IOPMrootDomain.cpp [plain text]
#include <libkern/c++/OSKext.h>
#include <libkern/c++/OSMetaClass.h>
#include <libkern/OSAtomic.h>
#include <libkern/OSDebug.h>
#include <IOKit/IOWorkLoop.h>
#include <IOKit/IOCommandGate.h>
#include <IOKit/IOPlatformExpert.h>
#include <IOKit/IOKitDebug.h>
#include <IOKit/IOTimeStamp.h>
#include <IOKit/pwr_mgt/IOPMlog.h>
#include <IOKit/pwr_mgt/RootDomain.h>
#include <IOKit/pwr_mgt/IOPMPrivate.h>
#include <IOKit/IODeviceTreeSupport.h>
#include <IOKit/IOMessage.h>
#include <IOKit/IOReturn.h>
#include "RootDomainUserClient.h"
#include "IOKit/pwr_mgt/IOPowerConnection.h"
#include "IOPMPowerStateQueue.h"
#include <IOKit/IOCatalogue.h>
#if HIBERNATION
#include <IOKit/IOHibernatePrivate.h>
#endif
#include <sys/syslog.h>
#include <sys/sysctl.h>
#include <sys/time.h>
#include "IOServicePrivate.h" // _IOServiceInterestNotifier
#include "IOServicePMPrivate.h"
__BEGIN_DECLS
#include <mach/shared_region.h>
__END_DECLS
#if defined(__i386__) || defined(__x86_64__)
__BEGIN_DECLS
#include "IOPMrootDomainInternal.h"
__END_DECLS
#endif
#define kIOPMrootDomainClass "IOPMrootDomain"
#define LOG_PREFIX "PMRD: "
#define MSG(x...) \
do { kprintf(LOG_PREFIX x); IOLog(x); } while (false)
#define LOG(x...) \
do { kprintf(LOG_PREFIX x); } while (false)
#define DLOG(x...) do { \
if (kIOLogPMRootDomain & gIOKitDebug) \
kprintf(LOG_PREFIX x); } while (false)
#define _LOG(x...)
#define CHECK_THREAD_CONTEXT
#ifdef CHECK_THREAD_CONTEXT
static IOWorkLoop * gIOPMWorkLoop = 0;
#define ASSERT_GATED() \
do { \
if (gIOPMWorkLoop && gIOPMWorkLoop->inGate() != true) { \
panic("RootDomain: not inside PM gate"); \
} \
} while(false)
#else
#define ASSERT_GATED()
#endif
#define CAP_LOSS(c) \
(((_pendingCapability & (c)) == 0) && \
((_currentCapability & (c)) != 0))
#define CAP_GAIN(c) \
(((_currentCapability & (c)) == 0) && \
((_pendingCapability & (c)) != 0))
#define CAP_CHANGE(c) \
(((_currentCapability ^ _pendingCapability) & (c)) != 0)
#define CAP_CURRENT(c) \
((_currentCapability & (c)) != 0)
#define CAP_HIGHEST(c) \
((_highestCapability & (c)) != 0)
#define DARK_TO_FULL_EVALUATE_CLAMSHELL 0
enum {
kPowerEventFeatureChanged = 1, kPowerEventReceivedPowerNotification, kPowerEventSystemBootCompleted, kPowerEventSystemShutdown, kPowerEventUserDisabledSleep, kPowerEventRegisterSystemCapabilityClient, kPowerEventRegisterKernelCapabilityClient, kPowerEventPolicyStimulus, kPowerEventAssertionCreate, kPowerEventAssertionRelease, kPowerEventAssertionSetLevel, kPowerEventQueueSleepWakeUUID, kPowerEventPublishSleepWakeUUID };
enum {
kStimulusDisplayWranglerSleep, kStimulusDisplayWranglerWake, kStimulusAggressivenessChanged, kStimulusDemandSystemSleep, kStimulusAllowSystemSleepChanged, kStimulusDarkWakeActivityTickle, kStimulusDarkWakeEntry, kStimulusDarkWakeReentry, kStimulusDarkWakeEvaluate };
extern "C" {
IOReturn OSKextSystemSleepOrWake( UInt32 );
}
static void idleSleepTimerExpired( thread_call_param_t, thread_call_param_t );
static void notifySystemShutdown( IOService * root, unsigned long event );
static void handleAggressivesFunction( thread_call_param_t, thread_call_param_t );
static void pmEventTimeStamp(uint64_t *recordTS);
static const OSSymbol *sleepSupportedPEFunction = NULL;
static const OSSymbol *sleepMessagePEFunction = NULL;
#define kIOSleepSupportedKey "IOSleepSupported"
#define kIOPMSystemCapabilitiesKey "System Capabilities"
#define kRD_AllPowerSources (kIOPMSupportedOnAC \
| kIOPMSupportedOnBatt \
| kIOPMSupportedOnUPS)
enum
{
kAutoWakePreWindow = 45,
kAutoWakePostWindow = 15
};
#define kLocalEvalClamshellCommand (1 << 15)
enum {
OFF_STATE = 0,
RESTART_STATE = 1,
SLEEP_STATE = 2,
ON_STATE = 3,
NUM_POWER_STATES
};
#define ON_POWER kIOPMPowerOn
#define RESTART_POWER kIOPMRestart
#define SLEEP_POWER kIOPMAuxPowerOn
static IOPMPowerState ourPowerStates[NUM_POWER_STATES] =
{
{1, 0, 0, 0, 0,0,0,0,0,0,0,0},
{1, kIOPMRestartCapability, kIOPMRestart, RESTART_POWER, 0,0,0,0,0,0,0,0},
{1, kIOPMSleepCapability, kIOPMSleep, SLEEP_POWER, 0,0,0,0,0,0,0,0},
{1, kIOPMPowerOn, kIOPMPowerOn, ON_POWER, 0,0,0,0,0,0,0,0}
};
#define kIOPMRootDomainWakeTypeMaintenance "Maintenance"
#define kIOPMRootDomainWakeTypeSleepTimer "SleepTimer"
#define kIOPMrootDomainWakeTypeLowBattery "LowBattery"
#define kIOPMRootDomainWakeTypeUser "User"
#define kIOPMRootDomainWakeTypeAlarm "Alarm"
#define kIOPMRootDomainWakeTypeNetwork "Network"
#define kIOPMSystemCapabilityInterest "IOPMSystemCapabilityInterest"
#define AGGRESSIVES_LOCK() IOLockLock(featuresDictLock)
#define AGGRESSIVES_UNLOCK() IOLockUnlock(featuresDictLock)
#define kAggressivesMinValue 1
enum {
kAggressivesStateBusy = 0x01,
kAggressivesStateQuickSpindown = 0x02
};
struct AggressivesRecord {
uint32_t flags;
uint32_t type;
uint32_t value;
};
struct AggressivesRequest {
queue_chain_t chain;
uint32_t options;
uint32_t dataType;
union {
IOService * service;
AggressivesRecord record;
} data;
};
enum {
kAggressivesRequestTypeService = 1,
kAggressivesRequestTypeRecord
};
enum {
kAggressivesOptionSynchronous = 0x00000001,
kAggressivesOptionQuickSpindownEnable = 0x00000100,
kAggressivesOptionQuickSpindownDisable = 0x00000200,
kAggressivesOptionQuickSpindownMask = 0x00000300
};
enum {
kAggressivesRecordFlagModified = 0x00000001,
kAggressivesRecordFlagMinValue = 0x00000002
};
enum {
kDarkWakeFlagHIDTickleEarly = 0x01, kDarkWakeFlagHIDTickleLate = 0x02, kDarkWakeFlagHIDTickleNone = 0x03, kDarkWakeFlagHIDTickleMask = 0x03,
kDarkWakeFlagIgnoreDiskIOInDark = 0x04, kDarkWakeFlagIgnoreDiskIOAlways = 0x08, kDarkWakeFlagIgnoreDiskIOMask = 0x0C,
kDarkWakeFlagAlarmIsDark = 0x0100
};
static IOPMrootDomain * gRootDomain;
static IONotifier * gSysPowerDownNotifier = 0;
static UInt32 gSleepOrShutdownPending = 0;
static UInt32 gWillShutdown = 0;
static UInt32 gPagingOff = 0;
static UInt32 gSleepWakeUUIDIsSet = false;
static uint32_t gAggressivesState = 0;
static uint32_t gDarkWakeFlags = kDarkWakeFlagHIDTickleNone;
struct timeval gIOLastSleepTime;
struct timeval gIOLastWakeTime;
#define kCPUUnknownIndex 9999999
enum {
kInformAC = 0,
kInformLid = 1,
kInformableCount = 2
};
const OSSymbol *gIOPMStatsApplicationResponseTimedOut;
const OSSymbol *gIOPMStatsApplicationResponseCancel;
const OSSymbol *gIOPMStatsApplicationResponseSlow;
class PMSettingHandle : public OSObject
{
OSDeclareFinalStructors( PMSettingHandle )
friend class PMSettingObject;
private:
PMSettingObject *pmso;
void free(void);
};
class PMSettingObject : public OSObject
{
OSDeclareFinalStructors( PMSettingObject )
friend class IOPMrootDomain;
private:
queue_head_t calloutQueue;
thread_t waitThread;
IOPMrootDomain *parent;
PMSettingHandle *pmsh;
IOPMSettingControllerCallback func;
OSObject *target;
uintptr_t refcon;
uint32_t *publishedFeatureID;
uint32_t settingCount;
bool disabled;
void free(void);
public:
static PMSettingObject *pmSettingObject(
IOPMrootDomain *parent_arg,
IOPMSettingControllerCallback handler_arg,
OSObject *target_arg,
uintptr_t refcon_arg,
uint32_t supportedPowerSources,
const OSSymbol *settings[],
OSObject **handle_obj);
void dispatchPMSetting(const OSSymbol *type, OSObject *object);
void clientHandleFreed(void);
};
struct PMSettingCallEntry {
queue_chain_t link;
thread_t thread;
};
#define PMSETTING_LOCK() IOLockLock(settingsCtrlLock)
#define PMSETTING_UNLOCK() IOLockUnlock(settingsCtrlLock)
#define PMSETTING_WAIT(p) IOLockSleep(settingsCtrlLock, p, THREAD_UNINT)
#define PMSETTING_WAKEUP(p) IOLockWakeup(settingsCtrlLock, p, true)
class IOPMTimeline : public OSObject
{
OSDeclareDefaultStructors( IOPMTimeline );
public:
static IOPMTimeline* timeline(IOPMrootDomain *root_domain);
bool setProperties(OSDictionary *d);
OSDictionary *copyInfoDictionary(void);
IOReturn recordSystemPowerEvent( PMEventDetails *details );
IOReturn recordDetailedPowerEvent( PMEventDetails *details );
IOMemoryDescriptor *getPMTraceMemoryDescriptor();
uint32_t getNumEventsLoggedThisPeriod();
void setNumEventsLoggedThisPeriod(uint32_t newCount);
bool isSleepCycleInProgress();
void setSleepCycleInProgressFlag(bool flag);
private:
bool init(void);
void free(void);
void setEventsTrackedCount(uint32_t newTracked);
void setEventsRecordingLevel(uint32_t eventsTrackedBits);
static uint32_t _atomicIndexIncrement(uint32_t *index, uint32_t limit);
enum {
kPMTimelineRecordTardyDrivers = 1 << 0,
kPMTmielineRecordSystemEvents = 1 << 1,
kPMTimelineRecordAllDrivers = 1 << 2,
kPMTimelineRecordOff = 0,
kPMTimelineRecordDefault = 3,
kPMTimelineRecordDebug = 7
};
uint32_t eventsRecordingLevel;
IOBufferMemoryDescriptor *pmTraceMemoryDescriptor;
IOPMSystemEventRecord *traceBuffer;
IOPMTraceBufferHeader *hdr;
uint16_t systemState;
IOLock *logLock;
IOPMrootDomain *owner;
uint32_t numEventsLoggedThisPeriod;
bool sleepCycleInProgress;
};
OSDefineMetaClassAndStructors( IOPMTimeline, OSObject )
typedef void (*IOPMTracePointHandler)(
void * target, uint32_t code, uint32_t data );
class PMTraceWorker : public OSObject
{
OSDeclareDefaultStructors(PMTraceWorker)
public:
typedef enum { kPowerChangeStart, kPowerChangeCompleted } change_t;
static PMTraceWorker *tracer( IOPMrootDomain * );
void tracePCIPowerChange(change_t, IOService *, uint32_t, uint32_t);
void tracePoint(uint8_t phase);
void tracePoint(uint8_t phase, uint8_t data8);
void traceDetail(uint32_t detail);
void traceLoginWindowPhase(uint8_t phase);
int recordTopLevelPCIDevice(IOService *);
void RTC_TRACE(void);
virtual bool serialize(OSSerialize *s) const;
IOPMTracePointHandler tracePointHandler;
void * tracePointTarget;
private:
IOPMrootDomain *owner;
IOLock *pciMappingLock;
OSArray *pciDeviceBitMappings;
uint8_t addedToRegistry;
uint8_t tracePhase;
uint8_t loginWindowPhase;
uint8_t traceData8;
uint32_t traceData32;
};
class PMAssertionsTracker : public OSObject
{
OSDeclareFinalStructors(PMAssertionsTracker)
public:
static PMAssertionsTracker *pmAssertionsTracker( IOPMrootDomain * );
IOReturn createAssertion(IOPMDriverAssertionType, IOPMDriverAssertionLevel, IOService *, const char *, IOPMDriverAssertionID *);
IOReturn releaseAssertion(IOPMDriverAssertionID);
IOReturn setAssertionLevel(IOPMDriverAssertionID, IOPMDriverAssertionLevel);
IOReturn setUserAssertionLevels(IOPMDriverAssertionType);
OSArray *copyAssertionsArray(void);
IOPMDriverAssertionType getActivatedAssertions(void);
IOPMDriverAssertionLevel getAssertionLevel(IOPMDriverAssertionType);
IOReturn handleCreateAssertion(OSData *);
IOReturn handleReleaseAssertion(IOPMDriverAssertionID);
IOReturn handleSetAssertionLevel(IOPMDriverAssertionID, IOPMDriverAssertionLevel);
IOReturn handleSetUserAssertionLevels(void * arg0);
void publishProperties(void);
private:
typedef struct {
IOPMDriverAssertionID id;
IOPMDriverAssertionType assertionBits;
uint64_t createdTime;
uint64_t modifiedTime;
const OSSymbol *ownerString;
IOService *ownerService;
IOPMDriverAssertionLevel level;
} PMAssertStruct;
uint32_t tabulateProducerCount;
uint32_t tabulateConsumerCount;
PMAssertStruct *detailsForID(IOPMDriverAssertionID, int *);
void tabulate(void);
IOPMrootDomain *owner;
OSArray *assertionsArray;
IOLock *assertionsArrayLock;
IOPMDriverAssertionID issuingUniqueID __attribute__((aligned(8)));
IOPMDriverAssertionType assertionsKernel;
IOPMDriverAssertionType assertionsUser;
IOPMDriverAssertionType assertionsCombined;
};
OSDefineMetaClassAndFinalStructors(PMAssertionsTracker, OSObject);
#define kPMHaltMaxWorkers 8
#define kPMHaltTimeoutMS 100
class PMHaltWorker : public OSObject
{
OSDeclareFinalStructors( PMHaltWorker )
public:
IOService * service; AbsoluteTime startTime; int depth; int visits; IOLock * lock;
bool timeout;
static PMHaltWorker * worker( void );
static void main( void * arg, wait_result_t waitResult );
static void work( PMHaltWorker * me );
static void checkTimeout( PMHaltWorker * me, AbsoluteTime * now );
virtual void free( void );
};
OSDefineMetaClassAndFinalStructors( PMHaltWorker, OSObject )
#define super IOService
OSDefineMetaClassAndFinalStructors(IOPMrootDomain, IOService)
static void IOPMRootDomainWillShutdown(void)
{
if (OSCompareAndSwap(0, 1, &gWillShutdown))
{
OSKext::willShutdown();
for (int i = 0; i < 100; i++)
{
if (OSCompareAndSwap(0, 1, &gSleepOrShutdownPending)) break;
IOSleep( 100 );
}
}
}
extern "C"
{
IONotifier * registerSleepWakeInterest(IOServiceInterestHandler handler, void * self, void * ref)
{
return gRootDomain->registerInterest( gIOGeneralInterest, handler, self, ref );
}
IONotifier * registerPrioritySleepWakeInterest(IOServiceInterestHandler handler, void * self, void * ref)
{
return gRootDomain->registerInterest( gIOPriorityPowerStateInterest, handler, self, ref );
}
IOReturn acknowledgeSleepWakeNotification(void * PMrefcon)
{
return gRootDomain->allowPowerChange ( (unsigned long)PMrefcon );
}
IOReturn vetoSleepWakeNotification(void * PMrefcon)
{
return gRootDomain->cancelPowerChange ( (unsigned long)PMrefcon );
}
IOReturn rootDomainRestart ( void )
{
return gRootDomain->restartSystem();
}
IOReturn rootDomainShutdown ( void )
{
return gRootDomain->shutdownSystem();
}
void IOSystemShutdownNotification(void)
{
IOPMRootDomainWillShutdown();
if (OSCompareAndSwap(0, 1, &gPagingOff))
{
#if !CONFIG_EMBEDDED
gRootDomain->handlePlatformHaltRestart(kPEPagingOff);
#endif
}
}
int sync_internal(void);
}
IOPMrootDomain * IOPMrootDomain::construct( void )
{
IOPMrootDomain *root;
root = new IOPMrootDomain;
if( root)
root->init();
return( root );
}
static void disk_sync_callout( thread_call_param_t p0, thread_call_param_t p1 )
{
IOService * rootDomain = (IOService *) p0;
uint32_t notifyRef = (uint32_t)(uintptr_t) p1;
uint32_t powerState = rootDomain->getPowerState();
DLOG("disk_sync_callout ps=%u\n", powerState);
if (ON_STATE == powerState)
{
#if HIBERNATION
IOHibernateSystemSleep();
#endif
sync_internal();
}
#if HIBERNATION
else
{
IOHibernateSystemPostWake();
}
#endif
rootDomain->allowPowerChange(notifyRef);
DLOG("disk_sync_callout finish\n");
}
static UInt32 computeDeltaTimeMS( const AbsoluteTime * startTime )
{
AbsoluteTime endTime;
UInt64 nano = 0;
clock_get_uptime(&endTime);
if (CMP_ABSOLUTETIME(&endTime, startTime) > 0)
{
SUB_ABSOLUTETIME(&endTime, startTime);
absolutetime_to_nanoseconds(endTime, &nano);
}
return (UInt32)(nano / 1000000ULL);
}
static int
sysctl_sleepwaketime SYSCTL_HANDLER_ARGS
{
struct timeval *swt = (struct timeval *)arg1;
struct proc *p = req->p;
if (p == kernproc) {
return sysctl_io_opaque(req, swt, sizeof(*swt), NULL);
} else if(proc_is64bit(p)) {
struct user64_timeval t;
t.tv_sec = swt->tv_sec;
t.tv_usec = swt->tv_usec;
return sysctl_io_opaque(req, &t, sizeof(t), NULL);
} else {
struct user32_timeval t;
t.tv_sec = swt->tv_sec;
t.tv_usec = swt->tv_usec;
return sysctl_io_opaque(req, &t, sizeof(t), NULL);
}
}
static SYSCTL_PROC(_kern, OID_AUTO, sleeptime,
CTLTYPE_STRUCT | CTLFLAG_RD | CTLFLAG_NOAUTO | CTLFLAG_KERN | CTLFLAG_LOCKED,
&gIOLastSleepTime, 0, sysctl_sleepwaketime, "S,timeval", "");
static SYSCTL_PROC(_kern, OID_AUTO, waketime,
CTLTYPE_STRUCT | CTLFLAG_RD | CTLFLAG_NOAUTO | CTLFLAG_KERN | CTLFLAG_LOCKED,
&gIOLastWakeTime, 0, sysctl_sleepwaketime, "S,timeval", "");
static int
sysctl_willshutdown
(__unused struct sysctl_oid *oidp, __unused void *arg1, __unused int arg2, struct sysctl_req *req)
{
int new_value, changed;
int error = sysctl_io_number(req, gWillShutdown, sizeof(int), &new_value, &changed);
if (changed) {
if (!gWillShutdown && (new_value == 1)) {
IOPMRootDomainWillShutdown();
} else
error = EINVAL;
}
return(error);
}
static SYSCTL_PROC(_kern, OID_AUTO, willshutdown,
CTLTYPE_INT | CTLFLAG_RW | CTLFLAG_NOAUTO | CTLFLAG_KERN | CTLFLAG_LOCKED,
0, 0, sysctl_willshutdown, "I", "");
#if !CONFIG_EMBEDDED
static int
sysctl_progressmeterenable
(__unused struct sysctl_oid *oidp, __unused void *arg1, __unused int arg2, struct sysctl_req *req)
{
int error;
int new_value, changed;
error = sysctl_io_number(req, vc_progress_meter_enable, sizeof(int), &new_value, &changed);
if (changed)
vc_enable_progressmeter(new_value);
return (error);
}
static int
sysctl_progressmeter
(__unused struct sysctl_oid *oidp, __unused void *arg1, __unused int arg2, struct sysctl_req *req)
{
int error;
int new_value, changed;
error = sysctl_io_number(req, vc_progress_meter_value, sizeof(int), &new_value, &changed);
if (changed)
vc_set_progressmeter(new_value);
return (error);
}
static SYSCTL_PROC(_kern, OID_AUTO, progressmeterenable,
CTLTYPE_INT | CTLFLAG_RW | CTLFLAG_NOAUTO | CTLFLAG_KERN | CTLFLAG_LOCKED,
0, 0, sysctl_progressmeterenable, "I", "");
static SYSCTL_PROC(_kern, OID_AUTO, progressmeter,
CTLTYPE_INT | CTLFLAG_RW | CTLFLAG_NOAUTO | CTLFLAG_KERN | CTLFLAG_LOCKED,
0, 0, sysctl_progressmeter, "I", "");
#endif
static SYSCTL_INT(_debug, OID_AUTO, darkwake, CTLFLAG_RW, &gDarkWakeFlags, 0, "");
static const OSSymbol * gIOPMSettingAutoWakeSecondsKey;
static const OSSymbol * gIOPMSettingDebugWakeRelativeKey;
static const OSSymbol * gIOPMSettingMaintenanceWakeCalendarKey;
#define kRootDomainSettingsCount 16
bool IOPMrootDomain::start( IOService * nub )
{
OSIterator *psIterator;
OSDictionary *tmpDict;
IORootParent * patriarch;
super::start(nub);
gRootDomain = this;
gIOPMSettingAutoWakeSecondsKey = OSSymbol::withCString(kIOPMSettingAutoWakeSecondsKey);
gIOPMSettingDebugWakeRelativeKey = OSSymbol::withCString(kIOPMSettingDebugWakeRelativeKey);
gIOPMSettingMaintenanceWakeCalendarKey =
OSSymbol::withCString(kIOPMSettingMaintenanceWakeCalendarKey);
gIOPMStatsApplicationResponseTimedOut = OSSymbol::withCString(kIOPMStatsResponseTimedOut);
gIOPMStatsApplicationResponseCancel = OSSymbol::withCString(kIOPMStatsResponseCancel);
gIOPMStatsApplicationResponseSlow = OSSymbol::withCString(kIOPMStatsResponseSlow);
sleepSupportedPEFunction = OSSymbol::withCString("IOPMSetSleepSupported");
sleepMessagePEFunction = OSSymbol::withCString("IOPMSystemSleepMessage");
const OSSymbol *settingsArr[kRootDomainSettingsCount] =
{
OSSymbol::withCString(kIOPMSettingSleepOnPowerButtonKey),
gIOPMSettingAutoWakeSecondsKey,
OSSymbol::withCString(kIOPMSettingAutoPowerSecondsKey),
