ArmPkg/Library/ArmLib/AArch64/AArch64Support.S - edk2 - Git at Google

 #------------------------------------------------------------------------------
 #
 # Copyright (c) 2008 - 2010, Apple Inc. All rights reserved.<BR>
 # Copyright (c) 2011 - 2017, ARM Limited. All rights reserved.
 # Copyright (c) 2016, Linaro 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.
 #
 #------------------------------------------------------------------------------

 #include <Chipset/AArch64.h>
 #include <AsmMacroIoLibV8.h>

 .set CTRL_M_BIT,      (1 << 0)
 .set CTRL_A_BIT,      (1 << 1)
 .set CTRL_C_BIT,      (1 << 2)
 .set CTRL_SA_BIT,     (1 << 3)
 .set CTRL_I_BIT,      (1 << 12)
 .set CTRL_V_BIT,      (1 << 12)
 .set CPACR_VFP_BITS,  (3 << 20)

 ASM_FUNC(ArmInvalidateDataCacheEntryByMVA)
   dc      ivac, x0    // Invalidate single data cache line
   ret


 ASM_FUNC(ArmCleanDataCacheEntryByMVA)
   dc      cvac, x0    // Clean single data cache line
   ret


 ASM_FUNC(ArmCleanDataCacheEntryToPoUByMVA)
   dc      cvau, x0    // Clean single data cache line to PoU
   ret

 ASM_FUNC(ArmInvalidateInstructionCacheEntryToPoUByMVA)
   ic      ivau, x0    // Invalidate single instruction cache line to PoU
   ret


 ASM_FUNC(ArmCleanInvalidateDataCacheEntryByMVA)
   dc      civac, x0   // Clean and invalidate single data cache line
   ret


 ASM_FUNC(ArmInvalidateDataCacheEntryBySetWay)
   dc      isw, x0     // Invalidate this line
   ret


 ASM_FUNC(ArmCleanInvalidateDataCacheEntryBySetWay)
   dc      cisw, x0    // Clean and Invalidate this line
   ret


 ASM_FUNC(ArmCleanDataCacheEntryBySetWay)
   dc      csw, x0     // Clean this line
   ret


 ASM_FUNC(ArmInvalidateInstructionCache)
   ic      iallu       // Invalidate entire instruction cache
   dsb     sy
   isb
   ret


 ASM_FUNC(ArmEnableMmu)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs     x0, sctlr_el1       // Read System control register EL1
    b       4f
 2: mrs     x0, sctlr_el2       // Read System control register EL2
    b       4f
 3: mrs     x0, sctlr_el3       // Read System control register EL3
 4: orr     x0, x0, #CTRL_M_BIT // Set MMU enable bit
    EL1_OR_EL2_OR_EL3(x1)
 1: tlbi    vmalle1
    dsb     nsh
    isb
    msr     sctlr_el1, x0       // Write back
    b       4f
 2: tlbi    alle2
    dsb     nsh
    isb
    msr     sctlr_el2, x0       // Write back
    b       4f
 3: tlbi    alle3
    dsb     nsh
    isb
    msr     sctlr_el3, x0       // Write back
 4: isb
    ret


 ASM_FUNC(ArmDisableMmu)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs     x0, sctlr_el1        // Read System Control Register EL1
    b       4f
 2: mrs     x0, sctlr_el2        // Read System Control Register EL2
    b       4f
 3: mrs     x0, sctlr_el3        // Read System Control Register EL3
 4: and     x0, x0, #~CTRL_M_BIT  // Clear MMU enable bit
    EL1_OR_EL2_OR_EL3(x1)
 1: msr     sctlr_el1, x0        // Write back
    tlbi    vmalle1
    b       4f
 2: msr     sctlr_el2, x0        // Write back
    tlbi    alle2
    b       4f
 3: msr     sctlr_el3, x0        // Write back
    tlbi    alle3
 4: dsb     sy
    isb
    ret


 ASM_FUNC(ArmDisableCachesAndMmu)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs     x0, sctlr_el1        // Get control register EL1
    b       4f
 2: mrs     x0, sctlr_el2        // Get control register EL2
    b       4f
 3: mrs     x0, sctlr_el3        // Get control register EL3
 4: mov     x1, #~(CTRL_M_BIT | CTRL_C_BIT | CTRL_I_BIT)  // Disable MMU, D & I caches
    and     x0, x0, x1
    EL1_OR_EL2_OR_EL3(x1)
 1: msr     sctlr_el1, x0        // Write back control register
    b       4f
 2: msr     sctlr_el2, x0        // Write back control register
    b       4f
 3: msr     sctlr_el3, x0        // Write back control register
 4: dsb     sy
    isb
    ret


