kernel/locking/qspinlock.c - third_party/linux - Git at Google

 /*
  * Queued spinlock
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License as published by
  * the Free Software Foundation; either version 2 of the License, or
  * (at your option) any later version.
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  * GNU General Public License for more details.
  *
  * (C) Copyright 2013-2015 Hewlett-Packard Development Company, L.P.
  * (C) Copyright 2013-2014 Red Hat, Inc.
  * (C) Copyright 2015 Intel Corp.
  * (C) Copyright 2015 Hewlett-Packard Enterprise Development LP
  *
  * Authors: Waiman Long <waiman.long@hpe.com>
  *          Peter Zijlstra <peterz@infradead.org>
  */

 #ifndef _GEN_PV_LOCK_SLOWPATH

 #include <linux/smp.h>
 #include <linux/bug.h>
 #include <linux/cpumask.h>
 #include <linux/percpu.h>
 #include <linux/hardirq.h>
 #include <linux/mutex.h>
 #include <asm/byteorder.h>
 #include <asm/qspinlock.h>

 /*
  * The basic principle of a queue-based spinlock can best be understood
  * by studying a classic queue-based spinlock implementation called the
  * MCS lock. The paper below provides a good description for this kind
  * of lock.
  *
  * http://www.cise.ufl.edu/tr/DOC/REP-1992-71.pdf
  *
  * This queued spinlock implementation is based on the MCS lock, however to make
  * it fit the 4 bytes we assume spinlock_t to be, and preserve its existing
  * API, we must modify it somehow.
  *
  * In particular; where the traditional MCS lock consists of a tail pointer
  * (8 bytes) and needs the next pointer (another 8 bytes) of its own node to
  * unlock the next pending (next->locked), we compress both these: {tail,
  * next->locked} into a single u32 value.
  *
  * Since a spinlock disables recursion of its own context and there is a limit
  * to the contexts that can nest; namely: task, softirq, hardirq, nmi. As there
  * are at most 4 nesting levels, it can be encoded by a 2-bit number. Now
  * we can encode the tail by combining the 2-bit nesting level with the cpu
  * number. With one byte for the lock value and 3 bytes for the tail, only a
  * 32-bit word is now needed. Even though we only need 1 bit for the lock,
  * we extend it to a full byte to achieve better performance for architectures
  * that support atomic byte write.
  *
  * We also change the first spinner to spin on the lock bit instead of its
  * node; whereby avoiding the need to carry a node from lock to unlock, and
  * preserving existing lock API. This also makes the unlock code simpler and
  * faster.
  *
  * N.B. The current implementation only supports architectures that allow
  *      atomic operations on smaller 8-bit and 16-bit data types.
  *
  */

 #include "mcs_spinlock.h"

 #ifdef CONFIG_PARAVIRT_SPINLOCKS
 #define MAX_NODES	8
 #else
 #define MAX_NODES	4
 #endif

 /*
  * Per-CPU queue node structures; we can never have more than 4 nested
  * contexts: task, softirq, hardirq, nmi.
  *
  * Exactly fits one 64-byte cacheline on a 64-bit architecture.
  *
  * PV doubles the storage and uses the second cacheline for PV state.
  */
 static DEFINE_PER_CPU_ALIGNED(struct mcs_spinlock, mcs_nodes[MAX_NODES]);

 /*
  * We must be able to distinguish between no-tail and the tail at 0:0,
  * therefore increment the cpu number by one.
  */

 static inline __pure u32 encode_tail(int cpu, int idx)
 {
 	u32 tail;

 #ifdef CONFIG_DEBUG_SPINLOCK
 	BUG_ON(idx > 3);
 #endif
 	tail  = (cpu + 1) << _Q_TAIL_CPU_OFFSET;
 	tail |= idx << _Q_TAIL_IDX_OFFSET; /* assume < 4 */

 	return tail;
 }

 static inline __pure struct mcs_spinlock *decode_tail(u32 tail)
 {
 	int cpu = (tail >> _Q_TAIL_CPU_OFFSET) - 1;
 	int idx = (tail &  _Q_TAIL_IDX_MASK) >> _Q_TAIL_IDX_OFFSET;

 	return per_cpu_ptr(&mcs_nodes[idx], cpu);
 }

 #define _Q_LOCKED_PENDING_MASK (_Q_LOCKED_MASK | _Q_PENDING_MASK)

 /*
  * By using the whole 2nd least significant byte for the pending bit, we
  * can allow better optimization of the lock acquisition for the pending
  * bit holder.
  *
  * This internal structure is also used by the set_locked function which
  * is not restricted to _Q_PENDING_BITS == 8.
  */
 struct __qspinlock {
 	union {
 		atomic_t val;
 #ifdef __LITTLE_ENDIAN
 		struct {
 			u8	locked;
 			u8	pending;
 		};
 		struct {
 			u16	locked_pending;
 			u16	tail;
 		};
 #else
 		struct {
 			u16	tail;
 			u16	locked_pending;
 		};
 		struct {
 			u8	reserved[2];
 			u8	pending;
 			u8	locked;
 		};
 #endif
 	};
 };

 #if _Q_PENDING_BITS == 8
 /**
  * clear_pending_set_locked - take ownership and clear the pending bit.
  * @lock: Pointer to queued spinlock structure
  *
  * *,1,0 -> *,0,1
  *
  * Lock stealing is not allowed if this function is used.
  */
 static __always_inline void clear_pending_set_locked(struct qspinlock *lock)
 {
 	struct __qspinlock *l = (void *)lock;