OSSymbol::withCString(kIOPMSettingAutoWakeCalendarKey),
OSSymbol::withCString(kIOPMSettingAutoPowerCalendarKey),
gIOPMSettingDebugWakeRelativeKey,
OSSymbol::withCString(kIOPMSettingDebugPowerRelativeKey),
OSSymbol::withCString(kIOPMSettingWakeOnRingKey),
OSSymbol::withCString(kIOPMSettingRestartOnPowerLossKey),
OSSymbol::withCString(kIOPMSettingWakeOnClamshellKey),
OSSymbol::withCString(kIOPMSettingWakeOnACChangeKey),
OSSymbol::withCString(kIOPMSettingTimeZoneOffsetKey),
OSSymbol::withCString(kIOPMSettingDisplaySleepUsesDimKey),
OSSymbol::withCString(kIOPMSettingMobileMotionModuleKey),
OSSymbol::withCString(kIOPMSettingGraphicsSwitchKey),
OSSymbol::withCString(kIOPMStateConsoleShutdown)
};
PE_parse_boot_argn("darkwake", &gDarkWakeFlags, sizeof(gDarkWakeFlags));
queue_init(&aggressivesQueue);
aggressivesThreadCall = thread_call_allocate(handleAggressivesFunction, this);
aggressivesData = OSData::withCapacity(
sizeof(AggressivesRecord) * (kPMLastAggressivenessType + 4));
featuresDictLock = IOLockAlloc();
settingsCtrlLock = IOLockAlloc();
setPMRootDomain(this);
extraSleepTimer = thread_call_allocate(
idleSleepTimerExpired,
(thread_call_param_t) this);
diskSyncCalloutEntry = thread_call_allocate(
&disk_sync_callout,
(thread_call_param_t) this);
setProperty(kIOSleepSupportedKey, true);
bzero(&pmStats, sizeof(pmStats));
pmTracer = PMTraceWorker::tracer(this);
pmAssertions = PMAssertionsTracker::pmAssertionsTracker(this);
userDisabledAllSleep = false;
systemBooting = true;
sleepSlider = 0;
idleSleepTimerPending = false;
wrangler = NULL;
clamshellClosed = false;
clamshellExists = false;
clamshellDisabled = true;
acAdaptorConnected = true;
_currentCapability = kIOPMSystemCapabilityCPU |
kIOPMSystemCapabilityGraphics |
kIOPMSystemCapabilityAudio |
kIOPMSystemCapabilityNetwork;
_pendingCapability = _currentCapability;
_desiredCapability = _currentCapability;
_highestCapability = _currentCapability;
setProperty(kIOPMSystemCapabilitiesKey, _currentCapability, 64);
queuedSleepWakeUUIDString = NULL;
pmStatsAppResponses = OSArray::withCapacity(5);
_statsNameKey = OSSymbol::withCString(kIOPMStatsNameKey);
_statsPIDKey = OSSymbol::withCString(kIOPMStatsPIDKey);
_statsTimeMSKey = OSSymbol::withCString(kIOPMStatsTimeMSKey);
_statsResponseTypeKey = OSSymbol::withCString(kIOPMStatsApplicationResponseTypeKey);
_statsMessageTypeKey = OSSymbol::withCString(kIOPMStatsMessageTypeKey);
idxPMCPUClamshell = kCPUUnknownIndex;
idxPMCPULimitedPower = kCPUUnknownIndex;
tmpDict = OSDictionary::withCapacity(1);
setProperty(kRootDomainSupportedFeatures, tmpDict);
tmpDict->release();
settingsCallbacks = OSDictionary::withCapacity(1);
allowedPMSettings = OSArray::withObjects(
(const OSObject **)settingsArr,
kRootDomainSettingsCount,
0);
fPMSettingsDict = OSDictionary::withCapacity(5);
PMinit();
pmPowerStateQueue = IOPMPowerStateQueue::PMPowerStateQueue(
this, OSMemberFunctionCast(IOEventSource::Action, this,
&IOPMrootDomain::dispatchPowerEvent));
getPMworkloop()->addEventSource(pmPowerStateQueue);
#ifdef CHECK_THREAD_CONTEXT
gIOPMWorkLoop = getPMworkloop();
#endif
patriarch = new IORootParent;
patriarch->init();
patriarch->attach(this);
patriarch->start(this);
patriarch->addPowerChild(this);
registerPowerDriver(this, ourPowerStates, NUM_POWER_STATES);
changePowerStateToPriv(ON_STATE);
if (gIOKitDebug & (kIOLogDriverPower1 | kIOLogDriverPower2))
{
timeline = IOPMTimeline::timeline(this);
if (timeline) {
OSDictionary *tlInfo = timeline->copyInfoDictionary();
if (tlInfo)
{
setProperty(kIOPMTimelineDictionaryKey, tlInfo);
tlInfo->release();
}
}
}
gSysPowerDownNotifier = registerPrioritySleepWakeInterest( &sysPowerDownHandler, this, 0);
#if !NO_KERNEL_HID
if ((tmpDict = serviceMatching("IODisplayWrangler")))
{
_displayWranglerNotifier = addMatchingNotification(
gIOPublishNotification, tmpDict,
(IOServiceMatchingNotificationHandler) &displayWranglerMatchPublished,
this, 0);
tmpDict->release();
}
#endif
const OSSymbol *ucClassName = OSSymbol::withCStringNoCopy("RootDomainUserClient");
setProperty(gIOUserClientClassKey, (OSObject *) ucClassName);
ucClassName->release();
psIterator = getMatchingServices( serviceMatching("IOPMPowerSource") );
if( psIterator && psIterator->getNextObject() )
{
publishFeature("DisplayDims");
}
if(psIterator) {
psIterator->release();
}
sysctl_register_oid(&sysctl__kern_sleeptime);
sysctl_register_oid(&sysctl__kern_waketime);
sysctl_register_oid(&sysctl__kern_willshutdown);
#if !CONFIG_EMBEDDED
sysctl_register_oid(&sysctl__kern_progressmeterenable);
sysctl_register_oid(&sysctl__kern_progressmeter);
#endif
#if HIBERNATION
IOHibernateSystemInit(this);
#endif
registerService();
return true;
}
IOReturn IOPMrootDomain::setProperties( OSObject * props_obj )
{
IOReturn return_value = kIOReturnSuccess;
OSDictionary *dict = OSDynamicCast(OSDictionary, props_obj);
OSBoolean *b;
OSNumber *n;
OSDictionary *d;
OSSymbol *type;
OSObject *obj;
unsigned int i;
const OSSymbol *publish_simulated_battery_string = OSSymbol::withCString("SoftwareSimulatedBatteries");
const OSSymbol *boot_complete_string = OSSymbol::withCString("System Boot Complete");
const OSSymbol *sys_shutdown_string = OSSymbol::withCString("System Shutdown");
const OSSymbol *stall_halt_string = OSSymbol::withCString("StallSystemAtHalt");
const OSSymbol *battery_warning_disabled_string = OSSymbol::withCString("BatteryWarningsDisabled");
const OSSymbol *idle_seconds_string = OSSymbol::withCString("System Idle Seconds");
const OSSymbol *sleepdisabled_string = OSSymbol::withCString("SleepDisabled");
const OSSymbol *ondeck_sleepwake_uuid_string = OSSymbol::withCString(kIOPMSleepWakeUUIDKey);
const OSSymbol *loginwindow_tracepoint_string = OSSymbol::withCString(kIOPMLoginWindowSecurityDebugKey);
const OSSymbol *pmTimelineLogging_string = OSSymbol::withCString(kIOPMTimelineDictionaryKey);
#if HIBERNATION
const OSSymbol *hibernatemode_string = OSSymbol::withCString(kIOHibernateModeKey);
const OSSymbol *hibernatefile_string = OSSymbol::withCString(kIOHibernateFileKey);
const OSSymbol *hibernatefreeratio_string = OSSymbol::withCString(kIOHibernateFreeRatioKey);
const OSSymbol *hibernatefreetime_string = OSSymbol::withCString(kIOHibernateFreeTimeKey);
#endif
if (!dict)
{
return_value = kIOReturnBadArgument;
goto exit;
}
if ((b = OSDynamicCast(OSBoolean, dict->getObject(publish_simulated_battery_string))))
{
publishResource(publish_simulated_battery_string, kOSBooleanTrue);
}
if ((n = OSDynamicCast(OSNumber, dict->getObject(idle_seconds_string))))
{
setProperty(idle_seconds_string, n);
idleSeconds = n->unsigned32BitValue();
}
if (boot_complete_string && dict->getObject(boot_complete_string))
{
pmPowerStateQueue->submitPowerEvent( kPowerEventSystemBootCompleted );
}
if( battery_warning_disabled_string && dict->getObject(battery_warning_disabled_string))
{
setProperty( battery_warning_disabled_string, dict->getObject(battery_warning_disabled_string));
}
if (pmTimelineLogging_string && (d = OSDynamicCast(OSDictionary, dict->getObject(pmTimelineLogging_string))))
{
if (timeline && timeline->setProperties(d))
{
OSDictionary *tlInfo = timeline->copyInfoDictionary();
if (tlInfo) {
setProperty(kIOPMTimelineDictionaryKey, tlInfo);
tlInfo->release();
}
}
}
if( sys_shutdown_string && (b = OSDynamicCast(OSBoolean, dict->getObject(sys_shutdown_string))))
{
pmPowerStateQueue->submitPowerEvent(kPowerEventSystemShutdown, (void *) b);
}
if( stall_halt_string && (b = OSDynamicCast(OSBoolean, dict->getObject(stall_halt_string))) )
{
setProperty(stall_halt_string, b);
}
#if HIBERNATION
if ( hibernatemode_string
&& (n = OSDynamicCast(OSNumber, dict->getObject(hibernatemode_string))))
{
setProperty(hibernatemode_string, n);
}
if ( hibernatefreeratio_string
&& (n = OSDynamicCast(OSNumber, dict->getObject(hibernatefreeratio_string))))
{
setProperty(hibernatefreeratio_string, n);
}
if ( hibernatefreetime_string
&& (n = OSDynamicCast(OSNumber, dict->getObject(hibernatefreetime_string))))
{
setProperty(hibernatefreetime_string, n);
}
OSString *str;
if ( hibernatefile_string
&& (str = OSDynamicCast(OSString, dict->getObject(hibernatefile_string))))
{
setProperty(hibernatefile_string, str);
}
#endif
if( sleepdisabled_string
&& (b = OSDynamicCast(OSBoolean, dict->getObject(sleepdisabled_string))) )
{
setProperty(sleepdisabled_string, b);
pmPowerStateQueue->submitPowerEvent(kPowerEventUserDisabledSleep, (void *) b);
}
if (ondeck_sleepwake_uuid_string
&& (obj = dict->getObject(ondeck_sleepwake_uuid_string)))
{
if(pmPowerStateQueue) {
obj->retain();
pmPowerStateQueue->submitPowerEvent(kPowerEventQueueSleepWakeUUID, (void *)obj);
}
}
if (loginwindow_tracepoint_string
&& (n = OSDynamicCast(OSNumber, dict->getObject(loginwindow_tracepoint_string)))
&& pmTracer)
{
pmTracer->traceLoginWindowPhase( n->unsigned8BitValue() );
}
if ((b = OSDynamicCast(OSBoolean, dict->getObject(kIOPMDeepSleepEnabledKey))))
{
setProperty(kIOPMDeepSleepEnabledKey, b);
}
if ((n = OSDynamicCast(OSNumber, dict->getObject(kIOPMDeepSleepDelayKey))))
{
setProperty(kIOPMDeepSleepDelayKey, n);
}
if ((b = OSDynamicCast(OSBoolean, dict->getObject(kIOPMDestroyFVKeyOnStandbyKey))))
{
setProperty(kIOPMDestroyFVKeyOnStandbyKey, b);
}
for(i = 0; i < allowedPMSettings->getCount(); i++) {
type = (OSSymbol *)allowedPMSettings->getObject(i);
if(!type) continue;
obj = dict->getObject(type);
if(!obj) continue;
if ((gIOPMSettingAutoWakeSecondsKey == type) && ((n = OSDynamicCast(OSNumber, obj))))
{
UInt32 rsecs = n->unsigned32BitValue();
if (!rsecs)
autoWakeStart = autoWakeEnd = 0;
else
{
AbsoluteTime deadline;
clock_interval_to_deadline(rsecs + kAutoWakePostWindow, kSecondScale, &deadline);
autoWakeEnd = AbsoluteTime_to_scalar(&deadline);
if (rsecs > kAutoWakePreWindow)
rsecs -= kAutoWakePreWindow;
else
rsecs = 0;
clock_interval_to_deadline(rsecs, kSecondScale, &deadline);
autoWakeStart = AbsoluteTime_to_scalar(&deadline);
}
}
if (gIOPMSettingDebugWakeRelativeKey == type)
{
if ((n = OSDynamicCast(OSNumber, obj)))
_debugWakeSeconds = n->unsigned32BitValue();
else
_debugWakeSeconds = 0;
}
return_value = setPMSetting(type, obj);
if(kIOReturnSuccess != return_value) goto exit;
}
exit:
if(publish_simulated_battery_string) publish_simulated_battery_string->release();
if(boot_complete_string) boot_complete_string->release();
if(sys_shutdown_string) sys_shutdown_string->release();
if(stall_halt_string) stall_halt_string->release();
if(battery_warning_disabled_string) battery_warning_disabled_string->release();
if(idle_seconds_string) idle_seconds_string->release();
if(sleepdisabled_string) sleepdisabled_string->release();
if(ondeck_sleepwake_uuid_string) ondeck_sleepwake_uuid_string->release();
if(loginwindow_tracepoint_string) loginwindow_tracepoint_string->release();
if(pmTimelineLogging_string) pmTimelineLogging_string->release();
#if HIBERNATION
if(hibernatemode_string) hibernatemode_string->release();
if(hibernatefile_string) hibernatefile_string->release();
if(hibernatefreeratio_string) hibernatefreeratio_string->release();
if(hibernatefreetime_string) hibernatefreetime_string->release();
#endif
return return_value;
}
IOReturn IOPMrootDomain::setAggressiveness(
unsigned long type,
unsigned long value )
{
return setAggressiveness( type, value, 0 );
}
IOReturn IOPMrootDomain::setAggressiveness(
unsigned long type,
unsigned long value,
IOOptionBits options )
{
AggressivesRequest * entry;
AggressivesRequest * request;
bool found = false;
DLOG("setAggressiveness(%x) 0x%x = %u\n",
(uint32_t) options, (uint32_t) type, (uint32_t) value);
request = IONew(AggressivesRequest, 1);
if (!request)
return kIOReturnNoMemory;
memset(request, 0, sizeof(*request));
request->options = options;
request->dataType = kAggressivesRequestTypeRecord;
request->data.record.type = (uint32_t) type;
request->data.record.value = (uint32_t) value;
AGGRESSIVES_LOCK();
if (options & kAggressivesOptionQuickSpindownEnable)
gAggressivesState |= kAggressivesStateQuickSpindown;
else if (options & kAggressivesOptionQuickSpindownDisable)
gAggressivesState &= ~kAggressivesStateQuickSpindown;
else
{
queue_iterate(&aggressivesQueue, entry, AggressivesRequest *, chain)
{
if ((entry->dataType == kAggressivesRequestTypeRecord) &&
(entry->data.record.type == type) &&
((entry->options & kAggressivesOptionQuickSpindownMask) == 0))
{
entry->data.record.value = value;
found = true;
break;
}
}
}
if (!found)
{
queue_enter(&aggressivesQueue, request, AggressivesRequest *, chain);
}
AGGRESSIVES_UNLOCK();
if (found)
IODelete(request, AggressivesRequest, 1);
if (options & kAggressivesOptionSynchronous)
handleAggressivesRequests(); else
thread_call_enter(aggressivesThreadCall);
return kIOReturnSuccess;
}
IOReturn IOPMrootDomain::getAggressiveness (
unsigned long type,
unsigned long * outLevel )
{
uint32_t value = 0;
int source = 0;
if (!outLevel)
return kIOReturnBadArgument;
AGGRESSIVES_LOCK();
if ((gAggressivesState & kAggressivesStateQuickSpindown) &&
(type == kPMMinutesToSpinDown))
{
value = kAggressivesMinValue;
source = 1;
}
if (!source)
{
AggressivesRequest * entry;
queue_iterate(&aggressivesQueue, entry, AggressivesRequest *, chain)
{
if ((entry->dataType == kAggressivesRequestTypeRecord) &&
(entry->data.record.type == type) &&
((entry->options & kAggressivesOptionQuickSpindownMask) == 0))
{
value = entry->data.record.value;
source = 2;
break;
}
}
}
if (!source && aggressivesData)
{
AggressivesRecord * record;
int i, count;
count = aggressivesData->getLength() / sizeof(AggressivesRecord);
record = (AggressivesRecord *) aggressivesData->getBytesNoCopy();
for (i = 0; i < count; i++, record++)
{
if (record->type == type)
{
value = record->value;
source = 3;
break;
}
}
}
AGGRESSIVES_UNLOCK();
if (source)
{
DLOG("getAggressiveness(%d) 0x%x = %u\n",
source, (uint32_t) type, value);
*outLevel = (unsigned long) value;
return kIOReturnSuccess;
}
else
{
DLOG("getAggressiveness type 0x%x not found\n", (uint32_t) type);
*outLevel = 0; return kIOReturnInvalid;
}
}
IOReturn IOPMrootDomain::joinAggressiveness(
IOService * service )
{
AggressivesRequest * request;
if (!service || (service == this))
return kIOReturnBadArgument;
DLOG("joinAggressiveness %s %p\n", service->getName(), service);
request = IONew(AggressivesRequest, 1);
if (!request)
return kIOReturnNoMemory;
service->retain();
memset(request, 0, sizeof(*request));
request->dataType = kAggressivesRequestTypeService;
request->data.service = service;
AGGRESSIVES_LOCK();
queue_enter(&aggressivesQueue, request, AggressivesRequest *, chain);
AGGRESSIVES_UNLOCK();
thread_call_enter(aggressivesThreadCall);
return kIOReturnSuccess;
}
static void
handleAggressivesFunction(
thread_call_param_t param1,
thread_call_param_t param2 )
{
if (param1)
{
((IOPMrootDomain *) param1)->handleAggressivesRequests();
}
}
void IOPMrootDomain::handleAggressivesRequests( void )
{
AggressivesRecord * start;
AggressivesRecord * record;
AggressivesRequest * request;
queue_head_t joinedQueue;
int i, count;
bool broadcast;
bool found;
bool pingSelf = false;
AGGRESSIVES_LOCK();
if ((gAggressivesState & kAggressivesStateBusy) || !aggressivesData ||
queue_empty(&aggressivesQueue))
goto unlock_done;
gAggressivesState |= kAggressivesStateBusy;
count = aggressivesData->getLength() / sizeof(AggressivesRecord);
start = (AggressivesRecord *) aggressivesData->getBytesNoCopy();
do
{
broadcast = false;
queue_init(&joinedQueue);
do
{
queue_remove_first(&aggressivesQueue, request, AggressivesRequest *, chain);
switch (request->dataType)
{
case kAggressivesRequestTypeRecord:
found = false;
for (i = 0, record = start; i < count; i++, record++)
{
if (record->type == request->data.record.type)
{
found = true;
if (request->options & kAggressivesOptionQuickSpindownEnable)
{
if ((record->flags & kAggressivesRecordFlagMinValue) == 0)
{
broadcast = true;
record->flags |= (kAggressivesRecordFlagMinValue |
kAggressivesRecordFlagModified);
DLOG("disk spindown accelerated, was %u min\n",
record->value);
}
}
else if (request->options & kAggressivesOptionQuickSpindownDisable)
{
if (record->flags & kAggressivesRecordFlagMinValue)
{
broadcast = true;
record->flags |= kAggressivesRecordFlagModified;
record->flags &= ~kAggressivesRecordFlagMinValue;
DLOG("disk spindown restored to %u min\n",
record->value);
}
}
else if (record->value != request->data.record.value)
{
record->value = request->data.record.value;
if ((record->flags & kAggressivesRecordFlagMinValue) == 0)
{
broadcast = true;
record->flags |= kAggressivesRecordFlagModified;
}
}
break;
}
}
if (!found &&
((request->options & kAggressivesOptionQuickSpindownDisable) == 0))
{
AggressivesRecord newRecord;
newRecord.flags = kAggressivesRecordFlagModified;
newRecord.type = request->data.record.type;
newRecord.value = request->data.record.value;
if (request->options & kAggressivesOptionQuickSpindownEnable)
{
newRecord.flags |= kAggressivesRecordFlagMinValue;
DLOG("disk spindown accelerated\n");
}
aggressivesData->appendBytes(&newRecord, sizeof(newRecord));
count = aggressivesData->getLength() / sizeof(AggressivesRecord);
start = (AggressivesRecord *) aggressivesData->getBytesNoCopy();
broadcast = true;
}
IODelete(request, AggressivesRequest, 1);
break;
case kAggressivesRequestTypeService:
queue_enter(&joinedQueue, request, AggressivesRequest *, chain);
break;
default:
panic("bad aggressives request type %x\n", request->dataType);
break;
}
} while (!queue_empty(&aggressivesQueue));
if (!queue_empty(&joinedQueue) || broadcast)
{
AGGRESSIVES_UNLOCK();
if (!queue_empty(&joinedQueue))
synchronizeAggressives(&joinedQueue, start, count);
if (broadcast)
broadcastAggressives(start, count);
AGGRESSIVES_LOCK();
}
for (i = 0, record = start; i < count; i++, record++)
{
if ((record->flags & kAggressivesRecordFlagModified) &&
((record->type == kPMMinutesToDim) ||
(record->type == kPMMinutesToSleep)))
pingSelf = true;
record->flags &= ~kAggressivesRecordFlagModified;
}
} while (!queue_empty(&aggressivesQueue));
gAggressivesState &= ~kAggressivesStateBusy;
unlock_done:
AGGRESSIVES_UNLOCK();
if (pingSelf && pmPowerStateQueue) {
pmPowerStateQueue->submitPowerEvent(
kPowerEventPolicyStimulus,
(void *) kStimulusAggressivenessChanged );
}
}
void IOPMrootDomain::synchronizeAggressives(
queue_head_t * joinedQueue,
const AggressivesRecord * array,
int count )
{
IOService * service;
AggressivesRequest * request;
const AggressivesRecord * record;
IOPMDriverCallEntry callEntry;
uint32_t value;
int i;
while (!queue_empty(joinedQueue))
{
queue_remove_first(joinedQueue, request, AggressivesRequest *, chain);
if (request->dataType == kAggressivesRequestTypeService)
service = request->data.service;
else
service = 0;
IODelete(request, AggressivesRequest, 1);
request = 0;
if (service)
{
if (service->assertPMDriverCall(&callEntry))
{
for (i = 0, record = array; i < count; i++, record++)
{
value = record->value;
if (record->flags & kAggressivesRecordFlagMinValue)
value = kAggressivesMinValue;
_LOG("synchronizeAggressives 0x%x = %u to %s\n",
record->type, value, service->getName());
service->setAggressiveness(record->type, value);
}
service->deassertPMDriverCall(&callEntry);
}
service->release(); }
}
}
void IOPMrootDomain::broadcastAggressives(
const AggressivesRecord * array,
int count )
{
IORegistryIterator * iter;
IORegistryEntry * entry;
IOPowerConnection * connect;
IOService * service;
const AggressivesRecord * record;
IOPMDriverCallEntry callEntry;
uint32_t value;
int i;
iter = IORegistryIterator::iterateOver(
this, gIOPowerPlane, kIORegistryIterateRecursively);
if (iter)
{
do
{
iter->reset();
while ((entry = iter->getNextObject()))
{
connect = OSDynamicCast(IOPowerConnection, entry);
if (!connect || !connect->getReadyFlag())
continue;
if ((service = (IOService *) connect->copyChildEntry(gIOPowerPlane)))
{
if (service->assertPMDriverCall(&callEntry))
{
for (i = 0, record = array; i < count; i++, record++)
{
if (record->flags & kAggressivesRecordFlagModified)
{
value = record->value;
if (record->flags & kAggressivesRecordFlagMinValue)
value = kAggressivesMinValue;
_LOG("broadcastAggressives %x = %u to %s\n",
record->type, value, service->getName());
service->setAggressiveness(record->type, value);
}
}
service->deassertPMDriverCall(&callEntry);
}
service->release();
}
}
}
while (!entry && !iter->isValid());
iter->release();
}
}
void IOPMrootDomain::startIdleSleepTimer( uint32_t inSeconds )
{
AbsoluteTime deadline;
ASSERT_GATED();
if (inSeconds)
{
clock_interval_to_deadline(inSeconds, kSecondScale, &deadline);
thread_call_enter_delayed(extraSleepTimer, deadline);
idleSleepTimerPending = true;
DLOG("idle timer set for %u seconds\n", inSeconds);
}
}
void IOPMrootDomain::cancelIdleSleepTimer( void )
{
ASSERT_GATED();
if (idleSleepTimerPending)
{
DLOG("idle timer cancelled\n");
thread_call_cancel(extraSleepTimer);
idleSleepTimerPending = false;
}
}
static void idleSleepTimerExpired(
thread_call_param_t us, thread_call_param_t )
{
((IOPMrootDomain *)us)->handleSleepTimerExpiration();
}
void IOPMrootDomain::handleSleepTimerExpiration( void )
{
if (!getPMworkloop()->inGate())
{
getPMworkloop()->runAction(
OSMemberFunctionCast(IOWorkLoop::Action, this,
&IOPMrootDomain::handleSleepTimerExpiration),
this);
return;
}
AbsoluteTime time;
DLOG("sleep timer expired\n");
ASSERT_GATED();
idleSleepTimerPending = false;
clock_get_uptime(&time);
if ((AbsoluteTime_to_scalar(&time) > autoWakeStart) &&
(AbsoluteTime_to_scalar(&time) < autoWakeEnd))
{
thread_call_enter_delayed(extraSleepTimer, *((AbsoluteTime *) &autoWakeEnd));
return;
}
setQuickSpinDownTimeout();
adjustPowerState(true);
}
void IOPMrootDomain::setQuickSpinDownTimeout( void )
{
ASSERT_GATED();
setAggressiveness(
kPMMinutesToSpinDown, 0, kAggressivesOptionQuickSpindownEnable );
}
void IOPMrootDomain::restoreUserSpinDownTimeout( void )
{
ASSERT_GATED();
setAggressiveness(
kPMMinutesToSpinDown, 0, kAggressivesOptionQuickSpindownDisable );
}
IOReturn IOPMrootDomain::sleepSystem( void )
{
return sleepSystemOptions(NULL);
}
IOReturn IOPMrootDomain::sleepSystemOptions( OSDictionary *options )
{
if (options && options->getObject("OSSwitch"))
{
return privateSleepSystem( kIOPMSleepReasonOSSwitchHibernate);
} else {
return privateSleepSystem( kIOPMSleepReasonSoftware);
}
}
IOReturn IOPMrootDomain::privateSleepSystem( uint32_t sleepReason )
{
static const char * IOPMSleepReasons[] = {
"",
kIOPMClamshellSleepKey,
kIOPMPowerButtonSleepKey,
kIOPMSoftwareSleepKey,
kIOPMOSSwitchHibernationKey,
kIOPMIdleSleepKey,
kIOPMLowPowerSleepKey,
kIOPMClamshellSleepKey,
kIOPMThermalEmergencySleepKey,
kIOPMMaintenanceSleepKey
};
PMEventDetails *details;
if (!checkSystemCanSleep())
{
details = PMEventDetails::eventDetails(kIOPMEventTypeSleep, NULL,
sleepReason, kIOReturnNotPermitted);
recordAndReleasePMEvent( details );
return kIOReturnNotPermitted;
}
if (timeline)
timeline->setSleepCycleInProgressFlag(true);
if(pmPowerStateQueue) {
pmPowerStateQueue->submitPowerEvent(kPowerEventPublishSleepWakeUUID, (void *)true);
}
details = PMEventDetails::eventDetails(kIOPMEventTypeSleep, NULL,
sleepReason, kIOReturnSuccess);
recordAndReleasePMEvent( details );
lastSleepReason = sleepReason;
sleepReason -= (kIOPMSleepReasonClamshell - 1);
if (sleepReason && (sleepReason < sizeof(IOPMSleepReasons)/sizeof(IOPMSleepReasons[0]))) {
setProperty(kRootDomainSleepReasonKey, IOPMSleepReasons[sleepReason]);
}
if (pmPowerStateQueue)
pmPowerStateQueue->submitPowerEvent(
kPowerEventPolicyStimulus,
(void *) kStimulusDemandSystemSleep );
return kIOReturnSuccess;
}
IOReturn IOPMrootDomain::recordPMEventGated(PMEventDetails *record)
{
if(!timeline)
return kIOReturnSuccess;
if(gIOPMWorkLoop->inGate() == false) {
IOReturn ret = gIOPMWorkLoop->runAction(
OSMemberFunctionCast(IOWorkLoop::Action, this, &IOPMrootDomain::recordPMEventGated),
(OSObject *)this,
(void *)record);
return ret;
}
else {
if(!record)
return kIOReturnBadArgument;
if(record->eventClassifier == kIOPMEventClassDriverEvent
|| record->eventClassifier == kIOPMEventClassSystemEvent)
return this->recordPMEvent(record);
else
return kIOReturnBadArgument;
}
}
IOReturn IOPMrootDomain::recordAndReleasePMEventGated(PMEventDetails *record)
{
IOReturn ret = kIOReturnBadArgument;
if (record)
{
ret = recordPMEventGated(record);
record->release();
}
return ret;
}
void IOPMrootDomain::powerChangeDone( unsigned long previousPowerState )
{
PMEventDetails *details;
ASSERT_GATED();
DLOG("PowerChangeDone: %u->%u\n",
(uint32_t) previousPowerState, (uint32_t) getPowerState());
switch ( getPowerState() )
{
case SLEEP_STATE: {
if (previousPowerState != ON_STATE)
break;
details = PMEventDetails::eventDetails(
kIOPMEventTypeSleepDone,
NULL,
NULL,
kIOReturnSuccess);
recordAndReleasePMEvent( details );
cancelIdleSleepTimer();
clock_sec_t secs;
clock_usec_t microsecs;
clock_get_calendar_microtime(&secs, µsecs);
logtime(secs);
gIOLastSleepTime.tv_sec = secs;
gIOLastSleepTime.tv_usec = microsecs;
gIOLastWakeTime.tv_sec = 0;
gIOLastWakeTime.tv_usec = 0;
#if HIBERNATION
LOG("System %sSleep\n", gIOHibernateState ? "Safe" : "");
IOHibernateSystemHasSlept();
evaluateSystemSleepPolicyFinal();
#else
LOG("System Sleep\n");
#endif
getPlatform()->sleepKernel();
clock_get_uptime(&systemWakeTime);
#if HIBERNATION
IOHibernateSystemWake();
#endif
gSleepOrShutdownPending = 0;
clock_wakeup_calendar();
#if HIBERNATION
LOG("System %sWake\n", gIOHibernateState ? "SafeSleep " : "");
#endif
getPlatform()->PMLog(kIOPMrootDomainClass, kPMLogSystemWake, 0, 0);
lowBatteryCondition = false;
lastSleepReason = 0;
details = PMEventDetails::eventDetails(
kIOPMEventTypeWake,
NULL,
0,
kIOReturnSuccess);
recordAndReleasePMEvent( details );
#ifndef __LP64__
systemWake();
#endif
#if defined(__i386__) || defined(__x86_64__)
wranglerTickled = false;
graphicsSuppressed = false;
darkWakePostTickle = false;
logGraphicsClamp = true;
logWranglerTickle = true;
sleepTimerMaintenance = false;
OSString * wakeType = OSDynamicCast(
OSString, getProperty(kIOPMRootDomainWakeTypeKey));
OSString * wakeReason = OSDynamicCast(
OSString, getProperty(kIOPMRootDomainWakeReasonKey));
if (wakeType && wakeType->isEqualTo(kIOPMrootDomainWakeTypeLowBattery))
{
lowBatteryCondition = true;
darkWakeMaintenance = true;
darkWakeToSleepASAP = true;
}
else if ((gDarkWakeFlags & kDarkWakeFlagHIDTickleMask) != 0)
{
OSNumber * hibOptions = OSDynamicCast(
OSNumber, getProperty(kIOHibernateOptionsKey));
if (hibernateAborted ||
((hibOptions &&
!(hibOptions->unsigned32BitValue() & kIOHibernateOptionDarkWake))) ||
((_debugWakeSeconds != 0) &&
((gDarkWakeFlags & kDarkWakeFlagAlarmIsDark) == 0)) ||
(wakeType && (
wakeType->isEqualTo(kIOPMRootDomainWakeTypeUser) ||
wakeType->isEqualTo(kIOPMRootDomainWakeTypeAlarm))))
{
wranglerTickled = true;
}
else
if (wakeType &&
wakeType->isEqualTo(kIOPMRootDomainWakeTypeMaintenance))
{
darkWakeMaintenance = true;
darkWakeToSleepASAP = true;
}
else
if (wakeType &&
wakeType->isEqualTo(kIOPMRootDomainWakeTypeSleepTimer))
{
darkWakeMaintenance = true;
darkWakeToSleepASAP = true;
sleepTimerMaintenance = true;
}
else
{
if (_debugWakeSeconds && (!wakeReason || wakeReason->isEqualTo("")))
wranglerTickled = true;
else
darkWakeToSleepASAP = true;
}
}
else
{
if (hibernateAborted || !wakeType ||
!wakeType->isEqualTo(kIOPMRootDomainWakeTypeMaintenance))
{
wranglerTickled = true;
}
else
{
darkWakeMaintenance = true;
darkWakeToSleepASAP = true;
}
}
if (wranglerTickled)
reportUserInput();
else if (!darkWakeMaintenance)
{
if (((gDarkWakeFlags & kDarkWakeFlagHIDTickleMask) ==
kDarkWakeFlagHIDTickleEarly) ||
((gDarkWakeFlags & kDarkWakeFlagHIDTickleMask) ==
kDarkWakeFlagHIDTickleLate))
{
darkWakePostTickle = true;
}
}
#else
wranglerTickled = true;
startIdleSleepTimer(30);
#endif
changePowerStateToPriv(ON_STATE);
} break;
case ON_STATE: {
bool wasPrevented = childPreventSystemSleep;
details = PMEventDetails::eventDetails(
kIOPMEventTypeWakeDone,
NULL,
0,
kIOReturnSuccess);
recordAndReleasePMEvent( details );
if (previousPowerState != ON_STATE)
_debugWakeSeconds = 0;
childPreventSystemSleep =
((currentCapability() & kIOPMChildClamp2) != 0);
if (wasPrevented && !childPreventSystemSleep)
{
evaluatePolicy( kStimulusDarkWakeEvaluate );
}
} break;
}
}
IOReturn IOPMrootDomain::requestPowerDomainState (
IOPMPowerFlags childDesire,
IOPowerConnection * childConnection,
unsigned long specification )
{
OSIterator *iter;
OSObject *next;
IOPowerConnection *connection;
IOPMPowerFlags mergedChildDesire = 0;
IOPMPowerFlags editedChildDesire;
IOPMPowerFlags thisDesire;
bool sleepASAP = false;
ASSERT_GATED();
if ((gDarkWakeFlags & kDarkWakeFlagIgnoreDiskIOAlways) &&
(kIOPMPreventIdleSleep & childDesire) &&
(childConnection != wranglerConnection))
{
childDesire &= ~kIOPMPreventIdleSleep;
}
editedChildDesire = 0;
if (childDesire & kIOPMPreventIdleSleep)
editedChildDesire |= (kIOPMPowerOn | kIOPMPreventIdleSleep);
if (childDesire & kIOPMPreventSystemSleep)
editedChildDesire |= (kIOPMPowerOn | kIOPMPreventSystemSleep);
iter = getChildIterator(gIOPowerPlane);
if ( iter )
{
while ( (next = iter->getNextObject()) )
{
if ( (connection = OSDynamicCast(IOPowerConnection, next)) )
{
if (connection->getReadyFlag() == false)
continue;
if (connection == childConnection)
{
thisDesire = editedChildDesire;
}
else
{
thisDesire = 0;
if (connection->getPreventIdleSleepFlag())
thisDesire |= (kIOPMPowerOn | kIOPMPreventIdleSleep);
if (connection->getPreventSystemSleepFlag())
thisDesire |= (kIOPMPowerOn | kIOPMPreventSystemSleep);
}
mergedChildDesire |= thisDesire;
if (thisDesire && (kIOLogPMRootDomain & gIOKitDebug))
{
IOService * child =
(IOService *) connection->getChildEntry(gIOPowerPlane);
LOG("child %p, noIdle %d, noSleep %d - %s\n",
child,
((thisDesire & kIOPMPreventIdleSleep) != 0),
((thisDesire & kIOPMPreventSystemSleep) != 0),
child ? child->getName() : "?");
}
}
}
iter->release();
}
DLOG("mergedChildDesire 0x%lx, extraSleepDelay %ld\n",
mergedChildDesire, extraSleepDelay);
if ( !mergedChildDesire && !systemBooting )
{
if (!wrangler)
{
changePowerStateToPriv(ON_STATE);
if (idleSeconds)
{
startIdleSleepTimer(idleSeconds);
}
}
else if (!extraSleepDelay && !idleSleepTimerPending && !systemDarkWake)
{
sleepASAP = true;
}
}
adjustPowerState(sleepASAP);
return super::requestPowerDomainState(
editedChildDesire, childConnection, specification);
}
bool IOPMrootDomain::tellChangeDown( unsigned long stateNum )
{
DLOG("tellChangeDown %u->%u\n",
(uint32_t) getPowerState(), (uint32_t) stateNum);
if (SLEEP_STATE == stateNum)
{
if (!ignoreTellChangeDown)
tracePoint( kIOPMTracePointSleepApplications );
else
tracePoint( kIOPMTracePointSleepPriorityClients );
}
if ((SLEEP_STATE == stateNum) && !ignoreTellChangeDown)
{
userActivityAtSleep = userActivityCount;
hibernateAborted = false;
DLOG("tellChangeDown::userActivityAtSleep %d\n", userActivityAtSleep);
OSKextSystemSleepOrWake( kIOMessageSystemWillSleep );
IOService::updateConsoleUsers(NULL, kIOMessageSystemWillSleep);
getPlatform()->callPlatformFunction(
sleepMessagePEFunction, false,
(void *)(uintptr_t) kIOMessageSystemWillSleep,
NULL, NULL, NULL);
ignoreTellChangeDown = true;
}
return super::tellClientsWithResponse( kIOMessageSystemWillSleep );
}
bool IOPMrootDomain::askChangeDown( unsigned long stateNum )
{
DLOG("askChangeDown %u->%u\n",
(uint32_t) getPowerState(), (uint32_t) stateNum);
if (kSystemTransitionSleep == _systemTransitionType)
tracePoint( kIOPMTracePointSleepApplications );
return super::tellClientsWithResponse( kIOMessageCanSystemSleep );
}
void IOPMrootDomain::askChangeDownDone(
IOPMPowerChangeFlags * inOutChangeFlags, bool * cancel )
{
DLOG("askChangeDownDone(0x%x, %u) type %x, cap %x->%x\n",
*inOutChangeFlags, *cancel,
_systemTransitionType,
_currentCapability, _pendingCapability);
if ((false == *cancel) && (kSystemTransitionSleep == _systemTransitionType))
{
if (!checkSystemCanSleep(true))
{
*cancel = true;
DLOG("cancel dark->sleep\n");
}
}
}
void IOPMrootDomain::tellNoChangeDown( unsigned long stateNum )
{
DLOG("tellNoChangeDown %u->%u\n",
(uint32_t) getPowerState(), (uint32_t) stateNum);
if (idleSeconds && !wrangler)
{
startIdleSleepTimer(idleSeconds);
}
return tellClients( kIOMessageSystemWillNotSleep );
}
void IOPMrootDomain::tellChangeUp( unsigned long stateNum )
{
OSData *publishPMStats = NULL;
DLOG("tellChangeUp %u->%u\n",
(uint32_t) getPowerState(), (uint32_t) stateNum);
ignoreTellChangeDown = false;
if ( stateNum == ON_STATE )
{
OSKextSystemSleepOrWake( kIOMessageSystemHasPoweredOn );
getPlatform()->callPlatformFunction(
sleepMessagePEFunction, false,
(void *)(uintptr_t) kIOMessageSystemHasPoweredOn,
NULL, NULL, NULL);
if (getPowerState() == ON_STATE)
{
if (idleSeconds && !wrangler)
{
startIdleSleepTimer(idleSeconds);
}
tellClients( kIOMessageSystemWillPowerOn );
}
tracePoint( kIOPMTracePointWakeApplications );
publishPMStats = OSData::withBytes(&pmStats, sizeof(pmStats));
setProperty(kIOPMSleepStatisticsKey, publishPMStats);
publishPMStats->release();
bzero(&pmStats, sizeof(pmStats));
if (pmStatsAppResponses)
{
setProperty(kIOPMSleepStatisticsAppsKey, pmStatsAppResponses);
pmStatsAppResponses->release();
pmStatsAppResponses = OSArray::withCapacity(5);
}
tellClients( kIOMessageSystemHasPoweredOn );
}
}
IOReturn IOPMrootDomain::sysPowerDownHandler(
void * target, void * refCon,
UInt32 messageType, IOService * service,
void * messageArgs, vm_size_t argSize )
{
IOReturn ret;
DLOG("sysPowerDownHandler message %s\n", getIOMessageString(messageType));
if (!gRootDomain)
return kIOReturnUnsupported;
if (messageType == kIOMessageSystemCapabilityChange)
{
IOPMSystemCapabilityChangeParameters * params =
(IOPMSystemCapabilityChangeParameters *) messageArgs;
DLOG("sysPowerDownHandler cap %x -> %x (flags %x)\n",
params->fromCapabilities, params->toCapabilities,
params->changeFlags);
if ((params->changeFlags & kIOPMSystemCapabilityWillChange) &&
(params->fromCapabilities & kIOPMSystemCapabilityCPU) &&
(params->toCapabilities & kIOPMSystemCapabilityCPU) == 0)
{
params->maxWaitForReply = 20 * 1000 * 1000;
#if HIBERNATION
gRootDomain->evaluateSystemSleepPolicyEarly();
if (gRootDomain->hibernateMode && !gRootDomain->hibernateDisabled)
{
params->maxWaitForReply = kCapabilityClientMaxWait;
}
DLOG("sysPowerDownHandler timeout %d s\n", (int) (params->maxWaitForReply / 1000 / 1000));
#endif
if ( !OSCompareAndSwap( 0, 1, &gSleepOrShutdownPending ) )
{
AbsoluteTime deadline;
clock_interval_to_deadline( 30, kSecondScale, &deadline );
thread_call_enter1_delayed(
gRootDomain->diskSyncCalloutEntry,
(thread_call_param_t) params->notifyRef,
deadline );
}
else
thread_call_enter1(
gRootDomain->diskSyncCalloutEntry,
(thread_call_param_t) params->notifyRef);
}
#if HIBERNATION
else
if ((params->changeFlags & kIOPMSystemCapabilityDidChange) &&
(params->toCapabilities & kIOPMSystemCapabilityCPU) &&
(params->fromCapabilities & kIOPMSystemCapabilityCPU) == 0)
{
params->maxWaitForReply = 110 * 1000 * 1000;
thread_call_enter1(
gRootDomain->diskSyncCalloutEntry,
(thread_call_param_t) params->notifyRef);
}
#endif
ret = kIOReturnSuccess;
}
return ret;
}
void IOPMrootDomain::handleQueueSleepWakeUUID(OSObject *obj)
{
OSString *str = NULL;
if (kOSBooleanFalse == obj)
{
handlePublishSleepWakeUUID(NULL);
}
else if ((str = OSDynamicCast(OSString, obj)))
{
if (queuedSleepWakeUUIDString) {
queuedSleepWakeUUIDString->release();
queuedSleepWakeUUIDString = NULL;
}
queuedSleepWakeUUIDString = str;
queuedSleepWakeUUIDString->retain();
DLOG("SleepWake UUID queued: %s\n", queuedSleepWakeUUIDString->getCStringNoCopy());
}
if (obj) {
obj->release();
}
return;
}
void IOPMrootDomain::handlePublishSleepWakeUUID( bool shouldPublish )
{
ASSERT_GATED();
if (gSleepWakeUUIDIsSet)
{
DLOG("SleepWake UUID cleared\n");
OSString *UUIDstring = NULL;
if (timeline &&
(UUIDstring = OSDynamicCast(OSString, getProperty(kIOPMSleepWakeUUIDKey))))
{
PMEventDetails *details = PMEventDetails::eventDetails(kIOPMEventTypeUUIDClear,
UUIDstring->getCStringNoCopy(), NULL, 0);
if (details) {
timeline->recordSystemPowerEvent( details );
details->release();
}