 ASM_FUNC(ArmMmuEnabled)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs     x0, sctlr_el1        // Get control register EL1
    b       4f
 2: mrs     x0, sctlr_el2        // Get control register EL2
    b       4f
 3: mrs     x0, sctlr_el3        // Get control register EL3
 4: and     x0, x0, #CTRL_M_BIT
    ret


 ASM_FUNC(ArmEnableDataCache)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs     x0, sctlr_el1        // Get control register EL1
    b       4f
 2: mrs     x0, sctlr_el2        // Get control register EL2
    b       4f
 3: mrs     x0, sctlr_el3        // Get control register EL3
 4: orr     x0, x0, #CTRL_C_BIT  // Set C bit
    EL1_OR_EL2_OR_EL3(x1)
 1: msr     sctlr_el1, x0        // Write back control register
    b       4f
 2: msr     sctlr_el2, x0        // Write back control register
    b       4f
 3: msr     sctlr_el3, x0        // Write back control register
 4: dsb     sy
    isb
    ret


 ASM_FUNC(ArmDisableDataCache)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs     x0, sctlr_el1        // Get control register EL1
    b       4f
 2: mrs     x0, sctlr_el2        // Get control register EL2
    b       4f
 3: mrs     x0, sctlr_el3        // Get control register EL3
 4: and     x0, x0, #~CTRL_C_BIT  // Clear C bit
    EL1_OR_EL2_OR_EL3(x1)
 1: msr     sctlr_el1, x0        // Write back control register
    b       4f
 2: msr     sctlr_el2, x0        // Write back control register
    b       4f
 3: msr     sctlr_el3, x0        // Write back control register
 4: dsb     sy
    isb
    ret


 ASM_FUNC(ArmEnableInstructionCache)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs     x0, sctlr_el1        // Get control register EL1
    b       4f
 2: mrs     x0, sctlr_el2        // Get control register EL2
    b       4f
 3: mrs     x0, sctlr_el3        // Get control register EL3
 4: orr     x0, x0, #CTRL_I_BIT  // Set I bit
    EL1_OR_EL2_OR_EL3(x1)
 1: msr     sctlr_el1, x0        // Write back control register
    b       4f
 2: msr     sctlr_el2, x0        // Write back control register
    b       4f
 3: msr     sctlr_el3, x0        // Write back control register
 4: dsb     sy
    isb
    ret


 ASM_FUNC(ArmDisableInstructionCache)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs     x0, sctlr_el1        // Get control register EL1
    b       4f
 2: mrs     x0, sctlr_el2        // Get control register EL2
    b       4f
 3: mrs     x0, sctlr_el3        // Get control register EL3
 4: and     x0, x0, #~CTRL_I_BIT  // Clear I bit
    EL1_OR_EL2_OR_EL3(x1)
 1: msr     sctlr_el1, x0        // Write back control register
    b       4f
 2: msr     sctlr_el2, x0        // Write back control register
    b       4f
 3: msr     sctlr_el3, x0        // Write back control register
 4: dsb     sy
    isb
    ret


 ASM_FUNC(ArmEnableAlignmentCheck)
    EL1_OR_EL2(x1)
 1: mrs     x0, sctlr_el1        // Get control register EL1
    b       3f
 2: mrs     x0, sctlr_el2        // Get control register EL2
 3: orr     x0, x0, #CTRL_A_BIT  // Set A (alignment check) bit
    EL1_OR_EL2(x1)
 1: msr     sctlr_el1, x0        // Write back control register
    b       3f
 2: msr     sctlr_el2, x0        // Write back control register
 3: dsb     sy
    isb
    ret


 ASM_FUNC(ArmDisableAlignmentCheck)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs     x0, sctlr_el1        // Get control register EL1
    b       4f
 2: mrs     x0, sctlr_el2        // Get control register EL2
    b       4f
 3: mrs     x0, sctlr_el3        // Get control register EL3
 4: and     x0, x0, #~CTRL_A_BIT  // Clear A (alignment check) bit
    EL1_OR_EL2_OR_EL3(x1)
 1: msr     sctlr_el1, x0        // Write back control register
    b       4f
 2: msr     sctlr_el2, x0        // Write back control register
    b       4f
 3: msr     sctlr_el3, x0        // Write back control register
 4: dsb     sy
    isb
    ret

