MacRISC2CPU.cpp   [plain text]


/*
 * Copyright (c) 1998-2000 Apple Computer, Inc. All rights reserved.
 *
 * @APPLE_LICENSE_HEADER_START@
 * 
 * The contents of this file constitute Original Code as defined in and
 * are subject to the Apple Public Source License Version 1.1 (the
 * "License").  You may not use this file except in compliance with the
 * License.  Please obtain a copy of the License at
 * http://www.apple.com/publicsource and read it before using this file.
 * 
 * This Original Code and all software distributed under the License are
 * distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, EITHER
 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT.  Please see the
 * License for the specific language governing rights and limitations
 * under the License.
 * 
 * @APPLE_LICENSE_HEADER_END@
 */
/*
 * Copyright (c) 1999-2002 Apple Computer, Inc.  All rights reserved.
 *
 *  DRI: Dave Radcliffe
 *
 */
#include <sys/cdefs.h>

__BEGIN_DECLS
#include <ppc/proc_reg.h>
__END_DECLS

#include <IOKit/IODeviceTreeSupport.h>
#include <IOKit/IOPlatformExpert.h>
#include <IOKit/IOCPU.h>
#include <IOKit/pci/IOPCIBridge.h>
#include <IOKit/pwr_mgt/RootDomain.h>

#include "MacRISC2CPU.h"

/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */

#define super IOCPU

OSDefineMetaClassAndStructors(MacRISC2CPU, IOCPU);

/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */

static IOCPUInterruptController *gCPUIC;

bool MacRISC2CPU::start(IOService *provider)
{
    kern_return_t        result;
    IORegistryEntry      *cpusRegEntry, *uniNRegEntry, *mpicRegEntry, *devicetreeRegEntry;
    OSIterator           *cpusIterator;
    OSData               *tmpData;
    IOService            *service;
    const OSSymbol       *interruptControllerName;
    OSData               *interruptData;
    OSArray              *tmpArray;
    UInt32               maxCPUs, uniNVersion, physCPU;
    ml_processor_info_t  processor_info;
	
    // callPlatformFunction symbols
    mpic_getProvider = OSSymbol::withCString("mpic_getProvider");
    mpic_getIPIVector= OSSymbol::withCString("mpic_getIPIVector");
    mpic_setCurrentTaskPriority = OSSymbol::withCString("mpic_setCurrentTaskPriority");
    mpic_setUpForSleep = OSSymbol::withCString("mpic_setUpForSleep");
    mpic_dispatchIPI = OSSymbol::withCString("mpic_dispatchIPI");
    keyLargo_restoreRegisterState = OSSymbol::withCString("keyLargo_restoreRegisterState");
    keyLargo_syncTimeBase = OSSymbol::withCString("keyLargo_syncTimeBase");
    keyLargo_saveRegisterState = OSSymbol::withCString("keyLargo_saveRegisterState");
    keyLargo_turnOffIO = OSSymbol::withCString("keyLargo_turnOffIO");
    keyLargo_writeRegUInt8 = OSSymbol::withCString("keyLargo_writeRegUInt8");
    keyLargo_getHostKeyLargo = OSSymbol::withCString("keyLargo_getHostKeyLargo");
    keyLargo_setPowerSupply = OSSymbol::withCString("setPowerSupply");

    macRISC2PE = OSDynamicCast(MacRISC2PE, getPlatform());
    if (macRISC2PE == 0) return false;
  
    if (!super::start(provider)) return false;

    // Get the Uni-N Version.
    uniNRegEntry = fromPath("/uni-n", gIODTPlane);
    if (uniNRegEntry == 0) return false;
    tmpData = OSDynamicCast(OSData, uniNRegEntry->getProperty("device-rev"));
    if (tmpData == 0) return false;
    uniNVersion = *(long *)tmpData->getBytesNoCopy();
  
    // Count the CPUs.
    numCPUs = 0;
    cpusRegEntry = fromPath("/cpus", gIODTPlane);
    if (cpusRegEntry == 0) return false;
    cpusIterator = cpusRegEntry->getChildIterator(gIODTPlane);
    while (cpusIterator->getNextObject()) numCPUs++;
    cpusIterator->release();
  
    // Limit the number of CPUs to one if uniNVersion is 1.0.7 or less.
    if (uniNVersion < kUniNVersion107) numCPUs = 1;
  
