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64a48099b3
Pull x86 syscall entry code changes for PTI from Ingo Molnar: "The main changes here are Andy Lutomirski's changes to switch the x86-64 entry code to use the 'per CPU entry trampoline stack'. This, besides helping fix KASLR leaks (the pending Page Table Isolation (PTI) work), also robustifies the x86 entry code" * 'WIP.x86-pti.entry-for-linus' of git://git.kernel.org/pub/scm/linux/kernel/git/tip/tip: (26 commits) x86/cpufeatures: Make CPU bugs sticky x86/paravirt: Provide a way to check for hypervisors x86/paravirt: Dont patch flush_tlb_single x86/entry/64: Make cpu_entry_area.tss read-only x86/entry: Clean up the SYSENTER_stack code x86/entry/64: Remove the SYSENTER stack canary x86/entry/64: Move the IST stacks into struct cpu_entry_area x86/entry/64: Create a per-CPU SYSCALL entry trampoline x86/entry/64: Return to userspace from the trampoline stack x86/entry/64: Use a per-CPU trampoline stack for IDT entries x86/espfix/64: Stop assuming that pt_regs is on the entry stack x86/entry/64: Separate cpu_current_top_of_stack from TSS.sp0 x86/entry: Remap the TSS into the CPU entry area x86/entry: Move SYSENTER_stack to the beginning of struct tss_struct x86/dumpstack: Handle stack overflow on all stacks x86/entry: Fix assumptions that the HW TSS is at the beginning of cpu_tss x86/kasan/64: Teach KASAN about the cpu_entry_area x86/mm/fixmap: Generalize the GDT fixmap mechanism, introduce struct cpu_entry_area x86/entry/gdt: Put per-CPU GDT remaps in ascending order x86/dumpstack: Add get_stack_info() support for the SYSENTER stack ...
456 lines
12 KiB
C
456 lines
12 KiB
C
/*
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* Suspend support specific for i386/x86-64.
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*
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* Distribute under GPLv2
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*
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* Copyright (c) 2007 Rafael J. Wysocki <rjw@sisk.pl>
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* Copyright (c) 2002 Pavel Machek <pavel@ucw.cz>
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* Copyright (c) 2001 Patrick Mochel <mochel@osdl.org>
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*/
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#include <linux/suspend.h>
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#include <linux/export.h>
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#include <linux/smp.h>
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#include <linux/perf_event.h>
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#include <linux/tboot.h>
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#include <asm/pgtable.h>
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#include <asm/proto.h>
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#include <asm/mtrr.h>
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#include <asm/page.h>
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#include <asm/mce.h>
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#include <asm/suspend.h>
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#include <asm/fpu/internal.h>
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#include <asm/debugreg.h>
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#include <asm/cpu.h>
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#include <asm/mmu_context.h>
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#include <linux/dmi.h>
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#ifdef CONFIG_X86_32
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__visible unsigned long saved_context_ebx;
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__visible unsigned long saved_context_esp, saved_context_ebp;
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__visible unsigned long saved_context_esi, saved_context_edi;
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__visible unsigned long saved_context_eflags;
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#endif
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struct saved_context saved_context;
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static void msr_save_context(struct saved_context *ctxt)
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{
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struct saved_msr *msr = ctxt->saved_msrs.array;
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struct saved_msr *end = msr + ctxt->saved_msrs.num;
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while (msr < end) {
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msr->valid = !rdmsrl_safe(msr->info.msr_no, &msr->info.reg.q);
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msr++;
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}
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}
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static void msr_restore_context(struct saved_context *ctxt)
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{
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struct saved_msr *msr = ctxt->saved_msrs.array;
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struct saved_msr *end = msr + ctxt->saved_msrs.num;
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while (msr < end) {
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if (msr->valid)
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wrmsrl(msr->info.msr_no, msr->info.reg.q);
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msr++;
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}
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}
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/**
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* __save_processor_state - save CPU registers before creating a
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* hibernation image and before restoring the memory state from it
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* @ctxt - structure to store the registers contents in
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*
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* NOTE: If there is a CPU register the modification of which by the
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* boot kernel (ie. the kernel used for loading the hibernation image)
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* might affect the operations of the restored target kernel (ie. the one
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* saved in the hibernation image), then its contents must be saved by this
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* function. In other words, if kernel A is hibernated and different
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* kernel B is used for loading the hibernation image into memory, the
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* kernel A's __save_processor_state() function must save all registers
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* needed by kernel A, so that it can operate correctly after the resume
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* regardless of what kernel B does in the meantime.
