| /* |
| * Copyright (c) 2019 Intel Corporation |
| * SPDX-License-Identifier: Apache-2.0 |
| */ |
| |
| #include <zephyr/toolchain.h> |
| #include <zephyr/arch/x86/multiboot.h> |
| #include <zephyr/arch/x86/efi.h> |
| #include <zephyr/sys/util.h> |
| #include <zephyr/arch/x86/msr.h> |
| #include <kernel_arch_data.h> |
| #include <offsets_short.h> |
| #include <zephyr/drivers/interrupt_controller/loapic.h> |
| #include <zephyr/arch/cpu.h> |
| #include <zephyr/sys/mem_manage.h> |
| |
| /* |
| * Definitions/macros for enabling paging |
| */ |
| |
| /* Long mode, no-execute, syscall */ |
| #define EFER_BITS (X86_EFER_MSR_LME | X86_EFER_MSR_NXE | X86_EFER_MSR_SCE) |
| |
| /* Paging, write-protect */ |
| #define CR0_BITS (CR0_PG | CR0_WP) |
| |
| /* PAE, SSE */ |
| #define CR4_BITS (CR4_PAE | CR4_OSFXSR) |
| |
| .macro set_efer |
| movl $X86_EFER_MSR, %ecx |
| rdmsr |
| orl $EFER_BITS, %eax |
| wrmsr |
| .endm |
| |
| .macro install_pagetables_32 |
| movl %cr4, %eax |
| orl $CR4_BITS, %eax |
| movl %eax, %cr4 |
| clts |
| |
| /* Page tables created at build time by gen_mmu.py |
| * NOTE: Presumes phys=virt |
| */ |
| movl $Z_MEM_PHYS_ADDR(z_x86_kernel_ptables), %eax |
| movl %eax, %cr3 |
| |
| set_efer |
| |
| movl %cr0, %eax |
| orl $CR0_BITS, %eax |
| movl %eax, %cr0 |
| .endm |
| |
| .macro install_pagetables_64 |
| /* Here, we are already in long mode with paging enabled and |
| * just need to switch to our own page tables, but let's be |
| * paranoid and ensure CR4, CR0, and EFER_MSR are set up |
| * exactly how we expect. Logic is the same as install_pagetables_32 |
| */ |
| movq %cr4, %rax |
| orq $CR4_BITS, %rax |
| movq %rax, %cr4 |
| clts |
| |
| /* NOTE: Presumes phys=virt */ |
| movq $Z_MEM_PHYS_ADDR(z_x86_kernel_ptables), %rax |
| movq %rax, %cr3 |
| |
| set_efer |
| |
| movq %cr0, %rax |
| /* Use 32-bit instructions due to assembler fussiness with large |
| * immediate values with `orq`, CR0_PG is bit 31. We don't ever set any |
| * high bits in cr0 anyway. |
| */ |
| orl $CR0_BITS, %eax |
| movq %rax, %cr0 |
| .endm |
| |
| /* The .locore section begins the page-aligned initialization region |
| * of low memory. The first address is used as the architectural |
| * entry point for auxiliary CPUs being brought up (in real mode!) |
| * via a startup IPI. It's is ALSO used by some loaders (well, |
| * ACRN...) who hard-coded the address by inspecting _start on a |
| * non-SMP build. |
| * |
| * === OUTRAGEOUS HACK FOLLOWS === |
| * |
| * Therefore it needs to start at OS entry with a 32 bit jump to the |
| * 32 bit entry point, and gets clobbered later (see the beginning of |
| * __start32) with NOP bytes such that the next CPU will fall through |
| * to the 16 bit SMP entry. |
| * |
| * We write out the JMP followed by 8 NOPs for simplicity. No i386 |
| * JMP encodes with more than 8 bytes, so we can come back later and |
| * scribble over it with 8 0x90 bytes (which is the 1-byte NOP) and be |
| * sure to get all of it without overwriting anything. |
| */ |
| .section .locore,"ax" |
| .code32 |
| .globl __start |
| __start: |
| jmp __start32 |
| nop |
| nop |
| nop |
| nop |
| nop |
| nop |
| nop |
| nop |
| |
| #if CONFIG_MP_MAX_NUM_CPUS > 1 |
| |
| .code16 |
| .global x86_ap_start |
| x86_ap_start: |
| |
| /* |
| * First, we move to 32-bit protected mode, and set up the |
| * same flat environment that the BSP gets from the loader. |
| */ |
| |
| lgdt gdt48 |
| lidt idt48 |
| movl %cr0, %eax |
| or $1, %eax |
| movl %eax, %cr0 |
| |
| jmpl $X86_KERNEL_CS_32, $1f |
| .code32 |
| 1: movw $X86_KERNEL_DS_32, %ax |
| movw %ax, %ds |
| movw %ax, %es |
| movw %ax, %ss |
| movw %ax, %fs |
| |
| /* |
| * Now, reverse-map our local APIC ID to our logical CPU ID |
| * so we can locate our x86_cpuboot[] bundle. Put it in EBP. |
| */ |
| |
| movl CONFIG_LOAPIC_BASE_ADDRESS+LOAPIC_ID, %eax |
| shrl $24, %eax |
| andl $0x0F, %eax /* local APIC ID -> EAX */ |
| |
| movl $x86_cpuboot, %ebp |
| xorl %ebx, %ebx |
| 1: cmpl $CONFIG_MP_MAX_NUM_CPUS, %ebx |
| jz unknown_loapic_id |
| cmpb %al, x86_cpu_loapics(%ebx) |
| je go64 /* proceed to 64-bit mode */ |
| incl %ebx |
| addl $__X86_CPUBOOT_SIZEOF, %ebp |
| jmp 1b |
| |
| unknown_loapic_id: |
| jmp unknown_loapic_id |
| |
| #endif /* CONFIG_MP_MAX_NUM_CPUS > 1 */ |
| |
| .code32 |
| .globl __start32 |
| __start32: |
| /* |
| * kernel execution begins here in 32-bit mode, with flat-mode |
| * descriptors in all segment registers, interrupts disabled. |
| */ |
| |
| /* See note above, re: OUTRAGEOUS HACK */ |
| movl $__start, %ebp |
| movb $0x90, 0(%ebp) |
| movb $0x90, 1(%ebp) |
| movb $0x90, 2(%ebp) |
| movb $0x90, 3(%ebp) |
| movb $0x90, 4(%ebp) |
| movb $0x90, 5(%ebp) |
| movb $0x90, 6(%ebp) |
| movb $0x90, 7(%ebp) |
| wbinvd |
| |
| lgdt gdt48 |
| lidt idt48 |
| |
| #include "../common.S" |
| |
| /* |
| * N.B.: if multiboot info struct is present, "common.S" |
| * has left a pointer to it in EBX. |
| */ |
| |
| movl $x86_cpu_boot_arg, %ebp |
| |