 	WRITE_ONCE(l->locked_pending, _Q_LOCKED_VAL);
 }

 /*
  * xchg_tail - Put in the new queue tail code word & retrieve previous one
  * @lock : Pointer to queued spinlock structure
  * @tail : The new queue tail code word
  * Return: The previous queue tail code word
  *
  * xchg(lock, tail)
  *
  * p,*,* -> n,*,* ; prev = xchg(lock, node)
  */
 static __always_inline u32 xchg_tail(struct qspinlock *lock, u32 tail)
 {
 	struct __qspinlock *l = (void *)lock;

 	/*
 	 * Use release semantics to make sure that the MCS node is properly
 	 * initialized before changing the tail code.
 	 */
 	return (u32)xchg_release(&l->tail,
 				 tail >> _Q_TAIL_OFFSET) << _Q_TAIL_OFFSET;
 }

 #else /* _Q_PENDING_BITS == 8 */

 /**
  * clear_pending_set_locked - take ownership and clear the pending bit.
  * @lock: Pointer to queued spinlock structure
  *
  * *,1,0 -> *,0,1
  */
 static __always_inline void clear_pending_set_locked(struct qspinlock *lock)
 {
 	atomic_add(-_Q_PENDING_VAL + _Q_LOCKED_VAL, &lock->val);
 }

 /**
  * xchg_tail - Put in the new queue tail code word & retrieve previous one
  * @lock : Pointer to queued spinlock structure
  * @tail : The new queue tail code word
  * Return: The previous queue tail code word
  *
  * xchg(lock, tail)
  *
  * p,*,* -> n,*,* ; prev = xchg(lock, node)
  */
 static __always_inline u32 xchg_tail(struct qspinlock *lock, u32 tail)
 {
 	u32 old, new, val = atomic_read(&lock->val);

 	for (;;) {
 		new = (val & _Q_LOCKED_PENDING_MASK) | tail;
 		/*
 		 * Use release semantics to make sure that the MCS node is
 		 * properly initialized before changing the tail code.
 		 */
 		old = atomic_cmpxchg_release(&lock->val, val, new);
 		if (old == val)
 			break;

 		val = old;
 	}
 	return old;
 }
 #endif /* _Q_PENDING_BITS == 8 */

 /**
  * set_locked - Set the lock bit and own the lock
  * @lock: Pointer to queued spinlock structure
  *
  * *,*,0 -> *,0,1
  */
 static __always_inline void set_locked(struct qspinlock *lock)
 {
 	struct __qspinlock *l = (void *)lock;

 	WRITE_ONCE(l->locked, _Q_LOCKED_VAL);
 }


 /*
  * Generate the native code for queued_spin_unlock_slowpath(); provide NOPs for
  * all the PV callbacks.
  */

 static __always_inline void __pv_init_node(struct mcs_spinlock *node) { }
 static __always_inline void __pv_wait_node(struct mcs_spinlock *node,
 					   struct mcs_spinlock *prev) { }
 static __always_inline void __pv_kick_node(struct qspinlock *lock,
 					   struct mcs_spinlock *node) { }
 static __always_inline u32  __pv_wait_head_or_lock(struct qspinlock *lock,
 						   struct mcs_spinlock *node)
 						   { return 0; }

 #define pv_enabled()		false

 #define pv_init_node		__pv_init_node
 #define pv_wait_node		__pv_wait_node
 #define pv_kick_node		__pv_kick_node
 #define pv_wait_head_or_lock	__pv_wait_head_or_lock

 #ifdef CONFIG_PARAVIRT_SPINLOCKS
 #define queued_spin_lock_slowpath	native_queued_spin_lock_slowpath
 #endif

 /*
  * Various notes on spin_is_locked() and spin_unlock_wait(), which are
  * 'interesting' functions:
  *
  * PROBLEM: some architectures have an interesting issue with atomic ACQUIRE
  * operations in that the ACQUIRE applies to the LOAD _not_ the STORE (ARM64,
  * PPC). Also qspinlock has a similar issue per construction, the setting of
  * the locked byte can be unordered acquiring the lock proper.
  *
  * This gets to be 'interesting' in the following cases, where the /should/s
  * end up false because of this issue.
  *
  *
  * CASE 1:
  *
  * So the spin_is_locked() correctness issue comes from something like:
  *
  *   CPU0				CPU1
  *
  *   global_lock();			local_lock(i)
  *     spin_lock(&G)			  spin_lock(&L[i])
  *     for (i)				  if (!spin_is_locked(&G)) {
  *       spin_unlock_wait(&L[i]);	    smp_acquire__after_ctrl_dep();
  *					    return;
  *					  }
  *					  // deal with fail
  *
  * Where it is important CPU1 sees G locked or CPU0 sees L[i] locked such
  * that there is exclusion between the two critical sections.
  *
  * The load from spin_is_locked(&G) /should/ be constrained by the ACQUIRE from
  * spin_lock(&L[i]), and similarly the load(s) from spin_unlock_wait(&L[i])
  * /should/ be constrained by the ACQUIRE from spin_lock(&G).
  *
  * Similarly, later stuff is constrained by the ACQUIRE from CTRL+RMB.
  *
  *
  * CASE 2:
  *
  * For spin_unlock_wait() there is a second correctness issue, namely:
  *
  *   CPU0				CPU1
  *
  *   flag = set;
  *   smp_mb();				spin_lock(&l)
  *   spin_unlock_wait(&l);		if (!flag)
  *					  // add to lockless list
  *					spin_unlock(&l);
  *   // iterate lockless list
  *
  * Which wants to ensure that CPU1 will stop adding bits to the list and CPU0
  * will observe the last entry on the list (if spin_unlock_wait() had ACQUIRE
  * semantics etc..)
  *
  * Where flag /should/ be ordered against the locked store of l.
  */

