Windows-Server-2003/net/rras/ip/sample/sync.c

/*++

Copyright (c) 1999, Microsoft Corporation

Module Name:

    sample\sync.h

Abstract:

    The file contains the READ_WRITE_LOCK definition which allows
    multiple-reader/single-writer.  This implementation DOES NOT
    starve a thread trying to acquire write accesss if there are
    a large number of threads interested in acquiring read access.

--*/

#include "pchsample.h"
#pragma hdrstop

//----------------------------------------------------------------------------
// Function: CreateReadWriteLock
//
// Initializes a multiple-reader/single-writer lock object
//----------------------------------------------------------------------------

DWORD
CreateReadWriteLock(
    PREAD_WRITE_LOCK pRWL
    ) {

    pRWL->RWL_ReaderCount = 0;

    __try {
        InitializeCriticalSection(&(pRWL)->RWL_ReadWriteBlock);
    }
    __except(EXCEPTION_EXECUTE_HANDLER) {
        return GetLastError();
    }

    pRWL->RWL_ReaderDoneEvent = CreateEvent(NULL,FALSE,FALSE,NULL);
    if (pRWL->RWL_ReaderDoneEvent != NULL) {
        return GetLastError();
    }

    return NO_ERROR;
}


//----------------------------------------------------------------------------
// Function:    DeleteReadWriteLock
//
// Frees resources used by a multiple-reader/single-writer lock object
//----------------------------------------------------------------------------

VOID
DeleteReadWriteLock(
    PREAD_WRITE_LOCK pRWL
    ) {

    CloseHandle(pRWL->RWL_ReaderDoneEvent);
    pRWL->RWL_ReaderDoneEvent = NULL;
    DeleteCriticalSection(&pRWL->RWL_ReadWriteBlock);
    pRWL->RWL_ReaderCount = 0;
}


//----------------------------------------------------------------------------
// Function:    AcquireReadLock
//
// Secures shared ownership of the lock object for the caller.
//
// readers enter the read-write critical section, increment the count,
// and leave the critical section
//----------------------------------------------------------------------------

VOID
AcquireReadLock(
    PREAD_WRITE_LOCK pRWL
    ) {

    EnterCriticalSection(&pRWL->RWL_ReadWriteBlock); 
    InterlockedIncrement(&pRWL->RWL_ReaderCount);
    LeaveCriticalSection(&pRWL->RWL_ReadWriteBlock);
}


//----------------------------------------------------------------------------
// Function:    ReleaseReadLock
//
// Relinquishes shared ownership of the lock object.
//
// the last reader sets the event to wake any waiting writers
//----------------------------------------------------------------------------

VOID
ReleaseReadLock(
    PREAD_WRITE_LOCK pRWL
    ) {

    if (InterlockedDecrement(&pRWL->RWL_ReaderCount) < 0) {
        SetEvent(pRWL->RWL_ReaderDoneEvent); 
    }
}


//----------------------------------------------------------------------------
// Function:    AcquireWriteLock
//
// Secures exclusive ownership of the lock object.
//
// the writer blocks other threads by entering the ReadWriteBlock section,
// and then waits for any thread(s) owning the lock to finish
//----------------------------------------------------------------------------

VOID
AcquireWriteLock(
    PREAD_WRITE_LOCK pRWL
    ) {

    EnterCriticalSection(&pRWL->RWL_ReadWriteBlock);
    if (InterlockedDecrement(&pRWL->RWL_ReaderCount) >= 0) { 
        WaitForSingleObject(pRWL->RWL_ReaderDoneEvent, INFINITE);
    }
}


//----------------------------------------------------------------------------
// Function:    ReleaseWriteLock
//
// Relinquishes exclusive ownership of the lock object.
//
// the writer releases the lock by setting the count to zero
// and then leaving the ReadWriteBlock critical section
//----------------------------------------------------------------------------

VOID
ReleaseWriteLock(
    PREAD_WRITE_LOCK pRWL
    ) {

    InterlockedIncrement(&pRWL->RWL_ReaderCount);
    LeaveCriticalSection(&(pRWL)->RWL_ReadWriteBlock);
}


//----------------------------------------------------------------------------
// InitializeDynamicLocksStore
//
// Initialize the structure from which dynamic readwrite locks are allocated.
//----------------------------------------------------------------------------