 ASM_FUNC(ArmEnableStackAlignmentCheck)
    EL1_OR_EL2(x1)
 1: mrs     x0, sctlr_el1        // Get control register EL1
    b       3f
 2: mrs     x0, sctlr_el2        // Get control register EL2
 3: orr     x0, x0, #CTRL_SA_BIT // Set SA (stack alignment check) bit
    EL1_OR_EL2(x1)
 1: msr     sctlr_el1, x0        // Write back control register
    b       3f
 2: msr     sctlr_el2, x0        // Write back control register
 3: dsb     sy
    isb
    ret


 ASM_FUNC(ArmDisableStackAlignmentCheck)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs     x0, sctlr_el1        // Get control register EL1
    b       4f
 2: mrs     x0, sctlr_el2        // Get control register EL2
    b       4f
 3: mrs     x0, sctlr_el3        // Get control register EL3
 4: bic     x0, x0, #CTRL_SA_BIT // Clear SA (stack alignment check) bit
    EL1_OR_EL2_OR_EL3(x1)
 1: msr     sctlr_el1, x0        // Write back control register
    b       4f
 2: msr     sctlr_el2, x0        // Write back control register
    b       4f
 3: msr     sctlr_el3, x0        // Write back control register
 4: dsb     sy
    isb
    ret


 // Always turned on in AArch64. Else implementation specific. Leave in for C compatibility for now
 ASM_FUNC(ArmEnableBranchPrediction)
   ret


 // Always turned on in AArch64. Else implementation specific. Leave in for C compatibility for now.
 ASM_FUNC(ArmDisableBranchPrediction)
   ret


 ASM_FUNC(AArch64AllDataCachesOperation)
 // We can use regs 0-7 and 9-15 without having to save/restore.
 // Save our link register on the stack. - The stack must always be quad-word aligned
   stp   x29, x30, [sp, #-16]!
   mov   x29, sp
   mov   x1, x0                  // Save Function call in x1
   mrs   x6, clidr_el1           // Read EL1 CLIDR
   and   x3, x6, #0x7000000      // Mask out all but Level of Coherency (LoC)
   lsr   x3, x3, #23             // Left align cache level value - the level is shifted by 1 to the
                                 // right to ease the access to CSSELR and the Set/Way operation.
   cbz   x3, L_Finished          // No need to clean if LoC is 0
   mov   x10, #0                 // Start clean at cache level 0

 Loop1:
   add   x2, x10, x10, lsr #1    // Work out 3x cachelevel for cache info
   lsr   x12, x6, x2             // bottom 3 bits are the Cache type for this level
   and   x12, x12, #7            // get those 3 bits alone
   cmp   x12, #2                 // what cache at this level?
   b.lt  L_Skip                  // no cache or only instruction cache at this level
   msr   csselr_el1, x10         // write the Cache Size selection register with current level (CSSELR)
   isb                           // isb to sync the change to the CacheSizeID reg
   mrs   x12, ccsidr_el1         // reads current Cache Size ID register (CCSIDR)
   and   x2, x12, #0x7           // extract the line length field
   add   x2, x2, #4              // add 4 for the line length offset (log2 16 bytes)
   mov   x4, #0x400
   sub   x4, x4, #1
   and   x4, x4, x12, lsr #3     // x4 is the max number on the way size (right aligned)
   clz   w5, w4                  // w5 is the bit position of the way size increment
   mov   x7, #0x00008000
   sub   x7, x7, #1
   and   x7, x7, x12, lsr #13    // x7 is the max number of the index size (right aligned)

 Loop2:
   mov   x9, x4                  // x9 working copy of the max way size (right aligned)

 Loop3:
   lsl   x11, x9, x5
   orr   x0, x10, x11            // factor in the way number and cache number
   lsl   x11, x7, x2
   orr   x0, x0, x11             // factor in the index number

   blr   x1                      // Goto requested cache operation

   subs  x9, x9, #1              // decrement the way number
   b.ge  Loop3
   subs  x7, x7, #1              // decrement the index
   b.ge  Loop2
 L_Skip:
   add   x10, x10, #2            // increment the cache number
   cmp   x3, x10
   b.gt  Loop1