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*/
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static void __save_processor_state(struct saved_context *ctxt)
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{
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#ifdef CONFIG_X86_32
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mtrr_save_fixed_ranges(NULL);
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#endif
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kernel_fpu_begin();
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/*
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* descriptor tables
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*/
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store_idt(&ctxt->idt);
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/*
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* We save it here, but restore it only in the hibernate case.
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* For ACPI S3 resume, this is loaded via 'early_gdt_desc' in 64-bit
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* mode in "secondary_startup_64". In 32-bit mode it is done via
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* 'pmode_gdt' in wakeup_start.
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*/
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ctxt->gdt_desc.size = GDT_SIZE - 1;
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ctxt->gdt_desc.address = (unsigned long)get_cpu_gdt_rw(smp_processor_id());
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store_tr(ctxt->tr);
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/* XMM0..XMM15 should be handled by kernel_fpu_begin(). */
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/*
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* segment registers
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*/
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#ifdef CONFIG_X86_32_LAZY_GS
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savesegment(gs, ctxt->gs);
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#endif
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#ifdef CONFIG_X86_64
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savesegment(gs, ctxt->gs);
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savesegment(fs, ctxt->fs);
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savesegment(ds, ctxt->ds);
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savesegment(es, ctxt->es);
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rdmsrl(MSR_FS_BASE, ctxt->fs_base);
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rdmsrl(MSR_GS_BASE, ctxt->kernelmode_gs_base);
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rdmsrl(MSR_KERNEL_GS_BASE, ctxt->usermode_gs_base);
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mtrr_save_fixed_ranges(NULL);
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rdmsrl(MSR_EFER, ctxt->efer);
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#endif
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/*
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* control registers
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*/
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ctxt->cr0 = read_cr0();
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ctxt->cr2 = read_cr2();
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ctxt->cr3 = __read_cr3();
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ctxt->cr4 = __read_cr4();
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#ifdef CONFIG_X86_64
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ctxt->cr8 = read_cr8();
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#endif
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ctxt->misc_enable_saved = !rdmsrl_safe(MSR_IA32_MISC_ENABLE,
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&ctxt->misc_enable);
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msr_save_context(ctxt);
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}
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/* Needed by apm.c */
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void save_processor_state(void)
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{
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__save_processor_state(&saved_context);
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x86_platform.save_sched_clock_state();
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}
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#ifdef CONFIG_X86_32
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EXPORT_SYMBOL(save_processor_state);
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#endif
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static void do_fpu_end(void)
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{
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/*
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* Restore FPU regs if necessary.
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*/
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kernel_fpu_end();
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}
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static void fix_processor_context(void)
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{
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int cpu = smp_processor_id();
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#ifdef CONFIG_X86_64
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struct desc_struct *desc = get_cpu_gdt_rw(cpu);
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tss_desc tss;
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#endif
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/*
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* We need to reload TR, which requires that we change the
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* GDT entry to indicate "available" first.
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*
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* XXX: This could probably all be replaced by a call to
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* force_reload_TR().
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*/
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set_tss_desc(cpu, &get_cpu_entry_area(cpu)->tss.x86_tss);
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#ifdef CONFIG_X86_64
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memcpy(&tss, &desc[GDT_ENTRY_TSS], sizeof(tss_desc));
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tss.type = 0x9; /* The available 64-bit TSS (see AMD vol 2, pg 91 */
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write_gdt_entry(desc, GDT_ENTRY_TSS, &tss, DESC_TSS);
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syscall_init(); /* This sets MSR_*STAR and related */
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#else
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if (boot_cpu_has(X86_FEATURE_SEP))
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enable_sep_cpu();
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#endif
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load_TR_desc(); /* This does ltr */
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load_mm_ldt(current->active_mm); /* This does lldt */
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initialize_tlbstate_and_flush();
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fpu__resume_cpu();
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/* The processor is back on the direct GDT, load back the fixmap */
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load_fixmap_gdt(cpu);
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}
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/**
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* __restore_processor_state - restore the contents of CPU registers saved
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* by __save_processor_state()
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* @ctxt - structure to load the registers contents from
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*
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* The asm code that gets us here will have restored a usable GDT, although
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* it will be pointing to the wrong alias.
