#include <IOKit/assert.h>
#include <IOKit/IOKitDebug.h>
#include <IOKit/IOLib.h>
#include <IOKit/IOMessage.h>
#include <IOKit/IOPlatformExpert.h>
#include <IOKit/IOService.h>
#include <IOKit/IOEventSource.h>
#include <IOKit/IOWorkLoop.h>
#include <IOKit/IOCommand.h>
#include <IOKit/IOTimeStamp.h>
#include <IOKit/IOReportMacros.h>
#include <IOKit/IODeviceTreeSupport.h>
#include <IOKit/pwr_mgt/IOPMlog.h>
#include <IOKit/pwr_mgt/IOPMinformee.h>
#include <IOKit/pwr_mgt/IOPMinformeeList.h>
#include <IOKit/pwr_mgt/IOPowerConnection.h>
#include <IOKit/pwr_mgt/RootDomain.h>
#include <IOKit/pwr_mgt/IOPMPrivate.h>
#include <sys/proc.h>
#include <sys/proc_internal.h>
#include <sys/sysctl.h>
#include <libkern/OSDebug.h>
#include <kern/thread.h>
#include "IOServicePrivate.h"
#include "IOServicePMPrivate.h"
#include "IOKitKernelInternal.h"
static void settle_timer_expired(thread_call_param_t, thread_call_param_t);
static void idle_timer_expired(thread_call_param_t, thread_call_param_t);
static void tellKernelClientApplier(OSObject * object, void * arg);
static void tellAppClientApplier(OSObject * object, void * arg);
static uint64_t
computeTimeDeltaNS( const AbsoluteTime * start )
{
AbsoluteTime now;
uint64_t nsec;
clock_get_uptime(&now);
SUB_ABSOLUTETIME(&now, start);
absolutetime_to_nanoseconds(now, &nsec);
return nsec;
}
#if PM_VARS_SUPPORT
OSDefineMetaClassAndStructors(IOPMprot, OSObject)
#endif
static bool gIOPMInitialized = false;
static uint32_t gIOPMBusyRequestCount = 0;
static uint32_t gIOPMWorkInvokeCount = 0;
static uint32_t gIOPMTickleGeneration = 0;
static IOWorkLoop * gIOPMWorkLoop = NULL;
static IOPMRequestQueue * gIOPMRequestQueue = NULL;
static IOPMRequestQueue * gIOPMReplyQueue = NULL;
static IOPMWorkQueue * gIOPMWorkQueue = NULL;
static IOPMCompletionQueue * gIOPMCompletionQueue = NULL;
static IOPMRequest * gIOPMRequest = NULL;
static IOService * gIOPMRootNode = NULL;
static IOPlatformExpert * gPlatform = NULL;
const OSSymbol * gIOPMPowerClientDevice = NULL;
const OSSymbol * gIOPMPowerClientDriver = NULL;
const OSSymbol * gIOPMPowerClientChildProxy = NULL;
const OSSymbol * gIOPMPowerClientChildren = NULL;
const OSSymbol * gIOPMPowerClientRootDomain = NULL;
static const OSSymbol * gIOPMPowerClientAdvisoryTickle = NULL;
static bool gIOPMAdvisoryTickleEnabled = true;
static thread_t gIOPMWatchDogThread = NULL;
uint32_t gCanSleepTimeout = 0;
static uint32_t
getPMRequestType( void )
{
uint32_t type = kIOPMRequestTypeInvalid;
if (gIOPMRequest) {
type = gIOPMRequest->getType();
}
return type;
}
static IOPMRequestTag
getPMRequestTag( void )
{
IOPMRequestTag tag = 0;
if (gIOPMRequest &&
(gIOPMRequest->getType() == kIOPMRequestTypeRequestPowerStateOverride)) {
tag = gIOPMRequest->fRequestTag;
}
return tag;
}
SYSCTL_UINT(_kern, OID_AUTO, pmtimeout, CTLFLAG_RW | CTLFLAG_LOCKED, &gCanSleepTimeout, 0, "Power Management Timeout");
#define PM_ERROR(x...) do { kprintf(x);IOLog(x); \
} while (false)
#define PM_LOG(x...) do { kprintf(x); } while (false)
#define PM_LOG1(x...) do { \
if (kIOLogDebugPower & gIOKitDebug) \
kprintf(x); } while (false)
#define PM_LOG2(x...) do { \
if (kIOLogDebugPower & gIOKitDebug) \
kprintf(x); } while (false)
#if 0
#define PM_LOG3(x...) do { kprintf(x); } while (false)
#else
#define PM_LOG3(x...)