DWORD
InitializeDynamicLocksStore (
    PDYNAMIC_LOCKS_STORE    pStore,
    HANDLE                  hHeap
    ) {

    // initialize the heap from where dynamic locks are allocated
    pStore->hHeap = hHeap;
    
    INITIALIZE_LOCKED_LIST(&pStore->llFreeLocksList);
    if (!LOCKED_LIST_INITIALIZED(&pStore->llFreeLocksList))
        return GetLastError();

    // initialize the count of the number of free and allocated locks
    pStore->ulCountAllocated = pStore->ulCountFree = 0;

    return NO_ERROR;
}


//----------------------------------------------------------------------------
// DeInitializeDynamicLocksStore
//
// Fail if any allocated locks have not been freed.
// Delete the free locks and the FreeLocksList.
//----------------------------------------------------------------------------

DWORD
DeInitializeDynamicLocksStore (
    PDYNAMIC_LOCKS_STORE    pStore
    ) {
    
    PDYNAMIC_READWRITE_LOCK pLock;
    PLIST_ENTRY             pleHead, ple;
    
    if (pStore->ulCountFree)
        return ERROR_CAN_NOT_COMPLETE;

    // deinitialize the count of the number of free and allocated locks
    pStore->ulCountAllocated = pStore->ulCountFree = 0;

    // deinitialize the FreeLocksList
    pStore->llFreeLocksList.created = 0;

    // delete all dynamic readwrite locks and free the memory.
    pleHead = &(pStore->llFreeLocksList.head);
    for (ple = pleHead->Flink; ple != pleHead; ple = ple->Flink)
    {
        pLock = CONTAINING_RECORD(ple, DYNAMIC_READWRITE_LOCK, leLink);
        DELETE_READ_WRITE_LOCK(&pLock->rwlLock);
        HeapFree(pStore->hHeap, 0, pLock);
    }

    DeleteCriticalSection(&(pStore->llFreeLocksList.lock));

    // deinitialize the heap from where dynamic locks are allocated
    pStore->hHeap = NULL;

    return NO_ERROR;
}


//----------------------------------------------------------------------------
// GetDynamicReadwriteLock
//
// Return a free dynamic readwrite lock, if one is available.
// Else allocate a new dynamic readwrite lock.
// Assumes pStore->llFreeLocksList is locked.
//----------------------------------------------------------------------------

PDYNAMIC_READWRITE_LOCK
GetDynamicReadwriteLock (
    PDYNAMIC_LOCKS_STORE    pStore
    ) {

    PDYNAMIC_READWRITE_LOCK pLock;
    PLIST_ENTRY             pleHead, ple;


    // a free dynamic lock is available. Return it
    pleHead = &(pStore->llFreeLocksList.head);
    if (!IsListEmpty(pleHead))
    {
        pStore->ulCountFree--;
        ple = RemoveHeadList(pleHead);
        pLock = CONTAINING_RECORD(ple, DYNAMIC_READWRITE_LOCK, leLink);
        return pLock;
    }
    
    // allocate memory for a new dynamic lock
    pLock = HeapAlloc(pStore->hHeap, 0, sizeof(DYNAMIC_READWRITE_LOCK));
    if (pLock ==  NULL)
        return NULL;

    // initialize the fields
    CREATE_READ_WRITE_LOCK(&(pLock->rwlLock));
    if (!READ_WRITE_LOCK_CREATED(&(pLock->rwlLock)))
    {
        HeapFree(pStore->hHeap, 0, pLock);
        return NULL;
    }
    pLock->ulCount = 0;

    pStore->ulCountAllocated++;

    return pLock;
}
    

//----------------------------------------------------------------------------
// FreeDynamicReadwriteLock
//
// Accepts a released dynamic readwrite lock.
// Frees it if there are too many dynamic readwrite locks.
// Assumes pStore->llFreeLocksList is locked.
//----------------------------------------------------------------------------

VOID
FreeDynamicReadwriteLock (
    PDYNAMIC_READWRITE_LOCK pLock,
    PDYNAMIC_LOCKS_STORE    pStore
    ) {

    PLIST_ENTRY             pleHead;


    // decrement count of allocated locks
    pStore->ulCountAllocated--;