 L_Finished:
   dsb   sy
   isb
   ldp   x29, x30, [sp], #0x10
   ret


 ASM_FUNC(ArmDataMemoryBarrier)
   dmb   sy
   ret


 ASM_FUNC(ArmDataSynchronizationBarrier)
   dsb   sy
   ret


 ASM_FUNC(ArmInstructionSynchronizationBarrier)
   isb
   ret


 ASM_FUNC(ArmWriteVBar)
    EL1_OR_EL2_OR_EL3(x1)
 1: msr   vbar_el1, x0            // Set the Address of the EL1 Vector Table in the VBAR register
    b     4f
 2: msr   vbar_el2, x0            // Set the Address of the EL2 Vector Table in the VBAR register
    b     4f
 3: msr   vbar_el3, x0            // Set the Address of the EL3 Vector Table in the VBAR register
 4: isb
    ret

 ASM_FUNC(ArmReadVBar)
    EL1_OR_EL2_OR_EL3(x1)
 1: mrs   x0, vbar_el1            // Set the Address of the EL1 Vector Table in the VBAR register
    ret
 2: mrs   x0, vbar_el2            // Set the Address of the EL2 Vector Table in the VBAR register
    ret
 3: mrs   x0, vbar_el3            // Set the Address of the EL3 Vector Table in the VBAR register
    ret


 ASM_FUNC(ArmEnableVFP)
   // Check whether floating-point is implemented in the processor.
   mov   x1, x30                 // Save LR
   bl    ArmReadIdPfr0           // Read EL1 Processor Feature Register (PFR0)
   mov   x30, x1                 // Restore LR
   ubfx  x0, x0, #16, #4         // Extract the FP bits 16:19
   cmp   x0, #0xF                // Check if FP bits are '1111b',
                                 // i.e. Floating Point not implemented
   b.eq  4f                      // Exit when VFP is not implemented.

   // FVP is implemented.
   // Make sure VFP exceptions are not trapped (to any exception level).
   mrs   x0, cpacr_el1           // Read EL1 Coprocessor Access Control Register (CPACR)
   orr   x0, x0, #CPACR_VFP_BITS // Disable FVP traps to EL1
   msr   cpacr_el1, x0           // Write back EL1 Coprocessor Access Control Register (CPACR)
   mov   x1, #AARCH64_CPTR_TFP   // TFP Bit for trapping VFP Exceptions
   EL1_OR_EL2_OR_EL3(x2)
 1:ret                           // Not configurable in EL1
 2:mrs   x0, cptr_el2            // Disable VFP traps to EL2
   bic   x0, x0, x1
   msr   cptr_el2, x0
   ret
 3:mrs   x0, cptr_el3            // Disable VFP traps to EL3
   bic   x0, x0, x1
   msr   cptr_el3, x0
 4:ret


 ASM_FUNC(ArmCallWFI)
   wfi
   ret


 ASM_FUNC(ArmReadMpidr)
   mrs   x0, mpidr_el1           // read EL1 MPIDR
   ret


 // Keep old function names for C compatibilty for now. Change later?
 ASM_FUNC(ArmReadTpidrurw)
   mrs   x0, tpidr_el0           // read tpidr_el0 (v7 TPIDRURW) -> (v8 TPIDR_EL0)
   ret


 // Keep old function names for C compatibilty for now. Change later?
 ASM_FUNC(ArmWriteTpidrurw)
   msr   tpidr_el0, x0           // write tpidr_el0 (v7 TPIDRURW) -> (v8 TPIDR_EL0)
   ret


 // Arch timers are mandatory on AArch64
 ASM_FUNC(ArmIsArchTimerImplemented)
   mov   x0, #1
   ret


 ASM_FUNC(ArmReadIdPfr0)
   mrs   x0, id_aa64pfr0_el1   // Read ID_AA64PFR0 Register
   ret


 // Q: id_aa64pfr1_el1 not defined yet. What does this funtion want to access?
 // A: used to setup arch timer. Check if we have security extensions, permissions to set stuff.
 //    See: ArmPkg/Library/ArmArchTimerLib/AArch64/ArmArchTimerLib.c
 //    Not defined yet, but stick in here for now, should read all zeros.
 ASM_FUNC(ArmReadIdPfr1)
   mrs   x0, id_aa64pfr1_el1   // Read ID_PFR1 Register
   ret

 // VOID ArmWriteHcr(UINTN Hcr)
 ASM_FUNC(ArmWriteHcr)
   msr   hcr_el2, x0        // Write the passed HCR value
   ret

 // UINTN ArmReadHcr(VOID)
 ASM_FUNC(ArmReadHcr)
   mrs   x0, hcr_el2
   ret

 // UINTN ArmReadCurrentEL(VOID)
 ASM_FUNC(ArmReadCurrentEL)
   mrs   x0, CurrentEL
   ret