timeline->setNumEventsLoggedThisPeriod(0);
}
gSleepWakeUUIDIsSet = false;
removeProperty(kIOPMSleepWakeUUIDKey);
messageClients(kIOPMMessageSleepWakeUUIDChange, kIOPMMessageSleepWakeUUIDCleared);
}
if (queuedSleepWakeUUIDString && shouldPublish) {
OSString *publishThisUUID = NULL;
publishThisUUID = queuedSleepWakeUUIDString;
publishThisUUID->retain();
if (timeline) {
PMEventDetails *details;
details = PMEventDetails::eventDetails(kIOPMEventTypeUUIDSet,
publishThisUUID->getCStringNoCopy(), NULL, 0);
if (details) {
timeline->recordSystemPowerEvent( details );
details->release();
}
}
if (publishThisUUID)
{
setProperty(kIOPMSleepWakeUUIDKey, publishThisUUID);
publishThisUUID->release();
}
gSleepWakeUUIDIsSet = true;
messageClients(kIOPMMessageSleepWakeUUIDChange, kIOPMMessageSleepWakeUUIDSet);
queuedSleepWakeUUIDString->release();
queuedSleepWakeUUIDString = NULL;
}
}
IOReturn IOPMrootDomain::changePowerStateTo( unsigned long ordinal )
{
return kIOReturnUnsupported; }
IOReturn IOPMrootDomain::changePowerStateToPriv( unsigned long ordinal )
{
DLOG("changePowerStateToPriv(%lu)\n", ordinal);
if ((ordinal != ON_STATE) && (ordinal != SLEEP_STATE))
return kIOReturnUnsupported;
return super::changePowerStateToPriv(ordinal);
}
bool IOPMrootDomain::activitySinceSleep(void)
{
return (userActivityCount != userActivityAtSleep);
}
bool IOPMrootDomain::abortHibernation(void)
{
bool ret = activitySinceSleep();
if (ret && !hibernateAborted)
{
DLOG("activitySinceSleep ABORT [%d, %d]\n", userActivityCount, userActivityAtSleep);
hibernateAborted = true;
}
return (ret);
}
extern "C" int
hibernate_should_abort(void)
{
if (gRootDomain)
return (gRootDomain->abortHibernation());
else
return (0);
}
bool IOPMrootDomain::shouldSleepOnClamshellClosed( void )
{
if (!clamshellExists)
return false;
DLOG("clamshell closed %d, disabled %d, desktopMode %d, ac %d\n",
clamshellClosed, clamshellDisabled, desktopMode, acAdaptorConnected);
return ( !clamshellDisabled && !(desktopMode && acAdaptorConnected) );
}
void IOPMrootDomain::sendClientClamshellNotification( void )
{
if (!clamshellExists)
return;
setProperty(kAppleClamshellStateKey,
clamshellClosed ? kOSBooleanTrue : kOSBooleanFalse);
setProperty(kAppleClamshellCausesSleepKey,
shouldSleepOnClamshellClosed() ? kOSBooleanTrue : kOSBooleanFalse);
messageClients(kIOPMMessageClamshellStateChange,
(void *) ( (clamshellClosed ? kClamshellStateBit : 0)
| ( shouldSleepOnClamshellClosed() ? kClamshellSleepBit : 0)) );
}
IOOptionBits IOPMrootDomain::getSleepSupported( void )
{
return( platformSleepSupport );
}
void IOPMrootDomain::setSleepSupported( IOOptionBits flags )
{
DLOG("setSleepSupported(%x)\n", (uint32_t) flags);
OSBitOrAtomic(flags, &platformSleepSupport);
}
void IOPMrootDomain::wakeFromDoze( void )
{
}
void IOPMrootDomain::publishFeature( const char * feature )
{
publishFeature(feature, kRD_AllPowerSources, NULL);
}
void IOPMrootDomain::publishFeature(
const char *feature,
uint32_t supportedWhere,
uint32_t *uniqueFeatureID)
{
static uint16_t next_feature_id = 500;
OSNumber *new_feature_data = NULL;
OSNumber *existing_feature = NULL;
OSArray *existing_feature_arr = NULL;
OSObject *osObj = NULL;
uint32_t feature_value = 0;
supportedWhere &= kRD_AllPowerSources;
if(!supportedWhere) {
return;
}
if(next_feature_id > 5000) {
return;
}
if(featuresDictLock) IOLockLock(featuresDictLock);
OSDictionary *features =
(OSDictionary *) getProperty(kRootDomainSupportedFeatures);
if ( features && OSDynamicCast(OSDictionary, features)) {
features = OSDictionary::withDictionary(features);
} else {
features = OSDictionary::withCapacity(1);
}
next_feature_id += 1;
if( uniqueFeatureID ) {
*uniqueFeatureID = next_feature_id;
}
feature_value = (uint32_t)next_feature_id;
feature_value <<= 16;
feature_value += supportedWhere;
new_feature_data = OSNumber::withNumber(
(unsigned long long)feature_value, 32);
if( (osObj = features->getObject(feature)) )
{
if(( existing_feature = OSDynamicCast(OSNumber, osObj) ))
{
existing_feature_arr = OSArray::withObjects(
(const OSObject **)&existing_feature, 1, 2);
} else if(( existing_feature_arr = OSDynamicCast(OSArray, osObj) ))
{
existing_feature_arr = OSArray::withArray(
existing_feature_arr,
existing_feature_arr->getCount() + 1);
}
if (existing_feature_arr)
{
existing_feature_arr->setObject(new_feature_data);
features->setObject(feature, existing_feature_arr);
existing_feature_arr->release();
existing_feature_arr = 0;
}
} else {
features->setObject(feature, new_feature_data);
}
new_feature_data->release();
setProperty(kRootDomainSupportedFeatures, features);
features->release();
if(featuresDictLock) IOLockUnlock(featuresDictLock);
if(pmPowerStateQueue) {
pmPowerStateQueue->submitPowerEvent( kPowerEventFeatureChanged );
}
}
IOReturn IOPMrootDomain::removePublishedFeature( uint32_t removeFeatureID )
{
IOReturn ret = kIOReturnError;
uint32_t feature_value = 0;
uint16_t feature_id = 0;
bool madeAChange = false;
OSSymbol *dictKey = NULL;
OSCollectionIterator *dictIterator = NULL;
OSArray *arrayMember = NULL;
OSNumber *numberMember = NULL;
OSObject *osObj = NULL;
OSNumber *osNum = NULL;
OSArray *arrayMemberCopy;
if(featuresDictLock) IOLockLock(featuresDictLock);
OSDictionary *features =
(OSDictionary *) getProperty(kRootDomainSupportedFeatures);
if ( features && OSDynamicCast(OSDictionary, features) )
{
features = OSDictionary::withDictionary(features);
} else {
features = NULL;
ret = kIOReturnNotFound;
goto exit;
}
dictIterator = OSCollectionIterator::withCollection(features);
if(!dictIterator) {
goto exit;
}
while( (dictKey = OSDynamicCast(OSSymbol, dictIterator->getNextObject())) )
{
osObj = features->getObject(dictKey);
if( osObj && (numberMember = OSDynamicCast(OSNumber, osObj)) )
{
feature_value = numberMember->unsigned32BitValue();
feature_id = (uint16_t)(feature_value >> 16);
if( feature_id == (uint16_t)removeFeatureID )
{
features->removeObject(dictKey);
madeAChange = true;
break;
}
} else if( osObj && (arrayMember = OSDynamicCast(OSArray, osObj)) )
{
unsigned int arrayCount = arrayMember->getCount();
for(unsigned int i=0; i<arrayCount; i++)
{
osNum = OSDynamicCast(OSNumber, arrayMember->getObject(i));
if(!osNum) {
continue;
}
feature_value = osNum->unsigned32BitValue();
feature_id = (uint16_t)(feature_value >> 16);
if( feature_id == (uint16_t)removeFeatureID )
{
if( 1 == arrayCount ) {
features->removeObject(dictKey);
} else {
arrayMemberCopy = OSArray::withArray(arrayMember);
if (arrayMemberCopy)
{
arrayMemberCopy->removeObject(i);
features->setObject(dictKey, arrayMemberCopy);
arrayMemberCopy->release();
}
}
madeAChange = true;
break;
}
}
}
}
dictIterator->release();
if( madeAChange )
{
ret = kIOReturnSuccess;
setProperty(kRootDomainSupportedFeatures, features);
if(pmPowerStateQueue) {
pmPowerStateQueue->submitPowerEvent( kPowerEventFeatureChanged );
}
} else {
ret = kIOReturnNotFound;
}
exit:
if(features) features->release();
if(featuresDictLock) IOLockUnlock(featuresDictLock);
return ret;
}
IOReturn IOPMrootDomain::setPMSetting(
const OSSymbol *type,
OSObject *object )
{
PMSettingCallEntry *entries = 0;
OSArray *chosen = 0;
const OSArray *array;
PMSettingObject *pmso;
thread_t thisThread;
int i, j, count, capacity;
if (NULL == type)
return kIOReturnBadArgument;
PMSETTING_LOCK();
fPMSettingsDict->setObject(type, object);
array = (const OSArray *) settingsCallbacks->getObject(type);
if (!array || ((capacity = array->getCount()) == 0))
goto unlock_exit;
chosen = OSArray::withCapacity(capacity);
if (!chosen)
goto unlock_exit;
entries = IONew(PMSettingCallEntry, capacity);
if (!entries)
goto unlock_exit; memset(entries, 0, sizeof(PMSettingCallEntry) * capacity);
thisThread = current_thread();
for (i = 0, j = 0; i<capacity; i++)
{
pmso = (PMSettingObject *) array->getObject(i);
if (pmso->disabled)
continue;
entries[j].thread = thisThread;
queue_enter(&pmso->calloutQueue, &entries[j], PMSettingCallEntry *, link);
chosen->setObject(pmso);
j++;
}
count = j;
if (!count)
goto unlock_exit;
PMSETTING_UNLOCK();
for (i=0; i<count; i++)
{
pmso = (PMSettingObject *) chosen->getObject(i);
pmso->dispatchPMSetting(type, object);
}
PMSETTING_LOCK();
for (i=0; i<count; i++)
{
pmso = (PMSettingObject *) chosen->getObject(i);
queue_remove(&pmso->calloutQueue, &entries[i], PMSettingCallEntry *, link);
if (pmso->waitThread)
{
PMSETTING_WAKEUP(pmso);
}
}
unlock_exit:
PMSETTING_UNLOCK();
if (chosen) chosen->release();
if (entries) IODelete(entries, PMSettingCallEntry, capacity);
return kIOReturnSuccess;
}
OSObject * IOPMrootDomain::copyPMSetting(
OSSymbol *whichSetting)
{
OSObject *obj = NULL;
if(!whichSetting) return NULL;
PMSETTING_LOCK();
obj = fPMSettingsDict->getObject(whichSetting);
if(obj) {
obj->retain();
}
PMSETTING_UNLOCK();
return obj;
}
IOReturn IOPMrootDomain::registerPMSettingController(
const OSSymbol * settings[],
IOPMSettingControllerCallback func,
OSObject *target,
uintptr_t refcon,
OSObject **handle)
{
return registerPMSettingController(
settings,
(kIOPMSupportedOnAC | kIOPMSupportedOnBatt | kIOPMSupportedOnUPS),
func, target, refcon, handle);
}
IOReturn IOPMrootDomain::registerPMSettingController(
const OSSymbol * settings[],
uint32_t supportedPowerSources,
IOPMSettingControllerCallback func,
OSObject *target,
uintptr_t refcon,
OSObject **handle)
{
PMSettingObject *pmso = NULL;
OSObject *pmsh = NULL;
OSArray *list = NULL;
int i;
if (NULL == settings ||
NULL == func ||
NULL == handle)
{
return kIOReturnBadArgument;
}
pmso = PMSettingObject::pmSettingObject(
(IOPMrootDomain *) this, func, target,
refcon, supportedPowerSources, settings, &pmsh);
if (!pmso) {
*handle = NULL;
return kIOReturnInternalError;
}
PMSETTING_LOCK();
for (i=0; settings[i]; i++)
{
list = (OSArray *) settingsCallbacks->getObject(settings[i]);
if (!list) {
list = OSArray::withCapacity(1);
settingsCallbacks->setObject(settings[i], list);
list->release();
}
list->setObject(pmso);
}
PMSETTING_UNLOCK();
*handle = pmsh;
return kIOReturnSuccess;
}
void IOPMrootDomain::deregisterPMSettingObject( PMSettingObject * pmso )
{
thread_t thisThread = current_thread();
PMSettingCallEntry *callEntry;
OSCollectionIterator *iter;
OSSymbol *sym;
OSArray *array;
int index;
bool wait;
PMSETTING_LOCK();
pmso->disabled = true;
do {
wait = false;
queue_iterate(&pmso->calloutQueue, callEntry, PMSettingCallEntry *, link)
{
if (callEntry->thread != thisThread)
{
wait = true;
break;
}
}
if (wait)
{
assert(0 == pmso->waitThread);
pmso->waitThread = thisThread;
PMSETTING_WAIT(pmso);
pmso->waitThread = 0;
}
} while (wait);
iter = OSCollectionIterator::withCollection(settingsCallbacks);
if (iter)
{
while ((sym = OSDynamicCast(OSSymbol, iter->getNextObject())))
{
array = (OSArray *) settingsCallbacks->getObject(sym);
index = array->getNextIndexOfObject(pmso, 0);
if (-1 != index) {
array->removeObject(index);
}
}
iter->release();
}
PMSETTING_UNLOCK();
pmso->release();
}
void IOPMrootDomain::informCPUStateChange(
uint32_t type,
uint32_t value )
{
#if defined(__i386__) || defined(__x86_64__)
pmioctlVariableInfo_t varInfoStruct;
int pmCPUret = 0;
const char *varNameStr = NULL;
int32_t *varIndex = NULL;
if (kInformAC == type) {
varNameStr = kIOPMRootDomainBatPowerCString;
varIndex = &idxPMCPULimitedPower;
} else if (kInformLid == type) {
varNameStr = kIOPMRootDomainLidCloseCString;
varIndex = &idxPMCPUClamshell;
} else {
return;
}
bzero(&varInfoStruct, sizeof(pmioctlVariableInfo_t));
varInfoStruct.varID = *varIndex;
varInfoStruct.varType = vBool;
varInfoStruct.varInitValue = value;
varInfoStruct.varCurValue = value;
strncpy( (char *)varInfoStruct.varName,
(const char *)varNameStr,
strlen(varNameStr) + 1 );
pmCPUret = pmCPUControl( PMIOCSETVARINFO, (void *)&varInfoStruct );
if ((0 == pmCPUret)
&& (*varIndex == kCPUUnknownIndex))
{
pmCPUret = pmCPUControl( PMIOCGETVARNAMEINFO, (void *)&varInfoStruct );
if (0 == pmCPUret)
{
*varIndex = varInfoStruct.varID;
}
}
return;
#endif
}
#if HIBERNATION
struct IOPMSystemSleepPolicyEntry
{
uint32_t factorMask;
uint32_t factorBits;
uint32_t sleepFlags;
uint32_t wakeEvents;
};
struct IOPMSystemSleepPolicyTable
{
uint8_t signature[4];
uint16_t version;
uint16_t entryCount;
IOPMSystemSleepPolicyEntry entries[];
};
enum {
kIOPMSleepFactorSleepTimerWake = 0x00000001,
kIOPMSleepFactorLidOpen = 0x00000002,
kIOPMSleepFactorACPower = 0x00000004,
kIOPMSleepFactorLowBattery = 0x00000008,
kIOPMSleepFactorDeepSleepNoDelay = 0x00000010,
kIOPMSleepFactorDeepSleepDemand = 0x00000020,
kIOPMSleepFactorDeepSleepDisable = 0x00000040,
kIOPMSleepFactorUSBExternalDevice = 0x00000080,
kIOPMSleepFactorBluetoothHIDDevice = 0x00000100,
kIOPMSleepFactorExternalMediaMounted = 0x00000200,
kIOPMSleepFactorDriverAssertBit5 = 0x00000400,
kIOPMSleepFactorDriverAssertBit6 = 0x00000800,
kIOPMSleepFactorDriverAssertBit7 = 0x00001000
};
bool IOPMrootDomain::evaluateSystemSleepPolicy( IOPMSystemSleepParameters * p )
{
const IOPMSystemSleepPolicyTable * pt;
OSObject * prop = 0;
OSData * policyData;
uint32_t currentFactors;
uint32_t deepSleepDelay = 0;
bool success = false;
if (getProperty(kIOPMDeepSleepEnabledKey) != kOSBooleanTrue)
return false;
getSleepOption(kIOPMDeepSleepDelayKey, &deepSleepDelay);
prop = getServiceRoot()->copyProperty(kIOPlatformSystemSleepPolicyKey);
if (!prop)
return false;
policyData = OSDynamicCast(OSData, prop);
if (!policyData ||
(policyData->getLength() < sizeof(IOPMSystemSleepPolicyTable)))
{
goto done;
}
pt = (const IOPMSystemSleepPolicyTable *) policyData->getBytesNoCopy();
if ((pt->signature[0] != 'S') ||
(pt->signature[1] != 'L') ||
(pt->signature[2] != 'P') ||
(pt->signature[3] != 'T') ||
(pt->version != 1) ||
(pt->entryCount == 0))
{
goto done;
}
if ((policyData->getLength() - sizeof(IOPMSystemSleepPolicyTable)) !=
(sizeof(IOPMSystemSleepPolicyEntry) * pt->entryCount))
{
goto done;
}
currentFactors = 0;
if (getPMAssertionLevel(kIOPMDriverAssertionUSBExternalDeviceBit) !=
kIOPMDriverAssertionLevelOff)
currentFactors |= kIOPMSleepFactorUSBExternalDevice;
if (getPMAssertionLevel(kIOPMDriverAssertionBluetoothHIDDevicePairedBit) !=
kIOPMDriverAssertionLevelOff)
currentFactors |= kIOPMSleepFactorBluetoothHIDDevice;
if (getPMAssertionLevel(kIOPMDriverAssertionExternalMediaMountedBit) !=
kIOPMDriverAssertionLevelOff)
currentFactors |= kIOPMSleepFactorExternalMediaMounted;
if (getPMAssertionLevel(kIOPMDriverAssertionReservedBit5) !=
kIOPMDriverAssertionLevelOff)
currentFactors |= kIOPMSleepFactorDriverAssertBit5;
if (getPMAssertionLevel(kIOPMDriverAssertionReservedBit7) !=
kIOPMDriverAssertionLevelOff)
currentFactors |= kIOPMSleepFactorDriverAssertBit7;
if (0 == deepSleepDelay)
currentFactors |= kIOPMSleepFactorDeepSleepNoDelay;
if (!clamshellClosed)
currentFactors |= kIOPMSleepFactorLidOpen;
if (acAdaptorConnected)
currentFactors |= kIOPMSleepFactorACPower;
if (lowBatteryCondition)
currentFactors |= kIOPMSleepFactorLowBattery;
if (sleepTimerMaintenance)
currentFactors |= kIOPMSleepFactorSleepTimerWake;
if ((hibernateMode & kIOHibernateModeOn) == 0)
currentFactors |= kIOPMSleepFactorDeepSleepDisable;
else if ((hibernateMode & kIOHibernateModeSleep) == 0)
currentFactors |= kIOPMSleepFactorDeepSleepDemand;
DLOG("Sleep policy %u entries, current factors 0x%x\n",
pt->entryCount, currentFactors);
for (uint32_t i = 0; i < pt->entryCount; i++)
{
const IOPMSystemSleepPolicyEntry * policyEntry = &pt->entries[i];
DLOG("factor mask 0x%08x, bits 0x%08x, flags 0x%08x, wake 0x%08x\n",
policyEntry->factorMask, policyEntry->factorBits,
policyEntry->sleepFlags, policyEntry->wakeEvents);
if ((currentFactors ^ policyEntry->factorBits) & policyEntry->factorMask)
continue;
if (p)
{
p->version = 1;
p->sleepFlags = policyEntry->sleepFlags;
p->sleepTimer = 0;
p->wakeEvents = policyEntry->wakeEvents;
if (p->sleepFlags & kIOPMSleepFlagSleepTimerEnable)
{
p->sleepTimer = deepSleepDelay;
}
}
DLOG("matched policy entry %u\n", i);
success = true;
break;
}
done:
if (prop)
prop->release();
return success;
}
void IOPMrootDomain::evaluateSystemSleepPolicyEarly( void )
{
IOPMSystemSleepParameters params;
DLOG("%s\n", __FUNCTION__);
removeProperty(kIOPMSystemSleepParametersKey);
hibernateDisabled = false;
hibernateMode = 0;
getSleepOption(kIOHibernateModeKey, &hibernateMode);
if (!hibernateNoDefeat &&
evaluateSystemSleepPolicy(¶ms) &&
((params.sleepFlags & kIOPMSleepFlagHibernate) == 0))
{
hibernateDisabled = true;
}
}
void IOPMrootDomain::evaluateSystemSleepPolicyFinal( void )
{
IOPMSystemSleepParameters params;
OSData * paramsData;
DLOG("%s\n", __FUNCTION__);
if (evaluateSystemSleepPolicy(¶ms))
{
if ((hibernateDisabled || hibernateAborted) &&
(params.sleepFlags & kIOPMSleepFlagHibernate))
{
params.sleepFlags &= ~kIOPMSleepFlagHibernate;
params.sleepFlags |= kIOPMSleepFlagSleepTimerEnable;
params.sleepTimer = 1;
hibernateNoDefeat = true;
DLOG("wake in %u secs for hibernateDisabled %d, hibernateAborted %d\n",
params.sleepTimer, hibernateDisabled, hibernateAborted);
}
else
hibernateNoDefeat = false;
paramsData = OSData::withBytes(¶ms, sizeof(params));
if (paramsData)
{
setProperty(kIOPMSystemSleepParametersKey, paramsData);
paramsData->release();
}
if (params.sleepFlags & kIOPMSleepFlagHibernate)
{
gIOHibernateMode &= ~kIOHibernateModeSleep;
}
}
}
bool IOPMrootDomain::getHibernateSettings(
uint32_t * hibernateMode,
uint32_t * hibernateFreeRatio,
uint32_t * hibernateFreeTime )
{
bool ok = getSleepOption(kIOHibernateModeKey, hibernateMode);
getSleepOption(kIOHibernateFreeRatioKey, hibernateFreeRatio);
getSleepOption(kIOHibernateFreeTimeKey, hibernateFreeTime);
if (hibernateDisabled)
*hibernateMode = 0;
DLOG("hibernateMode 0x%x\n", *hibernateMode);
return ok;
}
bool IOPMrootDomain::getSleepOption( const char * key, uint32_t * option )
{
OSObject * optionsProp;
OSDictionary * optionsDict;
OSObject * obj = 0;
OSNumber * num;
bool ok = false;
optionsProp = copyProperty(kRootDomainSleepOptionsKey);
optionsDict = OSDynamicCast(OSDictionary, optionsProp);
if (optionsDict)
{
obj = optionsDict->getObject(key);
if (obj) obj->retain();
}
if (!obj)
{