 /*
  * queued_spin_lock_slowpath() can (load-)ACQUIRE the lock before
  * issuing an _unordered_ store to set _Q_LOCKED_VAL.
  *
  * This means that the store can be delayed, but no later than the
  * store-release from the unlock. This means that simply observing
  * _Q_LOCKED_VAL is not sufficient to determine if the lock is acquired.
  *
  * There are two paths that can issue the unordered store:
  *
  *  (1) clear_pending_set_locked():	*,1,0 -> *,0,1
  *
  *  (2) set_locked():			t,0,0 -> t,0,1 ; t != 0
  *      atomic_cmpxchg_relaxed():	t,0,0 -> 0,0,1
  *
  * However, in both cases we have other !0 state we've set before to queue
  * ourseves:
  *
  * For (1) we have the atomic_cmpxchg_acquire() that set _Q_PENDING_VAL, our
  * load is constrained by that ACQUIRE to not pass before that, and thus must
  * observe the store.
  *
  * For (2) we have a more intersting scenario. We enqueue ourselves using
  * xchg_tail(), which ends up being a RELEASE. This in itself is not
  * sufficient, however that is followed by an smp_cond_acquire() on the same
  * word, giving a RELEASE->ACQUIRE ordering. This again constrains our load and
  * guarantees we must observe that store.
  *
  * Therefore both cases have other !0 state that is observable before the
  * unordered locked byte store comes through. This means we can use that to
  * wait for the lock store, and then wait for an unlock.
  */
 #ifndef queued_spin_unlock_wait
 void queued_spin_unlock_wait(struct qspinlock *lock)
 {
 	u32 val;

 	for (;;) {
 		val = atomic_read(&lock->val);

 		if (!val) /* not locked, we're done */
 			goto done;

 		if (val & _Q_LOCKED_MASK) /* locked, go wait for unlock */
 			break;

 		/* not locked, but pending, wait until we observe the lock */
 		cpu_relax();
 	}

 	/* any unlock is good */
 	while (atomic_read(&lock->val) & _Q_LOCKED_MASK)
 		cpu_relax();

 done:
 	smp_acquire__after_ctrl_dep();
 }
 EXPORT_SYMBOL(queued_spin_unlock_wait);
 #endif

 #endif /* _GEN_PV_LOCK_SLOWPATH */

 /**
  * queued_spin_lock_slowpath - acquire the queued spinlock
  * @lock: Pointer to queued spinlock structure
  * @val: Current value of the queued spinlock 32-bit word
  *
  * (queue tail, pending bit, lock value)
  *
  *              fast     :    slow                                  :    unlock
  *                       :                                          :
  * uncontended  (0,0,0) -:--> (0,0,1) ------------------------------:--> (*,*,0)
  *                       :       | ^--------.------.             /  :
  *                       :       v           \      \            |  :
  * pending               :    (0,1,1) +--> (0,1,0)   \           |  :
  *                       :       | ^--'              |           |  :
  *                       :       v                   |           |  :
  * uncontended           :    (n,x,y) +--> (n,0,0) --'           |  :
  *   queue               :       | ^--'                          |  :
  *                       :       v                               |  :
  * contended             :    (*,x,y) +--> (*,0,0) ---> (*,0,1) -'  :
  *   queue               :         ^--'                             :
  */
 void queued_spin_lock_slowpath(struct qspinlock *lock, u32 val)
 {
 	struct mcs_spinlock *prev, *next, *node;
 	u32 new, old, tail;
 	int idx;

 	BUILD_BUG_ON(CONFIG_NR_CPUS >= (1U << _Q_TAIL_CPU_BITS));

 	if (pv_enabled())
 		goto queue;

 	if (virt_spin_lock(lock))
 		return;

 	/*
 	 * wait for in-progress pending->locked hand-overs
 	 *
 	 * 0,1,0 -> 0,0,1
 	 */
 	if (val == _Q_PENDING_VAL) {
 		while ((val = atomic_read(&lock->val)) == _Q_PENDING_VAL)
 			cpu_relax();
 	}

 	/*
 	 * trylock || pending
 	 *
 	 * 0,0,0 -> 0,0,1 ; trylock
 	 * 0,0,1 -> 0,1,1 ; pending
 	 */
 	for (;;) {
 		/*
 		 * If we observe any contention; queue.
 		 */
 		if (val & ~_Q_LOCKED_MASK)
 			goto queue;

 		new = _Q_LOCKED_VAL;
 		if (val == new)
 			new |= _Q_PENDING_VAL;

 		/*
 		 * Acquire semantic is required here as the function may
 		 * return immediately if the lock was free.
 		 */
 		old = atomic_cmpxchg_acquire(&lock->val, val, new);
 		if (old == val)
 			break;

 		val = old;
 	}

 	/*
 	 * we won the trylock
 	 */
 	if (new == _Q_LOCKED_VAL)
 		return;

