) the target address space (ie. the cpu-physical space) is
# 64-bit, and (b) the translation values are meant as offsets for *modular*
# arithmetic.
#
# Accordingly, the translation itself needs to be implemented as:
#
# UINT64 UntranslatedIoAddress; // input parameter
# UINT32 UntranslatedMmio32Address; // input parameter
# UINT64 UntranslatedMmio64Address; // input parameter
#
# UINT64 TranslatedIoAddress; // output parameter
# UINT64 TranslatedMmio32Address; // output parameter
# UINT64 TranslatedMmio64Address; // output parameter
#
# TranslatedIoAddress = UntranslatedIoAddress +
# PcdPciIoTranslation;
# TranslatedMmio32Address = (UINT64)UntranslatedMmio32Address +
# PcdPciMmio32Translation;
# TranslatedMmio64Address = UntranslatedMmio64Address +
# PcdPciMmio64Translation;
#
# The modular arithmetic performed in UINT64 ensures that the translation
# works correctly regardless of the relation between IoCpuBase and
# PcdPciIoBase, Mmio32CpuBase and PcdPciMmio32Base, and Mmio64CpuBase and
# PcdPciMmio64Base.
#
gArmTokenSpaceGuid.PcdPciIoBase|0x0|UINT64|0x00000050
gArmTokenSpaceGuid.PcdPciIoSize|0x0|UINT64|0x00000051
gArmTokenSpaceGuid.PcdPciIoTranslation|0x0|UINT64|0x00000052
gArmTokenSpaceGuid.PcdPciMmio32Base|0x0|UINT32|0x00000053
gArmTokenSpaceGuid.PcdPciMmio32Size|0x0|UINT32|0x00000054
gArmTokenSpaceGuid.PcdPciMmio32Translation|0x0|UINT64|0x00000055
gArmTokenSpaceGuid.PcdPciMmio64Base|0x0|UINT64|0x00000056
gArmTokenSpaceGuid.PcdPciMmio64Size|0x0|UINT64|0x00000057
gArmTokenSpaceGuid.PcdPciMmio64Translation|0x0|UINT64|0x00000058
#
# Inclusive range of allowed PCI buses.
#
gArmTokenSpaceGuid.PcdPciBusMin|0x0|UINT32|0x00000059
gArmTokenSpaceGuid.PcdPciBusMax|0x0|UINT32|0x0000005A