| /* Inserting boot type */ |
| movl $MULTIBOOT_BOOT_TYPE, __x86_boot_arg_t_boot_type_OFFSET(%ebp) |
| /* and multiboot info */ |
| movl %ebx, __x86_boot_arg_t_arg_OFFSET(%ebp) |
| |
| movl $x86_cpuboot, %ebp /* BSP is always logical CPU id 0 */ |
| |
| go64: /* Install page tables and transition to long mode */ |
| install_pagetables_32 |
| jmpl $X86_KERNEL_CS, $enter_code64 |
| |
| /* Long mode entry point. Arrive here from the code |
| * immediately above (shared between main CPU startup and AP |
| * startup), or from EFI entry in __start64. |
| * |
| * Here we reload the segment registers, |
| * and configure per-CPU stuff: GS, task register, stack. |
| */ |
| .code64 |
| enter_code64: |
| movl $X86_KERNEL_DS, %eax |
| movw %ax, %ds |
| movw %ax, %es |
| movw %ax, %ss |
| movw %ax, %fs |
| |
| /* On Intel processors, if GS is not zero and is being set to |
| * zero, GS_BASE is also being set to zero. This would interfere |
| * with the actual use of GS_BASE for usespace. To avoid accidentally |
| * clearing GS_BASE, simply set GS to 0 at boot, so any subsequent |
| * clearing of GS will not clear GS_BASE. |
| */ |
| mov $0, %eax |
| movw %ax, %gs |
| |
| movw __x86_cpuboot_t_tr_OFFSET(%rbp), %ax |
| ltr %ax |
| |
| /* Set up MSRs for GS / KERNEL_GS base */ |
| movq __x86_cpuboot_t_gs_base_OFFSET(%rbp), %rax |
| movq %rax, %rdx |
| shrq $32, %rdx |
| /* X86_KERNEL_GS_BASE and X86_GS_BASE are swapped by the 'swapgs' |
| * instruction. |
| */ |
| movl $X86_KERNEL_GS_BASE, %ecx |
| wrmsr |
| /* X86_GS_BASE shadows base fields of %gs, effectively setting %gs */ |
| movl $X86_GS_BASE, %ecx |
| wrmsr |
| |
| movq __x86_cpuboot_t_sp_OFFSET(%rbp), %rsp |
| movq %rsp, %gs:__x86_tss64_t_ist1_OFFSET |
| |
| /* finally, complete environment for the C runtime and go. */ |
| cld /* GCC presumes a clear direction flag */ |
| |
| #ifdef CONFIG_INIT_STACKS |
| movq $0xAAAAAAAAAAAAAAAA, %rax |
| movq %rsp, %rdi |
| subq __x86_cpuboot_t_stack_size_OFFSET(%rbp), %rdi |
| movq __x86_cpuboot_t_stack_size_OFFSET(%rbp), %rcx |
| shr $3, %rcx /* moving 8 bytes a time, so fewer repeats */ |
| rep stosq |
| #endif |
| |
| /* Enter C domain now that we have a stack set up, never to return */ |
| movq %rbp, %rdi |
| call z_x86_cpu_init |
| |
| /* 64 bit OS entry point, used by EFI support. UEFI |
| * guarantees an identity-mapped page table that covers |
| * physical memory, and the loader stub already used it to |
| * write all of the Zephyr image, so we know it works for what |
| * we need. Other things need fixups to match what multiboot |
| * 32 bit startup does. |
| */ |
| .globl __start64 |
| __start64: |
| /* Zero the TSC */ |
| xorq %rax, %rax |
| xorq %rdx, %rdx |
| movq $X86_TIME_STAMP_COUNTER_MSR, %rcx |
| wrmsr |
| |
| lidt idt80 |
| lgdt gdt80 |
| |
| install_pagetables_64 |
| |
| /* Disable 8259 PIT. Almost certainly not needed on modern |
| * UEFI platforms taking this code path, but... |
| */ |
| movb $0xff, %al |
| outb %al, $0x21 |
| outb %al, $0xA1 |
| |
| movq $x86_cpu_boot_arg, %rbp |
| /* Inserting boot type */ |
| movq $EFI_BOOT_TYPE, __x86_boot_arg_t_boot_type_OFFSET(%rbp) |
| /* and EFI boot arg (if any) */ |
| movq %rbx, __x86_boot_arg_t_arg_OFFSET(%rbp) |
| |
| movq $x86_cpuboot, %rbp /* BSP is always logical CPU id 0 */ |
| |
| mov jmpdesc, %rax |
| jmp *%rax |
| jmpdesc: |
| .quad enter_code64 |
| .short X86_KERNEL_CS |
| |
| /* |
| * void x86_sse_init(struct k_thread *thread); |
| * |
| * Initialize floating-point state to something sane. If 'thread' is |
| * not NULL, then the resulting FP state is saved to thread->arch.sse. |
| */ |
| |
| .global x86_sse_init |
| x86_sse_init: |
| fninit |
| ldmxcsr mxcsr |
| testq %rdi, %rdi |
| jz 1f |
| fxsave _thread_offset_to_sse(%rdi) |
| 1: retq |
| |
| mxcsr: .long X86_MXCSR_SANE |
| |
| /* |
| * void z_x86_switch(void *switch_to, void **switched_from); |
| * |
| * Note that switch_handle for us is simply a pointer to the containing |
| * 'struct k_thread', thus: |
| * |
| * RDI = (struct k_thread *) switch_to |
| * RSI = (struct k_thread **) address of output thread switch_handle field |
| */ |
| |
| .globl z_x86_switch |
| z_x86_switch: |
| /* RSI contains the switch_handle field to which we are |
| * notionally supposed to store. Offset it to get back to the |
| * thread handle instead. |
| */ |
| subq $___thread_t_switch_handle_OFFSET, %rsi |
| |
| andb $~X86_THREAD_FLAG_ALL, _thread_offset_to_flags(%rsi) |
| |
| popq %rax |
| movq %rax, _thread_offset_to_rip(%rsi) |
| pushfq |
| popq %rax |
| movq %rax, _thread_offset_to_rflags(%rsi) |
| movq %rsp, _thread_offset_to_rsp(%rsi) |
| movq %rbx, _thread_offset_to_rbx(%rsi) |
| movq %rbp, _thread_offset_to_rbp(%rsi) |
| movq %r12, _thread_offset_to_r12(%rsi) |
| movq %r13, _thread_offset_to_r13(%rsi) |
| movq %r14, _thread_offset_to_r14(%rsi) |
| movq %r15, _thread_offset_to_r15(%rsi) |
| #ifdef CONFIG_USERSPACE |
| /* We're always in supervisor mode if we get here, the other case |
| * is when __resume is invoked from irq_dispatch |