 // UINT32 ArmReadCntHctl(VOID)
 ASM_FUNC(ArmReadCntHctl)
   mrs   x0, cnthctl_el2
   ret

 // VOID ArmWriteCntHctl(UINT32 CntHctl)
 ASM_FUNC(ArmWriteCntHctl)
   msr   cnthctl_el2, x0
   ret

 ASM_FUNCTION_REMOVE_IF_UNREFERENCED
	#------------------------------------------------------------------------------
	#
	# Copyright (c) 2008 - 2010, Apple Inc. All rights reserved.<BR>
	# Copyright (c) 2011 - 2017, ARM Limited. All rights reserved.
	# Copyright (c) 2016, Linaro 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.
	#
	#------------------------------------------------------------------------------

	#include <Chipset/AArch64.h>
	#include <AsmMacroIoLibV8.h>

	.set CTRL_M_BIT, (1 << 0)
	.set CTRL_A_BIT, (1 << 1)
	.set CTRL_C_BIT, (1 << 2)
	.set CTRL_SA_BIT, (1 << 3)
	.set CTRL_I_BIT, (1 << 12)
	.set CTRL_V_BIT, (1 << 12)
	.set CPACR_VFP_BITS, (3 << 20)

	ASM_FUNC(ArmInvalidateDataCacheEntryByMVA)
	dc ivac, x0 // Invalidate single data cache line
	ret


	ASM_FUNC(ArmCleanDataCacheEntryByMVA)
	dc cvac, x0 // Clean single data cache line
	ret


	ASM_FUNC(ArmCleanDataCacheEntryToPoUByMVA)
	dc cvau, x0 // Clean single data cache line to PoU
	ret

	ASM_FUNC(ArmInvalidateInstructionCacheEntryToPoUByMVA)
	ic ivau, x0 // Invalidate single instruction cache line to PoU
	ret


	ASM_FUNC(ArmCleanInvalidateDataCacheEntryByMVA)
	dc civac, x0 // Clean and invalidate single data cache line
	ret


	ASM_FUNC(ArmInvalidateDataCacheEntryBySetWay)
	dc isw, x0 // Invalidate this line
	ret


	ASM_FUNC(ArmCleanInvalidateDataCacheEntryBySetWay)
	dc cisw, x0 // Clean and Invalidate this line
	ret


	ASM_FUNC(ArmCleanDataCacheEntryBySetWay)
	dc csw, x0 // Clean this line
	ret


	ASM_FUNC(ArmInvalidateInstructionCache)
	ic iallu // Invalidate entire instruction cache
	dsb sy
	isb
	ret


	ASM_FUNC(ArmEnableMmu)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, sctlr_el1 // Read System control register EL1
	b 4f
	2: mrs x0, sctlr_el2 // Read System control register EL2
	b 4f
	3: mrs x0, sctlr_el3 // Read System control register EL3
	4: orr x0, x0, #CTRL_M_BIT // Set MMU enable bit
	EL1_OR_EL2_OR_EL3(x1)
	1: tlbi vmalle1
	dsb nsh
	isb
	msr sctlr_el1, x0 // Write back
	b 4f
	2: tlbi alle2
	dsb nsh
	isb
	msr sctlr_el2, x0 // Write back
	b 4f
	3: tlbi alle3
	dsb nsh
	isb
	msr sctlr_el3, x0 // Write back
	4: isb
	ret


	ASM_FUNC(ArmDisableMmu)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, sctlr_el1 // Read System Control Register EL1
	b 4f
	2: mrs x0, sctlr_el2 // Read System Control Register EL2
	b 4f
	3: mrs x0, sctlr_el3 // Read System Control Register EL3
	4: and x0, x0, #~CTRL_M_BIT // Clear MMU enable bit
	EL1_OR_EL2_OR_EL3(x1)
	1: msr sctlr_el1, x0 // Write back
	tlbi vmalle1
	b 4f
	2: msr sctlr_el2, x0 // Write back
	tlbi alle2
	b 4f
	3: msr sctlr_el3, x0 // Write back
	tlbi alle3
	4: dsb sy
	isb
	ret


	ASM_FUNC(ArmDisableCachesAndMmu)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, sctlr_el1 // Get control register EL1
	b 4f
	2: mrs x0, sctlr_el2 // Get control register EL2
	b 4f
	3: mrs x0, sctlr_el3 // Get control register EL3
	4: mov x1, #~(CTRL_M_BIT \| CTRL_C_BIT \| CTRL_I_BIT) // Disable MMU, D & I caches
	and x0, x0, x1
	EL1_OR_EL2_OR_EL3(x1)
	1: msr sctlr_el1, x0 // Write back control register
	b 4f
	2: msr sctlr_el2, x0 // Write back control register
	b 4f
	3: msr sctlr_el3, x0 // Write back control register
	4: dsb sy
	isb
	ret


