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5c7ce4475e
- Change INIT_FUNCTION and INIT_SECTION to CODE_SEG("INIT") and DATA_SEG("INIT") respectively - Remove INIT_FUNCTION from function prototypes - Remove alloc_text pragma calls as they are not needed anymore
317 lines
8.7 KiB
C
317 lines
8.7 KiB
C
/*
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* PROJECT: ReactOS HAL
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* LICENSE: GPL - See COPYING in the top level directory
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* PURPOSE: HAL Timer Routines
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* PROGRAMMERS: Alex Ionescu (alex.ionescu@reactos.org)
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* Timo Kreuzer (timo.kreuzer@reactos.org)
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*/
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/* INCLUDES ******************************************************************/
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#include <hal.h>
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#define NDEBUG
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#include <debug.h>
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/* GLOBALS *******************************************************************/
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#define PIT_LATCH 0x00
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extern HALP_ROLLOVER HalpRolloverTable[15];
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LARGE_INTEGER HalpLastPerfCounter;
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LARGE_INTEGER HalpPerfCounter;
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ULONG HalpPerfCounterCutoff;
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BOOLEAN HalpClockSetMSRate;
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ULONG HalpCurrentTimeIncrement;
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ULONG HalpCurrentRollOver;
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ULONG HalpNextMSRate = 14;
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ULONG HalpLargestClockMS = 15;
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/* PRIVATE FUNCTIONS *********************************************************/
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FORCEINLINE
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ULONG
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HalpRead8254Value(void)
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{
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ULONG TimerValue;
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/* Send counter latch command for channel 0 */
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__outbyte(TIMER_CONTROL_PORT, PIT_LATCH);
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__nop();
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/* Read the value, LSB first */
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TimerValue = __inbyte(TIMER_CHANNEL0_DATA_PORT);
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__nop();
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TimerValue |= __inbyte(TIMER_CHANNEL0_DATA_PORT) << 8;
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return TimerValue;
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}
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VOID
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NTAPI
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HalpSetTimerRollOver(USHORT RollOver)
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{
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ULONG_PTR Flags;
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TIMER_CONTROL_PORT_REGISTER TimerControl;
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/* Disable interrupts */
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Flags = __readeflags();
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_disable();
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/* Program the PIT for binary mode */
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TimerControl.BcdMode = FALSE;
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/*
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* Program the PIT to generate a normal rate wave (Mode 2) on channel 0.
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* Channel 0 is used for the IRQ0 clock interval timer, and channel
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* 1 is used for DRAM refresh.
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*
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* Mode 2 gives much better accuracy than Mode 3.
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*/
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TimerControl.OperatingMode = PitOperatingMode2;
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TimerControl.Channel = PitChannel0;
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/* Set the access mode that we'll use to program the reload value */
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TimerControl.AccessMode = PitAccessModeLowHigh;
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/* Now write the programming bits */
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__outbyte(TIMER_CONTROL_PORT, TimerControl.Bits);
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/* Next we write the reload value for channel 0 */
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__outbyte(TIMER_CHANNEL0_DATA_PORT, RollOver & 0xFF);
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__outbyte(TIMER_CHANNEL0_DATA_PORT, RollOver >> 8);
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/* Restore interrupts if they were previously enabled */
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__writeeflags(Flags);
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}
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CODE_SEG("INIT")
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VOID
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NTAPI
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HalpInitializeClock(VOID)
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{
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ULONG Increment;
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USHORT RollOver;
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DPRINT("HalpInitializeClock()\n");
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#if defined(SARCH_PC98)
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HalpInitializeClockPc98();
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#endif
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/* Get increment and rollover for the largest time clock ms possible */
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Increment = HalpRolloverTable[HalpLargestClockMS - 1].Increment;
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RollOver = (USHORT)HalpRolloverTable[HalpLargestClockMS - 1].RollOver;
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/* Set the maximum and minimum increment with the kernel */
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KeSetTimeIncrement(Increment, HalpRolloverTable[0].Increment);
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/* Set the rollover value for the timer */
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HalpSetTimerRollOver(RollOver);
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/* Save rollover and increment */
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HalpCurrentRollOver = RollOver;
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HalpCurrentTimeIncrement = Increment;
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}
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#ifdef _M_IX86
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#ifndef _MINIHAL_
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VOID
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FASTCALL
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HalpClockInterruptHandler(IN PKTRAP_FRAME TrapFrame)
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{
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ULONG LastIncrement;
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KIRQL Irql;
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/* Enter trap */
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KiEnterInterruptTrap(TrapFrame);
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/* Start the interrupt */
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if (HalBeginSystemInterrupt(CLOCK2_LEVEL, PRIMARY_VECTOR_BASE + PIC_TIMER_IRQ, &Irql))
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{
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/* Update the performance counter */
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HalpPerfCounter.QuadPart += HalpCurrentRollOver;
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HalpPerfCounterCutoff = KiEnableTimerWatchdog;
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/* Save increment */
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LastIncrement = HalpCurrentTimeIncrement;
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/* Check if someone changed the time rate */
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if (HalpClockSetMSRate)
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{
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/* Update the global values */
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HalpCurrentTimeIncrement = HalpRolloverTable[HalpNextMSRate - 1].Increment;
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HalpCurrentRollOver = HalpRolloverTable[HalpNextMSRate - 1].RollOver;
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/* Set new timer rollover */
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HalpSetTimerRollOver((USHORT)HalpCurrentRollOver);
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/* We're done */
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HalpClockSetMSRate = FALSE;
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}
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/* Update the system time -- the kernel will exit this trap */
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KeUpdateSystemTime(TrapFrame, LastIncrement, Irql);
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}
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/* Spurious, just end the interrupt */
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KiEoiHelper(TrapFrame);