| */ |
| movq $X86_KERNEL_CS, _thread_offset_to_cs(%rsi) |
| movq $X86_KERNEL_DS, _thread_offset_to_ss(%rsi) |
| #endif |
| /* Store the handle (i.e. our thread struct address) into the |
| * switch handle field, this is a synchronization signal that |
| * must occur after the last data from the old context is |
| * saved. |
| */ |
| movq %rsi, ___thread_t_switch_handle_OFFSET(%rsi) |
| |
| movq %gs:__x86_tss64_t_ist1_OFFSET, %rsp |
| |
| /* fall through to __resume */ |
| |
| /* |
| * Entry: |
| * RSP = top of CPU interrupt stack |
| * RDI = (struct k_thread *) thread to resume |
| */ |
| |
| __resume: |
| #ifdef CONFIG_THREAD_LOCAL_STORAGE |
| /* |
| * Write the TLS base pointer to FS_BASE MSR, |
| * where GCC emits code to access TLS data via |
| * offset to FS. |
| * Since wrmsr write EDX:EAX to MSR indicated by |
| * ECX, the high 32-bit needs to be loaded into |
| * RDX and right shifted by 32 bits so EDX has |
| * the higher 32-bit value. |
| */ |
| movl $X86_FS_BASE, %ecx |
| movq _thread_offset_to_tls(%rdi), %rax |
| movq _thread_offset_to_tls(%rdi), %rdx |
| shrq $32, %rdx |
| wrmsr |
| #endif |
| #if (!defined(CONFIG_X86_KPTI) && defined(CONFIG_USERSPACE)) \ |
| || defined(CONFIG_INSTRUMENT_THREAD_SWITCHING) |
| pushq %rdi /* Caller-saved, stash it */ |
| #if !defined(CONFIG_X86_KPTI) && defined(CONFIG_USERSPACE) |
| /* If KPTI is enabled we're always on the kernel's page tables in |
| * this context and the appropriate page table switch takes place |
| * when trampolining back to user mode |
| */ |
| call z_x86_swap_update_page_tables |
| #endif |
| #ifdef CONFIG_INSTRUMENT_THREAD_SWITCHING |
| call z_thread_mark_switched_in |
| #endif |
| popq %rdi |
| #endif /* (!CONFIG_X86_KPTI && CONFIG_USERSPACE) || \ |
| CONFIG_INSTRUMENT_THREAD_SWITCHING */ |
| |
| #ifdef CONFIG_USERSPACE |
| /* Set up exception return stack frame */ |
| pushq _thread_offset_to_ss(%rdi) /* SS */ |
| #else |
| pushq $X86_KERNEL_DS /* SS */ |
| #endif /* CONFIG_USERSPACE */ |
| pushq _thread_offset_to_rsp(%rdi) /* RSP */ |
| pushq _thread_offset_to_rflags(%rdi) /* RFLAGS */ |
| #ifdef CONFIG_USERSPACE |
| pushq _thread_offset_to_cs(%rdi) /* CS */ |
| #else |
| pushq $X86_KERNEL_CS /* CS */ |
| #endif |
| pushq _thread_offset_to_rip(%rdi) /* RIP */ |
| |
| #ifdef CONFIG_ASSERT |
| /* Poison the old thread's saved RIP pointer with a |
| * recognizable value near NULL, to easily catch reuse of the |
| * thread object across CPUs in SMP. Strictly speaking this |
| * is not an assertion, but it's very cheap and worth having |
| * on during routine testing. |
| */ |
| movq $0xB9, _thread_offset_to_rip(%rdi) |
| #endif |
| |
| |
| movq _thread_offset_to_rbx(%rdi), %rbx |
| movq _thread_offset_to_rbp(%rdi), %rbp |
| movq _thread_offset_to_r12(%rdi), %r12 |
| movq _thread_offset_to_r13(%rdi), %r13 |
| movq _thread_offset_to_r14(%rdi), %r14 |
| movq _thread_offset_to_r15(%rdi), %r15 |
| #ifdef CONFIG_USERSPACE |
| /* Set correct privilege elevation stack to manually switch to in |
| * z_x86_syscall_entry_stub() |
| */ |
| movq _thread_offset_to_psp(%rdi), %rax |
| movq %rax, %gs:__x86_tss64_t_psp_OFFSET |
| #endif |
| |
| testb $X86_THREAD_FLAG_ALL, _thread_offset_to_flags(%rdi) |
| jz 1f |
| |
| fxrstor _thread_offset_to_sse(%rdi) |
| movq _thread_offset_to_rax(%rdi), %rax |
| movq _thread_offset_to_rcx(%rdi), %rcx |
| movq _thread_offset_to_rdx(%rdi), %rdx |
| movq _thread_offset_to_rsi(%rdi), %rsi |
| movq _thread_offset_to_r8(%rdi), %r8 |
| movq _thread_offset_to_r9(%rdi), %r9 |
| movq _thread_offset_to_r10(%rdi), %r10 |
| movq _thread_offset_to_r11(%rdi), %r11 |
| movq _thread_offset_to_rdi(%rdi), %rdi /* do last :-) */ |
| |
| #ifdef CONFIG_USERSPACE |
| /* Swap GS register values if we are returning to user mode */ |
| testb $0x3, 8(%rsp) |
| jz 1f |
| #ifdef CONFIG_X86_KPTI |
| jmp z_x86_trampoline_to_user |
| #else |
| swapgs |
| #endif /* CONFIG_X86_KPTI */ |
| #endif /* CONFIG_USERSPACE */ |
| 1: |
| #ifdef CONFIG_X86_BOUNDS_CHECK_BYPASS_MITIGATION |
| /* swapgs variant of Spectre V1. Disable speculation past this point */ |
| lfence |
| #endif /* CONFIG_X86_BOUNDS_CHECK_BYPASS_MITIGATION */ |
| iretq |
| |
| |
| #ifdef CONFIG_X86_KPTI |
| #define EXCEPT_CODE(nr, ist) \ |
| vector_ ## nr: pushq %gs:__x86_tss64_t_ist ## ist ## _OFFSET; \ |
| pushq $nr; \ |
| jmp except |
| #define EXCEPT(nr, ist) \ |
| vector_ ## nr: pushq $0; \ |
| pushq %gs:__x86_tss64_t_ist ## ist ## _OFFSET; \ |
| pushq $nr; \ |
| jmp except |
| #else |
| #define EXCEPT_CODE(nr) vector_ ## nr: pushq $nr; jmp except |
| #define EXCEPT(nr) vector_ ## nr: pushq $0; pushq $nr; jmp except |
| #endif |
| |
| /* |
| * When we arrive at 'except' from one of the EXCEPT(X) stubs, |
| * we're on the exception stack with irqs unlocked (or the trampoline stack |
| * with irqs locked if KPTI is enabled) and it contains: |
| * |
| * SS |
| * RSP |
| * RFLAGS |
| * CS |
| * RIP |
| * Error Code if pushed by CPU, else 0 |
| * IST index in TSS |