 	/*
 	 * we're pending, wait for the owner to go away.
 	 *
 	 * *,1,1 -> *,1,0
 	 *
 	 * this wait loop must be a load-acquire such that we match the
 	 * store-release that clears the locked bit and create lock
 	 * sequentiality; this is because not all clear_pending_set_locked()
 	 * implementations imply full barriers.
 	 */
 	smp_cond_load_acquire(&lock->val.counter, !(VAL & _Q_LOCKED_MASK));

 	/*
 	 * take ownership and clear the pending bit.
 	 *
 	 * *,1,0 -> *,0,1
 	 */
 	clear_pending_set_locked(lock);
 	return;

 	/*
 	 * End of pending bit optimistic spinning and beginning of MCS
 	 * queuing.
 	 */
 queue:
 	node = this_cpu_ptr(&mcs_nodes[0]);
 	idx = node->count++;
 	tail = encode_tail(smp_processor_id(), idx);

 	node += idx;
 	node->locked = 0;
 	node->next = NULL;
 	pv_init_node(node);

 	/*
 	 * We touched a (possibly) cold cacheline in the per-cpu queue node;
 	 * attempt the trylock once more in the hope someone let go while we
 	 * weren't watching.
 	 */
 	if (queued_spin_trylock(lock))
 		goto release;

 	/*
 	 * We have already touched the queueing cacheline; don't bother with
 	 * pending stuff.
 	 *
 	 * p,*,* -> n,*,*
 	 *
 	 * RELEASE, such that the stores to @node must be complete.
 	 */
 	old = xchg_tail(lock, tail);
 	next = NULL;

 	/*
 	 * if there was a previous node; link it and wait until reaching the
 	 * head of the waitqueue.
 	 */
 	if (old & _Q_TAIL_MASK) {
 		prev = decode_tail(old);
 		/*
 		 * The above xchg_tail() is also a load of @lock which generates,
 		 * through decode_tail(), a pointer.
 		 *
 		 * The address dependency matches the RELEASE of xchg_tail()
 		 * such that the access to @prev must happen after.
 		 */
 		smp_read_barrier_depends();

 		WRITE_ONCE(prev->next, node);

 		pv_wait_node(node, prev);
 		arch_mcs_spin_lock_contended(&node->locked);

 		/*
 		 * While waiting for the MCS lock, the next pointer may have
 		 * been set by another lock waiter. We optimistically load
 		 * the next pointer & prefetch the cacheline for writing
 		 * to reduce latency in the upcoming MCS unlock operation.
 		 */
 		next = READ_ONCE(node->next);
 		if (next)
 			prefetchw(next);
 	}

 	/*
 	 * we're at the head of the waitqueue, wait for the owner & pending to
 	 * go away.
 	 *
 	 * *,x,y -> *,0,0
 	 *
 	 * this wait loop must use a load-acquire such that we match the
 	 * store-release that clears the locked bit and create lock
 	 * sequentiality; this is because the set_locked() function below
 	 * does not imply a full barrier.
 	 *
 	 * The PV pv_wait_head_or_lock function, if active, will acquire
 	 * the lock and return a non-zero value. So we have to skip the
 	 * smp_cond_load_acquire() call. As the next PV queue head hasn't been
 	 * designated yet, there is no way for the locked value to become
 	 * _Q_SLOW_VAL. So both the set_locked() and the
 	 * atomic_cmpxchg_relaxed() calls will be safe.
 	 *
 	 * If PV isn't active, 0 will be returned instead.
 	 *
 	 */
 	if ((val = pv_wait_head_or_lock(lock, node)))
 		goto locked;

 	val = smp_cond_load_acquire(&lock->val.counter, !(VAL & _Q_LOCKED_PENDING_MASK));

 locked:
 	/*
 	 * claim the lock:
 	 *
 	 * n,0,0 -> 0,0,1 : lock, uncontended
 	 * *,0,0 -> *,0,1 : lock, contended
 	 *
 	 * If the queue head is the only one in the queue (lock value == tail),
 	 * clear the tail code and grab the lock. Otherwise, we only need
 	 * to grab the lock.
 	 */
 	for (;;) {
 		/* In the PV case we might already have _Q_LOCKED_VAL set */
 		if ((val & _Q_TAIL_MASK) != tail) {
 			set_locked(lock);
 			break;
 		}
 		/*
 		 * The smp_cond_load_acquire() call above has provided the
 		 * necessary acquire semantics required for locking. At most
 		 * two iterations of this loop may be ran.
 		 */
 		old = atomic_cmpxchg_relaxed(&lock->val, val, _Q_LOCKED_VAL);
 		if (old == val)
 			goto release;	/* No contention */

 		val = old;
 	}

 	/*
 	 * contended path; wait for next if not observed yet, release.
 	 */
 	if (!next) {
 		while (!(next = READ_ONCE(node->next)))
 			cpu_relax();
 	}

 	arch_mcs_spin_unlock_contended(&next->locked);
 	pv_kick_node(lock, next);

 release:
 	/*
 	 * release the node
 	 */
 	__this_cpu_dec(mcs_nodes[0].count);
 }
 EXPORT_SYMBOL(queued_spin_lock_slowpath);

