#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "process.h" /* * per-CPU TSS segments. Threads are completely 'soft' on Linux, * no more per-task TSS's. The TSS size is kept cacheline-aligned * so they are allowed to end up in the .data..cacheline_aligned * section. Since TSS's are completely CPU-local, we want them * on exact cacheline boundaries, to eliminate cacheline ping-pong. */ __visible DEFINE_PER_CPU_SHARED_ALIGNED_USER_MAPPED(struct tss_struct, cpu_tss) = { .x86_tss = { .sp0 = TOP_OF_INIT_STACK, #ifdef CONFIG_X86_32 .ss0 = __KERNEL_DS, .ss1 = __KERNEL_CS, .io_bitmap_base = INVALID_IO_BITMAP_OFFSET, #endif }, #ifdef CONFIG_X86_32 /* * Note that the .io_bitmap member must be extra-big. This is because * the CPU will access an additional byte beyond the end of the IO * permission bitmap. The extra byte must be all 1 bits, and must * be within the limit. */ .io_bitmap = { [0 ... IO_BITMAP_LONGS] = ~0 }, #endif #ifdef CONFIG_X86_32 .SYSENTER_stack_canary = STACK_END_MAGIC, #endif }; EXPORT_PER_CPU_SYMBOL(cpu_tss); #ifdef CONFIG_X86_64 static DEFINE_PER_CPU(unsigned char, is_idle); static ATOMIC_NOTIFIER_HEAD(idle_notifier); void idle_notifier_register(struct notifier_block *n) { atomic_notifier_chain_register(&idle_notifier, n); } EXPORT_SYMBOL_GPL(idle_notifier_register); void idle_notifier_unregister(struct notifier_block *n) { atomic_notifier_chain_unregister(&idle_notifier, n); } EXPORT_SYMBOL_GPL(idle_notifier_unregister); #endif /* * this gets called so that we can store lazy state into memory and copy the * current task into the new thread. */ int arch_dup_task_struct(struct task_struct *dst, struct task_struct *src) { memcpy(dst, src, arch_task_struct_size); #ifdef CONFIG_VM86 dst->thread.vm86 = NULL; #endif return fpu__copy(&dst->thread.fpu, &src->thread.fpu); } /* * Free current thread data structures etc.. */ void exit_thread(struct task_struct *tsk) { struct thread_struct *t = &tsk->thread; unsigned long *bp = t->io_bitmap_ptr; struct fpu *fpu = &t->fpu; if (bp) { struct tss_struct *tss = &per_cpu(cpu_tss, get_cpu()); t->io_bitmap_ptr = NULL; clear_thread_flag(TIF_IO_BITMAP); /* * Careful, clear this in the TSS too: */ memset(tss->io_bitmap, 0xff, t->io_bitmap_max); t->io_bitmap_max = 0; put_cpu(); kfree(bp); } free_vm86(t); fpu__drop(fpu); } void flush_thread(void) { struct task_struct *tsk = current; flush_ptrace_hw_breakpoint(tsk); memset(tsk->thread.tls_array, 0, sizeof(tsk->thread.tls_array)); fpu__clear(&tsk->thread.fpu); } void disable_TSC(void) { preempt_disable(); if (!test_and_set_thread_flag(TIF_NOTSC)) /* * Must flip the CPU state synchronously with * TIF_NOTSC in the current running context. */ cr4_set_bits(X86_CR4_TSD); preempt_enable(); } static void enable_TSC(void) { preempt_disable(); if (test_and_clear_thread_flag(TIF_NOTSC)) /* * Must flip the CPU state synchronously with * TIF_NOTSC in the current running context. */ cr4_clear_bits(X86_CR4_TSD); preempt_enable(); } int get_tsc_mode(unsigned long adr) { unsigned int val; if (test_thread_flag(TIF_NOTSC)) val = PR_TSC_SIGSEGV; else val = PR_TSC_ENABLE; return put_user(val, (unsigned int __user *)adr); } int set_tsc_mode(unsigned int val) { if (val == PR_TSC_SIGSEGV) disable_TSC(); else if (val == PR_TSC_ENABLE) enable_TSC(); else return -EINVAL; return 0; } static inline void switch_to_bitmap(struct thread_struct *prev, struct thread_struct *next, unsigned long tifp, unsigned long tifn) { struct tss_struct *tss = this_cpu_ptr(&cpu_tss); if (tifn & _TIF_IO_BITMAP) { /* * Copy the relevant range of the IO bitmap. * Normally this is 128 bytes or less: */ memcpy(tss->io_bitmap, next->io_bitmap_ptr, max(prev->io_bitmap_max, next->io_bitmap_max)); } else if (tifp & _TIF_IO_BITMAP) { /* * Clear any possible leftover bits: */ memset(tss->io_bitmap, 0xff, prev->io_bitmap_max); } } #ifdef CONFIG_SMP struct ssb_state { struct ssb_state *shared_state; raw_spinlock_t lock; unsigned int disable_state; unsigned long local_state; }; #define LSTATE_SSB 0 static DEFINE_PER_CPU(struct ssb_state, ssb_state); void speculative_store_bypass_ht_init(void) { struct ssb_state *st = this_cpu_ptr(&ssb_state); unsigned int this_cpu = smp_processor_id(); unsigned int cpu; st->local_state = 0; /* * Shared state setup happens once on the first bringup * of the CPU. It's not destroyed on CPU hotunplug. */ if (st->shared_state) return; raw_spin_lock_init(&st->lock); /* * Go over HT siblings and check whether one of them has set up the * shared state pointer already. */ for_each_cpu(cpu, topology_sibling_cpumask(this_cpu)) { if (cpu == this_cpu) continue; if (!per_cpu(ssb_state, cpu).shared_state) continue; /* Link it to the state of the sibling: */ st->shared_state = per_cpu(ssb_state, cpu).shared_state; return; } /* * First HT sibling to come up on the core. Link shared state of * the first HT sibling to itself. The siblings on the same core * which come up later will see the shared state pointer and link * themself to the state of this CPU. */ st->shared_state = st; } /* * Logic is: First HT sibling enables SSBD for both siblings in the core * and last sibling to disable it, disables it for the whole core. This how * MSR_SPEC_CTRL works in "hardware": * * CORE_SPEC_CTRL = THREAD0_SPEC_CTRL | THREAD1_SPEC_CTRL */ static __always_inline void amd_set_core_ssb_state(unsigned long tifn) { struct ssb_state *st = this_cpu_ptr(&ssb_state); u64 msr = x86_amd_ls_cfg_base; if (!static_cpu_has(X86_FEATURE_ZEN)) { msr |= ssbd_tif_to_amd_ls_cfg(tifn); wrmsrl(MSR_AMD64_LS_CFG, msr); return; } if (tifn & _TIF_SSBD) { /* * Since this can race with prctl(), block reentry on the * same CPU. */ if (__test_and_set_bit(LSTATE_SSB, &st->local_state)) return; msr |= x86_amd_ls_cfg_ssbd_mask; raw_spin_lock(&st->shared_state->lock); /* First sibling enables SSBD: */ if (!st->shared_state->disable_state) wrmsrl(MSR_AMD64_LS_CFG, msr); st->shared_state->disable_state++; raw_spin_unlock(&st->shared_state->lock); } else { if (!__test_and_clear_bit(LSTATE_SSB, &st->local_state)) return; raw_spin_lock(&st->shared_state->lock); st->shared_state->disable_state--; if (!st->shared_state->disable_state) wrmsrl(MSR_AMD64_LS_CFG, msr); raw_spin_unlock(&st->shared_state->lock); } } #else static __always_inline void amd_set_core_ssb_state(unsigned long tifn) { u64 msr = x86_amd_ls_cfg_base | ssbd_tif_to_amd_ls_cfg(tifn); wrmsrl(MSR_AMD64_LS_CFG, msr); } #endif static __always_inline void amd_set_ssb_virt_state(unsigned long tifn) { /* * SSBD has the same definition in SPEC_CTRL and VIRT_SPEC_CTRL, * so ssbd_tif_to_spec_ctrl() just works. */ wrmsrl(MSR_AMD64_VIRT_SPEC_CTRL, ssbd_tif_to_spec_ctrl(tifn)); } /* * Update the MSRs managing speculation control, during context switch. * * tifp: Previous task's thread flags * tifn: Next task's thread flags */ static __always_inline void __speculation_ctrl_update(unsigned long tifp, unsigned long tifn) { unsigned long tif_diff = tifp ^ tifn; u64 msr = x86_spec_ctrl_base; bool updmsr = false; /* Handle change of TIF_SSBD depending on the mitigation method. */ if (static_cpu_has(X86_FEATURE_VIRT_SSBD)) { if (tif_diff & _TIF_SSBD) amd_set_ssb_virt_state(tifn); } else if (static_cpu_has(X86_FEATURE_LS_CFG_SSBD)) { if (tif_diff & _TIF_SSBD) amd_set_core_ssb_state(tifn); } else if (static_cpu_has(X86_FEATURE_SPEC_CTRL_SSBD) || static_cpu_has(X86_FEATURE_AMD_SSBD)) { updmsr |= !!