arch/powerpc/include/asm/paravirt.h - third_party/kernel - Git at Google

 /* SPDX-License-Identifier: GPL-2.0-or-later */
 #ifndef _ASM_POWERPC_PARAVIRT_H
 #define _ASM_POWERPC_PARAVIRT_H

 #include <linux/jump_label.h>
 #include <asm/smp.h>
 #ifdef CONFIG_PPC64
 #include <asm/paca.h>
 #include <asm/lppaca.h>
 #include <asm/hvcall.h>
 #endif

 #ifdef CONFIG_PPC_SPLPAR
 #include <linux/smp.h>
 #include <asm/kvm_guest.h>
 #include <asm/cputhreads.h>

 DECLARE_STATIC_KEY_FALSE(shared_processor);

 static inline bool is_shared_processor(void)
 {
 	return static_branch_unlikely(&shared_processor);
 }

 /* If bit 0 is set, the cpu has been preempted */
 static inline u32 yield_count_of(int cpu)
 {
 	__be32 yield_count = READ_ONCE(lppaca_of(cpu).yield_count);
 	return be32_to_cpu(yield_count);
 }

 /*
  * Spinlock code confers and prods, so don't trace the hcalls because the
  * tracing code takes spinlocks which can cause recursion deadlocks.
  *
  * These calls are made while the lock is not held: the lock slowpath yields if
  * it can not acquire the lock, and unlock slow path might prod if a waiter has
  * yielded). So this may not be a problem for simple spin locks because the
  * tracing does not technically recurse on the lock, but we avoid it anyway.
  *
  * However the queued spin lock contended path is more strictly ordered: the
  * H_CONFER hcall is made after the task has queued itself on the lock, so then
  * recursing on that lock will cause the task to then queue up again behind the
  * first instance (or worse: queued spinlocks use tricks that assume a context
  * never waits on more than one spinlock, so such recursion may cause random
  * corruption in the lock code).
  */
 static inline void yield_to_preempted(int cpu, u32 yield_count)
 {
 	plpar_hcall_norets_notrace(H_CONFER, get_hard_smp_processor_id(cpu), yield_count);
 }

 static inline void prod_cpu(int cpu)
 {
 	plpar_hcall_norets_notrace(H_PROD, get_hard_smp_processor_id(cpu));
 }

 static inline void yield_to_any(void)
 {
 	plpar_hcall_norets_notrace(H_CONFER, -1, 0);
 }
 #else
 static inline bool is_shared_processor(void)
 {
 	return false;
 }

 static inline u32 yield_count_of(int cpu)
 {
 	return 0;
 }

 extern void ___bad_yield_to_preempted(void);
 static inline void yield_to_preempted(int cpu, u32 yield_count)
 {
 	___bad_yield_to_preempted(); /* This would be a bug */
 }

 extern void ___bad_yield_to_any(void);
 static inline void yield_to_any(void)
 {
 	___bad_yield_to_any(); /* This would be a bug */
 }

 extern void ___bad_prod_cpu(void);
 static inline void prod_cpu(int cpu)
 {
 	___bad_prod_cpu(); /* This would be a bug */
 }

 #endif

 #define vcpu_is_preempted vcpu_is_preempted
 static inline bool vcpu_is_preempted(int cpu)
 {
 	if (!is_shared_processor())
 		return false;

 #ifdef CONFIG_PPC_SPLPAR
 	if (!is_kvm_guest()) {
 		int first_cpu;

 		/*
 		 * The result of vcpu_is_preempted() is used in a
 		 * speculative way, and is always subject to invalidation
 		 * by events internal and external to Linux. While we can
 		 * be called in preemptable context (in the Linux sense),
 		 * we're not accessing per-cpu resources in a way that can
 		 * race destructively with Linux scheduler preemption and
 		 * migration, and callers can tolerate the potential for
 		 * error introduced by sampling the CPU index without
 		 * pinning the task to it. So it is permissible to use
 		 * raw_smp_processor_id() here to defeat the preempt debug
 		 * warnings that can arise from using smp_processor_id()
 		 * in arbitrary contexts.
 		 */
 		first_cpu = cpu_first_thread_sibling(raw_smp_processor_id());

 		/*
 		 * Preemption can only happen at core granularity. This CPU
 		 * is not preempted if one of the CPU of this core is not
 		 * preempted.
 		 */
 		if (cpu_first_thread_sibling(cpu) == first_cpu)
 			return false;
 	}
 #endif

 	if (yield_count_of(cpu) & 1)
 		return true;
 	return false;
 }

 static inline bool pv_is_native_spin_unlock(void)
 {
 	return !is_shared_processor();
 }