obj = copyProperty(key);
}
if (obj && (num = OSDynamicCast(OSNumber, obj)))
{
*option = num->unsigned32BitValue();
ok = true;
}
if (obj)
obj->release();
if (optionsProp)
optionsProp->release();
return true;
}
#endif
struct HaltRestartApplierContext {
IOPMrootDomain * RootDomain;
unsigned long PowerState;
IOPMPowerFlags PowerFlags;
UInt32 MessageType;
UInt32 Counter;
};
static void
platformHaltRestartApplier( OSObject * object, void * context )
{
IOPowerStateChangeNotification notify;
HaltRestartApplierContext * ctx;
AbsoluteTime startTime;
UInt32 deltaTime;
ctx = (HaltRestartApplierContext *) context;
memset(¬ify, 0, sizeof(notify));
notify.powerRef = (void *)ctx->Counter;
notify.returnValue = 0;
notify.stateNumber = ctx->PowerState;
notify.stateFlags = ctx->PowerFlags;
clock_get_uptime(&startTime);
ctx->RootDomain->messageClient( ctx->MessageType, object, (void *)¬ify );
deltaTime = computeDeltaTimeMS(&startTime);
if ((deltaTime > kPMHaltTimeoutMS) ||
(gIOKitDebug & kIOLogPMRootDomain))
{
_IOServiceInterestNotifier * notifier;
notifier = OSDynamicCast(_IOServiceInterestNotifier, object);
if (notifier)
{
LOG("%s handler %p took %u ms\n",
(ctx->MessageType == kIOMessageSystemWillPowerOff) ? "PowerOff" :
(ctx->MessageType == kIOMessageSystemPagingOff) ? "PagingOff" : "Restart",
notifier->handler, (uint32_t) deltaTime );
}
}
ctx->Counter++;
}
void IOPMrootDomain::handlePlatformHaltRestart( UInt32 pe_type )
{
HaltRestartApplierContext ctx;
AbsoluteTime startTime;
UInt32 deltaTime;
memset(&ctx, 0, sizeof(ctx));
ctx.RootDomain = this;
clock_get_uptime(&startTime);
switch (pe_type)
{
case kPEHaltCPU:
case kPEUPSDelayHaltCPU:
ctx.PowerState = OFF_STATE;
ctx.MessageType = kIOMessageSystemWillPowerOff;
break;
case kPERestartCPU:
ctx.PowerState = RESTART_STATE;
ctx.MessageType = kIOMessageSystemWillRestart;
break;
case kPEPagingOff:
ctx.PowerState = ON_STATE;
ctx.MessageType = kIOMessageSystemPagingOff;
break;
default:
return;
}
applyToInterested(gIOPriorityPowerStateInterest, platformHaltRestartApplier, &ctx);
if (kPEHaltCPU == pe_type)
{
const OSSymbol * setting = OSSymbol::withCString(kIOPMSettingRestartOnPowerLossKey);
OSNumber * num = OSNumber::withNumber((unsigned long long) 0, 32);
if (setting && num)
{
setPMSetting(setting, num);
setting->release();
num->release();
}
}
if (kPEPagingOff != pe_type)
{
notifySystemShutdown(this, ctx.MessageType);
}
deltaTime = computeDeltaTimeMS(&startTime);
LOG("%s all drivers took %u ms\n",
(ctx.MessageType == kIOMessageSystemWillPowerOff) ? "PowerOff" :
(ctx.MessageType == kIOMessageSystemPagingOff) ? "PagingOff" : "Restart",
(uint32_t) deltaTime );
}
IOReturn IOPMrootDomain::shutdownSystem( void )
{
return kIOReturnUnsupported;
}
IOReturn IOPMrootDomain::restartSystem( void )
{
return kIOReturnUnsupported;
}
void IOPMrootDomain::tagPowerPlaneService(
IOService * service,
IOPMActions * actions )
{
uint32_t flags = 0;
bool isDisplayWrangler;
memset(actions, 0, sizeof(*actions));
actions->target = this;
if (service == this)
{
actions->actionPowerChangeStart =
OSMemberFunctionCast(
IOPMActionPowerChangeStart, this,
&IOPMrootDomain::handleOurPowerChangeStart);
actions->actionPowerChangeDone =
OSMemberFunctionCast(
IOPMActionPowerChangeDone, this,
&IOPMrootDomain::handleOurPowerChangeDone);
actions->actionPowerChangeOverride =
OSMemberFunctionCast(
IOPMActionPowerChangeOverride, this,
&IOPMrootDomain::overrideOurPowerChange);
return;
}
#if !NO_KERNEL_HID
isDisplayWrangler = (0 != service->metaCast("IODisplayWrangler"));
if (isDisplayWrangler)
{
wrangler = service;
wranglerConnection = (IOService *) service->getParentEntry(gIOPowerPlane);
}
#else
isDisplayWrangler = false;
#endif
#if defined(__i386__) || defined(__x86_64__)
if (isDisplayWrangler)
flags |= kPMActionsFlagIsDisplayWrangler;
if (service->getProperty("IOPMStrictTreeOrder"))
flags |= kPMActionsFlagIsGraphicsDevice;
if (service->getProperty("IOPMUnattendedWakePowerState"))
flags |= kPMActionsFlagIsAudioDevice;
#endif
if (flags)
{
IORegistryEntry * child = service;
IORegistryEntry * parent = child->getParentEntry(gIOPowerPlane);
while (child != this)
{
if ((parent == pciHostBridgeDriver) ||
(parent == this))
{
if (OSDynamicCast(IOPowerConnection, child))
{
IOPowerConnection * conn = (IOPowerConnection *) child;
conn->delayChildNotification = true;
}
break;
}
child = parent;
parent = child->getParentEntry(gIOPowerPlane);
}
}
if (flags)
{
DLOG("%s tag flags %x\n", service->getName(), flags);
actions->parameter |= flags;
actions->actionPowerChangeOverride =
OSMemberFunctionCast(
IOPMActionPowerChangeOverride, this,
&IOPMrootDomain::overridePowerChangeForUIService);
if (flags & kPMActionsFlagIsDisplayWrangler)
{
actions->actionActivityTickle =
OSMemberFunctionCast(
IOPMActionActivityTickle, this,
&IOPMrootDomain::handleActivityTickleForDisplayWrangler);
}
return;
}
if (!pciHostBridgeDevice && service->metaCast("IOPCIBridge"))
{
IOService * provider = service->getProvider();
if (OSDynamicCast(IOPlatformDevice, provider) &&
provider->inPlane(gIODTPlane))
{
pciHostBridgeDevice = provider;
pciHostBridgeDriver = service;
DLOG("PMTrace found PCI host bridge %s->%s\n",
provider->getName(), service->getName());
}
}
if (pciHostBridgeDevice && service->metaCast("IOPCIDevice"))
{
IORegistryEntry * parent = service->getParentEntry(gIODTPlane);
if ((parent == pciHostBridgeDevice) && service->getProperty("acpi-device"))
{
int bit = pmTracer->recordTopLevelPCIDevice( service );
if (bit >= 0)
{
actions->parameter |= (bit & kPMActionsPCIBitNumberMask);
actions->actionPowerChangeStart =
OSMemberFunctionCast(
IOPMActionPowerChangeStart, this,
&IOPMrootDomain::handlePowerChangeStartForPCIDevice);
actions->actionPowerChangeDone =
OSMemberFunctionCast(
IOPMActionPowerChangeDone, this,
&IOPMrootDomain::handlePowerChangeDoneForPCIDevice);
}
}
}
}
void IOPMrootDomain::overrideOurPowerChange(
IOService * service,
IOPMActions * actions,
unsigned long * inOutPowerState,
uint32_t * inOutChangeFlags )
{
uint32_t powerState = (uint32_t) *inOutPowerState;
uint32_t changeFlags = *inOutChangeFlags;
uint32_t currentPowerState = (uint32_t) getPowerState();
if ((currentPowerState == powerState) ||
(changeFlags & kIOPMParentInitiated))
{
return;
}
if (powerState < currentPowerState)
{
if ((changeFlags & kIOPMSkipAskPowerDown) == 0)
{
pmPowerStateQueue->submitPowerEvent(kPowerEventPublishSleepWakeUUID, (void *)true);
lastSleepReason = kIOPMSleepReasonIdle;
setProperty(kRootDomainSleepReasonKey, kIOPMIdleSleepKey);
}
if (CAP_CURRENT(kIOPMSystemCapabilityGraphics))
{
darkWakeToSleepASAP = true;
_desiredCapability &= ~(
kIOPMSystemCapabilityGraphics |
kIOPMSystemCapabilityAudio );
*inOutPowerState = ON_STATE;
*inOutChangeFlags |= kIOPMSynchronize;
changePowerStateToPriv(ON_STATE);
}
}
}
void IOPMrootDomain::handleOurPowerChangeStart(
IOService * service,
IOPMActions * actions,
uint32_t powerState,
uint32_t * inOutChangeFlags )
{
uint32_t changeFlags = *inOutChangeFlags;
uint32_t currentPowerState = (uint32_t) getPowerState();
_systemTransitionType = kSystemTransitionNone;
_systemMessageClientMask = 0;
capabilityLoss = false;
if (changeFlags & kIOPMSynchronize)
{
if (powerState == ON_STATE)
{
if (changeFlags & kIOPMSyncNoChildNotify)
_systemTransitionType = kSystemTransitionNewCapClient;
else
_systemTransitionType = kSystemTransitionCapability;
}
}
else if (powerState < currentPowerState)
_systemTransitionType = kSystemTransitionSleep;
else if (!systemBooting &&
(changeFlags & kIOPMSelfInitiated) &&
(powerState > currentPowerState))
{
_systemTransitionType = kSystemTransitionWake;
_desiredCapability = kIOPMSystemCapabilityCPU |
kIOPMSystemCapabilityNetwork;
if (wranglerTickled)
{
_desiredCapability |= (
kIOPMSystemCapabilityGraphics |
kIOPMSystemCapabilityAudio );
}
}
if (kSystemTransitionSleep == _systemTransitionType)
{
_pendingCapability = 0;
capabilityLoss = true;
}
else if (kSystemTransitionNewCapClient != _systemTransitionType)
{
_pendingCapability = _desiredCapability |
kIOPMSystemCapabilityCPU |
kIOPMSystemCapabilityNetwork;
if (_pendingCapability & kIOPMSystemCapabilityGraphics)
_pendingCapability |= kIOPMSystemCapabilityAudio;
if ((kSystemTransitionCapability == _systemTransitionType) &&
(_pendingCapability == _currentCapability))
{
_systemTransitionType = kSystemTransitionNone;
*inOutChangeFlags |= kIOPMNotDone;
}
if (__builtin_popcount(_pendingCapability) <
__builtin_popcount(_currentCapability))
capabilityLoss = true;
if (CAP_LOSS(kIOPMSystemCapabilityGraphics))
rejectWranglerTickle = true;
}
if (kSystemTransitionCapability == _systemTransitionType)
{
if (CAP_GAIN(kIOPMSystemCapabilityGraphics))
{
tracePoint( kIOPMTracePointDarkWakeExit );
wranglerSleepIgnored = false;
sleepTimerMaintenance = false;
hibernateNoDefeat = false;
_systemMessageClientMask = kSystemMessageClientUser;
if ((_highestCapability & kIOPMSystemCapabilityGraphics) == 0)
_systemMessageClientMask |= kSystemMessageClientKernel;
tellClients(kIOMessageSystemWillPowerOn);
}
if (CAP_LOSS(kIOPMSystemCapabilityGraphics))
{
tracePoint( kIOPMTracePointDarkWakeEntry );
*inOutChangeFlags |= kIOPMSyncTellPowerDown;
_systemMessageClientMask = kSystemMessageClientUser;
}
}
else if (kSystemTransitionSleep == _systemTransitionType)
{
tracePoint( kIOPMTracePointSleepStarted, lastSleepReason );
_systemMessageClientMask = kSystemMessageClientAll;
if ((_currentCapability & kIOPMSystemCapabilityGraphics) == 0)
_systemMessageClientMask &= ~kSystemMessageClientApp;
if ((_highestCapability & kIOPMSystemCapabilityGraphics) == 0)
_systemMessageClientMask &= ~kSystemMessageClientKernel;
if (changeFlags & kIOPMIgnoreChildren)
{
wranglerSleepIgnored = true;
}
logWranglerTickle = false;
}
else if (kSystemTransitionWake == _systemTransitionType)
{
wranglerSleepIgnored = false;
if (_pendingCapability & kIOPMSystemCapabilityGraphics)
{
_systemMessageClientMask = kSystemMessageClientAll;
}
else
{
_systemMessageClientMask = kSystemMessageClientConfigd;
}
tracePoint( kIOPMTracePointWakeWillPowerOnClients );
tellClients(kIOMessageSystemWillPowerOn);
}
if ((kSystemTransitionNone != _systemTransitionType) &&
(kSystemTransitionNewCapClient != _systemTransitionType))
{
_systemStateGeneration++;
systemDarkWake = false;
DLOG("=== START (%u->%u, 0x%x) type %u, gen %u, msg %x, "
"dcp %x:%x:%x\n",
currentPowerState, powerState, *inOutChangeFlags,
_systemTransitionType, _systemStateGeneration,
_systemMessageClientMask,
_desiredCapability, _currentCapability, _pendingCapability);
}
}
void IOPMrootDomain::handleOurPowerChangeDone(
IOService * service,
IOPMActions * actions,
uint32_t powerState,
uint32_t changeFlags )
{
if (kSystemTransitionNewCapClient == _systemTransitionType)
{
_systemTransitionType = kSystemTransitionNone;
return;
}
if (_systemTransitionType != kSystemTransitionNone)
{
uint32_t currentPowerState = (uint32_t) getPowerState();
if (changeFlags & kIOPMNotDone)
{
_pendingCapability = _currentCapability;
lastSleepReason = 0;
if (((_currentCapability & kIOPMSystemCapabilityGraphics) == 0) &&
(_currentCapability & kIOPMSystemCapabilityCPU))
{
pmPowerStateQueue->submitPowerEvent(
kPowerEventPolicyStimulus,
(void *) kStimulusDarkWakeReentry,
_systemStateGeneration );
}
changePowerStateToPriv(ON_STATE);
}
else
{
if (kSystemTransitionCapability == _systemTransitionType)
{
if (CAP_GAIN(kIOPMSystemCapabilityGraphics))
{
tellClients(kIOMessageSystemHasPoweredOn);
#if DARK_TO_FULL_EVALUATE_CLAMSHELL
if (clamshellClosed &&
((_systemMessageClientMask & kSystemMessageClientKernel) == 0))
{
receivePowerNotification( kLocalEvalClamshellCommand );
}
#endif
}
if (CAP_LOSS(kIOPMSystemCapabilityGraphics))
wranglerTickled = false;
}
if (CAP_GAIN(kIOPMSystemCapabilityGraphics) ||
CAP_LOSS(kIOPMSystemCapabilityCPU))
{
darkWakeMaintenance = false;
darkWakeToSleepASAP = false;
pciCantSleepValid = false;
rejectWranglerTickle = false;
}
if (((_pendingCapability & kIOPMSystemCapabilityGraphics) == 0) &&
(_pendingCapability & kIOPMSystemCapabilityCPU))
{
if (((gDarkWakeFlags & kDarkWakeFlagIgnoreDiskIOInDark) == 0) &&
(kSystemTransitionWake == _systemTransitionType) &&
(_debugWakeSeconds == 0))
{
OSObject * prop = copyProperty(kIOPMRootDomainWakeTypeKey);
if (prop)
{
OSString * wakeType = OSDynamicCast(OSString, prop);
if (wakeType &&
wakeType->isEqualTo(kIOPMRootDomainWakeTypeNetwork))
{
if (darkWakeToSleepASAP)
{
DLOG("cleared darkWakeToSleepASAP\n");
darkWakeToSleepASAP = false;
}
}
prop->release();
}
}
pmPowerStateQueue->submitPowerEvent(
kPowerEventPolicyStimulus,
(void *) kStimulusDarkWakeEntry,
_systemStateGeneration );
}
}
DLOG("=== FINISH (%u->%u, 0x%x) type %u, gen %u, msg %x, "
"dcp %x:%x:%x, dbgtimer %u\n",
currentPowerState, powerState, changeFlags,
_systemTransitionType, _systemStateGeneration,
_systemMessageClientMask,
_desiredCapability, _currentCapability, _pendingCapability,
_debugWakeSeconds);
if (_currentCapability != _pendingCapability)
_currentCapability = _pendingCapability;
if (!CAP_CURRENT(kIOPMSystemCapabilityCPU))
_highestCapability = 0; else
_highestCapability |= _currentCapability;
if (darkWakePostTickle &&
(kSystemTransitionWake == _systemTransitionType) &&
(gDarkWakeFlags & kDarkWakeFlagHIDTickleMask) ==
kDarkWakeFlagHIDTickleLate)
{
darkWakePostTickle = false;
reportUserInput();
}
if ((_systemTransitionType == kSystemTransitionCapability) ||
(_systemTransitionType == kSystemTransitionWake) ||
((_systemTransitionType == kSystemTransitionSleep) &&
(changeFlags & kIOPMNotDone)))
{
setProperty(kIOPMSystemCapabilitiesKey, _currentCapability, 64);
tracePoint( kIOPMTracePointSystemUp, 0 );
}
_systemTransitionType = kSystemTransitionNone;
_systemMessageClientMask = 0;
logGraphicsClamp = false;
}
}
void IOPMrootDomain::overridePowerChangeForUIService(
IOService * service,
IOPMActions * actions,
unsigned long * inOutPowerState,
uint32_t * inOutChangeFlags )
{
uint32_t powerState = (uint32_t) *inOutPowerState;
uint32_t changeFlags = (uint32_t) *inOutChangeFlags;
if (kSystemTransitionNone == _systemTransitionType)
{
}
else if ((actions->parameter & kPMActionsFlagLimitPower) == 0)
{
if ((actions->parameter & kPMActionsFlagIsDisplayWrangler) &&
((_pendingCapability & kIOPMSystemCapabilityGraphics) == 0))
{
actions->parameter |= kPMActionsFlagLimitPower;
}
else if ((actions->parameter & kPMActionsFlagIsAudioDevice) &&
((_pendingCapability & kIOPMSystemCapabilityAudio) == 0))
{
actions->parameter |= kPMActionsFlagLimitPower;
}
else if ((actions->parameter & kPMActionsFlagIsGraphicsDevice) &&
(_systemTransitionType == kSystemTransitionSleep))
{
actions->parameter |= kPMActionsFlagLimitPower;
}
if (actions->parameter & kPMActionsFlagLimitPower)
{
DLOG("+ plimit %s %p\n",
service->getName(), service);
}
}
else
{
if ((actions->parameter & (
kPMActionsFlagIsDisplayWrangler |
kPMActionsFlagIsGraphicsDevice )) &&
(_pendingCapability & kIOPMSystemCapabilityGraphics))
{
actions->parameter &= ~kPMActionsFlagLimitPower;
}
else if ((actions->parameter & kPMActionsFlagIsAudioDevice) &&
(_pendingCapability & kIOPMSystemCapabilityAudio))
{
actions->parameter &= ~kPMActionsFlagLimitPower;
}
if ((actions->parameter & kPMActionsFlagLimitPower) == 0)
{
DLOG("- plimit %s %p\n",
service->getName(), service);
}
}
if (actions->parameter & kPMActionsFlagLimitPower)
{
uint32_t maxPowerState = (uint32_t)(-1);
if (changeFlags & (kIOPMDomainDidChange | kIOPMDomainWillChange))
{
maxPowerState = 0;
if (actions->parameter & kPMActionsFlagIsDisplayWrangler)
{
if (changeFlags & kIOPMDomainWillChange)
maxPowerState = 3;
else
maxPowerState = 1;
}
}
else
{
maxPowerState = service->getPowerState();
}
if (powerState > maxPowerState)
{
DLOG("> plimit %s %p (%u->%u, 0x%x)\n",
service->getName(), service, powerState, maxPowerState,
changeFlags);
*inOutPowerState = maxPowerState;
if (darkWakePostTickle &&
(actions->parameter & kPMActionsFlagIsDisplayWrangler) &&
(changeFlags & kIOPMDomainWillChange) &&
((gDarkWakeFlags & kDarkWakeFlagHIDTickleMask) ==
kDarkWakeFlagHIDTickleEarly))
{
darkWakePostTickle = false;
reportUserInput();
}
}
if (!graphicsSuppressed && (changeFlags & kIOPMDomainDidChange))
{
if (logGraphicsClamp)
{
AbsoluteTime now;
uint64_t nsec;
clock_get_uptime(&now);
SUB_ABSOLUTETIME(&now, &systemWakeTime);
absolutetime_to_nanoseconds(now, &nsec);
MSG("Graphics suppressed %u ms\n",
((int)((nsec) / 1000000ULL)));
}
graphicsSuppressed = true;
}
}
}
void IOPMrootDomain::handleActivityTickleForDisplayWrangler(
IOService * service,
IOPMActions * actions )
{
assert(service == wrangler);
if (service == wrangler)
{
bool aborting = ((lastSleepReason == kIOPMSleepReasonIdle)
|| (lastSleepReason == kIOPMSleepReasonMaintenance));
if (aborting) {
userActivityCount++;
DLOG("display wrangler tickled1 %d lastSleepReason %d\n", userActivityCount, lastSleepReason);
}
}
if (!wranglerTickled && !lowBatteryCondition &&
((_pendingCapability & kIOPMSystemCapabilityGraphics) == 0))
{
DLOG("display wrangler tickled\n");
if (kIOLogPMRootDomain & gIOKitDebug)
OSReportWithBacktrace("Dark wake display tickle");
if (pmPowerStateQueue)
{
pmPowerStateQueue->submitPowerEvent(
kPowerEventPolicyStimulus,
(void *) kStimulusDarkWakeActivityTickle );
}
}
}
bool IOPMrootDomain::shouldDelayChildNotification(
IOService * service )
{
if (((gDarkWakeFlags & kDarkWakeFlagHIDTickleMask) != 0) &&
!wranglerTickled &&
(kSystemTransitionWake == _systemTransitionType))
{
DLOG("%s: delay child notify\n", service->getName());
return true;
}
return false;
}
void IOPMrootDomain::handlePowerChangeStartForPCIDevice(
IOService * service,
IOPMActions * actions,
uint32_t powerState,
uint32_t * inOutChangeFlags )
{
pmTracer->tracePCIPowerChange(
PMTraceWorker::kPowerChangeStart,
service, *inOutChangeFlags,
(actions->parameter & kPMActionsPCIBitNumberMask));
}
void IOPMrootDomain::handlePowerChangeDoneForPCIDevice(
IOService * service,
IOPMActions * actions,
uint32_t powerState,
uint32_t changeFlags )
{
pmTracer->tracePCIPowerChange(
PMTraceWorker::kPowerChangeCompleted,
service, changeFlags,
