Diff
checker
Texto
Texto
Imágenes
Documentos
Excel
Carpetas
Legal
Enterprise
Aplicación de escritorio
Precios
Iniciar sesión
Descargar Diffchecker Desktop
Comparar texto
Encuentra la diferencia entre dos archivos de texto
Herramientas
Historial
Editor live
Ocultar espacios en blanco
Ocultar sin cambios
Sin ajuste de línea
Vista
Dividido
Unificado
Nivel de detalle
Inteligente
Palabra
Letra
Estilos de texto
Cambiar apariencia
Resaltado de sintaxis
Elegir sintaxis
Ignorar
Transformar texto
Ir al primer cambio
Editar entrada
Diffchecker Desktop
La forma más segura de usar Diffchecker. ¡Obtén la app de Diffchecker Desktop: tus diffs nunca salen de tu computadora!
Obtener Desktop
balmgr.c MS and ReactOS
Creado
hace 7 años
El diff nunca expira
Borrar
Exportar
Compartir
Explicar
165 eliminaciones
Líneas
Total
Eliminado
Caracteres
Total
Eliminado
Para continuar usando esta función, actualice a
Diff
checker
Pro
Ver precios
189 líneas
Copiar todo
95 adiciones
Líneas
Total
Añadido
Caracteres
Total
Añadido
Para continuar usando esta función, actualice a
Diff
checker
Pro
Ver precios
114 líneas
Copiar todo
Copiar
Copiado
Copiar
Copiado
NTOS Kernel
REACT OS
VOID
VOID
Copiar
Copiado
Copiar
Copiado
KiScanReadyQueues
(
NTAPI
IN PKDPC Dpc,
KiScanReadyQueues
(
IN PKDPC Dpc,
IN PVOID DeferredContext,
IN PVOID DeferredContext,
IN PVOID SystemArgument1,
IN PVOID SystemArgument1,
IN PVOID SystemArgument2
IN PVOID SystemArgument2
)
)
/*++
Routine Description:
This function scans a section of the ready queues and attempts to
boost the priority of threads that run at variable priority levels.
N.B. This function is executed as a DPC from the periodic timer that
drives the balance set manager.
Arguments:
Dpc - Supplies a pointer to a DPC object - not used.
DeferredContext - Supplies the DPC context - not used.
SystemArgument1 - Supplies the first system argument - note used.
SystemArgument2 - Supplies the second system argument - note used.
Return Value:
None.
--*/
{
{
Copiar
Copiado
Copiar
Copiado
P
ULONG
ScanLast
=
DeferredContext
;
ULONG
Count
=
0;
ULONG
Scan
Index
= *ScanLast
;
PLIST_ENTRY Entry
;
ULONG
Count = 10,
Number =
16
;
ULONG
Index
;
PKPRCB Prcb
= KiProcessorBlock[ScanIndex]
;
PLIST_ENTRY ListHead
;
ULONG
Index = Prcb->QueueIndex
;
ULONG
Number =
0;
ULONG
WaitLimit = KeTickCount.LowPart - 300
;
KIRQL OldIrql
;
PKPRCB Prcb
;
ULONG
ScanIndex
;
P
ULONG
ScanLast
;
ULONG Summary;
ULONG Summary;
Copiar
Copiado
Copiar
Copiado
KIRQL OldIrql;
PLIST_ENTRY ListHead, NextEntry;
PKTHREAD Thread;
PKTHREAD Thread;
Copiar
Copiado
Copiar
Copiado
ULONG WaitLimit;
UNREFERENCED_PARAMETER(SystemArgument1);
UNREFERENCED_PARAMETER(SystemArgument2);
//
// Get the address of the queue index variable.
//
// N.B. If a fault occurs accessing queue index value, then the exception
// handler is either executed or a bugcheck occurs.
//
ScanLast = (PULONG)DeferredContext;
#if defined(_AMD64_)
try {
ScanIndex = *ScanLast;
} except(KiKernelDpcFilter(Dpc, GetExceptionInformation())) {
return;
}
#else
UNREFERENCED_PARAMETER(Dpc);
ScanIndex = *ScanLast;
#endif
//
// Lock the dispatcher database, acquire the PRCB lock, and check if
// there are any ready threads queued at the scanable priority levels.