    // Limit the number of CPUs by the cpu=# boot arg.
    if (PE_parse_boot_arg("cpus", &maxCPUs))
    {
        if (numCPUs > maxCPUs) numCPUs = maxCPUs;
    }
	
	doSleep = false;
  
    // Get the "flush-on-lock" property from the first cpu node.
    flushOnLock = false;
    cpusRegEntry = fromPath("/cpus/@0", gIODTPlane);
    if (cpusRegEntry == 0) return false;
    if (cpusRegEntry->getProperty("flush-on-lock") != 0) flushOnLock = true;
  
    // Set flushOnLock when numCPUs is not one.
    if (numCPUs != 1) flushOnLock = true;
  
    // If system is PowerMac3,5 (TowerG4), then set flushOnLock to disable nap
    devicetreeRegEntry = fromPath("/", gIODTPlane);
    tmpData = OSDynamicCast(OSData, devicetreeRegEntry->getProperty("model"));
    if (tmpData == 0) return false;
#if 0
    if(!strcmp((char *)tmpData->getBytesNoCopy(), "PowerMac3,5"))
        flushOnLock = true;
#endif

    // Get the physical CPU number from the "reg" property.
    tmpData = OSDynamicCast(OSData, provider->getProperty("reg"));
    if (tmpData == 0) return false;
    physCPU = *(long *)tmpData->getBytesNoCopy();
    setCPUNumber(physCPU);

    // Get the gpio offset for soft reset from the "soft-reset" property.
    tmpData = OSDynamicCast(OSData, provider->getProperty("soft-reset"));
    if (tmpData == 0) 
    {
        if (physCPU == 0)
            soft_reset_offset = 0x5B;
        else
            soft_reset_offset = 0x5C;
    }
    else
        soft_reset_offset = *(long *)tmpData->getBytesNoCopy();
   
    // Get the gpio offset for timebase enable from the "timebase-enable" property.
    tmpData = OSDynamicCast(OSData, provider->getProperty("timebase-enable"));
    if (tmpData == 0) 
        timebase_enable_offset = 0x73;
    else
        timebase_enable_offset = *(long *)tmpData->getBytesNoCopy();
  
    // Find out if this is the boot CPU.
    bootCPU = false;
    tmpData = OSDynamicCast(OSData, provider->getProperty("state"));
    if (tmpData == 0) return false;
    if (!strcmp((char *)tmpData->getBytesNoCopy(), "running")) bootCPU = true;
  
    if (bootCPU)
    {
        gCPUIC = new IOCPUInterruptController;
        if (gCPUIC == 0) return false;
        if (gCPUIC->initCPUInterruptController(numCPUs) != kIOReturnSuccess)
            return false;
        gCPUIC->attach(this);
        gCPUIC->registerCPUInterruptController();
    }
  
    // Get the l2cr value from the property list.
    tmpData = OSDynamicCast(OSData, provider->getProperty("l2cr"));
    if (tmpData != 0)
    {
        l2crValue = *(long *)tmpData->getBytesNoCopy() & 0x7FFFFFFF;
    }
    else
    {
        l2crValue = mfl2cr() & 0x7FFFFFFF;
    }
  
    // Wait for KeyLargo to show up.
    keyLargo = waitForService(serviceMatching("KeyLargo"));
    if (keyLargo == 0) return false;
  
    keyLargo->callPlatformFunction (keyLargo_getHostKeyLargo, false, &keyLargo, 0, 0, 0);
    if (keyLargo == 0)
    {
        kprintf ("MacRISC2CPU::start - getHostKeyLargo returned nil\n");
        return false;
    }

    // Wait for MPIC to show up.
    mpic = waitForService(serviceMatching("AppleMPICInterruptController"));
    if (mpic == 0) return false;
  