    // if there are too many dynamic readwrite locks, then free this lock
    if ((pStore->ulCountAllocated + pStore->ulCountFree + 1) >
        DYNAMIC_LOCKS_HIGH_THRESHOLD)
    {
        DELETE_READ_WRITE_LOCK(&pLock->rwlLock);
        HeapFree(pStore->hHeap, 0, pLock);    
    }
    else                        // insert into the list of free locks
    {
        pleHead = &(pStore->llFreeLocksList.head);
        InsertHeadList(pleHead, &pLock->leLink);
        pStore->ulCountFree++;
    }

    return;
}


//----------------------------------------------------------------------------
// AcquireDynamicLock
//
// Locks the FreeLocksList.
// Allocates a new dynamic lock if required.
// Increments the count.
// Unlocks the FreeLocksList.
// Acquires the dynamic lock.
//----------------------------------------------------------------------------

DWORD
AcquireDynamicReadwriteLock (
    PDYNAMIC_READWRITE_LOCK *ppLock,
    LOCK_MODE               lmMode,
    PDYNAMIC_LOCKS_STORE    pStore
    ) {

    // acquire the lock for the free locks list
    ACQUIRE_LIST_LOCK(&pStore->llFreeLocksList);
    
    // if it is does not already exist, allocate a new dynamic lock
    if (*ppLock == NULL)
    {
        *ppLock = GetDynamicReadwriteLock(pStore);

        // if could not get a lock we are in serious trouble
        if (*ppLock == NULL)
        {
            RELEASE_LIST_LOCK(&pStore->llFreeLocksList);
            return ERROR_CAN_NOT_COMPLETE;
        }
    }

    // increment count in the dynamic lock
    (*ppLock)->ulCount++;

    // release the lock for the free locks list
    RELEASE_LIST_LOCK(&pStore->llFreeLocksList);    

    // acquire dynamic lock
    if (lmMode == READ_MODE)
        ACQUIRE_READ_LOCK(&(*ppLock)->rwlLock);
    else
        ACQUIRE_WRITE_LOCK(&(*ppLock)->rwlLock);

    return NO_ERROR;
}


//----------------------------------------------------------------------------
// ReleaseDynamicReadwriteLock
//
// Locks the FreeLocksList.
// Releases the dynamic lock.
// Decrements the count.
//  Free the dynamic lock if count becomes 0.
// Unlocks the FreeLocksList.
//----------------------------------------------------------------------------

VOID
ReleaseDynamicReadwriteLock (
    PDYNAMIC_READWRITE_LOCK *ppLock,
    LOCK_MODE               lmMode,
    PDYNAMIC_LOCKS_STORE    pStore
    ) {

    // acquire the lock for the free locks list
    ACQUIRE_LIST_LOCK(&pStore->llFreeLocksList);

    // release the dynamic readwrite lock
    if (lmMode == READ_MODE)
        RELEASE_READ_LOCK(&(*ppLock)->rwlLock);
    else 
        RELEASE_WRITE_LOCK(&(*ppLock)->rwlLock);

    // decrement count in the dynamic lock, free it if count becomes 0
    if (!(*ppLock)->ulCount--)
    {
        FreeDynamicReadwriteLock(*ppLock, pStore);
        *ppLock = NULL;         // so it is known that it doesn't exist 
    }

    // release the lock for the free locks list
    RELEASE_LIST_LOCK(&pStore->llFreeLocksList);    

    return;
}
Initiall commit 2024-08-04 01:28:15 +02:00			`/*++`

			`Copyright (c) 1999, Microsoft Corporation`

			`Module Name:`

			`sample\sync.h`

			`Abstract:`

			`The file contains the READ_WRITE_LOCK definition which allows`
			`multiple-reader/single-writer. This implementation DOES NOT`
			`starve a thread trying to acquire write accesss if there are`
			`a large number of threads interested in acquiring read access.`

			`--*/`

			`#include "pchsample.h"`
			`#pragma hdrstop`

			`//----------------------------------------------------------------------------`
			`// Function: CreateReadWriteLock`
			`//`
			`// Initializes a multiple-reader/single-writer lock object`
			`//----------------------------------------------------------------------------`