| * Vector number <- RSP points here |
| * |
| */ |
| |
| except: /* |
| * finish struct NANO_ESF on stack. 'vector' .. 'ss' are |
| * already there from hardware trap and EXCEPT_*() stub. |
| */ |
| |
| pushq %r11 |
| |
| #ifdef CONFIG_USERSPACE |
| /* Swap GS register values and page tables if we came from user mode */ |
| testb $0x3, 40(%rsp) |
| jz 1f |
| swapgs |
| #ifdef CONFIG_X86_KPTI |
| /* Load kernel's page table. NOTE: Presumes phys=virt */ |
| movq $z_x86_kernel_ptables, %r11 |
| movq %r11, %cr3 |
| #endif /* CONFIG_X86_KPTI */ |
| 1: |
| #ifdef CONFIG_X86_BOUNDS_CHECK_BYPASS_MITIGATION |
| /* swapgs variant of Spectre V1. Disable speculation past this point */ |
| lfence |
| #endif /* CONFIG_X86_BOUNDS_CHECK_BYPASS_MITIGATION */ |
| #ifdef CONFIG_X86_KPTI |
| /* Save old trampoline stack pointer in R11 */ |
| movq %rsp, %r11 |
| |
| /* Switch to the correct stack */ |
| movq 16(%r11), %rsp |
| |
| /* Transplant trampoline stack contents */ |
| pushq 64(%r11) /* SS */ |
| pushq 56(%r11) /* RSP */ |
| pushq 48(%r11) /* RFLAGS */ |
| pushq 40(%r11) /* CS */ |
| pushq 32(%r11) /* RIP */ |
| pushq 24(%r11) /* Error code */ |
| pushq 8(%r11) /* Vector */ |
| pushq (%r11) /* Stashed R11 */ |
| movq $0, (%r11) /* Cover our tracks */ |
| |
| /* We're done, it's safe to re-enable interrupts. */ |
| sti |
| #endif /* CONFIG_X86_KPTI */ |
| #endif /* CONFIG_USERSPACE */ |
| |
| /* In addition to r11, push the rest of the caller-saved regs */ |
| /* Positioning of this fxsave is important, RSP must be 16-byte |
| * aligned |
| */ |
| subq $X86_FXSAVE_SIZE, %rsp |
| fxsave (%rsp) |
| pushq %r10 |
| pushq %r9 |
| pushq %r8 |
| pushq %rdi |
| pushq %rsi |
| pushq %rdx |
| pushq %rcx |
| pushq %rax |
| pushq %rbp |
| #ifdef CONFIG_EXCEPTION_DEBUG |
| /* Callee saved regs */ |
| pushq %r15 |
| pushq %r14 |
| pushq %r13 |
| pushq %r12 |
| pushq %rbx |
| #endif /* CONFIG_EXCEPTION_DEBUG */ |
| movq %rsp, %rdi |
| |
| call z_x86_exception |
| |
| /* If we returned, the exception was handled successfully and the |
| * thread may resume (the pushed RIP may have been modified) |
| */ |
| #ifdef CONFIG_EXCEPTION_DEBUG |
| popq %rbx |
| popq %r12 |
| popq %r13 |
| popq %r14 |
| popq %r15 |
| #endif /* CONFIG_EXCEPTION_DEBUG */ |
| popq %rbp |
| popq %rax |
| popq %rcx |
| popq %rdx |
| popq %rsi |
| popq %rdi |
| popq %r8 |
| popq %r9 |
| popq %r10 |
| fxrstor (%rsp) |
| addq $X86_FXSAVE_SIZE, %rsp |
| popq %r11 |
| |
| /* Drop the vector/err code pushed by the HW or EXCEPT_*() stub */ |
| add $16, %rsp |
| |
| #ifdef CONFIG_USERSPACE |
| /* Swap GS register values if we are returning to user mode */ |
| testb $0x3, 8(%rsp) |
| jz 1f |
| cli |
| #ifdef CONFIG_X86_KPTI |
| jmp z_x86_trampoline_to_user |
| #else |
| swapgs |
| #endif /* CONFIG_X86_KPTI */ |
| 1: |
| #endif /* CONFIG_USERSPACE */ |
| |
| iretq |
| |
| #ifdef CONFIG_X86_KPTI |
| EXCEPT ( 0, 7); EXCEPT ( 1, 7); EXCEPT (2, 6); EXCEPT ( 3, 7) |
| EXCEPT ( 4, 7); EXCEPT ( 5, 7); EXCEPT (6, 7); EXCEPT ( 7, 7) |
| EXCEPT_CODE ( 8, 7); EXCEPT ( 9, 7); EXCEPT_CODE (10, 7); EXCEPT_CODE (11, 7) |
| EXCEPT_CODE (12, 7); EXCEPT_CODE (13, 7); EXCEPT_CODE (14, 7); EXCEPT (15, 7) |
| EXCEPT (16, 7); EXCEPT_CODE (17, 7); EXCEPT (18, 7); EXCEPT (19, 7) |
| EXCEPT (20, 7); EXCEPT (21, 7); EXCEPT (22, 7); EXCEPT (23, 7) |
| EXCEPT (24, 7); EXCEPT (25, 7); EXCEPT (26, 7); EXCEPT (27, 7) |
| EXCEPT (28, 7); EXCEPT (29, 7); EXCEPT (30, 7); EXCEPT (31, 7) |
| |
| /* Vector reserved for handling a kernel oops; treat as an exception |
| * and not an interrupt |
| */ |
| EXCEPT(Z_X86_OOPS_VECTOR, 7); |
| #else |
| EXCEPT ( 0); EXCEPT ( 1); EXCEPT ( 2); EXCEPT ( 3) |
| EXCEPT ( 4); EXCEPT ( 5); EXCEPT ( 6); EXCEPT ( 7) |
| EXCEPT_CODE ( 8); EXCEPT ( 9); EXCEPT_CODE (10); EXCEPT_CODE (11) |
| EXCEPT_CODE (12); EXCEPT_CODE (13); EXCEPT_CODE (14); EXCEPT (15) |
| EXCEPT (16); EXCEPT_CODE (17); EXCEPT (18); EXCEPT (19) |
| EXCEPT (20); EXCEPT (21); EXCEPT (22); EXCEPT (23) |
| EXCEPT (24); EXCEPT (25); EXCEPT (26); EXCEPT (27) |
| EXCEPT (28); EXCEPT (29); EXCEPT (30); EXCEPT (31) |
| |
| /* Vector reserved for handling a kernel oops; treat as an exception |
| * and not an interrupt |
| */ |
| EXCEPT(Z_X86_OOPS_VECTOR); |
| #endif /* CONFIG_X86_KPTI */ |
| |
| /* |
| * When we arrive at 'irq' from one of the IRQ(X) stubs, |
| * we're on the "freshest" IRQ stack (or the trampoline stack if we came from |
| * user mode and KPTI is enabled) and it contains: |
| * |
| * SS |
| * RSP |
| * RFLAGS |
| * CS |
| * RIP |
| * (vector number - IV_IRQS) <-- RSP points here |
| */ |
| |
| .globl x86_irq_funcs /* see irq_manage.c .. */ |
| .globl x86_irq_args /* .. for these definitions */ |
| |
| irq: |
| pushq %rsi |
| |
| #ifdef CONFIG_USERSPACE |
| /* Swap GS register values if we came in from user mode */ |
| testb $0x3, 24(%rsp) |
| jz 1f |
| swapgs |
| #ifdef CONFIG_X86_KPTI |
| /* Load kernel's page table. NOTE: presumes phys=virt */ |
| movq $z_x86_kernel_ptables, %rsi |