    // Set the Interrupt Properties for this cpu.
    mpic->callPlatformFunction(mpic_getProvider, false, (void *)&mpicRegEntry, 0, 0, 0);
    interruptControllerName = IODTInterruptControllerName(mpicRegEntry);
    mpic->callPlatformFunction(mpic_getIPIVector, false, (void *)&physCPU, (void *)&interruptData, 0, 0);
    if ((interruptControllerName == 0) || (interruptData == 0)) return false;
  
    tmpArray = OSArray::withCapacity(1);
    tmpArray->setObject(interruptControllerName);
    cpuNub->setProperty(gIOInterruptControllersKey, tmpArray);
    tmpArray->release();
  
    tmpArray = OSArray::withCapacity(1);
    tmpArray->setObject(interruptData);
    cpuNub->setProperty(gIOInterruptSpecifiersKey, tmpArray);
    tmpArray->release();
  
    setCPUState(kIOCPUStateUninitalized);
  
    if (physCPU < numCPUs)
    {
        processor_info.cpu_id           = (cpu_id_t)this;
        processor_info.boot_cpu         = bootCPU;
        processor_info.start_paddr      = 0x0100;
        processor_info.l2cr_value       = l2crValue;
        processor_info.supports_nap     = !flushOnLock;
        processor_info.time_base_enable =
        (time_base_enable_t)&MacRISC2CPU::enableCPUTimeBase;
    
        // Register this CPU with mach.
        result = ml_processor_register(&processor_info, &machProcessor,	&ipi_handler);
        if (result == KERN_FAILURE) return false;
    
        processor_start(machProcessor);
    }

    // Before to go to sleep we wish to disable the napping mode so that the PMU
    // will not shutdown the system while going to sleep:
    service = waitForService(serviceMatching("IOPMrootDomain"));
    pmRootDomain = OSDynamicCast(IOPMrootDomain, service);
    if (pmRootDomain != 0)
    {
        kprintf("Register MacRISC2CPU %d to acknowledge power changes\n", getCPUNumber());
        pmRootDomain->registerInterestedDriver(this);
        
        // Join the Power Management Tree to receive setAggressiveness calls.
        PMinit();
        provider->joinPMtree(this);
    }
  
    registerService();
  
    // Finds the PMU so in quiesce we can put the machine to sleep.
    // I can not put this call there because quiesce runs in interrupt
    // context and waitForService may block.
    pmu = waitForService(serviceMatching("ApplePMU"));
    if (pmu == 0) return false;
    
    return true;
}

// This is called before to start the sleep process and after waking up before to
// start the wake process. We wish to disable the CPU nap mode going down and
// re-enable it before to go up.  For machines that support speed changing, we do
// some bookkeeping to make sure we end up in the right state coming out of sleep
IOReturn MacRISC2CPU::powerStateWillChangeTo ( IOPMPowerFlags theFlags, unsigned long, IOService*)
{
    if ( ! (theFlags & IOPMPowerOn) ) {
        // Sleep sequence:
        kprintf("MacRISC2CPU %d powerStateWillChangeTo to acknowledge power changes (DOWN) we set napping %d\n", getCPUNumber(), false);
        rememberNap = ml_enable_nap(getCPUNumber(), false);        // Disable napping (the function returns the previous state)

		// If processor based and currently slow, kick it back up so we safely come out of sleep
		if (macRISC2PE->processorSpeedChangeFlags & kProcessorBasedSpeedChange &&
			!(macRISC2PE->processorSpeedChangeFlags & kProcessorFast)) {
 				setAggressiveness (kPMSetProcessorSpeed, 0);				// Make it so
				macRISC2PE->processorSpeedChangeFlags &= ~kProcessorFast;	// Remember slow so we can set it after sleep
			}
   } else {
        // Wake sequence:
        kprintf("MacRISC2CPU %d powerStateWillChangeTo to acknowledge power changes (UP) we set napping %d\n", getCPUNumber(), rememberNap);
        ml_enable_nap(getCPUNumber(), rememberNap); 		   // Re-set the nap as it was before.
		
		if (macRISC2PE->processorSpeedChangeFlags & kEnvironmentalSpeedChange) {
			// Coming out of sleep we will be slow, so go to fast if necessary
			if (macRISC2PE->processorSpeedChangeFlags & kProcessorFast) {
				macRISC2PE->processorSpeedChangeFlags &= ~kProcessorFast;	// Clear fast flag so we know to speed up
				setAggressiveness (kPMSetProcessorSpeed, 0);				// Make it so
			} else
				doSleep = true;		// force delay on next call
		}
		
		// If processor based and flag indicates slow, we boosted it before going to sleep,
		// 		so set it back to slow
		if (macRISC2PE->processorSpeedChangeFlags & kProcessorBasedSpeedChange &&
			!(macRISC2PE->processorSpeedChangeFlags & kProcessorFast)) {
				macRISC2PE->processorSpeedChangeFlags |= kProcessorFast;	// Set fast so we know to go slow
 				setAggressiveness (kPMSetProcessorSpeed, 1);				// Make it so
			}
    }
    return IOPMAckImplied;
}