(actions->parameter & kPMActionsPCIBitNumberMask));
}
IONotifier * IOPMrootDomain::registerInterest(
const OSSymbol * typeOfInterest,
IOServiceInterestHandler handler,
void * target, void * ref )
{
IONotifier * notifier;
bool isSystemCapabilityClient;
bool isKernelCapabilityClient;
isSystemCapabilityClient =
typeOfInterest &&
typeOfInterest->isEqualTo(kIOPMSystemCapabilityInterest);
isKernelCapabilityClient =
typeOfInterest &&
typeOfInterest->isEqualTo(gIOPriorityPowerStateInterest);
if (isSystemCapabilityClient)
typeOfInterest = gIOAppPowerStateInterest;
notifier = super::registerInterest(typeOfInterest, handler, target, ref);
if (notifier && pmPowerStateQueue)
{
if (isSystemCapabilityClient)
{
notifier->retain();
if (pmPowerStateQueue->submitPowerEvent(
kPowerEventRegisterSystemCapabilityClient, notifier) == false)
notifier->release();
}
if (isKernelCapabilityClient)
{
notifier->retain();
if (pmPowerStateQueue->submitPowerEvent(
kPowerEventRegisterKernelCapabilityClient, notifier) == false)
notifier->release();
}
}
return notifier;
}
bool IOPMrootDomain::systemMessageFilter(
void * object, void * arg1, void * arg2, void * arg3 )
{
const IOPMInterestContext * context = (const IOPMInterestContext *) arg1;
bool isCapMsg = (context->messageType == kIOMessageSystemCapabilityChange);
bool isCapClient = false;
bool allow = false;
do {
if ((kSystemTransitionNewCapClient == _systemTransitionType) &&
(!isCapMsg || !_joinedCapabilityClients ||
!_joinedCapabilityClients->containsObject((OSObject *) object)))
break;
if (isCapMsg)
{
if ((context->notifyType == kNotifyPriority) ||
(context->notifyType == kNotifyCapabilityChangePriority))
isCapClient = true;
if ((context->notifyType == kNotifyCapabilityChangeApps) &&
(object == (void *) systemCapabilityNotifier))
isCapClient = true;
}
if (isCapClient)
{
IOPMSystemCapabilityChangeParameters * capArgs =
(IOPMSystemCapabilityChangeParameters *) arg2;
if (kSystemTransitionNewCapClient == _systemTransitionType)
{
capArgs->fromCapabilities = 0;
capArgs->toCapabilities = _currentCapability;
capArgs->changeFlags = 0;
}
else
{
capArgs->fromCapabilities = _currentCapability;
capArgs->toCapabilities = _pendingCapability;
if (context->isPreChange)
capArgs->changeFlags = kIOPMSystemCapabilityWillChange;
else
capArgs->changeFlags = kIOPMSystemCapabilityDidChange;
}
if ((context->notifyType == kNotifyCapabilityChangeApps) && arg3 &&
( (capabilityLoss && context->isPreChange) ||
(!capabilityLoss && !context->isPreChange) ) )
{
*((OSObject **) arg3) = kOSBooleanFalse;
}
allow = true;
break;
}
if ((kIOMessageCanSystemSleep == context->messageType) ||
(kIOMessageSystemWillNotSleep == context->messageType))
{
if (object == (OSObject *) systemCapabilityNotifier)
{
allow = true;
break;
}
if (context->changeFlags & kIOPMSkipAskPowerDown)
{
break;
}
}
if (isCapMsg || (object == (OSObject *) systemCapabilityNotifier))
{
break;
}
if ((context->notifyType == kNotifyApps) &&
(_systemMessageClientMask & kSystemMessageClientApp))
{
allow = true;
}
else if ((context->notifyType == kNotifyPriority) &&
(_systemMessageClientMask & kSystemMessageClientKernel))
{
allow = true;
}
}
while (false);
if (allow && isCapMsg && _joinedCapabilityClients)
{
_joinedCapabilityClients->removeObject((OSObject *) object);
if (_joinedCapabilityClients->getCount() == 0)
{
DLOG("destroyed capability client set %p\n",
_joinedCapabilityClients);
_joinedCapabilityClients->release();
_joinedCapabilityClients = 0;
}
}
return allow;
}
IOReturn IOPMrootDomain::setMaintenanceWakeCalendar(
const IOPMCalendarStruct * calendar )
{
OSData * data;
IOReturn ret;
if (!calendar)
return kIOReturnBadArgument;
data = OSData::withBytesNoCopy((void *) calendar, sizeof(*calendar));
if (!data)
return kIOReturnNoMemory;
ret = setPMSetting(gIOPMSettingMaintenanceWakeCalendarKey, data);
data->release();
return ret;
}
IOReturn IOPMrootDomain::displayWranglerNotification(
void * target, void * refCon,
UInt32 messageType, IOService * service,
void * messageArgument, vm_size_t argSize )
{
#if !NO_KERNEL_HID
int displayPowerState;
IOPowerStateChangeNotification * params =
(IOPowerStateChangeNotification *) messageArgument;
if ((messageType != kIOMessageDeviceWillPowerOff) &&
(messageType != kIOMessageDeviceHasPoweredOn))
return kIOReturnUnsupported;
ASSERT_GATED();
if (!gRootDomain)
return kIOReturnUnsupported;
displayPowerState = params->stateNumber;
DLOG("DisplayWrangler message 0x%x, power state %d\n",
(uint32_t) messageType, displayPowerState);
switch (messageType) {
case kIOMessageDeviceWillPowerOff:
if (displayPowerState > 2)
break;
gRootDomain->evaluatePolicy( kStimulusDisplayWranglerSleep );
break;
case kIOMessageDeviceHasPoweredOn:
if ( 4 != displayPowerState )
break;
gRootDomain->evaluatePolicy( kStimulusDisplayWranglerWake );
break;
}
#endif
return kIOReturnUnsupported;
}
bool IOPMrootDomain::displayWranglerMatchPublished(
void * target,
void * refCon,
IOService * newService,
IONotifier * notifier __unused)
{
#if !NO_KERNEL_HID
if( !newService->registerInterest( gIOGeneralInterest,
&displayWranglerNotification, target, 0) )
{
return false;
}
#endif
return true;
}
void IOPMrootDomain::reportUserInput( void )
{
#if !NO_KERNEL_HID
OSIterator * iter;
if(!wrangler)
{
iter = getMatchingServices(serviceMatching("IODisplayWrangler"));
if(iter)
{
wrangler = (IOService *) iter->getNextObject();
iter->release();
}
}
if(wrangler)
wrangler->activityTickle(0,0);
#endif
}
bool IOPMrootDomain::batteryPublished(
void * target,
void * root_domain,
IOService * resourceService,
IONotifier * notifier __unused )
{
((IOPMrootDomain *)root_domain)->publishFeature("DisplayDims");
return (true);
}
bool IOPMrootDomain::checkSystemCanSleep( IOOptionBits options )
{
int err = 0;
do {
if (userDisabledAllSleep)
{
err = 1; break;
}
if (systemBooting || systemShutdown)
{
err = 2; break;
}
if (options == 0)
break;
#if !CONFIG_SLEEP
err = 3; break;
#endif
if (lowBatteryCondition)
{
break; }
if (childPreventSystemSleep)
{
err = 4; break;
}
if (getPMAssertionLevel( kIOPMDriverAssertionCPUBit ) ==
kIOPMDriverAssertionLevelOn)
{
err = 5; break;
}
if (pciCantSleepValid)
{
if (pciCantSleepFlag)
err = 6; break;
}
else if (sleepSupportedPEFunction &&
CAP_HIGHEST(kIOPMSystemCapabilityGraphics))
{
IOReturn ret;
OSBitAndAtomic(~kPCICantSleep, &platformSleepSupport);
ret = getPlatform()->callPlatformFunction(
sleepSupportedPEFunction, false,
NULL, NULL, NULL, NULL);
pciCantSleepValid = true;
pciCantSleepFlag = false;
if ((platformSleepSupport & kPCICantSleep) ||
((ret != kIOReturnSuccess) && (ret != kIOReturnUnsupported)))
{
err = 6; pciCantSleepFlag = true;
break;
}
}
}
while (false);
if (err)
{
DLOG("System sleep prevented by %d\n", err);
return false;
}
return true;
}
void IOPMrootDomain::adjustPowerState( bool sleepASAP )
{
DLOG("adjustPowerState ps %u, asap %d, slider %ld\n",
(uint32_t) getPowerState(), sleepASAP, sleepSlider);
ASSERT_GATED();
if ((sleepSlider == 0) || !checkSystemCanSleep())
{
changePowerStateToPriv(ON_STATE);
}
else if ( sleepASAP )
{
changePowerStateToPriv(SLEEP_STATE);
}
}
void IOPMrootDomain::dispatchPowerEvent(
uint32_t event, void * arg0, uint64_t arg1 )
{
DLOG("power event %u args %p 0x%llx\n", event, arg0, arg1);
ASSERT_GATED();
switch (event)
{
case kPowerEventFeatureChanged:
messageClients(kIOPMMessageFeatureChange, this);
break;
case kPowerEventReceivedPowerNotification:
handlePowerNotification( (UInt32)(uintptr_t) arg0 );
break;
case kPowerEventSystemBootCompleted:
if (systemBooting)
{
systemBooting = false;
if ( clamshellClosed )
{
handlePowerNotification(kLocalEvalClamshellCommand);
}
evaluatePolicy( kStimulusAllowSystemSleepChanged );
}
break;
case kPowerEventSystemShutdown:
if (kOSBooleanTrue == (OSBoolean *) arg0)
{
systemShutdown = true;
} else {
systemShutdown = false;
}
break;
case kPowerEventUserDisabledSleep:
userDisabledAllSleep = (kOSBooleanTrue == (OSBoolean *) arg0);
break;
case kPowerEventRegisterSystemCapabilityClient:
if (systemCapabilityNotifier)
{
systemCapabilityNotifier->release();
systemCapabilityNotifier = 0;
}
if (arg0)
{
systemCapabilityNotifier = (IONotifier *) arg0;
systemCapabilityNotifier->retain();
}
case kPowerEventRegisterKernelCapabilityClient:
if (!_joinedCapabilityClients)
_joinedCapabilityClients = OSSet::withCapacity(8);
if (arg0)
{
IONotifier * notify = (IONotifier *) arg0;
if (_joinedCapabilityClients)
{
_joinedCapabilityClients->setObject(notify);
synchronizePowerTree( kIOPMSyncNoChildNotify );
}
notify->release();
}
break;
case kPowerEventPolicyStimulus:
if (arg0)
{
int stimulus = (uintptr_t) arg0;
evaluatePolicy( stimulus, (uint32_t) arg1 );
}
break;
case kPowerEventAssertionCreate:
if (pmAssertions) {
pmAssertions->handleCreateAssertion((OSData *)arg0);
}
break;
case kPowerEventAssertionRelease:
if (pmAssertions) {
pmAssertions->handleReleaseAssertion(arg1);
}
break;
case kPowerEventAssertionSetLevel:
if (pmAssertions) {
pmAssertions->handleSetAssertionLevel(arg1, (IOPMDriverAssertionLevel)(uintptr_t)arg0);
}
break;
case kPowerEventQueueSleepWakeUUID:
handleQueueSleepWakeUUID((OSObject *)arg0);
break;
case kPowerEventPublishSleepWakeUUID:
handlePublishSleepWakeUUID((bool)arg0);
break;
}
}
IOReturn IOPMrootDomain::systemPowerEventOccurred(
const OSSymbol *event,
uint32_t intValue)
{
IOReturn attempt = kIOReturnSuccess;
OSNumber *newNumber = NULL;
if (!event)
return kIOReturnBadArgument;
newNumber = OSNumber::withNumber(intValue, 8*sizeof(intValue));
if (!newNumber)
return kIOReturnInternalError;
attempt = systemPowerEventOccurred(event, (OSObject *)newNumber);
newNumber->release();
return attempt;
}
IOReturn IOPMrootDomain::systemPowerEventOccurred(
const OSSymbol *event,
OSObject *value)
{
OSDictionary *thermalsDict = NULL;
bool shouldUpdate = true;
if (!event || !value)
return kIOReturnBadArgument;
if (featuresDictLock) IOLockLock(featuresDictLock);
thermalsDict = (OSDictionary *)getProperty(kIOPMRootDomainPowerStatusKey);
if (thermalsDict && OSDynamicCast(OSDictionary, thermalsDict)) {
thermalsDict = OSDictionary::withDictionary(thermalsDict);
} else {
thermalsDict = OSDictionary::withCapacity(1);
}
if (!thermalsDict) {
shouldUpdate = false;
goto exit;
}
thermalsDict->setObject (event, value);
setProperty (kIOPMRootDomainPowerStatusKey, thermalsDict);
thermalsDict->release();
exit:
if (featuresDictLock) IOLockUnlock(featuresDictLock);
if (shouldUpdate)
messageClients (kIOPMMessageSystemPowerEventOccurred, (void *)NULL);
return kIOReturnSuccess;
}
IOReturn IOPMrootDomain::receivePowerNotification( UInt32 msg )
{
pmPowerStateQueue->submitPowerEvent(
kPowerEventReceivedPowerNotification, (void *) msg );
return kIOReturnSuccess;
}
void IOPMrootDomain::handlePowerNotification( UInt32 msg )
{
bool eval_clamshell = false;
ASSERT_GATED();
if (msg & kLocalEvalClamshellCommand)
{
eval_clamshell = true;
}
if (msg & kIOPMOverTemp)
{
MSG("PowerManagement emergency overtemp signal. Going to sleep!");
privateSleepSystem (kIOPMSleepReasonThermalEmergency);
}
if (msg & kIOPMSleepNow)
{
privateSleepSystem (kIOPMSleepReasonSoftware);
}
if (msg & kIOPMPowerEmergency)
{
lowBatteryCondition = true;
privateSleepSystem (kIOPMSleepReasonLowPower);
}
if (msg & kIOPMClamshellOpened)
{
clamshellClosed = false;
clamshellExists = true;
if (msg & kIOPMSetValue)
{
reportUserInput();
}
informCPUStateChange(kInformLid, 0);
sendClientClamshellNotification();
bool aborting = ((lastSleepReason == kIOPMSleepReasonClamshell)
|| (lastSleepReason == kIOPMSleepReasonIdle)
|| (lastSleepReason == kIOPMSleepReasonMaintenance));
if (aborting) userActivityCount++;
DLOG("clamshell tickled %d lastSleepReason %d\n", userActivityCount, lastSleepReason);
}
if (msg & kIOPMClamshellClosed)
{
clamshellClosed = true;
clamshellExists = true;
informCPUStateChange(kInformLid, 1);
sendClientClamshellNotification();
eval_clamshell = true;
}
if (msg & kIOPMSetDesktopMode)
{
desktopMode = (0 != (msg & kIOPMSetValue));
msg &= ~(kIOPMSetDesktopMode | kIOPMSetValue);
sendClientClamshellNotification();
if( clamshellClosed )
{
eval_clamshell = true;
}
}
if (msg & kIOPMSetACAdaptorConnected)
{
acAdaptorConnected = (0 != (msg & kIOPMSetValue));
msg &= ~(kIOPMSetACAdaptorConnected | kIOPMSetValue);
informCPUStateChange(kInformAC, !acAdaptorConnected);
post_sys_powersource(acAdaptorConnected ? 0:1);
sendClientClamshellNotification();
if( clamshellClosed )
{
eval_clamshell = true;
}
}
if (msg & kIOPMEnableClamshell)
{
if( clamshellClosed && (true == clamshellDisabled) )
{
eval_clamshell = true;
}
clamshellDisabled = false;
sendClientClamshellNotification();
}
if (msg & kIOPMDisableClamshell)
{
clamshellDisabled = true;
sendClientClamshellNotification();
}
if ( eval_clamshell && shouldSleepOnClamshellClosed() )
{
privateSleepSystem (kIOPMSleepReasonClamshell);
}
else if ( eval_clamshell )
{
evaluatePolicy(kStimulusDarkWakeEvaluate);
}
if (msg & kIOPMPowerButton)
{
if (!wranglerAsleep)
{
OSString *pbs = OSString::withCString("DisablePowerButtonSleep");
if( pbs ) {
if( kOSBooleanTrue != getProperty(pbs))
privateSleepSystem (kIOPMSleepReasonPowerButton);
}
}
else
reportUserInput();
}
}
void IOPMrootDomain::evaluatePolicy( int stimulus, uint32_t arg )
{
union {
struct {
int idleSleepEnabled : 1;
int idleSleepDisabled : 1;
int displaySleep : 1;
int sleepDelayChanged : 1;
int evaluateDarkWake : 1;
} bit;
uint32_t u32;
} flags;
DLOG("evaluatePolicy( %d, 0x%x )\n", stimulus, arg);
ASSERT_GATED();
flags.u32 = 0;
switch (stimulus)
{
case kStimulusDisplayWranglerSleep:
if (!wranglerAsleep)
{
wranglerAsleep = true;
clock_get_uptime(&wranglerSleepTime);
flags.bit.displaySleep = true;
}
break;
case kStimulusDisplayWranglerWake:
wranglerAsleep = false;
flags.bit.idleSleepDisabled = true;
break;
case kStimulusAggressivenessChanged:
{
unsigned long minutesToIdleSleep = 0;
unsigned long minutesToDisplayDim = 0;
unsigned long minutesDelta = 0;
getAggressiveness(kPMMinutesToSleep, &minutesToIdleSleep);
getAggressiveness(kPMMinutesToDim, &minutesToDisplayDim);
DLOG("aggressiveness changed: system %u->%u, display %u\n",
(uint32_t) sleepSlider,
(uint32_t) minutesToIdleSleep,
(uint32_t) minutesToDisplayDim);
DLOG("idle time -> %ld secs (ena %d)\n",
idleSeconds, (minutesToIdleSleep != 0));
if (0x7fffffff == minutesToIdleSleep)
minutesToIdleSleep = idleSeconds;
if ( minutesToIdleSleep > minutesToDisplayDim )
minutesDelta = minutesToIdleSleep - minutesToDisplayDim;
if ((sleepSlider == 0) && (minutesToIdleSleep != 0))
flags.bit.idleSleepEnabled = true;
if ((sleepSlider != 0) && (minutesToIdleSleep == 0))
flags.bit.idleSleepDisabled = true;
if ((minutesDelta != extraSleepDelay) &&
!flags.bit.idleSleepEnabled && !flags.bit.idleSleepDisabled)
flags.bit.sleepDelayChanged = true;
if (systemDarkWake && !darkWakeToSleepASAP &&
(flags.bit.idleSleepEnabled || flags.bit.idleSleepDisabled))
{
flags.bit.evaluateDarkWake = true;
}
sleepSlider = minutesToIdleSleep;
extraSleepDelay = minutesDelta;
} break;
case kStimulusDemandSystemSleep:
changePowerStateWithOverrideTo( SLEEP_STATE );
break;
case kStimulusAllowSystemSleepChanged:
adjustPowerState();
break;
case kStimulusDarkWakeActivityTickle:
if (false == wranglerTickled)
{
uint32_t options = 0;
IOService * pciRoot = 0;
if (rejectWranglerTickle)
{
DLOG("rejected tickle, type %u capability %x:%x\n",
_systemTransitionType,
_currentCapability, _pendingCapability);
break;
}
_desiredCapability |=
(kIOPMSystemCapabilityGraphics |
kIOPMSystemCapabilityAudio);
if ((kSystemTransitionWake == _systemTransitionType) &&
!(_pendingCapability & kIOPMSystemCapabilityGraphics) &&
!graphicsSuppressed)
{
DLOG("Promoting to full wake\n");
_pendingCapability |=
(kIOPMSystemCapabilityGraphics |
kIOPMSystemCapabilityAudio);
pciRoot = pciHostBridgeDriver;
_systemMessageClientMask = kSystemMessageClientAll;
tellClients(kIOMessageSystemWillPowerOn);
}
if (!CAP_HIGHEST(kIOPMSystemCapabilityGraphics)) {
options |= kIOPMSyncCancelPowerDown;
}
synchronizePowerTree( options, pciRoot );
wranglerTickled = true;
if(wrangler)
wrangler->activityTickle(0,0);
if (logWranglerTickle)
{
AbsoluteTime now;
uint64_t nsec;
clock_get_uptime(&now);
SUB_ABSOLUTETIME(&now, &systemWakeTime);
absolutetime_to_nanoseconds(now, &nsec);
MSG("HID tickle %u ms\n",
((int)((nsec) / 1000000ULL)));
logWranglerTickle = false;
}
}
break;
case kStimulusDarkWakeEntry:
case kStimulusDarkWakeReentry:
if (arg == _systemStateGeneration)
{
DLOG("dark wake entry\n");
systemDarkWake = true;
wranglerAsleep = true;
clock_get_uptime(&wranglerSleepTime);
cancelIdleSleepTimer();
setQuickSpinDownTimeout();
flags.bit.evaluateDarkWake = true;
}
break;
case kStimulusDarkWakeEvaluate:
if (systemDarkWake)
{
flags.bit.evaluateDarkWake = true;
}
#if !DARK_TO_FULL_EVALUATE_CLAMSHELL
else
{
if (clamshellClosed && shouldSleepOnClamshellClosed() &&
checkSystemCanSleep(true))
{
privateSleepSystem( kIOPMSleepReasonClamshell );
}
}
#endif
break;
}
if (flags.bit.evaluateDarkWake && !wranglerTickled)
{
if (darkWakeToSleepASAP ||
(clamshellClosed && !(desktopMode && acAdaptorConnected)))
{
if (checkSystemCanSleep(true))
{
if (lowBatteryCondition)
{
lastSleepReason = kIOPMSleepReasonLowPower;
setProperty(kRootDomainSleepReasonKey, kIOPMLowPowerSleepKey);
}
else if (darkWakeMaintenance)
{
lastSleepReason = kIOPMSleepReasonMaintenance;
setProperty(kRootDomainSleepReasonKey, kIOPMMaintenanceSleepKey);
}
changePowerStateWithOverrideTo( SLEEP_STATE );
}
else
{
rejectWranglerTickle = false;
}
} else {
if (checkSystemCanSleep(true))
{
adjustPowerState(true);
}
else
{
changePowerStateToPriv(ON_STATE);
}
rejectWranglerTickle = false;
}
}
if (systemDarkWake)
{
flags.u32 = 0;
}
if (flags.bit.displaySleep || flags.bit.sleepDelayChanged)
{
bool cancelQuickSpindown = false;
if (flags.bit.sleepDelayChanged)
{
DLOG("extra sleep timer changed\n");
cancelIdleSleepTimer();
cancelQuickSpindown = true;
}
else
{
DLOG("display sleep\n");
}
if (wranglerAsleep && !wranglerSleepIgnored)
{
if ( extraSleepDelay )
{
startIdleSleepTimer(gRootDomain->extraSleepDelay * 60);