#endif
#define RD_LOG(x...) do { \
if ((kIOLogPMRootDomain & gIOKitDebug) && \
(getPMRootDomain() == this)) { \
kprintf("PMRD: " x); \
}} while (false)
#define PM_ASSERT_IN_GATE(x) \
do { \
assert(gIOPMWorkLoop->inGate()); \
} while(false)
#define PM_LOCK() IOLockLock(fPMLock)
#define PM_UNLOCK() IOLockUnlock(fPMLock)
#define PM_LOCK_SLEEP(event, dl) IOLockSleepDeadline(fPMLock, event, dl, THREAD_UNINT)
#define PM_LOCK_WAKEUP(event) IOLockWakeup(fPMLock, event, false)
#define us_per_s 1000000
#define ns_per_us 1000
#define k30Seconds (30*us_per_s)
#define k5Seconds ( 5*us_per_s)
#if CONFIG_EMBEDDED
#define kCanSleepMaxTimeReq k5Seconds
#else
#define kCanSleepMaxTimeReq k30Seconds
#endif
#define kMaxTimeRequested k30Seconds
#define kMinAckTimeoutTicks (10*1000000)
#define kIOPMTardyAckSPSKey "IOPMTardyAckSetPowerState"
#define kIOPMTardyAckPSCKey "IOPMTardyAckPowerStateChange"
#define kPwrMgtKey "IOPowerManagement"
#define OUR_PMLog(t, a, b) do { \
if (pwrMgt) { \
if (gIOKitDebug & kIOLogPower) \
pwrMgt->pmPrint(t, a, b); \
if (gIOKitTrace & kIOTracePowerMgmt) \
pwrMgt->pmTrace(t, DBG_FUNC_NONE, a, b); \
} \
} while(0)
#define OUR_PMLogFuncStart(t, a, b) do { \
if (pwrMgt) { \
if (gIOKitDebug & kIOLogPower) \
pwrMgt->pmPrint(t, a, b); \
if (gIOKitTrace & kIOTracePowerMgmt) \
pwrMgt->pmTrace(t, DBG_FUNC_START, a, b); \
} \
} while(0)
#define OUR_PMLogFuncEnd(t, a, b) do { \
if (pwrMgt) { \
if (gIOKitDebug & kIOLogPower) \
pwrMgt->pmPrint(-t, a, b); \
if (gIOKitTrace & kIOTracePowerMgmt) \
pwrMgt->pmTrace(t, DBG_FUNC_END, a, b); \
} \
} while(0)
#define NS_TO_MS(nsec) ((int)((nsec) / 1000000ULL))
#define NS_TO_US(nsec) ((int)((nsec) / 1000ULL))
#define SUPPORT_IDLE_CANCEL 1
#define kIOPMPowerStateMax 0xFFFFFFFF
#define kInvalidTicklePowerState kIOPMPowerStateMax
#define kNoTickleCancelWindow (60ULL * 1000ULL * 1000ULL * 1000ULL)
#define IS_PM_ROOT (this == gIOPMRootNode)
#define IS_ROOT_DOMAIN (getPMRootDomain() == this)
#define IS_POWER_DROP (StateOrder(fHeadNotePowerState) < StateOrder(fCurrentPowerState))
#define IS_POWER_RISE (StateOrder(fHeadNotePowerState) > StateOrder(fCurrentPowerState))
#if defined(__i386__) || defined(__x86_64__)
#define LOG_SETPOWER_TIMES (300ULL * 1000ULL * 1000ULL)
#else
#define LOG_SETPOWER_TIMES (50ULL * 1000ULL * 1000ULL)
#endif
#define LOG_APP_RESPONSE_TIMES (100ULL * 1000ULL * 1000ULL)
#define LOG_APP_RESPONSE_MSG_TRACER (3 * 1000ULL * 1000ULL * 1000ULL)
#define LOG_KEXT_RESPONSE_TIMES (100ULL * 1000ULL * 1000ULL)
enum {
kReserveDomainPower = 1
};
#define MS_PUSH(n) \
do { assert(kIOPM_BadMachineState == fSavedMachineState); \
assert(kIOPM_BadMachineState != n); \
fSavedMachineState = n; } while (false)
#define MS_POP() \
do { assert(kIOPM_BadMachineState != fSavedMachineState); \
fMachineState = fSavedMachineState; \
fSavedMachineState = kIOPM_BadMachineState; } while (false)
#define PM_ACTION_0(a) \
do { if (fPMActions.a) { \
(fPMActions.a)(fPMActions.target, this, &fPMActions); } \
} while (false)
#define PM_ACTION_2(a, x, y) \
do { if (fPMActions.a) { \
(fPMActions.a)(fPMActions.target, this, &fPMActions, x, y, \
getPMRequestTag()); } \
} while (false)
#define PM_ACTION_3(a, x, y, z) \