			`DWORD`
			`CreateReadWriteLock(`
			`PREAD_WRITE_LOCK pRWL`
			`) {`

			`pRWL->RWL_ReaderCount = 0;`

			`__try {`
			`InitializeCriticalSection(&(pRWL)->RWL_ReadWriteBlock);`
			`}`
			`__except(EXCEPTION_EXECUTE_HANDLER) {`
			`return GetLastError();`
			`}`

			`pRWL->RWL_ReaderDoneEvent = CreateEvent(NULL,FALSE,FALSE,NULL);`
			`if (pRWL->RWL_ReaderDoneEvent != NULL) {`
			`return GetLastError();`
			`}`

			`return NO_ERROR;`
			`}`



			`//----------------------------------------------------------------------------`
			`// Function: DeleteReadWriteLock`
			`//`
			`// Frees resources used by a multiple-reader/single-writer lock object`
			`//----------------------------------------------------------------------------`

			`VOID`
			`DeleteReadWriteLock(`
			`PREAD_WRITE_LOCK pRWL`
			`) {`

			`CloseHandle(pRWL->RWL_ReaderDoneEvent);`
			`pRWL->RWL_ReaderDoneEvent = NULL;`
			`DeleteCriticalSection(&pRWL->RWL_ReadWriteBlock);`
			`pRWL->RWL_ReaderCount = 0;`
			`}`



			`//----------------------------------------------------------------------------`
			`// Function: AcquireReadLock`
			`//`
			`// Secures shared ownership of the lock object for the caller.`
			`//`
			`// readers enter the read-write critical section, increment the count,`
			`// and leave the critical section`
			`//----------------------------------------------------------------------------`

			`VOID`
			`AcquireReadLock(`
			`PREAD_WRITE_LOCK pRWL`
			`) {`

			`EnterCriticalSection(&pRWL->RWL_ReadWriteBlock);`
			`InterlockedIncrement(&pRWL->RWL_ReaderCount);`
			`LeaveCriticalSection(&pRWL->RWL_ReadWriteBlock);`
			`}`



			`//----------------------------------------------------------------------------`
			`// Function: ReleaseReadLock`
			`//`
			`// Relinquishes shared ownership of the lock object.`
			`//`
			`// the last reader sets the event to wake any waiting writers`
			`//----------------------------------------------------------------------------`

			`VOID`
			`ReleaseReadLock(`
			`PREAD_WRITE_LOCK pRWL`
			`) {`

			`if (InterlockedDecrement(&pRWL->RWL_ReaderCount) < 0) {`
			`SetEvent(pRWL->RWL_ReaderDoneEvent);`
			`}`
			`}`



			`//----------------------------------------------------------------------------`
			`// Function: AcquireWriteLock`
			`//`
			`// Secures exclusive ownership of the lock object.`
			`//`
			`// the writer blocks other threads by entering the ReadWriteBlock section,`
			`// and then waits for any thread(s) owning the lock to finish`
			`//----------------------------------------------------------------------------`

			`VOID`
			`AcquireWriteLock(`
			`PREAD_WRITE_LOCK pRWL`
			`) {`

			`EnterCriticalSection(&pRWL->RWL_ReadWriteBlock);`
			`if (InterlockedDecrement(&pRWL->RWL_ReaderCount) >= 0) {`
			`WaitForSingleObject(pRWL->RWL_ReaderDoneEvent, INFINITE);`
			`}`
			`}`



			`//----------------------------------------------------------------------------`
			`// Function: ReleaseWriteLock`
			`//`
			`// Relinquishes exclusive ownership of the lock object.`
			`//`
			`// the writer releases the lock by setting the count to zero`
			`// and then leaving the ReadWriteBlock critical section`
			`//----------------------------------------------------------------------------`

			`VOID`
			`ReleaseWriteLock(`
			`PREAD_WRITE_LOCK pRWL`
			`) {`

			`InterlockedIncrement(&pRWL->RWL_ReaderCount);`
			`LeaveCriticalSection(&(pRWL)->RWL_ReadWriteBlock);`
			`}`



			`//----------------------------------------------------------------------------`
			`// InitializeDynamicLocksStore`
			`//`
			`// Initialize the structure from which dynamic readwrite locks are allocated.`
			`//----------------------------------------------------------------------------`