//
Copiar
Copiado
Copiar
Copiado
Count = THREAD_READY_COUNT;
/* Lock the dispatcher and PRCB */
Number = THREAD_SCAN_COUNT;
OldIrql = KiAcquireDispatcherLock();
Prcb = KiProcessorBlock[ScanIndex];
Index = Prcb->QueueIndex;
WaitLimit = KiQueryLowTickCount() - READY_WITHOUT_RUNNING;
KiLockDispatcherDatabase(&OldIrql);
KiAcquirePrcbLock(Prcb);
KiAcquirePrcbLock(Prcb);
Copiar
Copiado
Copiar
Copiado
/* Check if there's any thread that need help */
Summary = Prcb->ReadySummary & ((1 << THREAD_BOOST_PRIORITY) - 2);
Summary = Prcb->ReadySummary & ((1 << THREAD_BOOST_PRIORITY) - 2);
Copiar
Copiado
Copiar
Copiado
if (Summary
!= 0) {
if (Summary
)
do {
{
/* Start scan loop */
//
do
// If the current ready queue index is beyond the end of the range
{
// of priorities that are scanned, then wrap back to the beginning
/* Normalize the index */
// priority.
if (Index > (THREAD_BOOST_PRIORITY - 1)) Index = 1;
//
if (Index > THREAD_SCAN_PRIORITY) {
Index = 1;
}
//
// If there are any ready threads queued at the current priority
// level, then attempt to boost the thread priority.
//
if (Summary & PRIORITY_MASK(Index)) {
Copiar
Copiado
Copiar
Copiado
ASSERT(
IsListEmpty(&Prcb->DispatcherReadyListHead[Index])
== FALSE
);
/* Loop for ready threads */
if (Summary & PRIORITY_MASK(Index))
{
/* Sanity check */
ASSERT(
!
IsListEmpty(&Prcb->DispatcherReadyListHead[Index])
);
Copiar
Copiado
Copiar
Copiado
/* Update summary and select list */
Summary ^= PRIORITY_MASK(Index);
Summary ^= PRIORITY_MASK(Index);
ListHead = &Prcb->DispatcherReadyListHead[Index];
ListHead = &Prcb->DispatcherReadyListHead[Index];
Copiar
Copiado
Copiar
Copiado
Entry = ListHead->Flink;
Next
Entry = ListHead->Flink;
do
{
do
{
//
/
* Select a
thread
*/
/
/ If the
thread
has been waiting for an extended period,
Thread = CONTAINING_RECORD(
NextEntry,
// then boost the priority of the selected.
KTHREAD,
//
WaitListEntry);
ASSERT(Thread->Priority == Index);
Thread = CONTAINING_RECORD(
Entry, KTHREAD, WaitListEntry);
ASSERT(Thread->Priority == (KPRIORITY)Index);
if (WaitLimit >= Thread->WaitTime) {
//
// Remove the thread from the respective ready queue.
//
Entry = Entry->Blink;
ASSERT((Prcb->ReadySummary & PRIORITY_MASK(Index)) != 0);
Copiar
Copiado
Copiar
Copiado
if (RemoveEntryList(
Entry->Flink)
!= FALSE) {
/* Check if the thread has been waiting too long */
if (WaitLimit >= Thread->WaitTime)
{
/* Remove the thread from the queue */
NextEntry = NextEntry->Blink;
ASSERT((Prcb->ReadySummary & PRIORITY_MASK(Index)));
if (RemoveEntryList(
Next
Entry->Flink)
)
{
/* The list is empty now */
Prcb->ReadySummary ^= PRIORITY_MASK(Index);
Prcb->ReadySummary ^= PRIORITY_MASK(Index);
}
}
Copiar
Copiado
Copiar
Copiado
/
/
/
* Verify
priority decrement
and
set the new
one */
// Compute the
priority decrement
value,
set the new
// thread priority, set the thread quantum to a value
// appropriate for lock ownership, and insert the
// thread in the ready list.