do { if (fPMActions.a) { \
(fPMActions.a)(fPMActions.target, this, &fPMActions, x, y, z); } \
} while (false)
static OSNumber * copyClientIDForNotification(
OSObject *object,
IOPMInterestContext *context);
static void logClientIDForNotification(
OSObject *object,
IOPMInterestContext *context,
const char *logString);
enum {
kIOPM_Finished = 0,
kIOPM_OurChangeTellClientsPowerDown = 1,
kIOPM_OurChangeTellUserPMPolicyPowerDown = 2,
kIOPM_OurChangeTellPriorityClientsPowerDown = 3,
kIOPM_OurChangeNotifyInterestedDriversWillChange = 4,
kIOPM_OurChangeSetPowerState = 5,
kIOPM_OurChangeWaitForPowerSettle = 6,
kIOPM_OurChangeNotifyInterestedDriversDidChange = 7,
kIOPM_OurChangeTellCapabilityDidChange = 8,
kIOPM_OurChangeFinish = 9,
kIOPM_ParentChangeTellPriorityClientsPowerDown = 10,
kIOPM_ParentChangeNotifyInterestedDriversWillChange = 11,
kIOPM_ParentChangeSetPowerState = 12,
kIOPM_ParentChangeWaitForPowerSettle = 13,
kIOPM_ParentChangeNotifyInterestedDriversDidChange = 14,
kIOPM_ParentChangeTellCapabilityDidChange = 15,
kIOPM_ParentChangeAcknowledgePowerChange = 16,
kIOPM_NotifyChildrenStart = 17,
kIOPM_NotifyChildrenOrdered = 18,
kIOPM_NotifyChildrenDelayed = 19,
kIOPM_SyncTellClientsPowerDown = 20,
kIOPM_SyncTellPriorityClientsPowerDown = 21,
kIOPM_SyncNotifyWillChange = 22,
kIOPM_SyncNotifyDidChange = 23,
kIOPM_SyncTellCapabilityDidChange = 24,
kIOPM_SyncFinish = 25,
kIOPM_TellCapabilityChangeDone = 26,
kIOPM_DriverThreadCallDone = 27,
kIOPM_BadMachineState = 0xFFFFFFFF
};
void
IOService::PMinit( void )
{
if (!initialized) {
if (!gIOPMInitialized) {
gPlatform = getPlatform();
gIOPMWorkLoop = IOWorkLoop::workLoop();
if (gIOPMWorkLoop) {
gIOPMRequestQueue = IOPMRequestQueue::create(
this, OSMemberFunctionCast(IOPMRequestQueue::Action,
this, &IOService::actionPMRequestQueue));
gIOPMReplyQueue = IOPMRequestQueue::create(
this, OSMemberFunctionCast(IOPMRequestQueue::Action,
this, &IOService::actionPMReplyQueue));
gIOPMWorkQueue = IOPMWorkQueue::create(this,
OSMemberFunctionCast(IOPMWorkQueue::Action, this,
&IOService::actionPMWorkQueueInvoke),
OSMemberFunctionCast(IOPMWorkQueue::Action, this,
&IOService::actionPMWorkQueueRetire));
gIOPMCompletionQueue = IOPMCompletionQueue::create(
this, OSMemberFunctionCast(IOPMCompletionQueue::Action,
this, &IOService::actionPMCompletionQueue));
if (gIOPMWorkLoop->addEventSource(gIOPMRequestQueue) !=
kIOReturnSuccess) {
gIOPMRequestQueue->release();
gIOPMRequestQueue = NULL;
}
if (gIOPMWorkLoop->addEventSource(gIOPMReplyQueue) !=
kIOReturnSuccess) {
gIOPMReplyQueue->release();
gIOPMReplyQueue = NULL;
}
if (gIOPMWorkLoop->addEventSource(gIOPMWorkQueue) !=
kIOReturnSuccess) {
gIOPMWorkQueue->release();
gIOPMWorkQueue = NULL;
}
if (gIOPMWorkLoop->addEventSource(gIOPMCompletionQueue) !=
kIOReturnSuccess) {
gIOPMCompletionQueue->release();
gIOPMCompletionQueue = NULL;
}
gIOPMPowerClientDevice =
OSSymbol::withCStringNoCopy( "DevicePowerState" );
gIOPMPowerClientDriver =
OSSymbol::withCStringNoCopy( "DriverPowerState" );
gIOPMPowerClientChildProxy =
OSSymbol::withCStringNoCopy( "ChildProxyPowerState" );
gIOPMPowerClientChildren =
OSSymbol::withCStringNoCopy( "ChildrenPowerState" );
gIOPMPowerClientAdvisoryTickle =