 #endif /* _ASM_POWERPC_PARAVIRT_H */
	/* SPDX-License-Identifier: GPL-2.0-or-later */
	#ifndef _ASM_POWERPC_PARAVIRT_H
	#define _ASM_POWERPC_PARAVIRT_H

	#include <linux/jump_label.h>
	#include <asm/smp.h>
	#ifdef CONFIG_PPC64
	#include <asm/paca.h>
	#include <asm/lppaca.h>
	#include <asm/hvcall.h>
	#endif

	#ifdef CONFIG_PPC_SPLPAR
	#include <linux/smp.h>
	#include <asm/kvm_guest.h>
	#include <asm/cputhreads.h>

	DECLARE_STATIC_KEY_FALSE(shared_processor);

	static inline bool is_shared_processor(void)
	{
	return static_branch_unlikely(&shared_processor);
	}

	/* If bit 0 is set, the cpu has been preempted */
	static inline u32 yield_count_of(int cpu)
	{
	__be32 yield_count = READ_ONCE(lppaca_of(cpu).yield_count);
	return be32_to_cpu(yield_count);
	}

	/*
	* Spinlock code confers and prods, so don't trace the hcalls because the
	* tracing code takes spinlocks which can cause recursion deadlocks.
	*
	* These calls are made while the lock is not held: the lock slowpath yields if
	* it can not acquire the lock, and unlock slow path might prod if a waiter has
	* yielded). So this may not be a problem for simple spin locks because the
	* tracing does not technically recurse on the lock, but we avoid it anyway.
	*
	* However the queued spin lock contended path is more strictly ordered: the
	* H_CONFER hcall is made after the task has queued itself on the lock, so then
	* recursing on that lock will cause the task to then queue up again behind the
	* first instance (or worse: queued spinlocks use tricks that assume a context
	* never waits on more than one spinlock, so such recursion may cause random
	* corruption in the lock code).
	*/
	static inline void yield_to_preempted(int cpu, u32 yield_count)
	{
	plpar_hcall_norets_notrace(H_CONFER, get_hard_smp_processor_id(cpu), yield_count);
	}

	static inline void prod_cpu(int cpu)
	{
	plpar_hcall_norets_notrace(H_PROD, get_hard_smp_processor_id(cpu));
	}

	static inline void yield_to_any(void)
	{
	plpar_hcall_norets_notrace(H_CONFER, -1, 0);
	}
	#else
	static inline bool is_shared_processor(void)
	{
	return false;
	}

	static inline u32 yield_count_of(int cpu)
	{
	return 0;
	}

	extern void ___bad_yield_to_preempted(void);
	static inline void yield_to_preempted(int cpu, u32 yield_count)
	{
	___bad_yield_to_preempted(); /* This would be a bug */
	}

	extern void ___bad_yield_to_any(void);
	static inline void yield_to_any(void)
	{
	___bad_yield_to_any(); /* This would be a bug */
	}

	extern void ___bad_prod_cpu(void);
	static inline void prod_cpu(int cpu)
	{
	___bad_prod_cpu(); /* This would be a bug */
	}

	#endif

	#define vcpu_is_preempted vcpu_is_preempted
	static inline bool vcpu_is_preempted(int cpu)
	{
	if (!is_shared_processor())
	return false;

	#ifdef CONFIG_PPC_SPLPAR
	if (!is_kvm_guest()) {
	int first_cpu;

	/*
	* The result of vcpu_is_preempted() is used in a
	* speculative way, and is always subject to invalidation
	* by events internal and external to Linux. While we can
	* be called in preemptable context (in the Linux sense),
	* we're not accessing per-cpu resources in a way that can
	* race destructively with Linux scheduler preemption and
	* migration, and callers can tolerate the potential for
	* error introduced by sampling the CPU index without
	* pinning the task to it. So it is permissible to use
	* raw_smp_processor_id() here to defeat the preempt debug
	* warnings that can arise from using smp_processor_id()
	* in arbitrary contexts.
	*/
	first_cpu = cpu_first_thread_sibling(raw_smp_processor_id());

	/*
	* Preemption can only happen at core granularity. This CPU
	* is not preempted if one of the CPU of this core is not
	* preempted.
	*/
	if (cpu_first_thread_sibling(cpu) == first_cpu)
	return false;
	}
	#endif

	if (yield_count_of(cpu) & 1)
	return true;
	return false;
	}

	static inline bool pv_is_native_spin_unlock(void)
	{
	return !is_shared_processor();
	}

	#endif /* _ASM_POWERPC_PARAVIRT_H */