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system76-edk2/ArmVirtPkg/PrePi/AArch64/ModuleEntryPoint.S
Ard Biesheuvel b16fd231f6 ArmVirtPkg/PrePi: use standard PeCoff routines for self-relocation 
Instead of having a GCC specific routine to perform self-relocation
based on ELF metadata, use the PE/COFF metadata and the existing
PeCoff library routines. This reduces the amount of bespoke assembler
code that is a burden to maintain, and is not portable across the set
of toolchains we support.

This does require some special care, as we have no control over how
the C code references global symbols, so we need to emit these
references from the calling assembler code. Otherwise, they may be
emitted as absolute references, in which case they need to be fixed
up themselves, leading to a circular dependency.

Signed-off-by: Ard Biesheuvel <ard.biesheuvel@arm.com>
Acked-by: Jiewen Yao <Jiewen.yao@intel.com>
Acked-by: Laszlo Ersek <lersek@redhat.com>
Acked-by: Sami Mujawar <Sami.Mujawar@arm.com>
2020-06-12 22:17:46 +00:00

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//
// Copyright (c) 2011-2013, ARM Limited. All rights reserved.
// Copyright (c) 2015-2016, Linaro Limited. All rights reserved.
//
// SPDX-License-Identifier: BSD-2-Clause-Patent
//
//
#include <AsmMacroIoLibV8.h>
ASM_FUNC(_ModuleEntryPoint)
bl ASM_PFX(DiscoverDramFromDt)
// Get ID of this CPU in Multicore system
bl ASM_PFX(ArmReadMpidr)
// Keep a copy of the MpId register value
mov x20, x0
// Check if we can install the stack at the top of the System Memory or if we need
// to install the stacks at the bottom of the Firmware Device (case the FD is located
// at the top of the DRAM)
_SetupStackPosition:
// Compute Top of System Memory
ldr x1, PcdGet64 (PcdSystemMemoryBase)
ldr x2, PcdGet64 (PcdSystemMemorySize)
sub x2, x2, #1
add x1, x1, x2 // x1 = SystemMemoryTop = PcdSystemMemoryBase + PcdSystemMemorySize
// Calculate Top of the Firmware Device
ldr x2, PcdGet64 (PcdFdBaseAddress)
MOV32 (w3, FixedPcdGet32 (PcdFdSize) - 1)
add x3, x3, x2 // x3 = FdTop = PcdFdBaseAddress + PcdFdSize
// UEFI Memory Size (stacks are allocated in this region)
MOV32 (x4, FixedPcdGet32(PcdSystemMemoryUefiRegionSize))
//
// Reserve the memory for the UEFI region (contain stacks on its top)
//
// Calculate how much space there is between the top of the Firmware and the Top of the System Memory
subs x0, x1, x3 // x0 = SystemMemoryTop - FdTop
b.mi _SetupStack // Jump if negative (FdTop > SystemMemoryTop). Case when the PrePi is in XIP memory outside of the DRAM
cmp x0, x4
b.ge _SetupStack
// Case the top of stacks is the FdBaseAddress
mov x1, x2
_SetupStack:
// x1 contains the top of the stack (and the UEFI Memory)
// Because the 'push' instruction is equivalent to 'stmdb' (decrement before), we need to increment
// one to the top of the stack. We check if incrementing one does not overflow (case of DRAM at the
// top of the memory space)
adds x21, x1, #1
b.cs _SetupOverflowStack
_SetupAlignedStack:
mov x1, x21
b _GetBaseUefiMemory
_SetupOverflowStack:
// Case memory at the top of the address space. Ensure the top of the stack is EFI_PAGE_SIZE
// aligned (4KB)
and x1, x1, ~EFI_PAGE_MASK
_GetBaseUefiMemory:
// Calculate the Base of the UEFI Memory
sub x21, x1, x4
_GetStackBase:
// r1 = The top of the Mpcore Stacks
mov sp, x1
// Stack for the primary core = PrimaryCoreStack
MOV32 (x2, FixedPcdGet32(PcdCPUCorePrimaryStackSize))
sub x22, x1, x2
mov x0, x20
mov x1, x21
mov x2, x22
// Set the frame pointer to NULL so any backtraces terminate here
mov x29, xzr
// Jump to PrePiCore C code
// x0 = MpId
// x1 = UefiMemoryBase
// x2 = StacksBase
bl ASM_PFX(CEntryPoint)
_NeverReturn:
b _NeverReturn
// VOID
// DiscoverDramFromDt (
// VOID *DeviceTreeBaseAddress, // passed by loader in x0
// VOID *ImageBase // passed by FDF trampoline in x1
// );
ASM_PFX(DiscoverDramFromDt):
//
// If we are booting from RAM using the Linux kernel boot protocol, x0 will
// point to the DTB image in memory. Otherwise, use the default value defined
// by the platform.
//
cbnz x0, 0f
ldr x0, PcdGet64 (PcdDeviceTreeInitialBaseAddress)
0:mov x29, x30 // preserve LR
mov x28, x0 // preserve DTB pointer
mov x27, x1 // preserve base of image pointer
//
// The base of the runtime image has been preserved in x1. Check whether
// the expected magic number can be found in the header.
//
ldr w8, .LArm64LinuxMagic
ldr w9, [x1, #0x38]
cmp w8, w9
bne .Lout
//
//
// OK, so far so good. We have confirmed that we likely have a DTB and are
// booting via the arm64 Linux boot protocol. Update the base-of-image PCD
// to the actual relocated value, and add the shift of PcdFdBaseAddress to
// PcdFvBaseAddress as well
//
adr x8, PcdGet64 (PcdFdBaseAddress)
adr x9, PcdGet64 (PcdFvBaseAddress)
ldr x6, [x8]
ldr x7, [x9]
sub x7, x7, x6
add x7, x7, x1
str x1, [x8]
str x7, [x9]
//
// The runtime address may be different from the link time address so fix
// up the PE/COFF relocations. Since we are calling a C function, use the
// window at the beginning of the FD image as a temp stack.
//
mov x0, x7
adr x1, PeCoffLoaderImageReadFromMemory
mov sp, x7
bl RelocatePeCoffImage
//
// Discover the memory size and offset from the DTB, and record in the
// respective PCDs. This will also return false if a corrupt DTB is
// encountered.
//
mov x0, x28
adr x1, PcdGet64 (PcdSystemMemoryBase)
adr x2, PcdGet64 (PcdSystemMemorySize)
bl FindMemnode
cbz x0, .Lout
//
// Copy the DTB to the slack space right after the 64 byte arm64/Linux style
// image header at the base of this image (defined in the FDF), and record the
// pointer in PcdDeviceTreeInitialBaseAddress.
//
adr x8, PcdGet64 (PcdDeviceTreeInitialBaseAddress)
add x27, x27, #0x40
str x27, [x8]
mov x0, x27
mov x1, x28
bl CopyFdt
.Lout:
ret x29
.LArm64LinuxMagic:
.byte 0x41, 0x52, 0x4d, 0x64
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