OSSymbol::withCStringNoCopy( "AdvisoryTicklePowerState" );
gIOPMPowerClientRootDomain =
OSSymbol::withCStringNoCopy( "RootDomainPower" );
}
if (gIOPMRequestQueue && gIOPMReplyQueue && gIOPMCompletionQueue) {
gIOPMInitialized = true;
}
}
if (!gIOPMInitialized) {
return;
}
pwrMgt = new IOServicePM;
pwrMgt->init();
setProperty(kPwrMgtKey, pwrMgt);
queue_init(&pwrMgt->WorkChain);
queue_init(&pwrMgt->RequestHead);
queue_init(&pwrMgt->PMDriverCallQueue);
fOwner = this;
fPMLock = IOLockAlloc();
fInterestedDrivers = new IOPMinformeeList;
fInterestedDrivers->initialize();
fDesiredPowerState = kPowerStateZero;
fDeviceDesire = kPowerStateZero;
fInitialPowerChange = true;
fInitialSetPowerState = true;
fPreviousRequestPowerFlags = 0;
fDeviceOverrideEnabled = false;
fMachineState = kIOPM_Finished;
fSavedMachineState = kIOPM_BadMachineState;
fIdleTimerMinPowerState = kPowerStateZero;
fActivityLock = IOLockAlloc();
fStrictTreeOrder = false;
fActivityTicklePowerState = kInvalidTicklePowerState;
fAdvisoryTicklePowerState = kInvalidTicklePowerState;
fControllingDriver = NULL;
fPowerStates = NULL;
fNumberOfPowerStates = 0;
fCurrentPowerState = kPowerStateZero;
fParentsCurrentPowerFlags = 0;
fMaxPowerState = kPowerStateZero;
fName = getName();
fParentsKnowState = false;
fSerialNumber = 0;
fResponseArray = NULL;
fNotifyClientArray = NULL;
fCurrentPowerConsumption = kIOPMUnknown;
fOverrideMaxPowerState = kIOPMPowerStateMax;
if (!gIOPMRootNode && (getParentEntry(gIOPowerPlane) == getRegistryRoot())) {
gIOPMRootNode = this;
fParentsKnowState = true;
} else if (getProperty(kIOPMResetPowerStateOnWakeKey) == kOSBooleanTrue) {
fResetPowerStateOnWake = true;
}
if (IS_ROOT_DOMAIN) {
fWatchdogTimer = thread_call_allocate(
&IOService::watchdog_timer_expired, (thread_call_param_t)this);
fWatchdogLock = IOLockAlloc();
fBlockedArray = OSArray::withCapacity(4);
}
fAckTimer = thread_call_allocate(
&IOService::ack_timer_expired, (thread_call_param_t)this);
fSettleTimer = thread_call_allocate(
&settle_timer_expired, (thread_call_param_t)this);
fIdleTimer = thread_call_allocate(
&idle_timer_expired, (thread_call_param_t)this);
fDriverCallEntry = thread_call_allocate(
(thread_call_func_t) &IOService::pmDriverCallout, this);
assert(fDriverCallEntry);
if (OSMemberFunctionCast(void (*)(void),
getResourceService(), &IOService::powerChangeDone) !=
OSMemberFunctionCast(void (*)(void),
this, &IOService::powerChangeDone)) {
fPCDFunctionOverride = true;
}
#if PM_VARS_SUPPORT
IOPMprot * prot = new IOPMprot;
if (prot) {
prot->init();
prot->ourName = fName;
prot->thePlatform = gPlatform;
fPMVars = prot;
pm_vars = prot;
}
#else
pm_vars = (void *) (uintptr_t) true;
#endif
initialized = true;
}
}
void
IOService::PMfree( void )
{
initialized = false;
pm_vars = NULL;
if (pwrMgt) {
assert(fMachineState == kIOPM_Finished);
assert(fInsertInterestSet == NULL);
assert(fRemoveInterestSet == NULL);
assert(fNotifyChildArray == NULL);
assert(queue_empty(&pwrMgt->RequestHead));
assert(queue_empty(&fPMDriverCallQueue));
if (fWatchdogTimer) {
thread_call_cancel(fWatchdogTimer);
thread_call_free(fWatchdogTimer);
fWatchdogTimer = NULL;
}
if (fWatchdogLock) {
IOLockFree(fWatchdogLock);
fWatchdogLock = NULL;