	ASM_FUNC(ArmMmuEnabled)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, sctlr_el1 // Get control register EL1
	b 4f
	2: mrs x0, sctlr_el2 // Get control register EL2
	b 4f
	3: mrs x0, sctlr_el3 // Get control register EL3
	4: and x0, x0, #CTRL_M_BIT
	ret


	ASM_FUNC(ArmEnableDataCache)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, sctlr_el1 // Get control register EL1
	b 4f
	2: mrs x0, sctlr_el2 // Get control register EL2
	b 4f
	3: mrs x0, sctlr_el3 // Get control register EL3
	4: orr x0, x0, #CTRL_C_BIT // Set C bit
	EL1_OR_EL2_OR_EL3(x1)
	1: msr sctlr_el1, x0 // Write back control register
	b 4f
	2: msr sctlr_el2, x0 // Write back control register
	b 4f
	3: msr sctlr_el3, x0 // Write back control register
	4: dsb sy
	isb
	ret


	ASM_FUNC(ArmDisableDataCache)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, sctlr_el1 // Get control register EL1
	b 4f
	2: mrs x0, sctlr_el2 // Get control register EL2
	b 4f
	3: mrs x0, sctlr_el3 // Get control register EL3
	4: and x0, x0, #~CTRL_C_BIT // Clear C bit
	EL1_OR_EL2_OR_EL3(x1)
	1: msr sctlr_el1, x0 // Write back control register
	b 4f
	2: msr sctlr_el2, x0 // Write back control register
	b 4f
	3: msr sctlr_el3, x0 // Write back control register
	4: dsb sy
	isb
	ret


	ASM_FUNC(ArmEnableInstructionCache)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, sctlr_el1 // Get control register EL1
	b 4f
	2: mrs x0, sctlr_el2 // Get control register EL2
	b 4f
	3: mrs x0, sctlr_el3 // Get control register EL3
	4: orr x0, x0, #CTRL_I_BIT // Set I bit
	EL1_OR_EL2_OR_EL3(x1)
	1: msr sctlr_el1, x0 // Write back control register
	b 4f
	2: msr sctlr_el2, x0 // Write back control register
	b 4f
	3: msr sctlr_el3, x0 // Write back control register
	4: dsb sy
	isb
	ret


	ASM_FUNC(ArmDisableInstructionCache)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, sctlr_el1 // Get control register EL1
	b 4f
	2: mrs x0, sctlr_el2 // Get control register EL2
	b 4f
	3: mrs x0, sctlr_el3 // Get control register EL3
	4: and x0, x0, #~CTRL_I_BIT // Clear I bit
	EL1_OR_EL2_OR_EL3(x1)
	1: msr sctlr_el1, x0 // Write back control register
	b 4f
	2: msr sctlr_el2, x0 // Write back control register
	b 4f
	3: msr sctlr_el3, x0 // Write back control register
	4: dsb sy
	isb
	ret


	ASM_FUNC(ArmEnableAlignmentCheck)
	EL1_OR_EL2(x1)
	1: mrs x0, sctlr_el1 // Get control register EL1
	b 3f
	2: mrs x0, sctlr_el2 // Get control register EL2
	3: orr x0, x0, #CTRL_A_BIT // Set A (alignment check) bit
	EL1_OR_EL2(x1)
	1: msr sctlr_el1, x0 // Write back control register
	b 3f
	2: msr sctlr_el2, x0 // Write back control register
	3: dsb sy
	isb
	ret


	ASM_FUNC(ArmDisableAlignmentCheck)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, sctlr_el1 // Get control register EL1
	b 4f
	2: mrs x0, sctlr_el2 // Get control register EL2
	b 4f
	3: mrs x0, sctlr_el3 // Get control register EL3
	4: and x0, x0, #~CTRL_A_BIT // Clear A (alignment check) bit
	EL1_OR_EL2_OR_EL3(x1)
	1: msr sctlr_el1, x0 // Write back control register
	b 4f
	2: msr sctlr_el2, x0 // Write back control register
	b 4f
	3: msr sctlr_el3, x0 // Write back control register
	4: dsb sy
	isb
	ret

