windows-nt/Source/XPSP1/NT/net/rras/ip/wanarp2/rwlock.h
2020-09-26 16:20:57 +08:00

157 lines
4.3 KiB
C

/*++
Copyright (c) 1991 Microsoft Corporation
Module Name:
tcpip\ip\ipmlock.h
Abstract:
Reader Writer lock primitives for the IP Multicasting
Author:
Amritansh Raghav
Revision History:
AmritanR Created
Notes:
--*/
//
// Need to include "debug.h" before this file is included because
// RT_LOCK is defined there
//
//
// A reader writer lock for kernel mode.
//
typedef struct _RW_LOCK
{
RT_LOCK rlReadLock;
RT_LOCK rlWriteLock;
LONG lReaderCount;
}RW_LOCK, *PRW_LOCK;
//
// VOID
// InitRwLock(
// PRW_LOCK pLock
// )
//
// Initializes the spin locks and the reader count
//
#define InitRwLock(l) \
RtInitializeSpinLock(&((l)->rlReadLock)); \
RtInitializeSpinLock(&((l)->rlWriteLock)); \
(l)->lReaderCount = 0
//
// VOID
// EnterReader(
// PRW_LOCK pLock,
// PKIRQL pCurrIrql
// )
//
// Acquires the Reader Spinlock (now thread is at DPC).
// InterlockedIncrements the reader count (interlocked because the reader
// lock is not taken when the count is decremented in ExitReader())
// If the thread is the first reader, also acquires the Writer Spinlock (at
// DPC to be more efficient) to block writers
// Releases the Reader Spinlock from DPC, so that it remains at DPC
// for the duration of the lock being held
//
// If a writer is in the code, the first reader will wait on the Writer
// Spinlock and all subsequent readers will wait on the Reader Spinlock
// If a reader is in the code and is executing the EnterReader, then a new
// reader will wait for sometime on the Reader Spinlock, and then proceed
// on to the code (at DPC)
//
#define EnterReader(l, q) \
RtAcquireSpinLock(&((l)->rlReadLock), (q)); \
if(InterlockedIncrement(&((l)->lReaderCount)) == 1) \
RtAcquireSpinLockAtDpcLevel(&((l)->rlWriteLock)); \
RtReleaseSpinLockFromDpcLevel(&((l)->rlReadLock))
#define EnterReaderAtDpcLevel(l) \
RtAcquireSpinLockAtDpcLevel(&((l)->rlReadLock)); \
if(InterlockedIncrement(&((l)->lReaderCount)) == 1) \
RtAcquireSpinLockAtDpcLevel(&((l)->rlWriteLock)); \
RtReleaseSpinLockFromDpcLevel(&((l)->rlReadLock))
//
// VOID
// ExitReader(
// PRW_LOCK pLock,
// KIRQL kiOldIrql
// )
//
// InterlockedDec the reader count.
// If this is the last reader, then release the Writer Spinlock to let
// other writers in
// Otherwise, just lower the irql to what was before the lock was
// acquired. Either way, the irql is down to original irql
//
#define ExitReader(l, q) \
if(InterlockedDecrement(&((l)->lReaderCount)) == 0) \
RtReleaseSpinLock(&((l)->rlWriteLock), q); \
else \
KeLowerIrql(q)
#define ExitReaderFromDpcLevel(l) \
if(InterlockedDecrement(&((l)->lReaderCount)) == 0) \
RtReleaseSpinLockFromDpcLevel(&((l)->rlWriteLock))
//
// EnterWriter(
// PRW_LOCK pLock,
// PKIRQL pCurrIrql
// )
//
// Acquire the reader and then the writer spin lock
// If there are readers in the code, the first writer will wait
// on the Writer Spinlock. All other writers will wait (with readers)
// on the Reader Spinlock
// If there is a writer in the code then a new writer will wait on
// the Reader Spinlock
#define EnterWriter(l, q) \
RtAcquireSpinLock(&((l)->rlReadLock), (q)); \
RtAcquireSpinLockAtDpcLevel(&((l)->rlWriteLock))
#define EnterWriterAtDpcLevel(l) \
RtAcquireSpinLockAtDpcLevel(&((l)->rlReadLock)); \
RtAcquireSpinLockAtDpcLevel(&((l)->rlWriteLock))
//
// ExitWriter(
// PRW_LOCK pLock,
// KIRQL kiOldIrql
// )
//
// Release both the locks
//
#define ExitWriter(l, q) \
RtReleaseSpinLockFromDpcLevel(&((l)->rlWriteLock)); \
RtReleaseSpinLock(&((l)->rlReadLock), q)
#define ExitWriterFromDpcLevel(l) \
RtReleaseSpinLockFromDpcLevel(&((l)->rlWriteLock)); \
RtReleaseSpinLockFromDpcLevel(&((l)->rlReadLock))