}
if (fBlockedArray) {
fBlockedArray->release();
fBlockedArray = NULL;
}
if (fSettleTimer) {
thread_call_cancel(fSettleTimer);
thread_call_free(fSettleTimer);
fSettleTimer = NULL;
}
if (fAckTimer) {
thread_call_cancel(fAckTimer);
thread_call_free(fAckTimer);
fAckTimer = NULL;
}
if (fIdleTimer) {
thread_call_cancel(fIdleTimer);
thread_call_free(fIdleTimer);
fIdleTimer = NULL;
}
if (fDriverCallEntry) {
thread_call_free(fDriverCallEntry);
fDriverCallEntry = NULL;
}
if (fPMLock) {
IOLockFree(fPMLock);
fPMLock = NULL;
}
if (fActivityLock) {
IOLockFree(fActivityLock);
fActivityLock = NULL;
}
if (fInterestedDrivers) {
fInterestedDrivers->release();
fInterestedDrivers = NULL;
}
if (fDriverCallParamSlots && fDriverCallParamPtr) {
IODelete(fDriverCallParamPtr, DriverCallParam, fDriverCallParamSlots);
fDriverCallParamPtr = NULL;
fDriverCallParamSlots = 0;
}
if (fResponseArray) {
fResponseArray->release();
fResponseArray = NULL;
}
if (fNotifyClientArray) {
fNotifyClientArray->release();
fNotifyClientArray = NULL;
}
if (fPowerStates && fNumberOfPowerStates) {
IODelete(fPowerStates, IOPMPSEntry, fNumberOfPowerStates);
fNumberOfPowerStates = 0;
fPowerStates = NULL;
}
if (fPowerClients) {
fPowerClients->release();
fPowerClients = NULL;
}
#if PM_VARS_SUPPORT
if (fPMVars) {
fPMVars->release();
fPMVars = NULL;
}
#endif
pwrMgt->release();
pwrMgt = NULL;
}
}
void
IOService::PMDebug( uint32_t event, uintptr_t param1, uintptr_t param2 )
{
OUR_PMLog(event, param1, param2);
}
void
IOService::joinPMtree( IOService * driver )
{
IOPlatformExpert * platform;
platform = getPlatform();
assert(platform != NULL);
platform->PMRegisterDevice(this, driver);
}
#ifndef __LP64__
IOReturn
IOService::youAreRoot( void )
{
return IOPMNoErr;
}
#endif
void
IOService::PMstop( void )
{
IOPMRequest * request;
if (!initialized) {
return;
}
PM_LOCK();
if (fLockedFlags.PMStop) {
PM_LOG2("%s: PMstop() already stopped\n", fName);
PM_UNLOCK();
return;
}
fLockedFlags.PMStop = true;
waitForPMDriverCall();
PM_UNLOCK();
request = acquirePMRequest( this, kIOPMRequestTypePMStop );
if (request) {
PM_LOG2("%s: %p PMstop\n", getName(), OBFUSCATE(this));
submitPMRequest( request );
}
}
void
IOService::handlePMstop( IOPMRequest * request )
{
OSIterator * iter;
OSObject * next;
IOPowerConnection * connection;
IOService * theChild;
IOService * theParent;
PM_ASSERT_IN_GATE();
PM_LOG2("%s: %p %s start\n", getName(), OBFUSCATE(this), __FUNCTION__);
getPMRootDomain()->updatePreventIdleSleepList(this, false);
getPMRootDomain()->updatePreventSystemSleepList(this, false);
removeProperty(kPwrMgtKey);
iter = getParentIterator(gIOPowerPlane);
if (iter) {
while ((next = iter->getNextObject())) {
if ((connection = OSDynamicCast(IOPowerConnection, next))) {
theParent = (IOService *)connection->copyParentEntry(gIOPowerPlane);
if (theParent) {
theParent->removePowerChild(connection);
theParent->release();
}
}
}
iter->release();
}
detachAbove( gIOPowerPlane );
fParentsKnowState = false;
iter = getChildIterator(gIOPowerPlane);
if (iter) {
while ((next = iter->getNextObject())) {
if ((connection = OSDynamicCast(IOPowerConnection, next))) {
theChild = ((IOService *)(connection->copyChildEntry(gIOPowerPlane)));