 /*
  * Generate the paravirt code for queued_spin_unlock_slowpath().
  */
 #if !defined(_GEN_PV_LOCK_SLOWPATH) && defined(CONFIG_PARAVIRT_SPINLOCKS)
 #define _GEN_PV_LOCK_SLOWPATH

 #undef  pv_enabled
 #define pv_enabled()	true

 #undef pv_init_node
 #undef pv_wait_node
 #undef pv_kick_node
 #undef pv_wait_head_or_lock

 #undef  queued_spin_lock_slowpath
 #define queued_spin_lock_slowpath	__pv_queued_spin_lock_slowpath

 #include "qspinlock_paravirt.h"
 #include "qspinlock.c"

 #endif
	/*
	* Queued spinlock
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License as published by
	* the Free Software Foundation; either version 2 of the License, or
	* (at your option) any later version.
	*
	* This program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	* (C) Copyright 2013-2015 Hewlett-Packard Development Company, L.P.
	* (C) Copyright 2013-2014 Red Hat, Inc.
	* (C) Copyright 2015 Intel Corp.
	* (C) Copyright 2015 Hewlett-Packard Enterprise Development LP
	*
	* Authors: Waiman Long <waiman.long@hpe.com>
	* Peter Zijlstra <peterz@infradead.org>
	*/

	#ifndef _GEN_PV_LOCK_SLOWPATH

	#include <linux/smp.h>
	#include <linux/bug.h>
	#include <linux/cpumask.h>
	#include <linux/percpu.h>
	#include <linux/hardirq.h>
	#include <linux/mutex.h>
	#include <asm/byteorder.h>
	#include <asm/qspinlock.h>

	/*
	* The basic principle of a queue-based spinlock can best be understood
	* by studying a classic queue-based spinlock implementation called the
	* MCS lock. The paper below provides a good description for this kind
	* of lock.
	*
	* http://www.cise.ufl.edu/tr/DOC/REP-1992-71.pdf
	*
	* This queued spinlock implementation is based on the MCS lock, however to make
	* it fit the 4 bytes we assume spinlock_t to be, and preserve its existing
	* API, we must modify it somehow.
	*
	* In particular; where the traditional MCS lock consists of a tail pointer
	* (8 bytes) and needs the next pointer (another 8 bytes) of its own node to
	* unlock the next pending (next->locked), we compress both these: {tail,
	* next->locked} into a single u32 value.
	*
	* Since a spinlock disables recursion of its own context and there is a limit
	* to the contexts that can nest; namely: task, softirq, hardirq, nmi. As there
	* are at most 4 nesting levels, it can be encoded by a 2-bit number. Now
	* we can encode the tail by combining the 2-bit nesting level with the cpu
	* number. With one byte for the lock value and 3 bytes for the tail, only a
	* 32-bit word is now needed. Even though we only need 1 bit for the lock,
	* we extend it to a full byte to achieve better performance for architectures
	* that support atomic byte write.
	*
	* We also change the first spinner to spin on the lock bit instead of its
	* node; whereby avoiding the need to carry a node from lock to unlock, and
	* preserving existing lock API. This also makes the unlock code simpler and
	* faster.
	*
	* N.B. The current implementation only supports architectures that allow
	* atomic operations on smaller 8-bit and 16-bit data types.
	*
	*/

	#include "mcs_spinlock.h"

	#ifdef CONFIG_PARAVIRT_SPINLOCKS
	#define MAX_NODES 8
	#else
	#define MAX_NODES 4
	#endif

	/*
	* Per-CPU queue node structures; we can never have more than 4 nested
	* contexts: task, softirq, hardirq, nmi.
	*
	* Exactly fits one 64-byte cacheline on a 64-bit architecture.
	*
	* PV doubles the storage and uses the second cacheline for PV state.
	*/
	static DEFINE_PER_CPU_ALIGNED(struct mcs_spinlock, mcs_nodes[MAX_NODES]);

	/*
	* We must be able to distinguish between no-tail and the tail at 0:0,
	* therefore increment the cpu number by one.
	*/

	static inline __pure u32 encode_tail(int cpu, int idx)
	{
	u32 tail;

	#ifdef CONFIG_DEBUG_SPINLOCK
	BUG_ON(idx > 3);
	#endif
	tail = (cpu + 1) << _Q_TAIL_CPU_OFFSET;
	tail \|= idx << _Q_TAIL_IDX_OFFSET; /* assume < 4 */

	return tail;
	}

	static inline __pure struct mcs_spinlock *decode_tail(u32 tail)
	{
	int cpu = (tail >> _Q_TAIL_CPU_OFFSET) - 1;
	int idx = (tail & _Q_TAIL_IDX_MASK) >> _Q_TAIL_IDX_OFFSET;

	return per_cpu_ptr(&mcs_nodes[idx], cpu);
	}

	#define _Q_LOCKED_PENDING_MASK (_Q_LOCKED_MASK \| _Q_PENDING_MASK)

	/*
	* By using the whole 2nd least significant byte for the pending bit, we
	* can allow better optimization of the lock acquisition for the pending
	* bit holder.
	*
	* This internal structure is also used by the set_locked function which
	* is not restricted to _Q_PENDING_BITS == 8.
	*/
	struct __qspinlock {
	union {
	atomic_t val;
	#ifdef __LITTLE_ENDIAN
	struct {
	u8 locked;
	u8 pending;
	};
	struct {
	u16 locked_pending;
	u16 tail;
	};
	#else
	struct {
	u16 tail;
	u16 locked_pending;
	};
	struct {
	u8 reserved[2];
	u8 pending;
	u8 locked;
	};
	#endif
	};
	};