/*
 * MacRISC2CPU::setAggressiveness - respond to messages regarding power conservation aggressiveness
 *
 * For the case we care about (kPMSetProcessorSpeed), newLevel means:
 * 		newLevel == 0 => run fast => cache on => true
 *		newLevel == 1 => run slow => cache off => false
 */
IOReturn MacRISC2CPU::setAggressiveness(unsigned long selector, unsigned long newLevel)
{
	bool		doChange = false;
   IOReturn		result;
    
    result = super::setAggressiveness(selector, newLevel);
	
    if ((selector == kPMSetProcessorSpeed) && (macRISC2PE->processorSpeedChangeFlags != kNoSpeedChange)) {
		
		if (doSleep) {
			IOSleep (1000);
			doSleep = false;
		}

		// Enable/Disable L2 if needed.
		if (macRISC2PE->processorSpeedChangeFlags & kDisableL2SpeedChange) {
			if (!(macRISC2PE->processorSpeedChangeFlags & kClamshellClosedSpeedChange)) {
				// newLevel == 0 => run fast => cache on => true
				// newLevel == 1 => run slow => cache off => false
				if (!newLevel) {
					// See if cache is disabled
					if (!(macRISC2PE->processorSpeedChangeFlags & kL2CacheEnabled)) {
						// Enable it
						ml_enable_cache_level(2, !newLevel);
						macRISC2PE->processorSpeedChangeFlags |= kL2CacheEnabled;
					}
				} else if (macRISC2PE->processorSpeedChangeFlags & kL2CacheEnabled) {
					// Disable it
					ml_enable_cache_level(2, !newLevel);
					macRISC2PE->processorSpeedChangeFlags &= ~kL2CacheEnabled;
				}
			}
		}

		// Enable/Disable L3 if needed.
		if (macRISC2PE->processorSpeedChangeFlags & kDisableL3SpeedChange) {
			if (!(macRISC2PE->processorSpeedChangeFlags & kClamshellClosedSpeedChange)) {
				// newLevel == 0 => run fast => cache on => true
				// newLevel == 1 => run slow => cache off => false
				if (!newLevel) {
					// See if cache is disabled
					if (!(macRISC2PE->processorSpeedChangeFlags & kL3CacheEnabled)) {
						// Enable it
						ml_enable_cache_level(3, !newLevel);
						macRISC2PE->processorSpeedChangeFlags |= kL3CacheEnabled;
					}
				} else if (macRISC2PE->processorSpeedChangeFlags & kL3CacheEnabled) {
					// Disable it
					ml_enable_cache_level(3, !newLevel);
					macRISC2PE->processorSpeedChangeFlags &= ~kL3CacheEnabled;
				}
			}
		}

		if (!newLevel) {
			// See if already running slow
			if (!(macRISC2PE->processorSpeedChangeFlags & kProcessorFast)) {
				// Signal to switch
				doChange = true;
				macRISC2PE->processorSpeedChangeFlags |= kProcessorFast;
			}
		} else if (macRISC2PE->processorSpeedChangeFlags & kProcessorFast) {
			// Signal to switch
			doChange = true;
			macRISC2PE->processorSpeedChangeFlags &= ~kProcessorFast;
		}

		if (macRISC2PE->processorSpeedChangeFlags & kPMUBasedSpeedChange) {
			if (doChange) {                                
				// Note the current processor speed so quiesceCPU knows what to do
				currentProcessorSpeed = newLevel;
				
				// Disable nap to prevent PMU doing reset too soon.
				rememberNap = ml_enable_nap(getCPUNumber(), false);
				
				// Set flags for processor speed change.
				processorSpeedChange = true;
				
				// Ask PM to do the processor speed change.
				pmRootDomain->receivePowerNotification(kIOPMProcessorSpeedChange);
				
				// Set flags for system sleep.
				processorSpeedChange = false;
				