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*/
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static void notrace __restore_processor_state(struct saved_context *ctxt)
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{
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if (ctxt->misc_enable_saved)
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wrmsrl(MSR_IA32_MISC_ENABLE, ctxt->misc_enable);
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/*
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* control registers
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*/
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/* cr4 was introduced in the Pentium CPU */
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#ifdef CONFIG_X86_32
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if (ctxt->cr4)
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__write_cr4(ctxt->cr4);
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#else
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/* CONFIG X86_64 */
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wrmsrl(MSR_EFER, ctxt->efer);
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write_cr8(ctxt->cr8);
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__write_cr4(ctxt->cr4);
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#endif
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write_cr3(ctxt->cr3);
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write_cr2(ctxt->cr2);
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write_cr0(ctxt->cr0);
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/* Restore the IDT. */
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load_idt(&ctxt->idt);
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/*
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* Just in case the asm code got us here with the SS, DS, or ES
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* out of sync with the GDT, update them.
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*/
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loadsegment(ss, __KERNEL_DS);
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loadsegment(ds, __USER_DS);
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loadsegment(es, __USER_DS);
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/*
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* Restore percpu access. Percpu access can happen in exception
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* handlers or in complicated helpers like load_gs_index().
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*/
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#ifdef CONFIG_X86_64
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wrmsrl(MSR_GS_BASE, ctxt->kernelmode_gs_base);
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#else
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loadsegment(fs, __KERNEL_PERCPU);
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loadsegment(gs, __KERNEL_STACK_CANARY);
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#endif
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/* Restore the TSS, RO GDT, LDT, and usermode-relevant MSRs. */
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fix_processor_context();
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/*
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* Now that we have descriptor tables fully restored and working
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* exception handling, restore the usermode segments.
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*/
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#ifdef CONFIG_X86_64
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loadsegment(ds, ctxt->es);
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loadsegment(es, ctxt->es);
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loadsegment(fs, ctxt->fs);
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load_gs_index(ctxt->gs);
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/*
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* Restore FSBASE and GSBASE after restoring the selectors, since
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* restoring the selectors clobbers the bases. Keep in mind
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* that MSR_KERNEL_GS_BASE is horribly misnamed.
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*/
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wrmsrl(MSR_FS_BASE, ctxt->fs_base);
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wrmsrl(MSR_KERNEL_GS_BASE, ctxt->usermode_gs_base);
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#elif defined(CONFIG_X86_32_LAZY_GS)
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loadsegment(gs, ctxt->gs);
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#endif
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do_fpu_end();
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tsc_verify_tsc_adjust(true);
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x86_platform.restore_sched_clock_state();
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mtrr_bp_restore();
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perf_restore_debug_store();
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msr_restore_context(ctxt);
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}
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/* Needed by apm.c */
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void notrace restore_processor_state(void)
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{
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__restore_processor_state(&saved_context);
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}
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#ifdef CONFIG_X86_32
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EXPORT_SYMBOL(restore_processor_state);
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#endif
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#if defined(CONFIG_HIBERNATION) && defined(CONFIG_HOTPLUG_CPU)
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static void resume_play_dead(void)
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{
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play_dead_common();
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tboot_shutdown(TB_SHUTDOWN_WFS);
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hlt_play_dead();
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}
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int hibernate_resume_nonboot_cpu_disable(void)
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{
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void (*play_dead)(void) = smp_ops.play_dead;
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int ret;
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/*
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* Ensure that MONITOR/MWAIT will not be used in the "play dead" loop
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* during hibernate image restoration, because it is likely that the
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* monitored address will be actually written to at that time and then
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* the "dead" CPU will attempt to execute instructions again, but the
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* address in its instruction pointer may not be possible to resolve
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* any more at that point (the page tables used by it previously may
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* have been overwritten by hibernate image data).
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*/
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smp_ops.play_dead = resume_play_dead;
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ret = disable_nonboot_cpus();
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smp_ops.play_dead = play_dead;
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return ret;
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}
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#endif
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/*
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* When bsp_check() is called in hibernate and suspend, cpu hotplug
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* is disabled already. So it's unnessary to handle race condition between
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* cpumask query and cpu hotplug.