(tif_diff & _TIF_SSBD); msr |= ssbd_tif_to_spec_ctrl(tifn); } /* Only evaluate TIF_SPEC_IB if conditional STIBP is enabled. */ if (IS_ENABLED(CONFIG_SMP) && static_branch_unlikely(&switch_to_cond_stibp)) { updmsr |= !!(tif_diff & _TIF_SPEC_IB); msr |= stibp_tif_to_spec_ctrl(tifn); } if (updmsr) wrmsrl(MSR_IA32_SPEC_CTRL, msr); } static unsigned long speculation_ctrl_update_tif(struct task_struct *tsk) { if (test_and_clear_tsk_thread_flag(tsk, TIF_SPEC_FORCE_UPDATE)) { if (task_spec_ssb_disable(tsk)) set_tsk_thread_flag(tsk, TIF_SSBD); else clear_tsk_thread_flag(tsk, TIF_SSBD); if (task_spec_ib_disable(tsk)) set_tsk_thread_flag(tsk, TIF_SPEC_IB); else clear_tsk_thread_flag(tsk, TIF_SPEC_IB); } /* Return the updated threadinfo flags*/ return task_thread_info(tsk)->flags; } void speculation_ctrl_update(unsigned long tif) { /* Forced update. Make sure all relevant TIF flags are different */ preempt_disable(); __speculation_ctrl_update(~tif, tif); preempt_enable(); } /* Called from seccomp/prctl update */ void speculation_ctrl_update_current(void) { preempt_disable(); speculation_ctrl_update(speculation_ctrl_update_tif(current)); preempt_enable(); } void __switch_to_xtra(struct task_struct *prev_p, struct task_struct *next_p) { struct thread_struct *prev, *next; unsigned long tifp, tifn; prev = &prev_p->thread; next = &next_p->thread; tifn = READ_ONCE(task_thread_info(next_p)->flags); tifp = READ_ONCE(task_thread_info(prev_p)->flags); switch_to_bitmap(prev, next, tifp, tifn); propagate_user_return_notify(prev_p, next_p); if ((tifp & _TIF_BLOCKSTEP || tifn & _TIF_BLOCKSTEP) && arch_has_block_step()) { unsigned long debugctl, msk; rdmsrl(MSR_IA32_DEBUGCTLMSR, debugctl); debugctl &= ~DEBUGCTLMSR_BTF; msk = tifn & _TIF_BLOCKSTEP; debugctl |= (msk >> TIF_BLOCKSTEP) << DEBUGCTLMSR_BTF_SHIFT; wrmsrl(MSR_IA32_DEBUGCTLMSR, debugctl); } if ((tifp ^ tifn) & _TIF_NOTSC) cr4_toggle_bits(X86_CR4_TSD); if (likely(!((tifp | tifn) & _TIF_SPEC_FORCE_UPDATE))) { __speculation_ctrl_update(tifp, tifn); } else { speculation_ctrl_update_tif(prev_p); tifn = speculation_ctrl_update_tif(next_p); /* Enforce MSR update to ensure consistent state */ __speculation_ctrl_update(~tifn, tifn); } } /* * Idle related variables and functions */ unsigned long boot_option_idle_override = IDLE_NO_OVERRIDE; EXPORT_SYMBOL(boot_option_idle_override); static void (*x86_idle)(void); #ifndef CONFIG_SMP static inline void play_dead(void) { BUG(); } #endif #ifdef CONFIG_X86_64 void enter_idle(void) { this_cpu_write(is_idle, 1); atomic_notifier_call_chain(&idle_notifier, IDLE_START, NULL); } static void __exit_idle(void) { if (x86_test_and_clear_bit_percpu(0, is_idle) == 0) return; atomic_notifier_call_chain(&idle_notifier, IDLE_END, NULL); } /* Called from interrupts to signify idle end */ void exit_idle(void) { /* idle loop has pid 0 */ if (current->pid) return; __exit_idle(); } #endif void arch_cpu_idle_enter(void) { local_touch_nmi(); enter_idle(); } void arch_cpu_idle_exit(void) { __exit_idle(); } void arch_cpu_idle_dead(void) { play_dead(); } /* * Called