	#if _Q_PENDING_BITS == 8
	/**
	* clear_pending_set_locked - take ownership and clear the pending bit.
	* @lock: Pointer to queued spinlock structure
	*
	* ,1,0 -> ,0,1
	*
	* Lock stealing is not allowed if this function is used.
	*/
	static __always_inline void clear_pending_set_locked(struct qspinlock *lock)
	{
	struct __qspinlock l = (void )lock;

	WRITE_ONCE(l->locked_pending, _Q_LOCKED_VAL);
	}

	/*
	* xchg_tail - Put in the new queue tail code word & retrieve previous one
	* @lock : Pointer to queued spinlock structure
	* @tail : The new queue tail code word
	* Return: The previous queue tail code word
	*
	* xchg(lock, tail)
	*
	* p,, -> n,, ; prev = xchg(lock, node)
	*/
	static __always_inline u32 xchg_tail(struct qspinlock *lock, u32 tail)
	{
	struct __qspinlock l = (void )lock;

	/*
	* Use release semantics to make sure that the MCS node is properly
	* initialized before changing the tail code.
	*/
	return (u32)xchg_release(&l->tail,
	tail >> _Q_TAIL_OFFSET) << _Q_TAIL_OFFSET;
	}

	#else /* _Q_PENDING_BITS == 8 */

	/**
	* clear_pending_set_locked - take ownership and clear the pending bit.
	* @lock: Pointer to queued spinlock structure
	*
	* ,1,0 -> ,0,1
	*/
	static __always_inline void clear_pending_set_locked(struct qspinlock *lock)
	{
	atomic_add(-_Q_PENDING_VAL + _Q_LOCKED_VAL, &lock->val);
	}

	/**
	* xchg_tail - Put in the new queue tail code word & retrieve previous one
	* @lock : Pointer to queued spinlock structure
	* @tail : The new queue tail code word
	* Return: The previous queue tail code word
	*
	* xchg(lock, tail)
	*
	* p,, -> n,, ; prev = xchg(lock, node)
	*/
	static __always_inline u32 xchg_tail(struct qspinlock *lock, u32 tail)
	{
	u32 old, new, val = atomic_read(&lock->val);

	for (;;) {
	new = (val & _Q_LOCKED_PENDING_MASK) \| tail;
	/*
	* Use release semantics to make sure that the MCS node is
	* properly initialized before changing the tail code.
	*/
	old = atomic_cmpxchg_release(&lock->val, val, new);
	if (old == val)
	break;

	val = old;
	}
	return old;
	}
	#endif /* _Q_PENDING_BITS == 8 */

	/**
	* set_locked - Set the lock bit and own the lock
	* @lock: Pointer to queued spinlock structure
	*
	* ,,0 -> *,0,1
	*/
	static __always_inline void set_locked(struct qspinlock *lock)
	{
	struct __qspinlock l = (void )lock;

	WRITE_ONCE(l->locked, _Q_LOCKED_VAL);
	}


	/*
	* Generate the native code for queued_spin_unlock_slowpath(); provide NOPs for
	* all the PV callbacks.
	*/

	static __always_inline void __pv_init_node(struct mcs_spinlock *node) { }
	static __always_inline void __pv_wait_node(struct mcs_spinlock *node,
	struct mcs_spinlock *prev) { }
	static __always_inline void __pv_kick_node(struct qspinlock *lock,
	struct mcs_spinlock *node) { }
	static __always_inline u32 __pv_wait_head_or_lock(struct qspinlock *lock,
	struct mcs_spinlock *node)
	{ return 0; }

	#define pv_enabled() false

	#define pv_init_node __pv_init_node
	#define pv_wait_node __pv_wait_node
	#define pv_kick_node __pv_kick_node
	#define pv_wait_head_or_lock __pv_wait_head_or_lock

	#ifdef CONFIG_PARAVIRT_SPINLOCKS
	#define queued_spin_lock_slowpath native_queued_spin_lock_slowpath
	#endif

	/*
	* Various notes on spin_is_locked() and spin_unlock_wait(), which are
	* 'interesting' functions:
	*
	* PROBLEM: some architectures have an interesting issue with atomic ACQUIRE
	* operations in that the ACQUIRE applies to the LOAD _not_ the STORE (ARM64,
	* PPC). Also qspinlock has a similar issue per construction, the setting of
	* the locked byte can be unordered acquiring the lock proper.
	*
	* This gets to be 'interesting' in the following cases, where the /should/s
	* end up false because of this issue.
	*
	*
	* CASE 1:
	*
	* So the spin_is_locked() correctness issue comes from something like:
	*
	* CPU0 CPU1
	*
	* global_lock(); local_lock(i)
	* spin_lock(&G) spin_lock(&L[i])
	* for (i) if (!spin_is_locked(&G)) {
	* spin_unlock_wait(&L[i]); smp_acquire__after_ctrl_dep();
	* return;
	* }
	* // deal with fail
	*
	* Where it is important CPU1 sees G locked or CPU0 sees L[i] locked such
	* that there is exclusion between the two critical sections.
	*
	* The load from spin_is_locked(&G) /should/ be constrained by the ACQUIRE from
	* spin_lock(&L[i]), and similarly the load(s) from spin_unlock_wait(&L[i])
	* /should/ be constrained by the ACQUIRE from spin_lock(&G).
	*
	* Similarly, later stuff is constrained by the ACQUIRE from CTRL+RMB.
	*
	*
	* CASE 2:
	*
	* For spin_unlock_wait() there is a second correctness issue, namely:
	*
	* CPU0 CPU1
	*
	* flag = set;
	* smp_mb(); spin_lock(&l)
	* spin_unlock_wait(&l); if (!flag)
	* // add to lockless list
	* spin_unlock(&l);
	* // iterate lockless list
	*
	* Which wants to ensure that CPU1 will stop adding bits to the list and CPU0
	* will observe the last entry on the list (if spin_unlock_wait() had ACQUIRE
	* semantics etc..)
	*
	* Where flag /should/ be ordered against the locked store of l.
	*/