	ASM_FUNC(ArmEnableStackAlignmentCheck)
	EL1_OR_EL2(x1)
	1: mrs x0, sctlr_el1 // Get control register EL1
	b 3f
	2: mrs x0, sctlr_el2 // Get control register EL2
	3: orr x0, x0, #CTRL_SA_BIT // Set SA (stack alignment check) bit
	EL1_OR_EL2(x1)
	1: msr sctlr_el1, x0 // Write back control register
	b 3f
	2: msr sctlr_el2, x0 // Write back control register
	3: dsb sy
	isb
	ret


	ASM_FUNC(ArmDisableStackAlignmentCheck)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, sctlr_el1 // Get control register EL1
	b 4f
	2: mrs x0, sctlr_el2 // Get control register EL2
	b 4f
	3: mrs x0, sctlr_el3 // Get control register EL3
	4: bic x0, x0, #CTRL_SA_BIT // Clear SA (stack alignment check) bit
	EL1_OR_EL2_OR_EL3(x1)
	1: msr sctlr_el1, x0 // Write back control register
	b 4f
	2: msr sctlr_el2, x0 // Write back control register
	b 4f
	3: msr sctlr_el3, x0 // Write back control register
	4: dsb sy
	isb
	ret


	// Always turned on in AArch64. Else implementation specific. Leave in for C compatibility for now
	ASM_FUNC(ArmEnableBranchPrediction)
	ret


	// Always turned on in AArch64. Else implementation specific. Leave in for C compatibility for now.
	ASM_FUNC(ArmDisableBranchPrediction)
	ret


	ASM_FUNC(AArch64AllDataCachesOperation)
	// We can use regs 0-7 and 9-15 without having to save/restore.
	// Save our link register on the stack. - The stack must always be quad-word aligned
	stp x29, x30, [sp, #-16]!
	mov x29, sp
	mov x1, x0 // Save Function call in x1
	mrs x6, clidr_el1 // Read EL1 CLIDR
	and x3, x6, #0x7000000 // Mask out all but Level of Coherency (LoC)
	lsr x3, x3, #23 // Left align cache level value - the level is shifted by 1 to the
	// right to ease the access to CSSELR and the Set/Way operation.
	cbz x3, L_Finished // No need to clean if LoC is 0
	mov x10, #0 // Start clean at cache level 0

	Loop1:
	add x2, x10, x10, lsr #1 // Work out 3x cachelevel for cache info
	lsr x12, x6, x2 // bottom 3 bits are the Cache type for this level
	and x12, x12, #7 // get those 3 bits alone
	cmp x12, #2 // what cache at this level?
	b.lt L_Skip // no cache or only instruction cache at this level
	msr csselr_el1, x10 // write the Cache Size selection register with current level (CSSELR)
	isb // isb to sync the change to the CacheSizeID reg
	mrs x12, ccsidr_el1 // reads current Cache Size ID register (CCSIDR)
	and x2, x12, #0x7 // extract the line length field
	add x2, x2, #4 // add 4 for the line length offset (log2 16 bytes)
	mov x4, #0x400
	sub x4, x4, #1
	and x4, x4, x12, lsr #3 // x4 is the max number on the way size (right aligned)
	clz w5, w4 // w5 is the bit position of the way size increment
	mov x7, #0x00008000
	sub x7, x7, #1
	and x7, x7, x12, lsr #13 // x7 is the max number of the index size (right aligned)

	Loop2:
	mov x9, x4 // x9 working copy of the max way size (right aligned)

	Loop3:
	lsl x11, x9, x5
	orr x0, x10, x11 // factor in the way number and cache number
	lsl x11, x7, x2
	orr x0, x0, x11 // factor in the index number

	blr x1 // Goto requested cache operation

	subs x9, x9, #1 // decrement the way number
	b.ge Loop3
	subs x7, x7, #1 // decrement the index
	b.ge Loop2
	L_Skip:
	add x10, x10, #2 // increment the cache number
	cmp x3, x10
	b.gt Loop1

	L_Finished:
	dsb sy
	isb
	ldp x29, x30, [sp], #0x10
	ret


	ASM_FUNC(ArmDataMemoryBarrier)
	dmb sy
	ret


	ASM_FUNC(ArmDataSynchronizationBarrier)
	dsb sy
	ret


	ASM_FUNC(ArmInstructionSynchronizationBarrier)
	isb
	ret


	ASM_FUNC(ArmWriteVBar)
	EL1_OR_EL2_OR_EL3(x1)
	1: msr vbar_el1, x0 // Set the Address of the EL1 Vector Table in the VBAR register
	b 4f
	2: msr vbar_el2, x0 // Set the Address of the EL2 Vector Table in the VBAR register
	b 4f
	3: msr vbar_el3, x0 // Set the Address of the EL3 Vector Table in the VBAR register
	4: isb
	ret