			`DWORD`
			`InitializeDynamicLocksStore (`
			`PDYNAMIC_LOCKS_STORE pStore,`
			`HANDLE hHeap`
			`) {`

			`// initialize the heap from where dynamic locks are allocated`
			`pStore->hHeap = hHeap;`

			`INITIALIZE_LOCKED_LIST(&pStore->llFreeLocksList);`
			`if (!LOCKED_LIST_INITIALIZED(&pStore->llFreeLocksList))`
			`return GetLastError();`

			`// initialize the count of the number of free and allocated locks`
			`pStore->ulCountAllocated = pStore->ulCountFree = 0;`

			`return NO_ERROR;`
			`}`



			`//----------------------------------------------------------------------------`
			`// DeInitializeDynamicLocksStore`
			`//`
			`// Fail if any allocated locks have not been freed.`
			`// Delete the free locks and the FreeLocksList.`
			`//----------------------------------------------------------------------------`

			`DWORD`
			`DeInitializeDynamicLocksStore (`
			`PDYNAMIC_LOCKS_STORE pStore`
			`) {`

			`PDYNAMIC_READWRITE_LOCK pLock;`
			`PLIST_ENTRY pleHead, ple;`

			`if (pStore->ulCountFree)`
			`return ERROR_CAN_NOT_COMPLETE;`

			`// deinitialize the count of the number of free and allocated locks`
			`pStore->ulCountAllocated = pStore->ulCountFree = 0;`

			`// deinitialize the FreeLocksList`
			`pStore->llFreeLocksList.created = 0;`

			`// delete all dynamic readwrite locks and free the memory.`
			`pleHead = &(pStore->llFreeLocksList.head);`
			`for (ple = pleHead->Flink; ple != pleHead; ple = ple->Flink)`
			`{`
			`pLock = CONTAINING_RECORD(ple, DYNAMIC_READWRITE_LOCK, leLink);`
			`DELETE_READ_WRITE_LOCK(&pLock->rwlLock);`
			`HeapFree(pStore->hHeap, 0, pLock);`
			`}`

			`DeleteCriticalSection(&(pStore->llFreeLocksList.lock));`

			`// deinitialize the heap from where dynamic locks are allocated`
			`pStore->hHeap = NULL;`

			`return NO_ERROR;`
			`}`



			`//----------------------------------------------------------------------------`
			`// GetDynamicReadwriteLock`
			`//`
			`// Return a free dynamic readwrite lock, if one is available.`
			`// Else allocate a new dynamic readwrite lock.`
			`// Assumes pStore->llFreeLocksList is locked.`
			`//----------------------------------------------------------------------------`

			`PDYNAMIC_READWRITE_LOCK`
			`GetDynamicReadwriteLock (`
			`PDYNAMIC_LOCKS_STORE pStore`
			`) {`

			`PDYNAMIC_READWRITE_LOCK pLock;`
			`PLIST_ENTRY pleHead, ple;`


			`// a free dynamic lock is available. Return it`
			`pleHead = &(pStore->llFreeLocksList.head);`
			`if (!IsListEmpty(pleHead))`
			`{`
			`pStore->ulCountFree--;`
			`ple = RemoveHeadList(pleHead);`
			`pLock = CONTAINING_RECORD(ple, DYNAMIC_READWRITE_LOCK, leLink);`
			`return pLock;`
			`}`

			`// allocate memory for a new dynamic lock`
			`pLock = HeapAlloc(pStore->hHeap, 0, sizeof(DYNAMIC_READWRITE_LOCK));`
			`if (pLock == NULL)`
			`return NULL;`

			`// initialize the fields`
			`CREATE_READ_WRITE_LOCK(&(pLock->rwlLock));`
			`if (!READ_WRITE_LOCK_CREATED(&(pLock->rwlLock)))`
			`{`
			`HeapFree(pStore->hHeap, 0, pLock);`
			`return NULL;`
			`}`
			`pLock->ulCount = 0;`

			`pStore->ulCountAllocated++;`

			`return pLock;`
			`}`



			`//----------------------------------------------------------------------------`
			`// FreeDynamicReadwriteLock`
			`//`
			`// Accepts a released dynamic readwrite lock.`
			`// Frees it if there are too many dynamic readwrite locks.`
			`// Assumes pStore->llFreeLocksList is locked.`
			`//----------------------------------------------------------------------------`

