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/*
* x86_64 boot and support code
*
* Copyright 2019 Linaro
*
* This work is licensed under the terms of the GNU GPL, version 3 or later.
* See the COPYING file in the top-level directory.
*
* Unlike the i386 version we instead use Xen's PVHVM booting header
* which should drop us automatically into 32 bit mode ready to go. I've
* nabbed bits of the Linux kernel setup to achieve this.
*
* SPDX-License-Identifier: GPL-3.0-or-later
*/
.section .head
#define ELFNOTE_START(name, type, flags) \
.pushsection .note.name, flags,@note ; \
.balign 4 ; \
.long 2f - 1f /* namesz */ ; \
.long 4484f - 3f /* descsz */ ; \
.long type ; \
1:.asciz #name ; \
2:.balign 4 ; \
3:
#define ELFNOTE_END \
4484:.balign 4 ; \
.popsection ;
#define ELFNOTE(name, type, desc) \
ELFNOTE_START(name, type, "") \
desc ; \
ELFNOTE_END
#define XEN_ELFNOTE_ENTRY 1
#define XEN_ELFNOTE_HYPERCALL_PAGE 2
#define XEN_ELFNOTE_VIRT_BASE 3
#define XEN_ELFNOTE_PADDR_OFFSET 4
#define XEN_ELFNOTE_PHYS32_ENTRY 18
#define __ASM_FORM(x) x
#define __ASM_SEL(a,b) __ASM_FORM(b)
#define _ASM_PTR __ASM_SEL(.long, .quad)
ELFNOTE(Xen, XEN_ELFNOTE_VIRT_BASE, _ASM_PTR 0x100000)
ELFNOTE(Xen, XEN_ELFNOTE_ENTRY, _ASM_PTR _start)
ELFNOTE(Xen, XEN_ELFNOTE_PHYS32_ENTRY, _ASM_PTR _start) /* entry == virtbase */
ELFNOTE(Xen, XEN_ELFNOTE_PADDR_OFFSET, _ASM_PTR 0)
/*
* Entry point for PVH guests.
*
* Xen ABI specifies the following register state when we come here:
*
* - `ebx`: contains the physical memory address where the loader has placed
* the boot start info structure.
* - `cr0`: bit 0 (PE) must be set. All the other writable bits are cleared.
* - `cr4`: all bits are cleared.
* - `cs `: must be a 32-bit read/execute code segment with a base of ‘0
* and a limit of ‘0xFFFFFFFF’. The selector value is unspecified.
* - `ds`, `es`: must be a 32-bit read/write data segment with a base of
*0’ and a limit of ‘0xFFFFFFFF’. The selector values are all
* unspecified.
* - `tr`: must be a 32-bit TSS (active) with a base of '0' and a limit
* of '0x67'.
* - `eflags`: bit 17 (VM) must be cleared. Bit 9 (IF) must be cleared.
* Bit 8 (TF) must be cleared. Other bits are all unspecified.
*
* All other processor registers and flag bits are unspecified. The OS is in
* charge of setting up it's own stack, GDT and IDT.
*/
.code32
.section .text
.global _start
_start:
cld
lgdt gdtr
ljmp $0x8,$.Lloadcs
.Lloadcs:
mov $0x10,%eax
mov %eax,%ds
mov %eax,%es
mov %eax,%fs
mov %eax,%gs
mov %eax,%ss
/* Enable PAE mode (bit 5). */
mov %cr4, %eax
btsl $5, %eax
mov %eax, %cr4
#define MSR_EFER 0xc0000080 /* extended feature register */
/* Enable Long mode. */
mov $MSR_EFER, %ecx
rdmsr
btsl $8, %eax
wrmsr
/* Enable paging */
mov $.Lpml4, %ecx
mov %ecx, %cr3
mov %cr0, %eax
btsl $31, %eax
mov %eax, %cr0
/* Jump to 64-bit mode. */
lgdt gdtr64
ljmp $0x8,$.Lenter64
.code64
.section .text
.Lenter64:
// Setup stack ASAP
movq $stack_end,%rsp
/* don't worry about stack frame, assume everything is garbage when we return */
call main
_exit: /* output any non-zero result in eax to isa-debug-exit device */
test %al, %al
jz 1f
out %ax, $0xf4
1: /* QEMU ACPI poweroff */
mov $0x604,%edx
mov $0x2000,%eax
out %ax,%dx
hlt
jmp 1b
/*
* Helper Functions
*
* x86_64 calling convention is rdi, rsi, rdx, rcx, r8, r9
*/
/* Output a single character to serial port */
.global __sys_outc
__sys_outc:
pushq %rax
mov %rax, %rdx
out %al,$0xE9
popq %rax
ret
/* Interrupt Descriptor Table */
.section .data
.align 16
idt_00: .int 0, 0
idt_01: .int 0, 0
idt_02: .int 0, 0
idt_03: .int 0, 0
idt_04: .int 0, 0
idt_05: .int 0, 0
idt_06: .int 0, 0 /* intr_6_opcode, Invalid Opcode */
idt_07: .int 0, 0
idt_08: .int 0, 0
idt_09: .int 0, 0
idt_0A: .int 0, 0
idt_0B: .int 0, 0
idt_0C: .int 0, 0
idt_0D: .int 0, 0
idt_0E: .int 0, 0
idt_0F: .int 0, 0
idt_10: .int 0, 0
idt_11: .int 0, 0
idt_12: .int 0, 0
idt_13: .int 0, 0
idt_14: .int 0, 0
idt_15: .int 0, 0
idt_16: .int 0, 0
idt_17: .int 0, 0
idt_18: .int 0, 0
idt_19: .int 0, 0
idt_1A: .int 0, 0
idt_1B: .int 0, 0
idt_1C: .int 0, 0
idt_1D: .int 0, 0
idt_1E: .int 0, 0
idt_1F: .int 0, 0
/*
* Global Descriptor Table (GDT)
*
* This describes various memory areas (segments) through
* segment descriptors. In 32 bit mode each segment each
* segment is associated with segment registers which are
* implicitly (or explicitly) referenced depending on the
* instruction. However in 64 bit mode selectors are flat and
* segmented addressing isn't used.
*/
gdt:
.short 0
gdtr:
.short gdt_en - gdt - 1
.int gdt
// Code cs:
.short 0xFFFF
.short 0
.byte 0
.byte 0x9b
.byte 0xCF
.byte 0
// Data ds:, ss:, es:, fs:, and gs:
.short 0xFFFF
.short 0
.byte 0
.byte 0x93
.byte 0xCF
.byte 0
gdt_en:
gdt64:
.short 0
gdtr64:
.short gdt64_en - gdt64 - 1
.int gdt64
// Code
.short 0xFFFF
.short 0
.byte 0
.byte 0x9b
.byte 0xAF
.byte 0
// Data
.short 0xFFFF
.short 0
.byte 0
.byte 0x93
.byte 0xCF
.byte 0
gdt64_en:
.section .bss
.align 16
stack: .space 65536
stack_end:
.section .data
.align 4096
.Lpd:
i = 0
.rept 512 * 4
.quad 0x1e7 | (i << 21)
i = i + 1
.endr
.align 4096
.Lpdp:
.quad .Lpd + 7 + 0 * 4096 /* 0-1 GB */
.quad .Lpd + 7 + 1 * 4096 /* 1-2 GB */
.quad .Lpd + 7 + 2 * 4096 /* 2-3 GB */
.quad .Lpd + 7 + 3 * 4096 /* 3-4 GB */
.align 4096
.Lpml4:
.quad .Lpdp + 7 /* 0-512 GB */