				// Enable nap as needed.
				ml_enable_nap(getCPUNumber(), rememberNap);
			}
		} 
		
		if (macRISC2PE->processorSpeedChangeFlags & kProcessorBasedSpeedChange && doChange) {
			IOReturn cpfResult = kIOReturnSuccess;
			
			if (newLevel == 0)
				cpfResult = keyLargo->callPlatformFunction (keyLargo_setPowerSupply, false,
					(void *)1, (void *)0, (void *)0, (void *)0);
			
			if (cpfResult == kIOReturnSuccess) {  
				// Set processor to new speed setting.
				ml_set_processor_speed(newLevel ? 1 : 0);
				
				if (newLevel != 0)
					cpfResult = keyLargo->callPlatformFunction (keyLargo_setPowerSupply, false,
						(void *)0, (void *)0, (void *)0, (void *)0);
			}
		}
	}
	
    return result;
}

void MacRISC2CPU::initCPU(bool boot)
{
	OSIterator 		*childIterator;
	IORegistryEntry *childEntry, *childDriver;
	IOPCIBridge		*pciDriver;
	OSData			*deviceTypeString;

    if (!boot && bootCPU) {
        // Tell Uni-N to enter normal mode.
        macRISC2PE->writeUniNReg(kUniNPowerMngmnt, kUniNNormal);
    
        // Set the running state for HWInit.
        macRISC2PE->writeUniNReg(kUniNHWInitState, kUniNHWInitStateRunning);
    
        if (!processorSpeedChange) {
			// Notify our pci children to restore their state
			if ((childIterator = macRISC2PE->getChildIterator (gIOServicePlane)) != NULL) {
				while ((childEntry = (IORegistryEntry *)(childIterator->getNextObject ())) != NULL) {
					deviceTypeString = OSDynamicCast( OSData, childEntry->getProperty( "device_type" ));
					if (deviceTypeString) {
						if (!strcmp((const char *)deviceTypeString->getBytesNoCopy(), "pci")) {
							childDriver = childEntry->copyChildEntry(gIOServicePlane);
							if (childDriver) {
								pciDriver = OSDynamicCast( IOPCIBridge, childDriver );
								if (pciDriver)
									// Got the driver - send the message
									pciDriver->setDevicePowerState (NULL, 3);

								childDriver->release();
							}
						}
					}
				}
			}

			keyLargo->callPlatformFunction(keyLargo_restoreRegisterState, false, 0, 0, 0, 0);
	
			// Disables the interrupts for this CPU.
			if (macRISC2PE->getMachineType() == kMacRISC2TypePowerMac)
			{
				kprintf("MacRISC2CPU::initCPU %d -> mpic->setUpForSleep on", getCPUNumber());
				mpic->callPlatformFunction(mpic_setUpForSleep, false, (void *)false, (void *)getCPUNumber(), 0, 0);
			}
		}
    }

    kprintf("MacRISC2CPU::initCPU %d Here!\n", getCPUNumber());
 
    // Set time base.
    if (bootCPU)
        keyLargo->callPlatformFunction(keyLargo_syncTimeBase, false, 0, 0, 0, 0);
  
    if (boot)
    {
        gCPUIC->enableCPUInterrupt(this);
    
        // Register and enable IPIs.
        cpuNub->registerInterrupt(0, this, (IOInterruptAction)&MacRISC2CPU::ipiHandler, 0);
        cpuNub->enableInterrupt(0);
    }
    else
    {
        long priority = 0;
        mpic->callPlatformFunction(mpic_setCurrentTaskPriority, false, (void *)&priority, 0, 0, 0);
    }
  
    setCPUState(kIOCPUStateRunning);
}

void MacRISC2CPU::quiesceCPU(void)
{
    if (bootCPU)
    {
        if (processorSpeedChange) {
            // Send PMU command to speed the system
            pmu->callPlatformFunction("setSpeedNow", false, (void *)currentProcessorSpeed, 0, 0, 0);
        } else {
			// Send PMU command to shutdown system before io is turned off
				pmu->callPlatformFunction("sleepNow", false, 0, 0, 0, 0);
	
			// Enables the interrupts for this CPU.
			if (macRISC2PE->getMachineType() == kMacRISC2TypePowerMac) 
			{
				kprintf("MacRISC2CPU::quiesceCPU %d -> mpic->setUpForSleep off", getCPUNumber());
				mpic->callPlatformFunction(mpic_setUpForSleep, false, (void *)true, (void *)getCPUNumber(), 0, 0);
			}
	
			kprintf("MacRISC2CPU::quiesceCPU %d -> keyLargo->saveRegisterState()\n", getCPUNumber());
			// Save KeyLargo's register state.
			keyLargo->callPlatformFunction(keyLargo_saveRegisterState, false, 0, 0, 0, 0);
	
			kprintf("MacRISC2CPU::quiesceCPU %d -> keyLargo->turnOffIO", getCPUNumber());
			// Turn Off all KeyLargo I/O.
			keyLargo->callPlatformFunction(keyLargo_turnOffIO, false, (void *)false, 0, 0, 0);
        }
        
        kprintf("MacRISC2CPU::quiesceCPU %d -> here\n", getCPUNumber());