//
ASSERT((Thread->PriorityDecrement >= 0) &&
ASSERT((Thread->PriorityDecrement >= 0) &&
Copiar
Copiado
Copiar
Copiado
(Thread->PriorityDecrement <=
Thread->Priority));
(Thread->PriorityDecrement <=
Thread->Priority));
Thread->PriorityDecrement +=
Thread->PriorityDecrement +=
(THREAD_BOOST_PRIORITY -
(THREAD_BOOST_PRIORITY -
Thread->Priority);
Thread->Priority);
ASSERT((Thread->PriorityDecrement >= 0) &&
ASSERT((Thread->PriorityDecrement >= 0) &&
Copiar
Copiado
Copiar
Copiado
(Thread->PriorityDecrement <=
THREAD_BOOST_PRIORITY));
(Thread->PriorityDecrement <=
THREAD_BOOST_PRIORITY));
Copiar
Copiado
Copiar
Copiado
/* Update priority and insert into ready list */
Thread->Priority = THREAD_BOOST_PRIORITY;
Thread->Priority = THREAD_BOOST_PRIORITY;
Copiar
Copiado
Copiar
Copiado
Thread->Quantum =
LOCK_OWNERSHIP
_QUANTUM
;
Thread->Quantum =
WAIT
_QUANTUM
_DECREMENT * 4
;
KiInsertDeferredReadyList(Thread);
KiInsertDeferredReadyList(Thread);
Copiar
Copiado
Copiar
Copiado
Count -
= 1
;
Count -
-
;
}
}
Copiar
Copiado
Copiar
Copiado
Entry =
Entry->Flink;
/* Go to the next entry */
Number
-= 1
;
Next
Entry =
Next
Entry->Flink;
} while
((
Entry != ListHead) && (Number
!= 0
) && (Count
!= 0
));
Number
--
;
} while
((Next
Entry != ListHead) && (Number
) && (Count
));
}
}
Copiar
Copiado
Copiar
Copiado
Index
+= 1
;
/* Increase index */
} while ((Summary
!= 0
) && (Number
!= 0
) && (Count
!= 0
));
Index
++
;
} while ((Summary
) && (Number
) && (Count
));
}
}
Copiar
Copiado
Copiar
Copiado
/
/
/
*
Release the
lock
s and
dispatcher
*/
//
Release the
PRCB
lock
, unlock the
dispatcher
database, and save the
// last ready queue index for the next scan.
//
KiReleasePrcbLock(Prcb);
KiReleasePrcbLock(Prcb);
Copiar
Copiado
Copiar
Copiado
KiUnlockDispatcherDatabase
(OldIrql);
KiReleaseDispatcherLock
(OldIrql);
if ((Count
!= 0
) && (Number
!= 0)) {
/* Update the queue index for next time */
if ((Count
) && (Number
))
{
/* Reset the queue at index 1 */
Prcb->QueueIndex = 1;
Prcb->QueueIndex = 1;
Copiar
Copiado
Copiar
Copiado
}
}
else
{
else
{
/* Set the index we're in now */
Prcb->QueueIndex = Index;
Prcb->QueueIndex = Index;
}
}
Copiar
Copiado
Copiar
Copiado
//
/* Increment the CPU number for next time and normalize to CPU count */
// Increment the processor number.