			`VOID`
			`FreeDynamicReadwriteLock (`
			`PDYNAMIC_READWRITE_LOCK pLock,`
			`PDYNAMIC_LOCKS_STORE pStore`
			`) {`

			`PLIST_ENTRY pleHead;`


			`// decrement count of allocated locks`
			`pStore->ulCountAllocated--;`

			`// if there are too many dynamic readwrite locks, then free this lock`
			`if ((pStore->ulCountAllocated + pStore->ulCountFree + 1) >`
			`DYNAMIC_LOCKS_HIGH_THRESHOLD)`
			`{`
			`DELETE_READ_WRITE_LOCK(&pLock->rwlLock);`
			`HeapFree(pStore->hHeap, 0, pLock);`
			`}`
			`else // insert into the list of free locks`
			`{`
			`pleHead = &(pStore->llFreeLocksList.head);`
			`InsertHeadList(pleHead, &pLock->leLink);`
			`pStore->ulCountFree++;`
			`}`

			`return;`
			`}`



			`//----------------------------------------------------------------------------`
			`// AcquireDynamicLock`
			`//`
			`// Locks the FreeLocksList.`
			`// Allocates a new dynamic lock if required.`
			`// Increments the count.`
			`// Unlocks the FreeLocksList.`
			`// Acquires the dynamic lock.`
			`//----------------------------------------------------------------------------`

			`DWORD`
			`AcquireDynamicReadwriteLock (`
			`PDYNAMIC_READWRITE_LOCK *ppLock,`
			`LOCK_MODE lmMode,`
			`PDYNAMIC_LOCKS_STORE pStore`
			`) {`

			`// acquire the lock for the free locks list`
			`ACQUIRE_LIST_LOCK(&pStore->llFreeLocksList);`

			`// if it is does not already exist, allocate a new dynamic lock`
			`if (*ppLock == NULL)`
			`{`
			`*ppLock = GetDynamicReadwriteLock(pStore);`

			`// if could not get a lock we are in serious trouble`
			`if (*ppLock == NULL)`
			`{`
			`RELEASE_LIST_LOCK(&pStore->llFreeLocksList);`
			`return ERROR_CAN_NOT_COMPLETE;`
			`}`
			`}`

			`// increment count in the dynamic lock`
			`(*ppLock)->ulCount++;`

			`// release the lock for the free locks list`
			`RELEASE_LIST_LOCK(&pStore->llFreeLocksList);`

			`// acquire dynamic lock`
			`if (lmMode == READ_MODE)`
			`ACQUIRE_READ_LOCK(&(*ppLock)->rwlLock);`
			`else`
			`ACQUIRE_WRITE_LOCK(&(*ppLock)->rwlLock);`

			`return NO_ERROR;`
			`}`



			`//----------------------------------------------------------------------------`
			`// ReleaseDynamicReadwriteLock`
			`//`
			`// Locks the FreeLocksList.`
			`// Releases the dynamic lock.`
			`// Decrements the count.`
			`// Free the dynamic lock if count becomes 0.`
			`// Unlocks the FreeLocksList.`
			`//----------------------------------------------------------------------------`

			`VOID`
			`ReleaseDynamicReadwriteLock (`
			`PDYNAMIC_READWRITE_LOCK *ppLock,`
			`LOCK_MODE lmMode,`
			`PDYNAMIC_LOCKS_STORE pStore`
			`) {`

			`// acquire the lock for the free locks list`
			`ACQUIRE_LIST_LOCK(&pStore->llFreeLocksList);`

			`// release the dynamic readwrite lock`
			`if (lmMode == READ_MODE)`
			`RELEASE_READ_LOCK(&(*ppLock)->rwlLock);`
			`else`
			`RELEASE_WRITE_LOCK(&(*ppLock)->rwlLock);`

			`// decrement count in the dynamic lock, free it if count becomes 0`
			`if (!(*ppLock)->ulCount--)`
			`{`
			`FreeDynamicReadwriteLock(*ppLock, pStore);`
			`*ppLock = NULL; // so it is known that it doesn't exist`
			`}`

			`// release the lock for the free locks list`
			`RELEASE_LIST_LOCK(&pStore->llFreeLocksList);`

			`return;`
			`}`