        // Set the wake vector to point to the reset vector
        ml_phys_write(0x0080, 0x100);

        // Set the sleeping state for HWInit.
        macRISC2PE->writeUniNReg(kUniNHWInitState, kUniNHWInitStateSleeping);

        // Tell Uni-N to enter sleep mode.
        macRISC2PE->writeUniNReg(kUniNPowerMngmnt, processorSpeedChange ? kUniNIdle2 : kUniNSleep);
    }

    ml_ppc_sleep();
}

kern_return_t MacRISC2CPU::startCPU(vm_offset_t /*start_paddr*/, vm_offset_t /*arg_paddr*/)
{
    long gpioOffset = soft_reset_offset;

#if 0  
    switch (getCPUNumber())
    {
        case 0 : gpioOffset = 0x5B; break;
        case 1 : gpioOffset = 0x5C; break;
        case 2 : gpioOffset = 0x67; break;
        case 3 : gpioOffset = 0x68; break;
        default : return KERN_FAILURE;
    }
#endif
  
    // Strobe the reset line for this CPU.
    keyLargo->callPlatformFunction(keyLargo_writeRegUInt8, false, (void *)&gpioOffset, (void *)4, 0, 0);
    keyLargo->callPlatformFunction(keyLargo_writeRegUInt8, false, (void *)&gpioOffset, (void *)5, 0, 0);
  
    return KERN_SUCCESS;
}

void MacRISC2CPU::haltCPU(void)
{
	OSIterator 		*childIterator;
	IORegistryEntry *childEntry, *childDriver;
	IOPCIBridge		*pciDriver;
	OSData			*deviceTypeString;

  
    setCPUState(kIOCPUStateStopped);
  
    if (bootCPU)
    {
		// Notify our pci children to save their state
		if ((childIterator = macRISC2PE->getChildIterator (gIOServicePlane)) != NULL) {
			while ((childEntry = (IORegistryEntry *)(childIterator->getNextObject ())) != NULL) {
				deviceTypeString = OSDynamicCast( OSData, childEntry->getProperty( "device_type" ));
				if (deviceTypeString) {
					if (!strcmp((const char *)deviceTypeString->getBytesNoCopy(), "pci")) {
						childDriver = childEntry->copyChildEntry(gIOServicePlane);
						if (childDriver) {
							pciDriver = OSDynamicCast( IOPCIBridge, childDriver );
							if (pciDriver)
								// Got the driver - send the message
								pciDriver->setDevicePowerState (NULL, 2);
								
							childDriver->release();
						}
					}
				}
			}
		}
    }

   kprintf("MacRISC2CPU::haltCPU %d Here!\n", getCPUNumber());

   processor_exit(machProcessor);
}

void MacRISC2CPU::signalCPU(IOCPU *target)
{
    UInt32 physCPU = getCPUNumber();
    MacRISC2CPU *targetCPU = OSDynamicCast(MacRISC2CPU, target);
  
    if (targetCPU == 0) return;
  
    mpic->callPlatformFunction(mpic_dispatchIPI, false, (void *)&physCPU, (void *)(1 << targetCPU->getCPUNumber()), 0, 0);
}

void MacRISC2CPU::enableCPUTimeBase(bool enable)
{
    long gpioOffset = timebase_enable_offset;
    UInt8 value;
  
    //gpioOffset = 0x73;
    value = enable ? 5 : 4;

    keyLargo->callPlatformFunction(keyLargo_writeRegUInt8, false, (void *)&gpioOffset, (void *)value, 0, 0);
}

void MacRISC2CPU::ipiHandler(void *refCon, void *nub, int source)
{
    // Call mach IPI handler for this CPU.
    if (ipi_handler) ipi_handler();
}

const OSSymbol *MacRISC2CPU::getCPUName(void)
{
    char tmpStr[256];
  
    sprintf(tmpStr, "Primary%ld", getCPUNumber());
  
    return OSSymbol::withCString(tmpStr);
}