| movq %rsi, %cr3 |
| #endif /* CONFIG_X86_KPTI */ |
| 1: |
| #ifdef CONFIG_X86_BOUNDS_CHECK_BYPASS_MITIGATION |
| /* swapgs variant of Spectre V1. Disable speculation past this point */ |
| lfence |
| #endif /* CONFIG_X86_BOUNDS_CHECK_BYPASS_MITIGATION */ |
| #ifdef CONFIG_X86_KPTI |
| /* Save old trampoline stack pointer in RSI */ |
| movq %rsp, %rsi |
| |
| /* Switch to the interrupt stack stack */ |
| movq %gs:__x86_tss64_t_ist1_OFFSET, %rsp |
| |
| /* Transplant trampoline stack contents */ |
| pushq 48(%rsi) /* SS */ |
| pushq 40(%rsi) /* RSP */ |
| pushq 32(%rsi) /* RFLAGS */ |
| pushq 24(%rsi) /* CS */ |
| pushq 16(%rsi) /* RIP */ |
| pushq 8(%rsi) /* Vector */ |
| pushq (%rsi) /* Stashed RSI value */ |
| movq $0, (%rsi) /* Cover our tracks, stashed RSI might be sensitive */ |
| #endif /* CONFIG_X86_KPTI */ |
| #endif /* CONFIG_USERSPACE */ |
| |
| movq %gs:__x86_tss64_t_cpu_OFFSET, %rsi |
| |
| /* |
| * Bump the IRQ nesting count and move to the next IRQ stack. |
| * That's sufficient to safely re-enable interrupts, so if we |
| * haven't reached the maximum nesting depth yet, do it. |
| */ |
| |
| incl ___cpu_t_nested_OFFSET(%rsi) |
| subq $CONFIG_ISR_SUBSTACK_SIZE, %gs:__x86_tss64_t_ist1_OFFSET |
| cmpl $CONFIG_ISR_DEPTH, ___cpu_t_nested_OFFSET(%rsi) |
| jz 1f |
| sti |
| 1: cmpl $1, ___cpu_t_nested_OFFSET(%rsi) |
| je irq_enter_unnested |
| |
| /* |
| * if we're a nested interrupt, we have to dump the state to the |
| * stack. we play some games here to re-arrange the stack thusly: |
| * |
| * SS RSP RFLAGS CS RIP RAX RSI |
| * RCX RDX RDI R8 R9 R10 R11 |
| * X86_FXSAVE_SIZE bytes of SSE data <-- RSP points here |
| * |
| * note that the final value of RSP must be 16-byte aligned here, |
| * both to satisfy FXSAVE/FXRSTOR but also to honor the C ABI. |
| */ |
| |
| irq_enter_nested: /* Nested IRQ: dump register state to stack. */ |
| pushq %rcx |
| movq 16(%rsp), %rcx /* RCX = vector */ |
| movq %rax, 16(%rsp) /* looks like we pushed RAX, not the vector */ |
| pushq %rdx |
| pushq %rdi |
| pushq %r8 |
| pushq %r9 |
| pushq %r10 |
| pushq %r11 |
| subq $X86_FXSAVE_SIZE, %rsp |
| fxsave (%rsp) |
| jmp irq_dispatch |
| |
| irq_enter_unnested: /* Not nested: dump state to thread struct for __resume */ |
| movq ___cpu_t_current_OFFSET(%rsi), %rsi |
| orb $X86_THREAD_FLAG_ALL, _thread_offset_to_flags(%rsi) |
| fxsave _thread_offset_to_sse(%rsi) |
| movq %rbx, _thread_offset_to_rbx(%rsi) |
| movq %rbp, _thread_offset_to_rbp(%rsi) |
| movq %r12, _thread_offset_to_r12(%rsi) |
| movq %r13, _thread_offset_to_r13(%rsi) |
| movq %r14, _thread_offset_to_r14(%rsi) |
| movq %r15, _thread_offset_to_r15(%rsi) |
| movq %rax, _thread_offset_to_rax(%rsi) |
| movq %rcx, _thread_offset_to_rcx(%rsi) |
| movq %rdx, _thread_offset_to_rdx(%rsi) |
| movq %rdi, _thread_offset_to_rdi(%rsi) |
| movq %r8, _thread_offset_to_r8(%rsi) |
| movq %r9, _thread_offset_to_r9(%rsi) |
| movq %r10, _thread_offset_to_r10(%rsi) |
| movq %r11, _thread_offset_to_r11(%rsi) |
| popq %rax /* RSI */ |
| movq %rax, _thread_offset_to_rsi(%rsi) |
| popq %rcx /* vector number */ |
| popq %rax /* RIP */ |
| movq %rax, _thread_offset_to_rip(%rsi) |
| popq %rax /* CS */ |
| #ifdef CONFIG_USERSPACE |
| movq %rax, _thread_offset_to_cs(%rsi) |
| #endif |
| popq %rax /* RFLAGS */ |
| movq %rax, _thread_offset_to_rflags(%rsi) |
| popq %rax /* RSP */ |
| movq %rax, _thread_offset_to_rsp(%rsi) |
| popq %rax /* SS */ |
| #ifdef CONFIG_USERSPACE |
| movq %rax, _thread_offset_to_ss(%rsi) |
| #endif |
| |
| irq_dispatch: |
| #ifdef CONFIG_SCHED_THREAD_USAGE |
| pushq %rcx |
| call z_sched_usage_stop |
| popq %rcx |
| #endif |
| movq x86_irq_funcs(,%rcx,8), %rax |
| movq x86_irq_args(,%rcx,8), %rdi |
| call *%rax |
| |
| xorq %rax, %rax |
| #ifdef CONFIG_X2APIC |
| xorl %edx, %edx |
| movl $(X86_X2APIC_BASE_MSR + (LOAPIC_EOI >> 4)), %ecx |
| wrmsr |
| #else /* xAPIC */ |
| movq z_loapic_regs, %rdx |
| movl %eax, LOAPIC_EOI(%rdx) |
| #endif /* CONFIG_X2APIC */ |
| |
| movq %gs:__x86_tss64_t_cpu_OFFSET, %rsi |
| |
| cli |
| addq $CONFIG_ISR_SUBSTACK_SIZE, %gs:__x86_tss64_t_ist1_OFFSET |
| decl ___cpu_t_nested_OFFSET(%rsi) |
| jnz irq_exit_nested |
| |
| /* not nested; ask the scheduler who's up next and resume it */ |
| |
| movq ___cpu_t_current_OFFSET(%rsi), %rdi |
| call z_get_next_switch_handle |
| movq %rax, %rdi |
| jmp __resume |
| |
| irq_exit_nested: |
| fxrstor (%rsp) |
| addq $X86_FXSAVE_SIZE, %rsp |
| popq %r11 |
| popq %r10 |
| popq %r9 |
| popq %r8 |
| popq %rdi |
| popq %rdx |
| popq %rcx |
| popq %rsi |
| popq %rax |
| iretq |
| |
| #define IRQ(nr) vector_ ## nr: pushq $(nr - IV_IRQS); jmp irq |
| |
| IRQ( 33); IRQ( 34); IRQ( 35); IRQ( 36); IRQ( 37); IRQ( 38); IRQ( 39) |
| IRQ( 40); IRQ( 41); IRQ( 42); IRQ( 43); IRQ( 44); IRQ( 45); IRQ( 46); IRQ( 47) |
| IRQ( 48); IRQ( 49); IRQ( 50); IRQ( 51); IRQ( 52); IRQ( 53); IRQ( 54); IRQ( 55) |
| IRQ( 56); IRQ( 57); IRQ( 58); IRQ( 59); IRQ( 60); IRQ( 61); IRQ( 62); IRQ( 63) |