	/*
	* queued_spin_lock_slowpath() can (load-)ACQUIRE the lock before
	* issuing an _unordered_ store to set _Q_LOCKED_VAL.
	*
	* This means that the store can be delayed, but no later than the
	* store-release from the unlock. This means that simply observing
	* _Q_LOCKED_VAL is not sufficient to determine if the lock is acquired.
	*
	* There are two paths that can issue the unordered store:
	*
	* (1) clear_pending_set_locked(): ,1,0 -> ,0,1
	*
	* (2) set_locked(): t,0,0 -> t,0,1 ; t != 0
	* atomic_cmpxchg_relaxed(): t,0,0 -> 0,0,1
	*
	* However, in both cases we have other !0 state we've set before to queue
	* ourseves:
	*
	* For (1) we have the atomic_cmpxchg_acquire() that set _Q_PENDING_VAL, our
	* load is constrained by that ACQUIRE to not pass before that, and thus must
	* observe the store.
	*
	* For (2) we have a more intersting scenario. We enqueue ourselves using
	* xchg_tail(), which ends up being a RELEASE. This in itself is not
	* sufficient, however that is followed by an smp_cond_acquire() on the same
	* word, giving a RELEASE->ACQUIRE ordering. This again constrains our load and
	* guarantees we must observe that store.
	*
	* Therefore both cases have other !0 state that is observable before the
	* unordered locked byte store comes through. This means we can use that to
	* wait for the lock store, and then wait for an unlock.
	*/
	#ifndef queued_spin_unlock_wait
	void queued_spin_unlock_wait(struct qspinlock *lock)
	{
	u32 val;

	for (;;) {
	val = atomic_read(&lock->val);

	if (!val) /* not locked, we're done */
	goto done;

	if (val & _Q_LOCKED_MASK) /* locked, go wait for unlock */
	break;

	/* not locked, but pending, wait until we observe the lock */
	cpu_relax();
	}

	/* any unlock is good */
	while (atomic_read(&lock->val) & _Q_LOCKED_MASK)
	cpu_relax();

	done:
	smp_acquire__after_ctrl_dep();
	}
	EXPORT_SYMBOL(queued_spin_unlock_wait);
	#endif

	#endif /* _GEN_PV_LOCK_SLOWPATH */

	/**
	* queued_spin_lock_slowpath - acquire the queued spinlock
	* @lock: Pointer to queued spinlock structure
	* @val: Current value of the queued spinlock 32-bit word
	*
	* (queue tail, pending bit, lock value)
	*
	* fast : slow : unlock
	* : :
	* uncontended (0,0,0) -:--> (0,0,1) ------------------------------:--> (,,0)
	* : \| ^--------.------. / :
	* : v \ \ \| :
	* pending : (0,1,1) +--> (0,1,0) \ \| :
	* : \| ^--' \| \| :
	* : v \| \| :
	* uncontended : (n,x,y) +--> (n,0,0) --' \| :
	* queue : \| ^--' \| :
	* : v \| :
	* contended : (,x,y) +--> (,0,0) ---> (*,0,1) -' :
	* queue : ^--' :
	*/
	void queued_spin_lock_slowpath(struct qspinlock *lock, u32 val)
	{
	struct mcs_spinlock prev, next, *node;
	u32 new, old, tail;
	int idx;

	BUILD_BUG_ON(CONFIG_NR_CPUS >= (1U << _Q_TAIL_CPU_BITS));

	if (pv_enabled())
	goto queue;

	if (virt_spin_lock(lock))
	return;

	/*
	* wait for in-progress pending->locked hand-overs
	*
	* 0,1,0 -> 0,0,1
	*/
	if (val == _Q_PENDING_VAL) {
	while ((val = atomic_read(&lock->val)) == _Q_PENDING_VAL)
	cpu_relax();
	}

	/*
	* trylock \|\| pending
	*
	* 0,0,0 -> 0,0,1 ; trylock
	* 0,0,1 -> 0,1,1 ; pending
	*/
	for (;;) {
	/*
	* If we observe any contention; queue.
	*/
	if (val & ~_Q_LOCKED_MASK)
	goto queue;

	new = _Q_LOCKED_VAL;
	if (val == new)
	new \|= _Q_PENDING_VAL;

	/*
	* Acquire semantic is required here as the function may
	* return immediately if the lock was free.
	*/
	old = atomic_cmpxchg_acquire(&lock->val, val, new);
	if (old == val)
	break;

	val = old;
	}

	/*
	* we won the trylock
	*/
	if (new == _Q_LOCKED_VAL)
	return;