if (theChild) {
connection->detachFromChild(theChild, gIOPowerPlane);
theChild->release();
}
detachFromChild(connection, gIOPowerPlane);
}
}
iter->release();
}
if (fInterestedDrivers) {
IOPMinformeeList * list = fInterestedDrivers;
IOPMinformee * item;
PM_LOCK();
while ((item = list->firstInList())) {
list->removeFromList(item->whatObject);
}
PM_UNLOCK();
}
fIdleTimerPeriod = 0;
if (fIdleTimer && thread_call_cancel(fIdleTimer)) {
release();
}
PM_LOG2("%s: %p %s done\n", getName(), OBFUSCATE(this), __FUNCTION__);
}
IOReturn
IOService::addPowerChild( IOService * child )
{
IOPowerConnection * connection = NULL;
IOPMRequest * requests[3] = {NULL, NULL, NULL};
OSIterator * iter;
bool ok = true;
if (!child) {
return kIOReturnBadArgument;
}
if (!initialized || !child->initialized) {
return IOPMNotYetInitialized;
}
OUR_PMLog( kPMLogAddChild, (uintptr_t) child, 0 );
do {
iter = child->getParentIterator( gIOPowerPlane );
if (iter) {
IORegistryEntry * entry;
OSObject * next;
while ((next = iter->getNextObject())) {
if ((entry = OSDynamicCast(IORegistryEntry, next)) &&
isChild(entry, gIOPowerPlane)) {
ok = false;
break;
}
}
iter->release();
}
if (!ok) {
PM_LOG2("%s: %s (%p) is already a child\n",
getName(), child->getName(), OBFUSCATE(child));
break;
}
connection = new IOPowerConnection;
if (!connection) {
break;
}
requests[0] = acquirePMRequest(
this,
kIOPMRequestTypeAddPowerChild1 );
requests[1] = acquirePMRequest(
child,
kIOPMRequestTypeAddPowerChild2 );
requests[2] = acquirePMRequest(
this,
kIOPMRequestTypeAddPowerChild3 );
if (!requests[0] || !requests[1] || !requests[2]) {
break;
}
requests[0]->attachNextRequest( requests[1] );
requests[1]->attachNextRequest( requests[2] );
connection->init();
connection->start(this);
connection->setAwaitingAck(false);
connection->setReadyFlag(false);
attachToChild( connection, gIOPowerPlane );
connection->attachToChild( child, gIOPowerPlane );
requests[0]->fArg0 = connection;
requests[1]->fArg0 = connection;
requests[2]->fArg0 = connection;
submitPMRequests( requests, 3 );
return kIOReturnSuccess;
}while (false);
if (connection) {
connection->release();
}
if (requests[0]) {
releasePMRequest(requests[0]);
}
if (requests[1]) {
releasePMRequest(requests[1]);
}
if (requests[2]) {
releasePMRequest(requests[2]);
}
return kIOReturnSuccess;
}
void
IOService::addPowerChild1( IOPMRequest * request )
{
IOPMPowerStateIndex tempDesire = kPowerStateZero;
PM_ASSERT_IN_GATE();
OUR_PMLog( kPMLogMakeUsable, kPMLogMakeUsable, 0 );
if (fControllingDriver && inPlane(gIOPowerPlane) && fParentsKnowState) {
tempDesire = fHighestPowerState;
}
if ((tempDesire != kPowerStateZero) &&
(IS_PM_ROOT || (StateOrder(fMaxPowerState) >= StateOrder(tempDesire)))) {
adjustPowerState(tempDesire);
}
}
void
IOService::addPowerChild2( IOPMRequest * request )
{
IOPowerConnection * connection = (IOPowerConnection *) request->fArg0;
IOService * parent;
IOPMPowerFlags powerFlags;
bool knowsState;
unsigned long powerState;
unsigned long tempDesire;
PM_ASSERT_IN_GATE();
parent = (IOService *) connection->getParentEntry(gIOPowerPlane);
if (!parent || !inPlane(gIOPowerPlane)) {
PM_LOG("%s: addPowerChild2 not in power plane\n", getName());
return;
}