}
else if ( sleepSlider )
{
setQuickSpinDownTimeout();
cancelQuickSpindown = false;
}
}
if (cancelQuickSpindown)
restoreUserSpinDownTimeout();
}
if (flags.bit.idleSleepEnabled)
{
DLOG("idle sleep timer enabled\n");
if (!wrangler)
{
changePowerStateToPriv(ON_STATE);
if (idleSeconds)
{
startIdleSleepTimer( idleSeconds );
}
}
else
{
if (wranglerAsleep)
{
AbsoluteTime now;
uint64_t nanos;
uint32_t minutesSinceDisplaySleep = 0;
uint32_t sleepDelay;
clock_get_uptime(&now);
if (CMP_ABSOLUTETIME(&now, &wranglerSleepTime) > 0)
{
SUB_ABSOLUTETIME(&now, &wranglerSleepTime);
absolutetime_to_nanoseconds(now, &nanos);
minutesSinceDisplaySleep = nanos / (60000000000ULL);
}
if (extraSleepDelay > minutesSinceDisplaySleep)
{
sleepDelay = extraSleepDelay - minutesSinceDisplaySleep;
}
else
{
sleepDelay = 1; }
startIdleSleepTimer(sleepDelay * 60);
DLOG("display slept %u min, set idle timer to %u min\n",
minutesSinceDisplaySleep, sleepDelay);
}
}
}
if (flags.bit.idleSleepDisabled)
{
DLOG("idle sleep timer disabled\n");
cancelIdleSleepTimer();
restoreUserSpinDownTimeout();
adjustPowerState();
}
}
void IOPMrootDomain::pmStatsRecordEvent(
int eventIndex,
AbsoluteTime timestamp)
{
bool starting = eventIndex & kIOPMStatsEventStartFlag ? true:false;
bool stopping = eventIndex & kIOPMStatsEventStopFlag ? true:false;
uint64_t delta;
uint64_t nsec;
eventIndex &= ~(kIOPMStatsEventStartFlag | kIOPMStatsEventStopFlag);
absolutetime_to_nanoseconds(timestamp, &nsec);
switch (eventIndex) {
case kIOPMStatsHibernateImageWrite:
if (starting)
pmStats.hibWrite.start = nsec;
else if (stopping)
pmStats.hibWrite.stop = nsec;
if (stopping) {
delta = pmStats.hibWrite.stop - pmStats.hibWrite.start;
IOLog("PMStats: Hibernate write took %qd ms\n", delta/1000000ULL);
}
break;
case kIOPMStatsHibernateImageRead:
if (starting)
pmStats.hibRead.start = nsec;
else if (stopping)
pmStats.hibRead.stop = nsec;
if (stopping) {
delta = pmStats.hibRead.stop - pmStats.hibRead.start;
IOLog("PMStats: Hibernate read took %qd ms\n", delta/1000000ULL);
}
break;
}
}
void IOPMrootDomain::pmStatsRecordApplicationResponse(
const OSSymbol *response,
const char *name,
int messageType,
uint32_t delay_ms,
int app_pid)
{
OSDictionary *responseDescription = NULL;
OSNumber *delayNum = NULL;
OSNumber *pidNum = NULL;
OSNumber *msgNum = NULL;
const OSSymbol *appname;
const OSSymbol *entryName;
OSObject *entryType;
int i;
if (!pmStatsAppResponses || pmStatsAppResponses->getCount() > 50)
return;
i = 0;
while ((responseDescription = (OSDictionary *) pmStatsAppResponses->getObject(i++)))
{
entryType = responseDescription->getObject(_statsResponseTypeKey);
entryName = (OSSymbol *) responseDescription->getObject(_statsNameKey);
if (entryName && (entryType == response) && entryName->isEqualTo(name))
{
OSNumber * entryValue;
entryValue = (OSNumber *) responseDescription->getObject(_statsTimeMSKey);
if (entryValue && (entryValue->unsigned32BitValue() < delay_ms))
entryValue->setValue(delay_ms);
return;
}
}
responseDescription = OSDictionary::withCapacity(5);
if (responseDescription)
{
if (response) {
responseDescription->setObject(_statsResponseTypeKey, response);
}
if (messageType != 0) {
msgNum = OSNumber::withNumber(messageType, 32);
if (msgNum) {
responseDescription->setObject(_statsMessageTypeKey, msgNum);
msgNum->release();
}
}
if (name && (strlen(name) > 0))
{
appname = OSSymbol::withCString(name);
if (appname) {
responseDescription->setObject(_statsNameKey, appname);
appname->release();
}
}
if (app_pid != -1) {
pidNum = OSNumber::withNumber(app_pid, 32);
if (pidNum) {
responseDescription->setObject(_statsPIDKey, pidNum);
pidNum->release();
}
}
delayNum = OSNumber::withNumber(delay_ms, 32);
if (delayNum) {
responseDescription->setObject(_statsTimeMSKey, delayNum);
delayNum->release();
}
if (pmStatsAppResponses) {
pmStatsAppResponses->setObject(responseDescription);
}
responseDescription->release();
}
return;
}
#define kIOPMRegisterNVRAMTracePointHandlerKey \
"IOPMRegisterNVRAMTracePointHandler"
IOReturn IOPMrootDomain::callPlatformFunction(
const OSSymbol * functionName,
bool waitForFunction,
void * param1, void * param2,
void * param3, void * param4 )
{
if (pmTracer && functionName &&
functionName->isEqualTo(kIOPMRegisterNVRAMTracePointHandlerKey) &&
!pmTracer->tracePointHandler && !pmTracer->tracePointTarget)
{
uint32_t tracePointPhases, tracePointPCI;
uint64_t statusCode;
pmTracer->tracePointHandler = (IOPMTracePointHandler) param1;
pmTracer->tracePointTarget = (void *) param2;
tracePointPCI = (uint32_t)(uintptr_t) param3;
tracePointPhases = (uint32_t)(uintptr_t) param4;
statusCode = (((uint64_t)tracePointPCI) << 32) | tracePointPhases;
if ((tracePointPhases >> 24) != kIOPMTracePointSystemUp)
{
MSG("Sleep failure code 0x%08x 0x%08x\n",
tracePointPCI, tracePointPhases);
}
setProperty(kIOPMSleepWakeFailureCodeKey, statusCode, 64);
pmTracer->tracePointHandler( pmTracer->tracePointTarget, 0, 0 );
return kIOReturnSuccess;
}
return super::callPlatformFunction(
functionName, waitForFunction, param1, param2, param3, param4);
}
void IOPMrootDomain::tracePoint( uint8_t point )
{
if (!systemBooting)
pmTracer->tracePoint(point);
}
void IOPMrootDomain::tracePoint( uint8_t point, uint8_t data )
{
if (!systemBooting)
pmTracer->tracePoint(point, data);
}
void IOPMrootDomain::traceDetail( uint32_t detail )
{
if (!systemBooting)
pmTracer->traceDetail( detail );
}
#undef super
#define super OSObject
OSDefineMetaClassAndStructors(PMTraceWorker, OSObject)
#define kPMBestGuessPCIDevicesCount 25
#define kPMMaxRTCBitfieldSize 32
PMTraceWorker *PMTraceWorker::tracer(IOPMrootDomain *owner)
{
PMTraceWorker *me;
me = OSTypeAlloc( PMTraceWorker );
if (!me || !me->init())
{
return NULL;
}
DLOG("PMTraceWorker %p\n", me);
me->owner = owner;
me->pciDeviceBitMappings = NULL;
me->pciMappingLock = IOLockAlloc();
me->tracePhase = kIOPMTracePointSystemUp;
me->loginWindowPhase = 0;
me->traceData32 = 0;
return me;
}
void PMTraceWorker::RTC_TRACE(void)
{
if (tracePointHandler && tracePointTarget)
{
uint32_t wordA;
wordA = (tracePhase << 24) | (loginWindowPhase << 16) |
(traceData8 << 8);
tracePointHandler( tracePointTarget, traceData32, wordA );
_LOG("RTC_TRACE wrote 0x%08x 0x%08x\n", traceData32, wordA);
}
}
int PMTraceWorker::recordTopLevelPCIDevice(IOService * pciDevice)
{
const OSSymbol * deviceName;
int index = -1;
IOLockLock(pciMappingLock);
if (!pciDeviceBitMappings)
{
pciDeviceBitMappings = OSArray::withCapacity(kPMBestGuessPCIDevicesCount);
if (!pciDeviceBitMappings)
goto exit;
}
if (pciDeviceBitMappings->getCount() >= kPMMaxRTCBitfieldSize)
goto exit;
if ((deviceName = pciDevice->copyName()) &&
(pciDeviceBitMappings->getNextIndexOfObject(deviceName, 0) == (unsigned int)-1) &&
pciDeviceBitMappings->setObject(deviceName))
{
index = pciDeviceBitMappings->getCount() - 1;
_LOG("PMTrace PCI array: set object %s => %d\n",
deviceName->getCStringNoCopy(), index);
}
if (deviceName)
deviceName->release();
if (!addedToRegistry && (index >= 0))
addedToRegistry = owner->setProperty("PCITopLevel", this);
exit:
IOLockUnlock(pciMappingLock);
return index;
}
bool PMTraceWorker::serialize(OSSerialize *s) const
{
bool ok = false;
if (pciDeviceBitMappings)
{
IOLockLock(pciMappingLock);
ok = pciDeviceBitMappings->serialize(s);
IOLockUnlock(pciMappingLock);
}
return ok;
}
void PMTraceWorker::tracePoint(uint8_t phase)
{
if (tracePhase != phase)
traceData32 = 0;
tracePhase = phase;
DLOG("trace point 0x%02x\n", tracePhase);
RTC_TRACE();
}
void PMTraceWorker::tracePoint(uint8_t phase, uint8_t data8)
{
if (tracePhase != phase)
traceData32 = 0;
tracePhase = phase;
traceData8 = data8;
DLOG("trace point 0x%02x 0x%02x\n", tracePhase, traceData8);
RTC_TRACE();
}
void PMTraceWorker::traceDetail(uint32_t detail)
{
if (kIOPMTracePointSleepPriorityClients != tracePhase)
return;
traceData32 = detail;
DLOG("trace point 0x%02x detail 0x%08x\n", tracePhase, traceData32);
RTC_TRACE();
}
void PMTraceWorker::traceLoginWindowPhase(uint8_t phase)
{
loginWindowPhase = phase;
DLOG("loginwindow tracepoint 0x%02x\n", loginWindowPhase);
RTC_TRACE();
}
void PMTraceWorker::tracePCIPowerChange(
change_t type, IOService *service, uint32_t changeFlags, uint32_t bitNum)
{
uint32_t bitMask;
uint32_t expectedFlag;
if ((kIOPMTracePointSleepPowerPlaneDrivers != tracePhase) &&
(kIOPMTracePointWakePowerPlaneDrivers != tracePhase))
return;
changeFlags &= (kIOPMDomainWillChange | kIOPMDomainDidChange);
expectedFlag = (kIOPMTracePointSleepPowerPlaneDrivers == tracePhase) ?
kIOPMDomainWillChange : kIOPMDomainDidChange;
if (changeFlags != expectedFlag)
return;
if (bitNum < kPMMaxRTCBitfieldSize)
{
bitMask = (1 << bitNum);
if (kPowerChangeStart == type)
{
traceData32 |= bitMask;
_LOG("PMTrace: Device %s started - bit %2d mask 0x%08x => 0x%08x\n",
service->getName(), bitNum, bitMask, traceData32);
}
else
{
traceData32 &= ~bitMask;
_LOG("PMTrace: Device %s finished - bit %2d mask 0x%08x => 0x%08x\n",
service->getName(), bitNum, bitMask, traceData32);
}
RTC_TRACE();
}
}
static unsigned int gPMHaltBusyCount;
static unsigned int gPMHaltIdleCount;
static int gPMHaltDepth;
static unsigned long gPMHaltEvent;
static IOLock * gPMHaltLock = 0;
static OSArray * gPMHaltArray = 0;
static const OSSymbol * gPMHaltClientAcknowledgeKey = 0;
PMHaltWorker * PMHaltWorker::worker( void )
{
PMHaltWorker * me;
IOThread thread;
do {
me = OSTypeAlloc( PMHaltWorker );
if (!me || !me->init())
break;
me->lock = IOLockAlloc();
if (!me->lock)
break;
DLOG("PMHaltWorker %p\n", me);
me->retain(); if (KERN_SUCCESS != kernel_thread_start(&PMHaltWorker::main, (void *) me, &thread))
{
me->release();
break;
}
thread_deallocate(thread);
return me;
} while (false);
if (me) me->release();
return 0;
}
void PMHaltWorker::free( void )
{
DLOG("PMHaltWorker free %p\n", this);
if (lock)
{
IOLockFree(lock);
lock = 0;
}
return OSObject::free();
}
void PMHaltWorker::main( void * arg, wait_result_t waitResult )
{
PMHaltWorker * me = (PMHaltWorker *) arg;
IOLockLock( gPMHaltLock );
gPMHaltBusyCount++;
me->depth = gPMHaltDepth;
IOLockUnlock( gPMHaltLock );
while (me->depth >= 0)
{
PMHaltWorker::work( me );
IOLockLock( gPMHaltLock );
if (++gPMHaltIdleCount >= gPMHaltBusyCount)
{
gPMHaltDepth--;
me->depth = gPMHaltDepth;
gPMHaltIdleCount = 0;
thread_wakeup((event_t) &gPMHaltIdleCount);
}
else
{
me->depth = gPMHaltDepth - 1;
do {
IOLockSleep(gPMHaltLock, &gPMHaltIdleCount, THREAD_UNINT);
} while (me->depth != gPMHaltDepth);
}
IOLockUnlock( gPMHaltLock );
}
DLOG("All done for worker: %p (visits = %u)\n", me, me->visits);
thread_wakeup( &gPMHaltDepth );
me->release();
}
void PMHaltWorker::work( PMHaltWorker * me )
{
IOService * service;
OSSet * inner;
AbsoluteTime startTime;
UInt32 deltaTime;
bool timeout;
while (true)
{
service = 0;
timeout = false;
IOLockLock( gPMHaltLock );
inner = (OSSet *)gPMHaltArray->getObject(me->depth);
if (inner)
{
service = (IOService *)inner->getAnyObject();
if (service)
{
service->retain();
inner->removeObject(service);
}
}
IOLockUnlock( gPMHaltLock );
if (!service)
break;
clock_get_uptime(&startTime);
if (!service->isInactive() &&
service->setProperty(gPMHaltClientAcknowledgeKey, me))
{
IOLockLock(me->lock);
me->startTime = startTime;
me->service = service;
me->timeout = false;
IOLockUnlock(me->lock);
service->systemWillShutdown( gPMHaltEvent );
IOLockLock(me->lock);
while (service->getProperty(gPMHaltClientAcknowledgeKey))
{
IOLockSleep(me->lock, me, THREAD_UNINT);
}
me->service = 0;
timeout = me->timeout;
IOLockUnlock(me->lock);
}
deltaTime = computeDeltaTimeMS(&startTime);
if ((deltaTime > kPMHaltTimeoutMS) || timeout ||
(gIOKitDebug & kIOLogPMRootDomain))
{
LOG("%s driver %s (%p) took %u ms\n",
(gPMHaltEvent == kIOMessageSystemWillPowerOff) ?
"PowerOff" : "Restart",
service->getName(), service,
(uint32_t) deltaTime );
}
service->release();
me->visits++;
}
}
void PMHaltWorker::checkTimeout( PMHaltWorker * me, AbsoluteTime * now )
{
UInt64 nano;
AbsoluteTime startTime;
AbsoluteTime endTime;
endTime = *now;
IOLockLock(me->lock);
if (me->service && !me->timeout)
{
startTime = me->startTime;
nano = 0;
if (CMP_ABSOLUTETIME(&endTime, &startTime) > 0)
{
SUB_ABSOLUTETIME(&endTime, &startTime);
absolutetime_to_nanoseconds(endTime, &nano);
}
if (nano > 3000000000ULL)
{
me->timeout = true;
MSG("%s still waiting on %s\n",
(gPMHaltEvent == kIOMessageSystemWillPowerOff) ?
"PowerOff" : "Restart",
me->service->getName());
}
}
IOLockUnlock(me->lock);
}
void IOPMrootDomain::acknowledgeSystemWillShutdown( IOService * from )
{
PMHaltWorker * worker;
OSObject * prop;
if (!from)
return;
prop = from->copyProperty( gPMHaltClientAcknowledgeKey );
if (prop)
{
worker = (PMHaltWorker *) prop;
IOLockLock(worker->lock);
from->removeProperty( gPMHaltClientAcknowledgeKey );
thread_wakeup((event_t) worker);
IOLockUnlock(worker->lock);
worker->release();
}
else
{
DLOG("%s acknowledged without worker property\n",
from->getName());
}
}
static void
notifySystemShutdown( IOService * root, unsigned long event )
{
#define PLACEHOLDER ((OSSet *)gPMHaltArray)
IORegistryIterator * iter;
IORegistryEntry * entry;
IOService * node;
OSSet * inner;
PMHaltWorker * workers[kPMHaltMaxWorkers];
AbsoluteTime deadline;
unsigned int totalNodes = 0;
unsigned int depth;
unsigned int rootDepth;
unsigned int numWorkers;
unsigned int count;
int waitResult;
void * baseFunc;
bool ok;
DLOG("%s event = %lx\n", __FUNCTION__, event);
baseFunc = OSMemberFunctionCast(void *, root, &IOService::systemWillShutdown);
rootDepth = root->getDepth( gIOPowerPlane );
if (!rootDepth) goto done;
while (PMHaltWorker::metaClass->getInstanceCount())
IOSleep(1);
if (!gPMHaltArray)
{
gPMHaltArray = OSArray::withCapacity(40);
if (!gPMHaltArray) goto done;
}
else gPMHaltArray->flushCollection();
if (!gPMHaltLock)
{
gPMHaltLock = IOLockAlloc();
if (!gPMHaltLock) goto done;
}
if (!gPMHaltClientAcknowledgeKey)
{
gPMHaltClientAcknowledgeKey =
OSSymbol::withCStringNoCopy("PMShutdown");
if (!gPMHaltClientAcknowledgeKey) goto done;
}
gPMHaltEvent = event;
iter = IORegistryIterator::iterateOver(
root, gIOPowerPlane, kIORegistryIterateRecursively);
if (iter)
{
while ((entry = iter->getNextObject()))
{
node = OSDynamicCast(IOService, entry);
if (!node)
continue;
if (baseFunc ==
OSMemberFunctionCast(void *, node, &IOService::systemWillShutdown))
continue;
depth = node->getDepth( gIOPowerPlane );
if (depth <= rootDepth)
continue;
ok = false;
depth -= (rootDepth + 1);
count = gPMHaltArray->getCount();
while (depth >= count)
{
gPMHaltArray->setObject(PLACEHOLDER);
count++;
}
count = gPMHaltArray->getCount();
if (depth < count)
{
inner = (OSSet *)gPMHaltArray->getObject(depth);
if (inner == PLACEHOLDER)
{
inner = OSSet::withCapacity(40);
if (inner)
{
gPMHaltArray->replaceObject(depth, inner);
inner->release();
}
}
if (inner)
ok = inner->setObject(node);
}
if (!ok)
DLOG("Skipped PM node %s\n", node->getName());
}
iter->release();
}
for (int i = 0; (inner = (OSSet *)gPMHaltArray->getObject(i)); i++)
{
count = 0;
if (inner != PLACEHOLDER)
count = inner->getCount();
DLOG("Nodes at depth %u = %u\n", i, count);
}
numWorkers = 0;
for (int i = 0; (inner = (OSSet *)gPMHaltArray->getObject(i)); )
{
if (inner == PLACEHOLDER)
{
gPMHaltArray->removeObject(i);
continue;
}
count = inner->getCount();
if (count > numWorkers)
numWorkers = count;
totalNodes += count;
i++;
}
if (gPMHaltArray->getCount() == 0 || !numWorkers)
goto done;
gPMHaltBusyCount = 0;
gPMHaltIdleCount = 0;
gPMHaltDepth = gPMHaltArray->getCount() - 1;
if (numWorkers > kPMHaltMaxWorkers)
numWorkers = kPMHaltMaxWorkers;
DLOG("PM nodes = %u, maxDepth = %u, workers = %u\n",
totalNodes, gPMHaltArray->getCount(), numWorkers);
for (unsigned int i = 0; i < numWorkers; i++)
workers[i] = PMHaltWorker::worker();
IOLockLock(gPMHaltLock);
while (gPMHaltDepth >= 0)
{
clock_interval_to_deadline(1000, kMillisecondScale, &deadline);
waitResult = IOLockSleepDeadline(
gPMHaltLock, &gPMHaltDepth, deadline, THREAD_UNINT);
if (THREAD_TIMED_OUT == waitResult)
{
AbsoluteTime now;
clock_get_uptime(&now);
IOLockUnlock(gPMHaltLock);
for (unsigned int i = 0 ; i < numWorkers; i++)
{
if (workers[i])
PMHaltWorker::checkTimeout(workers[i], &now);
}
IOLockLock(gPMHaltLock);
}
}
IOLockUnlock(gPMHaltLock);
for (unsigned int i = 0; i < numWorkers; i++)
{
if (workers[i])
workers[i]->release();
}
done:
DLOG("%s done\n", __FUNCTION__);
return;
}
IOMemoryDescriptor *IOPMrootDomain::getPMTraceMemoryDescriptor(void)
{
if (timeline)
return timeline->getPMTraceMemoryDescriptor();
else
return NULL;
}
IOReturn IOPMrootDomain::recordPMEvent(PMEventDetails *details)
{
if (timeline && details) {
IOReturn rc;
if(details->eventClassifier == kIOPMEventClassDriverEvent) {
rc = timeline->recordDetailedPowerEvent( details );
}
else if(details->eventClassifier == kIOPMEventClassSystemEvent) {
rc = timeline->recordSystemPowerEvent( details );
}
else {
return kIOReturnBadArgument;
}
if(details->eventType == kIOPMEventTypeWakeDone) {
timeline->setSleepCycleInProgressFlag(false);
}
return rc;
}
else
return kIOReturnNotReady;
}
IOReturn IOPMrootDomain::recordAndReleasePMEvent(PMEventDetails *details)
{
IOReturn ret = kIOReturnBadArgument;
if (details)
{
ret = recordPMEvent(details);
details->release();
}
return ret;
}
IOPMDriverAssertionID IOPMrootDomain::createPMAssertion(
IOPMDriverAssertionType whichAssertionBits,
IOPMDriverAssertionLevel assertionLevel,
IOService *ownerService,
const char *ownerDescription)
{
IOReturn ret;
IOPMDriverAssertionID newAssertion;
if (!pmAssertions)
return 0;
ret = pmAssertions->createAssertion(whichAssertionBits, assertionLevel, ownerService, ownerDescription, &newAssertion);
if (kIOReturnSuccess == ret)
return newAssertion;
else
return 0;
}
IOReturn IOPMrootDomain::releasePMAssertion(IOPMDriverAssertionID releaseAssertion)
{
if (!pmAssertions)
return kIOReturnInternalError;
return pmAssertions->releaseAssertion(releaseAssertion);
}
IOReturn IOPMrootDomain::setPMAssertionLevel(
IOPMDriverAssertionID assertionID,
IOPMDriverAssertionLevel assertionLevel)
{