from the generic idle code. */ void arch_cpu_idle(void) { x86_idle(); } /* * We use this if we don't have any better idle routine.. */ void __cpuidle default_idle(void) { trace_cpu_idle_rcuidle(1, smp_processor_id()); safe_halt(); trace_cpu_idle_rcuidle(PWR_EVENT_EXIT, smp_processor_id()); } #ifdef CONFIG_APM_MODULE EXPORT_SYMBOL(default_idle); #endif #ifdef CONFIG_XEN bool xen_set_default_idle(void) { bool ret = !!x86_idle; x86_idle = default_idle; return ret; } #endif void stop_this_cpu(void *dummy) { local_irq_disable(); /* * Remove this CPU: */ set_cpu_online(smp_processor_id(), false); disable_local_APIC(); mcheck_cpu_clear(this_cpu_ptr(&cpu_info)); for (;;) halt(); } bool amd_e400_c1e_detected; EXPORT_SYMBOL(amd_e400_c1e_detected); static cpumask_var_t amd_e400_c1e_mask; void amd_e400_remove_cpu(int cpu) { if (amd_e400_c1e_mask != NULL) cpumask_clear_cpu(cpu, amd_e400_c1e_mask); } /* * AMD Erratum 400 aware idle routine. We check for C1E active in the interrupt * pending message MSR. If we detect C1E, then we handle it the same * way as C3 power states (local apic timer and TSC stop) */ static void amd_e400_idle(void) { if (!amd_e400_c1e_detected) { u32 lo, hi; rdmsr(MSR_K8_INT_PENDING_MSG, lo, hi); if (lo & K8_INTP_C1E_ACTIVE_MASK) { amd_e400_c1e_detected = true; if (!boot_cpu_has(X86_FEATURE_NONSTOP_TSC)) mark_tsc_unstable("TSC halt in AMD C1E"); pr_info("System has AMD C1E enabled\n"); } } if (amd_e400_c1e_detected) { int cpu = smp_processor_id(); if (!cpumask_test_cpu(cpu, amd_e400_c1e_mask)) { cpumask_set_cpu(cpu, amd_e400_c1e_mask); /* Force broadcast so ACPI can not interfere. */ tick_broadcast_force(); pr_info("Switch to broadcast mode on CPU%d\n", cpu); } tick_broadcast_enter(); default_idle(); /* * The switch back from broadcast mode needs to be * called with interrupts disabled. */ local_irq_disable(); tick_broadcast_exit(); local_irq_enable(); } else default_idle(); } /* * Intel Core2 and older machines prefer MWAIT over HALT for C1. * We can't rely on cpuidle installing MWAIT, because it will not load * on systems that support only C1 -- so the boot default must be MWAIT. * * Some AMD machines are the opposite, they depend on using HALT. * * So for default C1, which is used during boot until cpuidle loads, * use MWAIT-C1 on Intel HW that has it, else use HALT. */ static int prefer_mwait_c1_over_halt(const struct cpuinfo_x86 *c) { if (c->x86_vendor != X86_VENDOR_INTEL) return 0; if (!cpu_has(c, X86_FEATURE_MWAIT) || static_cpu_has_bug(X86_BUG_MONITOR)) return 0; return 1; } /* * MONITOR/MWAIT with no hints, used for default C1 state. This invokes MWAIT * with interrupts enabled and no flags, which is backwards compatible with the * original MWAIT implementation. */ static __cpuidle void mwait_idle(void) { if (!current_set_polling_and_test()) { trace_cpu_idle_rcuidle(1, smp_processor_id()); if (this_cpu_has(X86_BUG_CLFLUSH_MONITOR)) { mb(); /* quirk */ clflush((void *)¤t_thread_info()->flags); mb(); /* quirk */ } __monitor((void *)¤t_thread_info()->flags, 0, 0); if (!need_resched()) __sti_mwait(0, 0); else local_irq_enable(); trace_cpu_idle_rcuidle(PWR_EVENT_EXIT, smp_processor_id()); } else { local_irq_enable(); } __current_clr_polling(); } void select_idle_routine(const struct cpuinfo_x86 *c) { #ifdef CONFIG_SMP if (boot_option_idle_override == IDLE_POLL && smp_num_siblings > 1) pr_warn_once("WARNING: polling idle and HT enabled, performance may degrade\n"); #endif