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*/
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static int bsp_check(void)
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{
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if (cpumask_first(cpu_online_mask) != 0) {
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pr_warn("CPU0 is offline.\n");
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return -ENODEV;
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}
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return 0;
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}
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static int bsp_pm_callback(struct notifier_block *nb, unsigned long action,
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void *ptr)
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{
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int ret = 0;
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switch (action) {
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case PM_SUSPEND_PREPARE:
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case PM_HIBERNATION_PREPARE:
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ret = bsp_check();
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break;
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#ifdef CONFIG_DEBUG_HOTPLUG_CPU0
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case PM_RESTORE_PREPARE:
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/*
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* When system resumes from hibernation, online CPU0 because
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* 1. it's required for resume and
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* 2. the CPU was online before hibernation
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*/
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if (!cpu_online(0))
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_debug_hotplug_cpu(0, 1);
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break;
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case PM_POST_RESTORE:
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/*
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* When a resume really happens, this code won't be called.
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*
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* This code is called only when user space hibernation software
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* prepares for snapshot device during boot time. So we just
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* call _debug_hotplug_cpu() to restore to CPU0's state prior to
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* preparing the snapshot device.
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*
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* This works for normal boot case in our CPU0 hotplug debug
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* mode, i.e. CPU0 is offline and user mode hibernation
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* software initializes during boot time.
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*
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* If CPU0 is online and user application accesses snapshot
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* device after boot time, this will offline CPU0 and user may
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* see different CPU0 state before and after accessing
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* the snapshot device. But hopefully this is not a case when
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* user debugging CPU0 hotplug. Even if users hit this case,
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* they can easily online CPU0 back.
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*
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* To simplify this debug code, we only consider normal boot
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* case. Otherwise we need to remember CPU0's state and restore
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* to that state and resolve racy conditions etc.
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*/
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_debug_hotplug_cpu(0, 0);
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break;
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#endif
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default:
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break;
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}
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return notifier_from_errno(ret);
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}
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static int __init bsp_pm_check_init(void)
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{
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/*
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* Set this bsp_pm_callback as lower priority than
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* cpu_hotplug_pm_callback. So cpu_hotplug_pm_callback will be called
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* earlier to disable cpu hotplug before bsp online check.
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*/
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pm_notifier(bsp_pm_callback, -INT_MAX);
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return 0;
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}
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core_initcall(bsp_pm_check_init);
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static int msr_init_context(const u32 *msr_id, const int total_num)
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{
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int i = 0;
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struct saved_msr *msr_array;
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if (saved_context.saved_msrs.array || saved_context.saved_msrs.num > 0) {
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pr_err("x86/pm: MSR quirk already applied, please check your DMI match table.\n");
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return -EINVAL;
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}
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msr_array = kmalloc_array(total_num, sizeof(struct saved_msr), GFP_KERNEL);
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if (!msr_array) {
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pr_err("x86/pm: Can not allocate memory to save/restore MSRs during suspend.\n");
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return -ENOMEM;
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}
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for (i = 0; i < total_num; i++) {
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msr_array[i].info.msr_no = msr_id[i];
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msr_array[i].valid = false;
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msr_array[i].info.reg.q = 0;
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}
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saved_context.saved_msrs.num = total_num;
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saved_context.saved_msrs.array = msr_array;
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return 0;
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}
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/*
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* The following section is a quirk framework for problematic BIOSen:
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* Sometimes MSRs are modified by the BIOSen after suspended to
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* RAM, this might cause unexpected behavior after wakeup.
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* Thus we save/restore these specified MSRs across suspend/resume
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* in order to work around it.
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*
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* For any further problematic BIOSen/platforms,
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* please add your own function similar to msr_initialize_bdw.
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*/
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static int msr_initialize_bdw(const struct dmi_system_id *d)
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{
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/* Add any extra MSR ids into this array. */
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u32 bdw_msr_id[] = { MSR_IA32_THERM_CONTROL };
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pr_info("x86/pm: %s detected, MSR saving is needed during suspending.\n", d->ident);
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return msr_init_context(bdw_msr_id, ARRAY_SIZE(bdw_msr_id));
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}
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static const struct dmi_system_id msr_save_dmi_table[] = {
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{
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.callback = msr_initialize_bdw,
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.ident = "BROADWELL BDX_EP",
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.matches = {
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DMI_MATCH(DMI_PRODUCT_NAME, "GRANTLEY"),
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DMI_MATCH(DMI_PRODUCT_VERSION, "E63448-400"),
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},
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},
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{}
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};
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static int pm_check_save_msr(void)
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{
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dmi_check_system(msr_save_dmi_table);
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return 0;
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}
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device_initcall(pm_check_save_msr);
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