return pmAssertions->setAssertionLevel(assertionID, assertionLevel);
}
IOPMDriverAssertionLevel IOPMrootDomain::getPMAssertionLevel(IOPMDriverAssertionType whichAssertion)
{
IOPMDriverAssertionType sysLevels;
if (!pmAssertions || whichAssertion == 0)
return kIOPMDriverAssertionLevelOff;
sysLevels = pmAssertions->getActivatedAssertions();
if ((sysLevels & whichAssertion) == whichAssertion)
return kIOPMDriverAssertionLevelOn;
else
return kIOPMDriverAssertionLevelOff;
}
IOReturn IOPMrootDomain::setPMAssertionUserLevels(IOPMDriverAssertionType inLevels)
{
if (!pmAssertions)
return kIOReturnNotFound;
return pmAssertions->setUserAssertionLevels(inLevels);
}
bool IOPMrootDomain::serializeProperties( OSSerialize * s ) const
{
if (pmAssertions)
{
pmAssertions->publishProperties();
}
return( IOService::serializeProperties(s) );
}
OSDefineMetaClassAndStructors( PMSettingHandle, OSObject )
void PMSettingHandle::free( void )
{
if (pmso)
{
pmso->clientHandleFreed();
pmso->release();
pmso = 0;
}
OSObject::free();
}
#undef super
#define super OSObject
OSDefineMetaClassAndFinalStructors( PMSettingObject, OSObject )
PMSettingObject *PMSettingObject::pmSettingObject(
IOPMrootDomain *parent_arg,
IOPMSettingControllerCallback handler_arg,
OSObject *target_arg,
uintptr_t refcon_arg,
uint32_t supportedPowerSources,
const OSSymbol * settings[],
OSObject **handle_obj)
{
uint32_t settingCount = 0;
PMSettingObject *pmso = 0;
PMSettingHandle *pmsh = 0;
if ( !parent_arg || !handler_arg || !settings || !handle_obj )
return NULL;
while (settings[settingCount]) {
settingCount++;
}
if (0 == settingCount)
return NULL;
pmso = new PMSettingObject;
if (!pmso || !pmso->init())
goto fail;
pmsh = new PMSettingHandle;
if (!pmsh || !pmsh->init())
goto fail;
queue_init(&pmso->calloutQueue);
pmso->parent = parent_arg;
pmso->func = handler_arg;
pmso->target = target_arg;
pmso->refcon = refcon_arg;
pmso->settingCount = settingCount;
pmso->retain(); pmsh->pmso = pmso;
pmso->pmsh = pmsh;
pmso->publishedFeatureID = (uint32_t *)IOMalloc(sizeof(uint32_t)*settingCount);
if (pmso->publishedFeatureID) {
for (unsigned int i=0; i<settingCount; i++) {
parent_arg->publishFeature( settings[i]->getCStringNoCopy(),
supportedPowerSources, &pmso->publishedFeatureID[i] );
}
}
*handle_obj = pmsh;
return pmso;
fail:
if (pmso) pmso->release();
if (pmsh) pmsh->release();
return NULL;
}
void PMSettingObject::free( void )
{
if (publishedFeatureID) {
for (uint32_t i=0; i<settingCount; i++) {
if (publishedFeatureID[i]) {
parent->removePublishedFeature( publishedFeatureID[i] );
}
}
IOFree(publishedFeatureID, sizeof(uint32_t) * settingCount);
}
super::free();
}
void PMSettingObject::dispatchPMSetting( const OSSymbol * type, OSObject * object )
{
(*func)(target, type, object, refcon);
}
void PMSettingObject::clientHandleFreed( void )
{
parent->deregisterPMSettingObject(this);
}
#undef super
#define super OSObject
IOPMTimeline *IOPMTimeline::timeline(IOPMrootDomain *root_domain)
{
IOPMTimeline *myself;
if (!root_domain)
return NULL;
myself = new IOPMTimeline;
if (myself) {
myself->owner = root_domain;
myself->init();
}
return myself;
}
bool IOPMTimeline::init(void)
{
if (!super::init()) {
return false;
}
logLock = IOLockAlloc();
this->numEventsLoggedThisPeriod = 0;
this->sleepCycleInProgress = false;
this->setEventsTrackedCount(kIOPMDefaultSystemEventsTracked);
return true;
}
void IOPMTimeline::free(void)
{
if (pmTraceMemoryDescriptor) {
pmTraceMemoryDescriptor->release();
pmTraceMemoryDescriptor = NULL;
}
IOLockFree(logLock);
super::free();
}
IOMemoryDescriptor *IOPMTimeline::getPMTraceMemoryDescriptor()
{
return pmTraceMemoryDescriptor;
}
bool IOPMTimeline::setProperties(OSDictionary *d)
{
OSNumber *n = NULL;
OSBoolean *b = NULL;
bool changed = false;
n = (OSNumber *)d->getObject(kIOPMTimelineSystemNumberTrackedKey);
if (OSDynamicCast(OSNumber, n))
{
changed = true;
this->setEventsTrackedCount(n->unsigned32BitValue());
}
b = (OSBoolean *)d->getObject(kIOPMTimelineEnabledKey);
if (b)
{
changed = true;
this->setEventsRecordingLevel((int)(kOSBooleanTrue == b));
}
return changed;
}
OSDictionary *IOPMTimeline::copyInfoDictionary(void)
{
OSDictionary *out = OSDictionary::withCapacity(3);
OSNumber *n = NULL;
if (!out || !hdr)
return NULL;
n = OSNumber::withNumber(hdr->sizeEntries, 32);
out->setObject(kIOPMTimelineSystemNumberTrackedKey, n);
n->release();
n = OSNumber::withNumber(hdr->sizeBytes, 32);
out->setObject(kIOPMTimelineSystemBufferSizeKey, n);
n->release();
out->setObject(kIOPMTimelineEnabledKey, eventsRecordingLevel ? kOSBooleanTrue : kOSBooleanFalse);
return out;
}
IOReturn IOPMTimeline::recordSystemPowerEvent( PMEventDetails *details )
{
static bool wakeDonePending = true;
IOPMSystemEventRecord *record_to = NULL;
OSString *swUUIDKey = NULL;
uint32_t useIndex = 0;
if (!details)
return kIOReturnBadArgument;
if (!traceBuffer)
return kIOReturnNotReady;
if (details->eventType == kIOPMEventTypeWakeDone)
{
if(!wakeDonePending)
return kIOReturnBadArgument;
}
IOLockLock(logLock);
if (details->eventType == kIOPMEventTypeWake) {
wakeDonePending = true;
} else if (details->eventType == kIOPMEventTypeWakeDone) {
wakeDonePending = false;
}
systemState = details->eventType;
useIndex = _atomicIndexIncrement(&hdr->index, hdr->sizeEntries);
if (useIndex + 1 >= hdr->sizeEntries) {
traceBuffer[useIndex + 1].eventType = 0;
} else {
traceBuffer[0].eventType = 0;
}
record_to = &traceBuffer[useIndex];
bzero(record_to, sizeof(IOPMSystemEventRecord));
record_to->eventType = details->eventType;
record_to->eventReason = details->reason;
record_to->eventResult = details->result;
pmEventTimeStamp(&record_to->timestamp);
if (!details->uuid) {
swUUIDKey = OSDynamicCast(OSString, owner->copyProperty(kIOPMSleepWakeUUIDKey));
if (swUUIDKey)
details->uuid = swUUIDKey->getCStringNoCopy();
}
if (details->uuid)
strncpy(record_to->uuid, details->uuid, kMaxPMStringLength);
if (swUUIDKey)
swUUIDKey->release();
numEventsLoggedThisPeriod++;
IOLockUnlock(logLock);
return kIOReturnSuccess;
}
IOReturn IOPMTimeline::recordDetailedPowerEvent( PMEventDetails *details )
{
IOPMSystemEventRecord *record_to = NULL;
uint32_t useIndex;
if (!details->eventType || !details->ownerName)
return kIOReturnBadArgument;
IOLockLock(logLock);
useIndex = _atomicIndexIncrement(&hdr->index, hdr->sizeEntries);
record_to = (IOPMSystemEventRecord *)&traceBuffer[useIndex];
bzero(record_to, sizeof(IOPMSystemEventRecord));
record_to->eventType = details->eventType;
if (details->ownerName && (strlen(details->ownerName) > 1)) {
strlcpy( record_to->ownerName,
details->ownerName,
sizeof(record_to->ownerName));
}
record_to->ownerDisambiguateID = details->ownerUnique;
if (details->interestName && (strlen(details->interestName) > 1)) {
strlcpy(record_to->interestName,
details->interestName,
sizeof(record_to->interestName));
}
record_to->oldState = details->oldState;
record_to->newState = details->newState;
record_to->eventResult = details->result;
record_to->elapsedTimeUS = details->elapsedTimeUS;
pmEventTimeStamp(&record_to->timestamp);
numEventsLoggedThisPeriod++;
IOLockUnlock(logLock);
return kIOReturnSuccess;
}
uint32_t IOPMTimeline::getNumEventsLoggedThisPeriod() {
return this->numEventsLoggedThisPeriod;
}
void IOPMTimeline::setNumEventsLoggedThisPeriod(uint32_t newCount) {
this->numEventsLoggedThisPeriod = newCount;
}
bool IOPMTimeline::isSleepCycleInProgress() {
return this->sleepCycleInProgress;
}
void IOPMTimeline::setSleepCycleInProgressFlag(bool flag) {
this->sleepCycleInProgress = flag;
}
void IOPMTimeline::setEventsTrackedCount(uint32_t newTracked)
{
size_t make_buf_size = 0;
make_buf_size = sizeof(IOPMTraceBufferHeader) + (newTracked * sizeof(IOPMSystemEventRecord));
IOLockLock(logLock);
if (pmTraceMemoryDescriptor) {
pmTraceMemoryDescriptor->release();
pmTraceMemoryDescriptor = NULL;
}
hdr = NULL;
traceBuffer = NULL;
if (0 == newTracked)
{
IOLog("IOPMrootDomain -> erased buffer.\n");
goto exit;
}
pmTraceMemoryDescriptor = IOBufferMemoryDescriptor::withOptions(
kIOMemoryKernelUserShared | kIODirectionIn, make_buf_size);
if (!pmTraceMemoryDescriptor)
{
IOLog("IOPMRootDomain -> IOBufferMemoryDescriptor(%d) returns NULL\n", (int)make_buf_size);
goto exit;
}
pmTraceMemoryDescriptor->prepare(kIODirectionIn);
hdr = (IOPMTraceBufferHeader *)pmTraceMemoryDescriptor->getBytesNoCopy();
traceBuffer = (IOPMSystemEventRecord *)((uint8_t *)hdr + sizeof(IOPMTraceBufferHeader));
bzero(hdr, make_buf_size);
hdr->sizeBytes = make_buf_size;
hdr->sizeEntries = newTracked;
IOLog("IOPMRootDomain -> IOBufferMemoryDescriptor(%d) returns bufferMB with address 0x%08x\n", (int)make_buf_size, (unsigned int)(uintptr_t)traceBuffer);
exit:
IOLockUnlock(logLock);
}
void IOPMTimeline::setEventsRecordingLevel(uint32_t eventsTrackedBits)
{
return;
}
uint32_t IOPMTimeline::_atomicIndexIncrement(uint32_t *index, uint32_t limit)
{
uint32_t was_index;
uint32_t inc_index;
if(!index)
return NULL;
do {
was_index = *index;
inc_index = (was_index+1)%limit;
} while (!OSCompareAndSwap(was_index, inc_index, index));
return inc_index;
}
#define kAssertUniqueIDStart 500
PMAssertionsTracker *PMAssertionsTracker::pmAssertionsTracker( IOPMrootDomain *rootDomain )
{
PMAssertionsTracker *myself;
myself = new PMAssertionsTracker;
if (myself) {
myself->init();
myself->owner = rootDomain;
myself->issuingUniqueID = kAssertUniqueIDStart;
myself->assertionsArray = OSArray::withCapacity(5);
myself->assertionsKernel = 0;
myself->assertionsUser = 0;
myself->assertionsCombined = 0;
myself->assertionsArrayLock = IOLockAlloc();
myself->tabulateProducerCount = myself->tabulateConsumerCount = 0;
if (!myself->assertionsArray || !myself->assertionsArrayLock)
myself = NULL;
}
return myself;
}
void PMAssertionsTracker::tabulate(void)
{
int i;
int count;
PMAssertStruct *_a = NULL;
OSData *_d = NULL;
IOPMDriverAssertionType oldKernel = assertionsKernel;
IOPMDriverAssertionType oldCombined = assertionsCombined;
ASSERT_GATED();
assertionsKernel = 0;
assertionsCombined = 0;
if (!assertionsArray)
return;
if ((count = assertionsArray->getCount()))
{
for (i=0; i<count; i++)
{
_d = OSDynamicCast(OSData, assertionsArray->getObject(i));
if (_d)
{
_a = (PMAssertStruct *)_d->getBytesNoCopy();
if (_a && (kIOPMDriverAssertionLevelOn == _a->level))
assertionsKernel |= _a->assertionBits;
}
}
}
tabulateProducerCount++;
assertionsCombined = assertionsKernel | assertionsUser;
if ((assertionsKernel != oldKernel) ||
(assertionsCombined != oldCombined))
{
owner->messageClients(kIOPMMessageDriverAssertionsChanged);
if (((assertionsCombined & kIOPMDriverAssertionPreventDisplaySleepBit) != 0)
&& ((oldCombined & kIOPMDriverAssertionPreventDisplaySleepBit) == 0))
{
owner->evaluatePolicy(kStimulusDarkWakeActivityTickle);
} else {
owner->evaluatePolicy(kStimulusDarkWakeEvaluate);
}
}
}
void PMAssertionsTracker::publishProperties( void )
{
OSArray *assertionsSummary = NULL;
if (tabulateConsumerCount != tabulateProducerCount)
{
IOLockLock(assertionsArrayLock);
tabulateConsumerCount = tabulateProducerCount;
assertionsSummary = copyAssertionsArray();
if (assertionsSummary)
{
owner->setProperty(kIOPMAssertionsDriverDetailedKey, assertionsSummary);
assertionsSummary->release();
}
else
{
owner->removeProperty(kIOPMAssertionsDriverDetailedKey);
}
owner->setProperty(kIOPMAssertionsDriverKey, assertionsKernel, 64);
IOLockUnlock(assertionsArrayLock);
}
}
PMAssertionsTracker::PMAssertStruct *PMAssertionsTracker::detailsForID(IOPMDriverAssertionID _id, int *index)
{
PMAssertStruct *_a = NULL;
OSData *_d = NULL;
int found = -1;
int count = 0;
int i = 0;
if (assertionsArray
&& (count = assertionsArray->getCount()))
{
for (i=0; i<count; i++)
{
_d = OSDynamicCast(OSData, assertionsArray->getObject(i));
if (_d)
{
_a = (PMAssertStruct *)_d->getBytesNoCopy();
if (_a && (_id == _a->id)) {
found = i;
break;
}
}
}
}
if (-1 == found) {
return NULL;
} else {
if (index)
*index = found;
return _a;
}
}
IOReturn PMAssertionsTracker::handleCreateAssertion(OSData *newAssertion)
{
ASSERT_GATED();
if (newAssertion)
{
IOLockLock(assertionsArrayLock);
assertionsArray->setObject(newAssertion);
IOLockUnlock(assertionsArrayLock);
newAssertion->release();
tabulate();
}
return kIOReturnSuccess;
}
IOReturn PMAssertionsTracker::createAssertion(
IOPMDriverAssertionType which,
IOPMDriverAssertionLevel level,
IOService *serviceID,
const char *whoItIs,
IOPMDriverAssertionID *outID)
{
OSData *dataStore = NULL;
PMAssertStruct track;
track.id = OSIncrementAtomic64((SInt64*) &issuingUniqueID);
track.level = level;
track.assertionBits = which;
track.ownerString = whoItIs ? OSSymbol::withCString(whoItIs) : 0;
track.ownerService = serviceID;
track.modifiedTime = 0;
pmEventTimeStamp(&track.createdTime);
dataStore = OSData::withBytes(&track, sizeof(PMAssertStruct));
if (!dataStore)
{
if (track.ownerString)
track.ownerString->release();
return kIOReturnNoMemory;
}
*outID = track.id;
if (owner && owner->pmPowerStateQueue) {
owner->pmPowerStateQueue->submitPowerEvent(kPowerEventAssertionCreate, (void *)dataStore);
}
return kIOReturnSuccess;
}
IOReturn PMAssertionsTracker::handleReleaseAssertion(
IOPMDriverAssertionID _id)
{
ASSERT_GATED();
int index;
PMAssertStruct *assertStruct = detailsForID(_id, &index);
if (!assertStruct)
return kIOReturnNotFound;
IOLockLock(assertionsArrayLock);
if (assertStruct->ownerString)
assertStruct->ownerString->release();
assertionsArray->removeObject(index);
IOLockUnlock(assertionsArrayLock);
tabulate();
return kIOReturnSuccess;
}
IOReturn PMAssertionsTracker::releaseAssertion(
IOPMDriverAssertionID _id)
{
if (owner && owner->pmPowerStateQueue) {
owner->pmPowerStateQueue->submitPowerEvent(kPowerEventAssertionRelease, 0, _id);
}
return kIOReturnSuccess;
}
IOReturn PMAssertionsTracker::handleSetAssertionLevel(
IOPMDriverAssertionID _id,
IOPMDriverAssertionLevel _level)
{
PMAssertStruct *assertStruct = detailsForID(_id, NULL);
ASSERT_GATED();
if (!assertStruct) {
return kIOReturnNotFound;
}
IOLockLock(assertionsArrayLock);
pmEventTimeStamp(&assertStruct->modifiedTime);
assertStruct->level = _level;
IOLockUnlock(assertionsArrayLock);
tabulate();
return kIOReturnSuccess;
}
IOReturn PMAssertionsTracker::setAssertionLevel(
IOPMDriverAssertionID _id,
IOPMDriverAssertionLevel _level)
{
if (owner && owner->pmPowerStateQueue) {
owner->pmPowerStateQueue->submitPowerEvent(kPowerEventAssertionSetLevel,
(void *)_level, _id);
}
return kIOReturnSuccess;
}
IOReturn PMAssertionsTracker::handleSetUserAssertionLevels(void * arg0)
{
IOPMDriverAssertionType new_user_levels = *(IOPMDriverAssertionType *) arg0;
ASSERT_GATED();
if (new_user_levels != assertionsUser)
{
assertionsUser = new_user_levels;
DLOG("assertionsUser 0x%llx\n", assertionsUser);
}
tabulate();
return kIOReturnSuccess;
}
IOReturn PMAssertionsTracker::setUserAssertionLevels(
IOPMDriverAssertionType new_user_levels)
{
if (gIOPMWorkLoop) {
gIOPMWorkLoop->runAction(
OSMemberFunctionCast(
IOWorkLoop::Action,
this,
&PMAssertionsTracker::handleSetUserAssertionLevels),
this,
(void *) &new_user_levels, 0, 0, 0);
}
return kIOReturnSuccess;
}
OSArray *PMAssertionsTracker::copyAssertionsArray(void)
{
int count;
int i;
OSArray *outArray = NULL;
if (!assertionsArray ||
(0 == (count = assertionsArray->getCount())) ||
(NULL == (outArray = OSArray::withCapacity(count))))
{
goto exit;
}
for (i=0; i<count; i++)
{
PMAssertStruct *_a = NULL;
OSData *_d = NULL;
OSDictionary *details = NULL;
_d = OSDynamicCast(OSData, assertionsArray->getObject(i));
if (_d && (_a = (PMAssertStruct *)_d->getBytesNoCopy()))
{
OSNumber *_n = NULL;
details = OSDictionary::withCapacity(7);
if (!details)
continue;
outArray->setObject(details);
details->release();
_n = OSNumber::withNumber(_a->id, 64);
if (_n) {
details->setObject(kIOPMDriverAssertionIDKey, _n);
_n->release();
}
_n = OSNumber::withNumber(_a->createdTime, 64);
if (_n) {
details->setObject(kIOPMDriverAssertionCreatedTimeKey, _n);
_n->release();
}
_n = OSNumber::withNumber(_a->modifiedTime, 64);
if (_n) {
details->setObject(kIOPMDriverAssertionModifiedTimeKey, _n);
_n->release();
}
_n = OSNumber::withNumber((uintptr_t)_a->ownerService, 64);
if (_n) {
details->setObject(kIOPMDriverAssertionOwnerServiceKey, _n);
_n->release();
}
_n = OSNumber::withNumber(_a->level, 64);
if (_n) {
details->setObject(kIOPMDriverAssertionLevelKey, _n);
_n->release();
}
_n = OSNumber::withNumber(_a->assertionBits, 64);
if (_n) {
details->setObject(kIOPMDriverAssertionAssertedKey, _n);
_n->release();
}
if (_a->ownerString) {
details->setObject(kIOPMDriverAssertionOwnerStringKey, _a->ownerString);
}
}
}
exit:
return outArray;
}
IOPMDriverAssertionType PMAssertionsTracker::getActivatedAssertions(void)
{
return assertionsCombined;
}
IOPMDriverAssertionLevel PMAssertionsTracker::getAssertionLevel(
IOPMDriverAssertionType type)
{
if (type && ((type & assertionsKernel) == assertionsKernel))
{
return kIOPMDriverAssertionLevelOn;
} else {
return kIOPMDriverAssertionLevelOff;
}
}
static void pmEventTimeStamp(uint64_t *recordTS)
{
clock_sec_t tsec;
clock_usec_t tusec;
if (!recordTS)
return;
clock_get_calendar_microtime(&tsec, &tusec);
*recordTS = 0;
*recordTS |= (uint32_t)tusec;
*recordTS |= ((uint64_t)tsec << 32);
return;
}
OSDefineMetaClassAndFinalStructors(IORootParent, IOService)
static IOPMPowerState patriarchPowerStates[2] =
{
{1,0,ON_POWER,0,0,0,0,0,0,0,0,0},
{1,0,ON_POWER,0,0,0,0,0,0,0,0,0},
};
void IORootParent::initialize( void )
{
}
bool IORootParent::start( IOService * nub )
{
IOService::start(nub);
attachToParent( getRegistryRoot(), gIOPowerPlane );
PMinit();
registerPowerDriver(this, patriarchPowerStates, 2);
makeUsable();
return true;
}
void IORootParent::shutDownSystem( void )
{
}
void IORootParent::restartSystem( void )
{
}
void IORootParent::sleepSystem( void )
{
}
void IORootParent::dozeSystem( void )
{
}
void IORootParent::sleepToDoze( void )
{
}
void IORootParent::wakeSystem( void )
{
}
OSObject * IORootParent::copyProperty( const char * aKey) const
{
return (IOService::copyProperty(aKey));
}