if (x86_idle || boot_option_idle_override == IDLE_POLL) return; if (boot_cpu_has_bug(X86_BUG_AMD_E400)) { pr_info("using AMD E400 aware idle routine\n"); x86_idle = amd_e400_idle; } else if (prefer_mwait_c1_over_halt(c)) { pr_info("using mwait in idle threads\n"); x86_idle = mwait_idle; } else x86_idle = default_idle; } void __init init_amd_e400_c1e_mask(void) { /* If we're using amd_e400_idle, we need to allocate amd_e400_c1e_mask. */ if (x86_idle == amd_e400_idle) zalloc_cpumask_var(&amd_e400_c1e_mask, GFP_KERNEL); } static int __init idle_setup(char *str) { if (!str) return -EINVAL; if (!strcmp(str, "poll")) { pr_info("using polling idle threads\n"); boot_option_idle_override = IDLE_POLL; cpu_idle_poll_ctrl(true); } else if (!strcmp(str, "halt")) { /* * When the boot option of idle=halt is added, halt is * forced to be used for CPU idle. In such case CPU C2/C3 * won't be used again. * To continue to load the CPU idle driver, don't touch * the boot_option_idle_override. */ x86_idle = default_idle; boot_option_idle_override = IDLE_HALT; } else if (!strcmp(str, "nomwait")) { /* * If the boot option of "idle=nomwait" is added, * it means that mwait will be disabled for CPU C2/C3 * states. In such case it won't touch the variable * of boot_option_idle_override. */ boot_option_idle_override = IDLE_NOMWAIT; } else return -1; return 0; } early_param("idle", idle_setup); unsigned long arch_align_stack(unsigned long sp) { if (!(current->personality & ADDR_NO_RANDOMIZE) && randomize_va_space) sp -= get_random_int() % 8192; return sp & ~0xf; } unsigned long arch_randomize_brk(struct mm_struct *mm) { return randomize_page(mm->brk, 0x02000000); } /* * Return saved PC of a blocked thread. * What is this good for? it will be always the scheduler or ret_from_fork. */ unsigned long thread_saved_pc(struct task_struct *tsk) { struct inactive_task_frame *frame = (struct inactive_task_frame *) READ_ONCE(tsk->thread.sp); return READ_ONCE_NOCHECK(frame->ret_addr); } /* * Called from fs/proc with a reference on @p to find the function * which called into schedule(). This needs to be done carefully * because the task might wake up and we might look at a stack * changing under us. */ unsigned long get_wchan(struct task_struct *p) { unsigned long start, bottom, top, sp, fp, ip, ret = 0; int count = 0; if (!p || p == current || p->state == TASK_RUNNING) return 0; if (!try_get_task_stack(p)) return 0; start = (unsigned long)task_stack_page(p); if (!start) goto out; /* * Layout of the stack page: * * ----------- topmax = start + THREAD_SIZE - sizeof(unsigned long) * PADDING * ----------- top = topmax - TOP_OF_KERNEL_STACK_PADDING * stack * ----------- bottom = start * * The tasks stack pointer points at the location where the * framepointer is stored. The data on the stack is: * ... IP FP ... IP FP * * We need to read FP and IP, so we need to adjust the upper * bound by another unsigned long. */ top = start + THREAD_SIZE - TOP_OF_KERNEL_STACK_PADDING; top -= 2 * sizeof(unsigned long); bottom = start; sp = READ_ONCE(p->thread.sp); if (sp < bottom || sp > top) goto out; fp = READ_ONCE_NOCHECK(((struct inactive_task_frame *)sp)->bp); do { if (fp < bottom || fp > top) goto out; ip = READ_ONCE_NOCHECK(*(unsigned long *)(fp + sizeof(unsigned long))); if (!in_sched_functions(ip)) { ret = ip; goto out; } fp = READ_ONCE_NOCHECK(*(unsigned long *)fp); } while (count++ < 16 && p->state != TASK_RUNNING); out: put_task_stack(p); return ret; }