	/*
	* we're pending, wait for the owner to go away.
	*
	* ,1,1 -> ,1,0
	*
	* this wait loop must be a load-acquire such that we match the
	* store-release that clears the locked bit and create lock
	* sequentiality; this is because not all clear_pending_set_locked()
	* implementations imply full barriers.
	*/
	smp_cond_load_acquire(&lock->val.counter, !(VAL & _Q_LOCKED_MASK));

	/*
	* take ownership and clear the pending bit.
	*
	* ,1,0 -> ,0,1
	*/
	clear_pending_set_locked(lock);
	return;

	/*
	* End of pending bit optimistic spinning and beginning of MCS
	* queuing.
	*/
	queue:
	node = this_cpu_ptr(&mcs_nodes[0]);
	idx = node->count++;
	tail = encode_tail(smp_processor_id(), idx);

	node += idx;
	node->locked = 0;
	node->next = NULL;
	pv_init_node(node);

	/*
	* We touched a (possibly) cold cacheline in the per-cpu queue node;
	* attempt the trylock once more in the hope someone let go while we
	* weren't watching.
	*/
	if (queued_spin_trylock(lock))
	goto release;

	/*
	* We have already touched the queueing cacheline; don't bother with
	* pending stuff.
	*
	* p,, -> n,,
	*
	* RELEASE, such that the stores to @node must be complete.
	*/
	old = xchg_tail(lock, tail);
	next = NULL;

	/*
	* if there was a previous node; link it and wait until reaching the
	* head of the waitqueue.
	*/
	if (old & _Q_TAIL_MASK) {
	prev = decode_tail(old);
	/*
	* The above xchg_tail() is also a load of @lock which generates,
	* through decode_tail(), a pointer.
	*
	* The address dependency matches the RELEASE of xchg_tail()
	* such that the access to @prev must happen after.
	*/
	smp_read_barrier_depends();

	WRITE_ONCE(prev->next, node);

	pv_wait_node(node, prev);
	arch_mcs_spin_lock_contended(&node->locked);

	/*
	* While waiting for the MCS lock, the next pointer may have
	* been set by another lock waiter. We optimistically load
	* the next pointer & prefetch the cacheline for writing
	* to reduce latency in the upcoming MCS unlock operation.
	*/
	next = READ_ONCE(node->next);
	if (next)
	prefetchw(next);
	}

	/*
	* we're at the head of the waitqueue, wait for the owner & pending to
	* go away.
	*
	* ,x,y -> ,0,0
	*
	* this wait loop must use a load-acquire such that we match the
	* store-release that clears the locked bit and create lock
	* sequentiality; this is because the set_locked() function below
	* does not imply a full barrier.
	*
	* The PV pv_wait_head_or_lock function, if active, will acquire
	* the lock and return a non-zero value. So we have to skip the
	* smp_cond_load_acquire() call. As the next PV queue head hasn't been
	* designated yet, there is no way for the locked value to become
	* _Q_SLOW_VAL. So both the set_locked() and the
	* atomic_cmpxchg_relaxed() calls will be safe.
	*
	* If PV isn't active, 0 will be returned instead.
	*
	*/
	if ((val = pv_wait_head_or_lock(lock, node)))
	goto locked;

	val = smp_cond_load_acquire(&lock->val.counter, !(VAL & _Q_LOCKED_PENDING_MASK));

	locked:
	/*
	* claim the lock:
	*
	* n,0,0 -> 0,0,1 : lock, uncontended
	* ,0,0 -> ,0,1 : lock, contended
	*
	* If the queue head is the only one in the queue (lock value == tail),
	* clear the tail code and grab the lock. Otherwise, we only need
	* to grab the lock.
	*/
	for (;;) {
	/* In the PV case we might already have _Q_LOCKED_VAL set */
	if ((val & _Q_TAIL_MASK) != tail) {
	set_locked(lock);
	break;
	}
	/*
	* The smp_cond_load_acquire() call above has provided the
	* necessary acquire semantics required for locking. At most
	* two iterations of this loop may be ran.
	*/
	old = atomic_cmpxchg_relaxed(&lock->val, val, _Q_LOCKED_VAL);
	if (old == val)
	goto release; /* No contention */

	val = old;
	}

	/*
	* contended path; wait for next if not observed yet, release.
	*/
	if (!next) {
	while (!(next = READ_ONCE(node->next)))
	cpu_relax();
	}

	arch_mcs_spin_unlock_contended(&next->locked);
	pv_kick_node(lock, next);

	release:
	/*
	* release the node
	*/
	__this_cpu_dec(mcs_nodes[0].count);
	}
	EXPORT_SYMBOL(queued_spin_lock_slowpath);

	/*
	* Generate the paravirt code for queued_spin_unlock_slowpath().
	*/
	#if !defined(_GEN_PV_LOCK_SLOWPATH) && defined(CONFIG_PARAVIRT_SPINLOCKS)
	#define _GEN_PV_LOCK_SLOWPATH

	#undef pv_enabled
	#define pv_enabled() true

	#undef pv_init_node
	#undef pv_wait_node
	#undef pv_kick_node
	#undef pv_wait_head_or_lock

	#undef queued_spin_lock_slowpath
	#define queued_spin_lock_slowpath __pv_queued_spin_lock_slowpath

	#include "qspinlock_paravirt.h"
	#include "qspinlock.c"

	#endif