| IRQ( 64); IRQ( 65); IRQ( 66); IRQ( 67); IRQ( 68); IRQ( 69); IRQ( 70); IRQ( 71) |
| IRQ( 72); IRQ( 73); IRQ( 74); IRQ( 75); IRQ( 76); IRQ( 77); IRQ( 78); IRQ( 79) |
| IRQ( 80); IRQ( 81); IRQ( 82); IRQ( 83); IRQ( 84); IRQ( 85); IRQ( 86); IRQ( 87) |
| IRQ( 88); IRQ( 89); IRQ( 90); IRQ( 91); IRQ( 92); IRQ( 93); IRQ( 94); IRQ( 95) |
| IRQ( 96); IRQ( 97); IRQ( 98); IRQ( 99); IRQ(100); IRQ(101); IRQ(102); IRQ(103) |
| IRQ(104); IRQ(105); IRQ(106); IRQ(107); IRQ(108); IRQ(109); IRQ(110); IRQ(111) |
| IRQ(112); IRQ(113); IRQ(114); IRQ(115); IRQ(116); IRQ(117); IRQ(118); IRQ(119) |
| IRQ(120); IRQ(121); IRQ(122); IRQ(123); IRQ(124); IRQ(125); IRQ(126); IRQ(127) |
| IRQ(128); IRQ(129); IRQ(130); IRQ(131); IRQ(132); IRQ(133); IRQ(134); IRQ(135) |
| IRQ(136); IRQ(137); IRQ(138); IRQ(139); IRQ(140); IRQ(141); IRQ(142); IRQ(143) |
| IRQ(144); IRQ(145); IRQ(146); IRQ(147); IRQ(148); IRQ(149); IRQ(150); IRQ(151) |
| IRQ(152); IRQ(153); IRQ(154); IRQ(155); IRQ(156); IRQ(157); IRQ(158); IRQ(159) |
| IRQ(160); IRQ(161); IRQ(162); IRQ(163); IRQ(164); IRQ(165); IRQ(166); IRQ(167) |
| IRQ(168); IRQ(169); IRQ(170); IRQ(171); IRQ(172); IRQ(173); IRQ(174); IRQ(175) |
| IRQ(176); IRQ(177); IRQ(178); IRQ(179); IRQ(180); IRQ(181); IRQ(182); IRQ(183) |
| IRQ(184); IRQ(185); IRQ(186); IRQ(187); IRQ(188); IRQ(189); IRQ(190); IRQ(191) |
| IRQ(192); IRQ(193); IRQ(194); IRQ(195); IRQ(196); IRQ(197); IRQ(198); IRQ(199) |
| IRQ(200); IRQ(201); IRQ(202); IRQ(203); IRQ(204); IRQ(205); IRQ(206); IRQ(207) |
| IRQ(208); IRQ(209); IRQ(210); IRQ(211); IRQ(212); IRQ(213); IRQ(214); IRQ(215) |
| IRQ(216); IRQ(217); IRQ(218); IRQ(219); IRQ(220); IRQ(221); IRQ(222); IRQ(223) |
| IRQ(224); IRQ(225); IRQ(226); IRQ(227); IRQ(228); IRQ(229); IRQ(230); IRQ(231) |
| IRQ(232); IRQ(233); IRQ(234); IRQ(235); IRQ(236); IRQ(237); IRQ(238); IRQ(239) |
| IRQ(240); IRQ(241); IRQ(242); IRQ(243); IRQ(244); IRQ(245); IRQ(246); IRQ(247) |
| IRQ(248); IRQ(249); IRQ(250); IRQ(251); IRQ(252); IRQ(253); IRQ(254); IRQ(255) |
| |
| .section .lorodata,"a" |
| |
| /* |
| * IDT. |
| */ |
| |
| /* Descriptor type. Traps don't implicitly disable interrupts. User variants |
| * can be invoked by software running in user mode (ring 3). |
| * |
| * For KPTI everything lands on the trampoline stack and we must get off of |
| * it before re-enabling interrupts; use interrupt gates for everything. |
| */ |
| #define INTR 0x8e |
| #define USER_INTR 0xee |
| #ifdef CONFIG_X86_KPTI |
| #define TRAP INTR |
| #define USER_TRAP UINTR |
| #else |
| #define TRAP 0x8f |
| #define USER_TRAP 0xef |
| #endif |
| |
| #define IDT(nr, type, ist) \ |
| .word vector_ ## nr, X86_KERNEL_CS; \ |
| .byte ist, type; \ |
| .word 0, 0, 0, 0, 0 |
| |
| /* Which IST entry in TSS to use for automatic stack switching, or 0 if |
| * no automatic switch is to take place. Stack page must be present in |
| * the current page tables, if KPTI is on only the trampoline stack and |
| * the current user stack can be accessed. |
| */ |
| #ifdef CONFIG_X86_KPTI |
| /* Everything lands on ist2, which is set to the trampoline stack. |
| * Interrupt/exception entry updates page tables and manually switches to |
| * the irq/exception stacks stored in ist1/ist7 |
| */ |
| #define IRQ_STACK 2 |
| #define EXC_STACK 2 |
| #define BAD_STACK 2 |
| #define NMI_STACK 2 |
| #else |
| #define IRQ_STACK 1 |
| #define NMI_STACK 6 /* NMI stack */ |
| #define EXC_STACK 7 |
| #define BAD_STACK 7 /* Horrible things: double faults, MCEs */ |
| #endif |
| |
| .align 16 |
| idt: |
| IDT( 0, TRAP, EXC_STACK); IDT( 1, TRAP, EXC_STACK) |
| IDT( 2, TRAP, NMI_STACK); IDT( 3, TRAP, EXC_STACK) |
| IDT( 4, TRAP, EXC_STACK); IDT( 5, TRAP, EXC_STACK) |
| IDT( 6, TRAP, EXC_STACK); IDT( 7, TRAP, EXC_STACK) |
| IDT( 8, TRAP, BAD_STACK); IDT( 9, TRAP, EXC_STACK) |
| IDT( 10, TRAP, EXC_STACK); IDT( 11, TRAP, EXC_STACK) |
| IDT( 12, TRAP, EXC_STACK); IDT( 13, TRAP, EXC_STACK) |
| IDT( 14, TRAP, EXC_STACK); IDT( 15, TRAP, EXC_STACK) |
| IDT( 16, TRAP, EXC_STACK); IDT( 17, TRAP, EXC_STACK) |
| IDT( 18, TRAP, BAD_STACK); IDT( 19, TRAP, EXC_STACK) |
| IDT( 20, TRAP, EXC_STACK); IDT( 21, TRAP, EXC_STACK) |
| IDT( 22, TRAP, EXC_STACK); IDT( 23, TRAP, EXC_STACK) |
| IDT( 24, TRAP, EXC_STACK); IDT( 25, TRAP, EXC_STACK) |
| IDT( 26, TRAP, EXC_STACK); IDT( 27, TRAP, EXC_STACK) |
| IDT( 28, TRAP, EXC_STACK); IDT( 29, TRAP, EXC_STACK) |
| IDT( 30, TRAP, EXC_STACK); IDT( 31, TRAP, EXC_STACK) |
| |
| /* Oops vector can be invoked from Ring 3 and runs on exception stack */ |
| IDT(Z_X86_OOPS_VECTOR, USER_INTR, EXC_STACK); IDT( 33, INTR, IRQ_STACK) |
| IDT( 34, INTR, IRQ_STACK); IDT( 35, INTR, IRQ_STACK) |
| IDT( 36, INTR, IRQ_STACK); IDT( 37, INTR, IRQ_STACK) |
| IDT( 38, INTR, IRQ_STACK); IDT( 39, INTR, IRQ_STACK) |
| IDT( 40, INTR, IRQ_STACK); IDT( 41, INTR, IRQ_STACK) |
| IDT( 42, INTR, IRQ_STACK); IDT( 43, INTR, IRQ_STACK) |
| IDT( 44, INTR, IRQ_STACK); IDT( 45, INTR, IRQ_STACK) |
| IDT( 46, INTR, IRQ_STACK); IDT( 47, INTR, IRQ_STACK) |
| IDT( 48, INTR, IRQ_STACK); IDT( 49, INTR, IRQ_STACK) |