knowsState = (parent->fPowerStates) && (parent->fParentsKnowState);
powerState = parent->fCurrentPowerState;
if (knowsState) {
powerFlags = parent->fPowerStates[powerState].outputPowerFlags;
} else {
powerFlags = 0;
}
OUR_PMLog(kPMLogSetParent, knowsState, powerFlags);
setParentInfo( powerFlags, connection, knowsState );
connection->setReadyFlag(true);
if (fControllingDriver && fParentsKnowState) {
fMaxPowerState = fControllingDriver->maxCapabilityForDomainState(fParentsCurrentPowerFlags);
tempDesire = fControllingDriver->initialPowerStateForDomainState(fParentsCurrentPowerFlags);
fPreviousRequestPowerFlags = (IOPMPowerFlags)(-1);
adjustPowerState(tempDesire);
}
getPMRootDomain()->tagPowerPlaneService(this, &fPMActions);
}
void
IOService::addPowerChild3( IOPMRequest * request )
{
IOPowerConnection * connection = (IOPowerConnection *) request->fArg0;
IOService * child;
IOPMrootDomain * rootDomain = getPMRootDomain();
PM_ASSERT_IN_GATE();
child = (IOService *) connection->getChildEntry(gIOPowerPlane);
if (child && inPlane(gIOPowerPlane)) {
if ((this != rootDomain) && child->getProperty("IOPMStrictTreeOrder")) {
PM_LOG1("%s: strict PM order enforced\n", getName());
fStrictTreeOrder = true;
}
if (rootDomain) {
rootDomain->joinAggressiveness( child );
}
} else {
PM_LOG("%s: addPowerChild3 not in power plane\n", getName());
}
connection->release();
}
#ifndef __LP64__
IOReturn
IOService::setPowerParent(
IOPowerConnection * theParent, bool stateKnown, IOPMPowerFlags powerFlags )
{
return kIOReturnUnsupported;
}
#endif
IOReturn
IOService::removePowerChild( IOPowerConnection * theNub )
{
IORegistryEntry * theChild;
PM_ASSERT_IN_GATE();
OUR_PMLog( kPMLogRemoveChild, 0, 0 );
theNub->retain();
theChild = theNub->copyChildEntry(gIOPowerPlane);
if (theChild) {
theNub->detachFromChild(theChild, gIOPowerPlane);
theChild->release();
}
detachFromChild(theNub, gIOPowerPlane);
if (theNub->getAwaitingAck()) {
theNub->setAwaitingAck(false);
if (fHeadNotePendingAcks != 0) {
fHeadNotePendingAcks--;
if (fHeadNotePendingAcks == 0) {
stop_ack_timer();
getPMRootDomain()->reset_watchdog_timer(this, 0);
gIOPMWorkQueue->incrementProducerCount();
}
}
}
theNub->release();
if (!fAdjustPowerScheduled) {
IOPMRequest * request;
request = acquirePMRequest( this, kIOPMRequestTypeAdjustPowerState );
if (request) {
submitPMRequest( request );
fAdjustPowerScheduled = true;
}
}
return IOPMNoErr;
}
IOReturn
IOService::registerPowerDriver(
IOService * powerDriver,
IOPMPowerState * powerStates,
unsigned long numberOfStates )
{
IOPMRequest * request;
IOPMPSEntry * powerStatesCopy = NULL;
IOPMPowerStateIndex stateOrder;
IOReturn error = kIOReturnSuccess;
if (!initialized) {
return IOPMNotYetInitialized;
}
if (!powerStates || (numberOfStates < 2)) {
OUR_PMLog(kPMLogControllingDriverErr5, numberOfStates, 0);
return kIOReturnBadArgument;
}
if (!powerDriver || !powerDriver->initialized) {
OUR_PMLog(kPMLogControllingDriverErr4, 0, 0);
return kIOReturnBadArgument;
}
if (powerStates[0].version > kIOPMPowerStateVersion2) {
OUR_PMLog(kPMLogControllingDriverErr1, powerStates[0].version, 0);
return kIOReturnBadArgument;
}
do {
powerStatesCopy = IONew(IOPMPSEntry, numberOfStates);