ScanIndex++;
//
if (ScanIndex ==
KeNumberProcessors)
ScanIndex = 0;
ScanIndex += 1;
if (ScanIndex ==
(ULONG)
KeNumberProcessors)
{
ScanIndex = 0;
}
Copiar
Copiado
Copiar
Copiado
/* Return the index */
*ScanLast = ScanIndex;
*ScanLast = ScanIndex;
Copiar
Copiado
Copiar
Copiado
return;
}
}
Diferencias guardadas
Texto original
Abrir archivo
NTOS Kernel VOID KiScanReadyQueues ( IN PKDPC Dpc, IN PVOID DeferredContext, IN PVOID SystemArgument1, IN PVOID SystemArgument2 ) /*++ Routine Description: This function scans a section of the ready queues and attempts to boost the priority of threads that run at variable priority levels. N.B. This function is executed as a DPC from the periodic timer that drives the balance set manager. Arguments: Dpc - Supplies a pointer to a DPC object - not used. DeferredContext - Supplies the DPC context - not used. SystemArgument1 - Supplies the first system argument - note used. SystemArgument2 - Supplies the second system argument - note used. Return Value: None. --*/ { ULONG Count = 0; PLIST_ENTRY Entry; ULONG Index; PLIST_ENTRY ListHead; ULONG Number = 0; KIRQL OldIrql; PKPRCB Prcb; ULONG ScanIndex; PULONG ScanLast; ULONG Summary; PKTHREAD Thread; ULONG WaitLimit; UNREFERENCED_PARAMETER(SystemArgument1); UNREFERENCED_PARAMETER(SystemArgument2); // // Get the address of the queue index variable. // // N.B. If a fault occurs accessing queue index value, then the exception // handler is either executed or a bugcheck occurs. // ScanLast = (PULONG)DeferredContext; #if defined(_AMD64_) try { ScanIndex = *ScanLast; } except(KiKernelDpcFilter(Dpc, GetExceptionInformation())) { return; } #else UNREFERENCED_PARAMETER(Dpc); ScanIndex = *ScanLast; #endif // // Lock the dispatcher database, acquire the PRCB lock, and check if // there are any ready threads queued at the scanable priority levels. // Count = THREAD_READY_COUNT; Number = THREAD_SCAN_COUNT; Prcb = KiProcessorBlock[ScanIndex]; Index = Prcb->QueueIndex; WaitLimit = KiQueryLowTickCount() - READY_WITHOUT_RUNNING; KiLockDispatcherDatabase(&OldIrql); KiAcquirePrcbLock(Prcb); Summary = Prcb->ReadySummary & ((1 << THREAD_BOOST_PRIORITY) - 2); if (Summary != 0) { do { // // If the current ready queue index is beyond the end of the range // of priorities that are scanned, then wrap back to the beginning // priority. // if (Index > THREAD_SCAN_PRIORITY) { Index = 1; } // // If there are any ready threads queued at the current priority // level, then attempt to boost the thread priority. // if (Summary & PRIORITY_MASK(Index)) { ASSERT(IsListEmpty(&Prcb->DispatcherReadyListHead[Index]) == FALSE); Summary ^= PRIORITY_MASK(Index); ListHead = &Prcb->DispatcherReadyListHead[Index]; Entry = ListHead->Flink; do { // // If the thread has been waiting for an extended period, // then boost the priority of the selected. // Thread = CONTAINING_RECORD(Entry, KTHREAD, WaitListEntry); ASSERT(Thread->Priority == (KPRIORITY)Index); if (WaitLimit >= Thread->WaitTime) { // // Remove the thread from the respective ready queue. // Entry = Entry->Blink; ASSERT((Prcb->ReadySummary & PRIORITY_MASK(Index)) != 0); if (RemoveEntryList(Entry->Flink) != FALSE) { Prcb->ReadySummary ^= PRIORITY_MASK(Index); } // // Compute the priority decrement value, set the new // thread priority, set the thread quantum to a value // appropriate for lock ownership, and insert the // thread in the ready list. // ASSERT((Thread->PriorityDecrement >= 0) && (Thread->PriorityDecrement <= Thread->Priority)); Thread->PriorityDecrement += (THREAD_BOOST_PRIORITY - Thread->Priority); ASSERT((Thread->PriorityDecrement >= 0) && (Thread->PriorityDecrement <= THREAD_BOOST_PRIORITY)); Thread->Priority = THREAD_BOOST_PRIORITY; Thread->Quantum = LOCK_OWNERSHIP_QUANTUM; KiInsertDeferredReadyList(Thread); Count -= 1; } Entry = Entry->Flink; Number -= 1; } while ((Entry != ListHead) && (Number != 0) && (Count != 0)); } Index += 1; } while ((Summary != 0) && (Number != 0) && (Count != 0)); } // // Release the PRCB lock, unlock the dispatcher database, and save the // last ready queue index for the next scan. // KiReleasePrcbLock(Prcb); KiUnlockDispatcherDatabase(OldIrql); if ((Count != 0) && (Number != 0)) { Prcb->QueueIndex = 1; } else { Prcb->QueueIndex = Index; } // // Increment the processor number. // ScanIndex += 1; if (ScanIndex == (ULONG)KeNumberProcessors) { ScanIndex = 0; } *ScanLast = ScanIndex; return; }
Texto modificado
Abrir archivo
REACT OS VOID NTAPI KiScanReadyQueues(IN PKDPC Dpc, IN PVOID DeferredContext, IN PVOID SystemArgument1, IN PVOID SystemArgument2) { PULONG ScanLast = DeferredContext; ULONG ScanIndex = *ScanLast; ULONG Count = 10, Number = 16; PKPRCB Prcb = KiProcessorBlock[ScanIndex]; ULONG Index = Prcb->QueueIndex; ULONG WaitLimit = KeTickCount.LowPart - 300; ULONG Summary; KIRQL OldIrql; PLIST_ENTRY ListHead, NextEntry; PKTHREAD Thread; /* Lock the dispatcher and PRCB */ OldIrql = KiAcquireDispatcherLock(); KiAcquirePrcbLock(Prcb); /* Check if there's any thread that need help */ Summary = Prcb->ReadySummary & ((1 << THREAD_BOOST_PRIORITY) - 2); if (Summary) { /* Start scan loop */ do { /* Normalize the index */ if (Index > (THREAD_BOOST_PRIORITY - 1)) Index = 1; /* Loop for ready threads */ if (Summary & PRIORITY_MASK(Index)) { /* Sanity check */ ASSERT(!IsListEmpty(&Prcb->DispatcherReadyListHead[Index])); /* Update summary and select list */ Summary ^= PRIORITY_MASK(Index); ListHead = &Prcb->DispatcherReadyListHead[Index]; NextEntry = ListHead->Flink; do { /* Select a thread */ Thread = CONTAINING_RECORD(NextEntry, KTHREAD, WaitListEntry); ASSERT(Thread->Priority == Index); /* Check if the thread has been waiting too long */ if (WaitLimit >= Thread->WaitTime) { /* Remove the thread from the queue */ NextEntry = NextEntry->Blink; ASSERT((Prcb->ReadySummary & PRIORITY_MASK(Index))); if (RemoveEntryList(NextEntry->Flink)) { /* The list is empty now */ Prcb->ReadySummary ^= PRIORITY_MASK(Index); } /* Verify priority decrement and set the new one */ ASSERT((Thread->PriorityDecrement >= 0) && (Thread->PriorityDecrement <= Thread->Priority)); Thread->PriorityDecrement += (THREAD_BOOST_PRIORITY - Thread->Priority); ASSERT((Thread->PriorityDecrement >= 0) && (Thread->PriorityDecrement <= THREAD_BOOST_PRIORITY)); /* Update priority and insert into ready list */ Thread->Priority = THREAD_BOOST_PRIORITY; Thread->Quantum = WAIT_QUANTUM_DECREMENT * 4; KiInsertDeferredReadyList(Thread); Count --; } /* Go to the next entry */ NextEntry = NextEntry->Flink; Number--; } while((NextEntry != ListHead) && (Number) && (Count)); } /* Increase index */ Index++; } while ((Summary) && (Number) && (Count)); } /* Release the locks and dispatcher */ KiReleasePrcbLock(Prcb); KiReleaseDispatcherLock(OldIrql); /* Update the queue index for next time */ if ((Count) && (Number)) { /* Reset the queue at index 1 */ Prcb->QueueIndex = 1; } else { /* Set the index we're in now */ Prcb->QueueIndex = Index; } /* Increment the CPU number for next time and normalize to CPU count */ ScanIndex++; if (ScanIndex == KeNumberProcessors) ScanIndex = 0; /* Return the index */ *ScanLast = ScanIndex; }
Encontrar la diferencia