| IDT( 50, INTR, IRQ_STACK); IDT( 51, INTR, IRQ_STACK) |
| IDT( 52, INTR, IRQ_STACK); IDT( 53, INTR, IRQ_STACK) |
| IDT( 54, INTR, IRQ_STACK); IDT( 55, INTR, IRQ_STACK) |
| IDT( 56, INTR, IRQ_STACK); IDT( 57, INTR, IRQ_STACK) |
| IDT( 58, INTR, IRQ_STACK); IDT( 59, INTR, IRQ_STACK) |
| IDT( 60, INTR, IRQ_STACK); IDT( 61, INTR, IRQ_STACK) |
| IDT( 62, INTR, IRQ_STACK); IDT( 63, INTR, IRQ_STACK) |
| IDT( 64, INTR, IRQ_STACK); IDT( 65, INTR, IRQ_STACK) |
| IDT( 66, INTR, IRQ_STACK); IDT( 67, INTR, IRQ_STACK) |
| IDT( 68, INTR, IRQ_STACK); IDT( 69, INTR, IRQ_STACK) |
| IDT( 70, INTR, IRQ_STACK); IDT( 71, INTR, IRQ_STACK) |
| IDT( 72, INTR, IRQ_STACK); IDT( 73, INTR, IRQ_STACK) |
| IDT( 74, INTR, IRQ_STACK); IDT( 75, INTR, IRQ_STACK) |
| IDT( 76, INTR, IRQ_STACK); IDT( 77, INTR, IRQ_STACK) |
| IDT( 78, INTR, IRQ_STACK); IDT( 79, INTR, IRQ_STACK) |
| IDT( 80, INTR, IRQ_STACK); IDT( 81, INTR, IRQ_STACK) |
| IDT( 82, INTR, IRQ_STACK); IDT( 83, INTR, IRQ_STACK) |
| IDT( 84, INTR, IRQ_STACK); IDT( 85, INTR, IRQ_STACK) |
| IDT( 86, INTR, IRQ_STACK); IDT( 87, INTR, IRQ_STACK) |
| IDT( 88, INTR, IRQ_STACK); IDT( 89, INTR, IRQ_STACK) |
| IDT( 90, INTR, IRQ_STACK); IDT( 91, INTR, IRQ_STACK) |
| IDT( 92, INTR, IRQ_STACK); IDT( 93, INTR, IRQ_STACK) |
| IDT( 94, INTR, IRQ_STACK); IDT( 95, INTR, IRQ_STACK) |
| IDT( 96, INTR, IRQ_STACK); IDT( 97, INTR, IRQ_STACK) |
| IDT( 98, INTR, IRQ_STACK); IDT( 99, INTR, IRQ_STACK) |
| IDT(100, INTR, IRQ_STACK); IDT(101, INTR, IRQ_STACK) |
| IDT(102, INTR, IRQ_STACK); IDT(103, INTR, IRQ_STACK) |
| IDT(104, INTR, IRQ_STACK); IDT(105, INTR, IRQ_STACK) |
| IDT(106, INTR, IRQ_STACK); IDT(107, INTR, IRQ_STACK) |
| IDT(108, INTR, IRQ_STACK); IDT(109, INTR, IRQ_STACK) |
| IDT(110, INTR, IRQ_STACK); IDT(111, INTR, IRQ_STACK) |
| IDT(112, INTR, IRQ_STACK); IDT(113, INTR, IRQ_STACK) |
| IDT(114, INTR, IRQ_STACK); IDT(115, INTR, IRQ_STACK) |
| IDT(116, INTR, IRQ_STACK); IDT(117, INTR, IRQ_STACK) |
| IDT(118, INTR, IRQ_STACK); IDT(119, INTR, IRQ_STACK) |
| IDT(120, INTR, IRQ_STACK); IDT(121, INTR, IRQ_STACK) |
| IDT(122, INTR, IRQ_STACK); IDT(123, INTR, IRQ_STACK) |
| IDT(124, INTR, IRQ_STACK); IDT(125, INTR, IRQ_STACK) |
| IDT(126, INTR, IRQ_STACK); IDT(127, INTR, IRQ_STACK) |
| IDT(128, INTR, IRQ_STACK); IDT(129, INTR, IRQ_STACK) |
| IDT(130, INTR, IRQ_STACK); IDT(131, INTR, IRQ_STACK) |
| IDT(132, INTR, IRQ_STACK); IDT(133, INTR, IRQ_STACK) |
| IDT(134, INTR, IRQ_STACK); IDT(135, INTR, IRQ_STACK) |
| IDT(136, INTR, IRQ_STACK); IDT(137, INTR, IRQ_STACK) |
| IDT(138, INTR, IRQ_STACK); IDT(139, INTR, IRQ_STACK) |
| IDT(140, INTR, IRQ_STACK); IDT(141, INTR, IRQ_STACK) |
| IDT(142, INTR, IRQ_STACK); IDT(143, INTR, IRQ_STACK) |
| IDT(144, INTR, IRQ_STACK); IDT(145, INTR, IRQ_STACK) |
| IDT(146, INTR, IRQ_STACK); IDT(147, INTR, IRQ_STACK) |
| IDT(148, INTR, IRQ_STACK); IDT(149, INTR, IRQ_STACK) |
| IDT(150, INTR, IRQ_STACK); IDT(151, INTR, IRQ_STACK) |
| IDT(152, INTR, IRQ_STACK); IDT(153, INTR, IRQ_STACK) |
| IDT(154, INTR, IRQ_STACK); IDT(155, INTR, IRQ_STACK) |
| IDT(156, INTR, IRQ_STACK); IDT(157, INTR, IRQ_STACK) |
| IDT(158, INTR, IRQ_STACK); IDT(159, INTR, IRQ_STACK) |
| IDT(160, INTR, IRQ_STACK); IDT(161, INTR, IRQ_STACK) |
| IDT(162, INTR, IRQ_STACK); IDT(163, INTR, IRQ_STACK) |
| IDT(164, INTR, IRQ_STACK); IDT(165, INTR, IRQ_STACK) |
| IDT(166, INTR, IRQ_STACK); IDT(167, INTR, IRQ_STACK) |
| IDT(168, INTR, IRQ_STACK); IDT(169, INTR, IRQ_STACK) |
| IDT(170, INTR, IRQ_STACK); IDT(171, INTR, IRQ_STACK) |
| IDT(172, INTR, IRQ_STACK); IDT(173, INTR, IRQ_STACK) |
| IDT(174, INTR, IRQ_STACK); IDT(175, INTR, IRQ_STACK) |
| IDT(176, INTR, IRQ_STACK); IDT(177, INTR, IRQ_STACK) |
| IDT(178, INTR, IRQ_STACK); IDT(179, INTR, IRQ_STACK) |
| IDT(180, INTR, IRQ_STACK); IDT(181, INTR, IRQ_STACK) |
| IDT(182, INTR, IRQ_STACK); IDT(183, INTR, IRQ_STACK) |
| IDT(184, INTR, IRQ_STACK); IDT(185, INTR, IRQ_STACK) |
| IDT(186, INTR, IRQ_STACK); IDT(187, INTR, IRQ_STACK) |
| IDT(188, INTR, IRQ_STACK); IDT(189, INTR, IRQ_STACK) |
| IDT(190, INTR, IRQ_STACK); IDT(191, INTR, IRQ_STACK) |
| IDT(192, INTR, IRQ_STACK); IDT(193, INTR, IRQ_STACK) |
| IDT(194, INTR, IRQ_STACK); IDT(195, INTR, IRQ_STACK) |
| IDT(196, INTR, IRQ_STACK); IDT(197, INTR, IRQ_STACK) |
| IDT(198, INTR, IRQ_STACK); IDT(199, INTR, IRQ_STACK) |
| IDT(200, INTR, IRQ_STACK); IDT(201, INTR, IRQ_STACK) |
| IDT(202, INTR, IRQ_STACK); IDT(203, INTR, IRQ_STACK) |
| IDT(204, INTR, IRQ_STACK); IDT(205, INTR, IRQ_STACK) |
| IDT(206, INTR, IRQ_STACK); IDT(207, INTR, IRQ_STACK) |
| IDT(208, INTR, IRQ_STACK); IDT(209, INTR, IRQ_STACK) |
| IDT(210, INTR, IRQ_STACK); IDT(211, INTR, IRQ_STACK) |
| IDT(212, INTR, IRQ_STACK); IDT(213, INTR, IRQ_STACK) |
| IDT(214, INTR, IRQ_STACK); IDT(215, INTR, IRQ_STACK) |
| IDT(216, INTR, IRQ_STACK); IDT(217, INTR, IRQ_STACK) |
| IDT(218, INTR, IRQ_STACK); IDT(219, INTR, IRQ_STACK) |
| IDT(220, INTR, IRQ_STACK); IDT(221, INTR, IRQ_STACK) |
| IDT(222, INTR, IRQ_STACK); IDT(223, INTR, IRQ_STACK) |
| IDT(224, INTR, IRQ_STACK); IDT(225, INTR, IRQ_STACK) |