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}
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VOID
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FASTCALL
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HalpProfileInterruptHandler(IN PKTRAP_FRAME TrapFrame)
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{
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KIRQL Irql;
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/* Enter trap */
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KiEnterInterruptTrap(TrapFrame);
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/* Start the interrupt */
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if (HalBeginSystemInterrupt(PROFILE_LEVEL, PRIMARY_VECTOR_BASE + PIC_RTC_IRQ, &Irql))
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{
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#if defined(SARCH_PC98)
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/* Clear the interrupt flag */
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HalpAcquireCmosSpinLock();
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(VOID)__inbyte(RTC_IO_i_INTERRUPT_RESET);
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HalpReleaseCmosSpinLock();
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#else
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/* Spin until the interrupt pending bit is clear */
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HalpAcquireCmosSpinLock();
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while (HalpReadCmos(RTC_REGISTER_C) & RTC_REG_C_IRQ)
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NOTHING;
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HalpReleaseCmosSpinLock();
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#endif
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/* If profiling is enabled, call the kernel function */
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if (!HalpProfilingStopped)
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{
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KeProfileInterrupt(TrapFrame);
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}
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/* Finish the interrupt */
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_disable();
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HalEndSystemInterrupt(Irql, TrapFrame);
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}
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/* Spurious, just end the interrupt */
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KiEoiHelper(TrapFrame);
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}
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#endif /* !_MINIHAL_ */
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#endif /* _M_IX86 */
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/* PUBLIC FUNCTIONS ***********************************************************/
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/*
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* @implemented
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*/
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VOID
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NTAPI
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HalCalibratePerformanceCounter(IN volatile PLONG Count,
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IN ULONGLONG NewCount)
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{
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ULONG_PTR Flags;
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/* Disable interrupts */
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Flags = __readeflags();
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_disable();
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/* Do a decrement for this CPU */
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_InterlockedDecrement(Count);
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/* Wait for other CPUs */
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while (*Count);
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/* Restore interrupts if they were previously enabled */
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__writeeflags(Flags);
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}
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/*
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* @implemented
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*/
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ULONG
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NTAPI
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HalSetTimeIncrement(IN ULONG Increment)
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{
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/* Round increment to ms */
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Increment /= 10000;
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/* Normalize between our minimum (1 ms) and maximum (variable) setting */
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if (Increment > HalpLargestClockMS) Increment = HalpLargestClockMS;
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if (Increment <= 0) Increment = 1;
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/* Set the rate and tell HAL we want to change it */
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HalpNextMSRate = Increment;
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HalpClockSetMSRate = TRUE;
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/* Return the increment */
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return HalpRolloverTable[Increment - 1].Increment;
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}
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LARGE_INTEGER
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NTAPI
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KeQueryPerformanceCounter(PLARGE_INTEGER PerformanceFrequency)
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{
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LARGE_INTEGER CurrentPerfCounter;
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ULONG CounterValue, ClockDelta;
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KIRQL OldIrql;
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/* If caller wants performance frequency, return hardcoded value */
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if (PerformanceFrequency) PerformanceFrequency->QuadPart = PIT_FREQUENCY;
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/* Check if we were called too early */
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if (HalpCurrentRollOver == 0) return HalpPerfCounter;
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/* Check if interrupts are disabled */
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if(!(__readeflags() & EFLAGS_INTERRUPT_MASK)) return HalpPerfCounter;
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/* Raise irql to DISPATCH_LEVEL */
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OldIrql = KeGetCurrentIrql();
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if (OldIrql < DISPATCH_LEVEL) KfRaiseIrql(DISPATCH_LEVEL);
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do
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{
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/* Get the current performance counter value */
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CurrentPerfCounter = HalpPerfCounter;
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/* Read the 8254 counter value */
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CounterValue = HalpRead8254Value();
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/* Repeat if the value has changed (a clock interrupt happened) */
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} while (CurrentPerfCounter.QuadPart != HalpPerfCounter.QuadPart);
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/* After someone changed the clock rate, during the first clock cycle we
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might see a counter value larger than the rollover. In this case we
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pretend it already has the new rollover value. */
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if (CounterValue > HalpCurrentRollOver) CounterValue = HalpCurrentRollOver;
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/* The interrupt is issued on the falling edge of the OUT line, when the
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counter changes from 1 to max. Calculate a clock delta, so that directly
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after the interrupt it is 0, going up to (HalpCurrentRollOver - 1). */
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ClockDelta = HalpCurrentRollOver - CounterValue;
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/* Add the clock delta */
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CurrentPerfCounter.QuadPart += ClockDelta;
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/* Check if the value is smaller then before, this means, we somehow
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missed an interrupt. This is a sign that the timer interrupt
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is very inaccurate. Probably a virtual machine. */
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if (CurrentPerfCounter.QuadPart < HalpLastPerfCounter.QuadPart)
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{
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/* We missed an interrupt. Assume we will receive it later */
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CurrentPerfCounter.QuadPart += HalpCurrentRollOver;
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}
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/* Update the last counter value */
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HalpLastPerfCounter = CurrentPerfCounter;
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/* Restore previous irql */
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if (OldIrql < DISPATCH_LEVEL) KfLowerIrql(OldIrql);
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/* Return the result */
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return CurrentPerfCounter;
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}
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/* EOF */
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