	ASM_FUNC(ArmReadVBar)
	EL1_OR_EL2_OR_EL3(x1)
	1: mrs x0, vbar_el1 // Set the Address of the EL1 Vector Table in the VBAR register
	ret
	2: mrs x0, vbar_el2 // Set the Address of the EL2 Vector Table in the VBAR register
	ret
	3: mrs x0, vbar_el3 // Set the Address of the EL3 Vector Table in the VBAR register
	ret


	ASM_FUNC(ArmEnableVFP)
	// Check whether floating-point is implemented in the processor.
	mov x1, x30 // Save LR
	bl ArmReadIdPfr0 // Read EL1 Processor Feature Register (PFR0)
	mov x30, x1 // Restore LR
	ubfx x0, x0, #16, #4 // Extract the FP bits 16:19
	cmp x0, #0xF // Check if FP bits are '1111b',
	// i.e. Floating Point not implemented
	b.eq 4f // Exit when VFP is not implemented.

	// FVP is implemented.
	// Make sure VFP exceptions are not trapped (to any exception level).
	mrs x0, cpacr_el1 // Read EL1 Coprocessor Access Control Register (CPACR)
	orr x0, x0, #CPACR_VFP_BITS // Disable FVP traps to EL1
	msr cpacr_el1, x0 // Write back EL1 Coprocessor Access Control Register (CPACR)
	mov x1, #AARCH64_CPTR_TFP // TFP Bit for trapping VFP Exceptions
	EL1_OR_EL2_OR_EL3(x2)
	1:ret // Not configurable in EL1
	2:mrs x0, cptr_el2 // Disable VFP traps to EL2
	bic x0, x0, x1
	msr cptr_el2, x0
	ret
	3:mrs x0, cptr_el3 // Disable VFP traps to EL3
	bic x0, x0, x1
	msr cptr_el3, x0
	4:ret


	ASM_FUNC(ArmCallWFI)
	wfi
	ret


	ASM_FUNC(ArmReadMpidr)
	mrs x0, mpidr_el1 // read EL1 MPIDR
	ret


	// Keep old function names for C compatibilty for now. Change later?
	ASM_FUNC(ArmReadTpidrurw)
	mrs x0, tpidr_el0 // read tpidr_el0 (v7 TPIDRURW) -> (v8 TPIDR_EL0)
	ret


	// Keep old function names for C compatibilty for now. Change later?
	ASM_FUNC(ArmWriteTpidrurw)
	msr tpidr_el0, x0 // write tpidr_el0 (v7 TPIDRURW) -> (v8 TPIDR_EL0)
	ret


	// Arch timers are mandatory on AArch64
	ASM_FUNC(ArmIsArchTimerImplemented)
	mov x0, #1
	ret


	ASM_FUNC(ArmReadIdPfr0)
	mrs x0, id_aa64pfr0_el1 // Read ID_AA64PFR0 Register
	ret


	// Q: id_aa64pfr1_el1 not defined yet. What does this funtion want to access?
	// A: used to setup arch timer. Check if we have security extensions, permissions to set stuff.
	// See: ArmPkg/Library/ArmArchTimerLib/AArch64/ArmArchTimerLib.c
	// Not defined yet, but stick in here for now, should read all zeros.
	ASM_FUNC(ArmReadIdPfr1)
	mrs x0, id_aa64pfr1_el1 // Read ID_PFR1 Register
	ret

	// VOID ArmWriteHcr(UINTN Hcr)
	ASM_FUNC(ArmWriteHcr)
	msr hcr_el2, x0 // Write the passed HCR value
	ret

	// UINTN ArmReadHcr(VOID)
	ASM_FUNC(ArmReadHcr)
	mrs x0, hcr_el2
	ret

	// UINTN ArmReadCurrentEL(VOID)
	ASM_FUNC(ArmReadCurrentEL)
	mrs x0, CurrentEL
	ret

	// UINT32 ArmReadCntHctl(VOID)
	ASM_FUNC(ArmReadCntHctl)
	mrs x0, cnthctl_el2
	ret

	// VOID ArmWriteCntHctl(UINT32 CntHctl)
	ASM_FUNC(ArmWriteCntHctl)
	msr cnthctl_el2, x0
	ret

	ASM_FUNCTION_REMOVE_IF_UNREFERENCED