| IDT(226, INTR, IRQ_STACK); IDT(227, INTR, IRQ_STACK) |
| IDT(228, INTR, IRQ_STACK); IDT(229, INTR, IRQ_STACK) |
| IDT(230, INTR, IRQ_STACK); IDT(231, INTR, IRQ_STACK) |
| IDT(232, INTR, IRQ_STACK); IDT(233, INTR, IRQ_STACK) |
| IDT(234, INTR, IRQ_STACK); IDT(235, INTR, IRQ_STACK) |
| IDT(236, INTR, IRQ_STACK); IDT(237, INTR, IRQ_STACK) |
| IDT(238, INTR, IRQ_STACK); IDT(239, INTR, IRQ_STACK) |
| IDT(240, INTR, IRQ_STACK); IDT(241, INTR, IRQ_STACK) |
| IDT(242, INTR, IRQ_STACK); IDT(243, INTR, IRQ_STACK) |
| IDT(244, INTR, IRQ_STACK); IDT(245, INTR, IRQ_STACK) |
| IDT(246, INTR, IRQ_STACK); IDT(247, INTR, IRQ_STACK) |
| IDT(248, INTR, IRQ_STACK); IDT(249, INTR, IRQ_STACK) |
| IDT(250, INTR, IRQ_STACK); IDT(251, INTR, IRQ_STACK) |
| IDT(252, INTR, IRQ_STACK); IDT(253, INTR, IRQ_STACK) |
| IDT(254, INTR, IRQ_STACK); IDT(255, INTR, IRQ_STACK) |
| idt_end: |
| |
| idt48: /* LIDT descriptor for 32 bit mode */ |
| .word (idt_end - idt - 1) |
| .long idt |
| |
| idt80: /* LIDT descriptor for 64 bit mode */ |
| .word (idt_end - idt - 1) |
| .quad idt |
| |
| .section .gdt,"ad" |
| |
| /* |
| * GDT - a single GDT is shared by all threads (and, eventually, all CPUs). |
| * This layout must agree with the selectors in |
| * include/arch/x86/intel64/thread.h. |
| * |
| * The 64-bit kernel code and data segment descriptors must be in sequence as |
| * required by 'syscall' |
| * |
| * The 32-bit user code, 64-bit user code, and 64-bit user data segment |
| * descriptors must be in sequence as required by 'sysret' |
| */ |
| .align 8 |
| |
| gdt: |
| .word 0, 0, 0, 0 /* 0x00: null descriptor */ |
| .word 0xFFFF, 0, 0x9A00, 0x00CF /* 0x08: 32-bit kernel code */ |
| .word 0xFFFF, 0, 0x9200, 0x00CF /* 0x10: 32-bit kernel data */ |
| .word 0, 0, 0x9800, 0x0020 /* 0x18: 64-bit kernel code */ |
| .word 0, 0, 0x9200, 0x0000 /* 0x20: 64-bit kernel data */ |
| .word 0xFFFF, 0, 0xFA00, 0x00CF /* 0x28: 32-bit user code (unused) */ |
| .word 0, 0, 0xF200, 0x0000 /* 0x30: 64-bit user data */ |
| .word 0, 0, 0xF800, 0x0020 /* 0x38: 64-bit user code */ |
| |
| /* Remaining entries are TSS for each enabled CPU */ |
| |
| .word __X86_TSS64_SIZEOF-1 /* 0x40: 64-bit TSS (16-byte entry) */ |
| .word tss0 |
| .word 0x8900 |
| .word 0, 0, 0, 0, 0 |
| |
| #if CONFIG_MP_MAX_NUM_CPUS > 1 |
| .word __X86_TSS64_SIZEOF-1 /* 0x50: 64-bit TSS (16-byte entry) */ |
| .word tss1 |
| .word 0x8900 |
| .word 0, 0, 0, 0, 0 |
| #endif |
| |
| #if CONFIG_MP_MAX_NUM_CPUS > 2 |
| .word __X86_TSS64_SIZEOF-1 /* 0x60: 64-bit TSS (16-byte entry) */ |
| .word tss2 |
| .word 0x8900 |
| .word 0, 0, 0, 0, 0 |
| #endif |
| |
| #if CONFIG_MP_MAX_NUM_CPUS > 3 |
| .word __X86_TSS64_SIZEOF-1 /* 0x70: 64-bit TSS (16-byte entry) */ |
| .word tss3 |
| .word 0x8900 |
| .word 0, 0, 0, 0, 0 |
| #endif |
| |
| gdt_end: |
| |
| gdt48: /* LGDT descriptor for 32 bit mode */ |
| .word (gdt_end - gdt - 1) |
| .long gdt |
| |
| gdt80: /* LGDT descriptor for long mode */ |
| .word (gdt_end - gdt - 1) |
| .quad gdt |
| .section .lodata,"ad" |
| |
| /* |
| * Known-good stack for handling CPU exceptions. |
| */ |
| |
| .global z_x86_exception_stack |
| .align 16 |
| z_x86_exception_stack: |
| .fill CONFIG_X86_EXCEPTION_STACK_SIZE, 1, 0xAA |
| .global z_x86_nmi_stack |
| .align 16 |
| z_x86_nmi_stack: |
| .fill CONFIG_X86_EXCEPTION_STACK_SIZE, 1, 0xAA |
| |
| #if CONFIG_MP_MAX_NUM_CPUS > 1 |
| .global z_x86_exception_stack1 |
| .align 16 |
| z_x86_exception_stack1: |
| .fill CONFIG_X86_EXCEPTION_STACK_SIZE, 1, 0xAA |
| .global z_x86_nmi_stack1 |
| .align 16 |
| z_x86_nmi_stack1: |
| .fill CONFIG_X86_EXCEPTION_STACK_SIZE, 1, 0xAA |
| #endif |
| |
| #if CONFIG_MP_MAX_NUM_CPUS > 2 |
| .global z_x86_exception_stack2 |
| .align 16 |
| z_x86_exception_stack2: |
| .fill CONFIG_X86_EXCEPTION_STACK_SIZE, 1, 0xAA |
| .global z_x86_nmi_stack2 |
| .align 16 |
| z_x86_nmi_stack2: |
| .fill CONFIG_X86_EXCEPTION_STACK_SIZE, 1, 0xAA |
| #endif |
| |
| #if CONFIG_MP_MAX_NUM_CPUS > 3 |
| .global z_x86_exception_stack3 |
| .align 16 |
| z_x86_exception_stack3: |
| .fill CONFIG_X86_EXCEPTION_STACK_SIZE, 1, 0xAA |
| .global z_x86_nmi_stack3 |
| .align 16 |
| z_x86_nmi_stack3: |
| .fill CONFIG_X86_EXCEPTION_STACK_SIZE, 1, 0xAA |
| #endif |
| |
| #ifdef CONFIG_X86_KPTI |
| .section .trampolines,"ad" |
| |
| .global z_x86_trampoline_stack |
| .align 16 |
| z_x86_trampoline_stack: |
| .fill Z_X86_TRAMPOLINE_STACK_SIZE, 1, 0xAA |
| |
| #if CONFIG_MP_MAX_NUM_CPUS > 1 |
| .global z_x86_trampoline_stack1 |
| .align 16 |
| z_x86_trampoline_stack1: |
| .fill Z_X86_TRAMPOLINE_STACK_SIZE, 1, 0xAA |
| #endif |
| |
| #if CONFIG_MP_MAX_NUM_CPUS > 2 |
| .global z_x86_trampoline_stack2 |
| .align 16 |
| z_x86_trampoline_stack2: |
| .fill Z_X86_TRAMPOLINE_STACK_SIZE, 1, 0xAA |
| #endif |
| |
| #if CONFIG_MP_MAX_NUM_CPUS > 3 |
| .global z_x86_trampoline_stack3 |
| .align 16 |
| z_x86_trampoline_stack3: |
| .fill Z_X86_TRAMPOLINE_STACK_SIZE, 1, 0xAA |
| #endif |
| #endif /* CONFIG_X86_KPTI */ |