if (!powerStatesCopy) {
error = kIOReturnNoMemory;
break;
}
for (IOPMPowerStateIndex i = 0; i < numberOfStates; i++) {
powerStatesCopy[i].stateOrderToIndex = kIOPMPowerStateMax;
}
for (uint32_t i = 0; i < numberOfStates; i++) {
powerStatesCopy[i].capabilityFlags = powerStates[i].capabilityFlags;
powerStatesCopy[i].outputPowerFlags = powerStates[i].outputPowerCharacter;
powerStatesCopy[i].inputPowerFlags = powerStates[i].inputPowerRequirement;
powerStatesCopy[i].staticPower = powerStates[i].staticPower;
powerStatesCopy[i].settleUpTime = powerStates[i].settleUpTime;
powerStatesCopy[i].settleDownTime = powerStates[i].settleDownTime;
if (powerStates[i].version >= kIOPMPowerStateVersion2) {
stateOrder = powerStates[i].stateOrder;
} else {
stateOrder = i;
}
if (stateOrder < numberOfStates) {
powerStatesCopy[i].stateOrder = stateOrder;
powerStatesCopy[stateOrder].stateOrderToIndex = i;
}
}
for (IOPMPowerStateIndex i = 0; i < numberOfStates; i++) {
if (powerStatesCopy[i].stateOrderToIndex == kIOPMPowerStateMax) {
error = kIOReturnBadArgument;
break;
}
}
if (kIOReturnSuccess != error) {
break;
}
request = acquirePMRequest( this, kIOPMRequestTypeRegisterPowerDriver );
if (!request) {
error = kIOReturnNoMemory;
break;
}
powerDriver->retain();
request->fArg0 = (void *) powerDriver;
request->fArg1 = (void *) powerStatesCopy;
request->fArg2 = (void *) numberOfStates;
submitPMRequest( request );
return kIOReturnSuccess;
}while (false);
if (powerStatesCopy) {
IODelete(powerStatesCopy, IOPMPSEntry, numberOfStates);
}
return error;
}
void
IOService::handleRegisterPowerDriver( IOPMRequest * request )
{
IOService * powerDriver = (IOService *) request->fArg0;
IOPMPSEntry * powerStates = (IOPMPSEntry *) request->fArg1;
unsigned long numberOfStates = (unsigned long) request->fArg2;
unsigned long i, stateIndex;
unsigned long lowestPowerState;
IOService * root;
OSIterator * iter;
PM_ASSERT_IN_GATE();
assert(powerStates);
assert(powerDriver);
assert(numberOfStates > 1);
if (!fNumberOfPowerStates) {
OUR_PMLog(kPMLogControllingDriver,
(unsigned long) numberOfStates,
(unsigned long) kIOPMPowerStateVersion1);
fPowerStates = powerStates;
fNumberOfPowerStates = numberOfStates;
fControllingDriver = powerDriver;
fCurrentCapabilityFlags = fPowerStates[0].capabilityFlags;
lowestPowerState = fPowerStates[0].stateOrderToIndex;
fHighestPowerState = fPowerStates[numberOfStates - 1].stateOrderToIndex;
#if !(defined(RC_HIDE_N144) || defined(RC_HIDE_N146))
{
uint32_t aotFlags;
IOService * service;
OSObject * object;
OSData * data;
aotFlags = 0;
service = this;
while (service && !service->inPlane(gIODTPlane)) {
service = service->getProvider();
}
if (service) {
object = service->copyProperty(kIOPMAOTPowerKey, gIODTPlane);
data = OSDynamicCast(OSData, object);
if (data && (data->getLength() >= sizeof(uint32_t))) {
aotFlags = ((uint32_t *)data->getBytesNoCopy())[0];
}
OSSafeReleaseNULL(object);
}
if (!aotFlags) {
for (i = 0; i < numberOfStates; i++) {
if (kIOPMAOTPower & fPowerStates[i].inputPowerFlags) {
fPowerStates[i].inputPowerFlags = 0xFFFFFFFF;
fPowerStates[i].capabilityFlags = 0;
fPowerStates[i].outputPowerFlags = 0;
}
}
}
}
#endif
fMergedOutputPowerFlags = 0;
fDeviceUsablePowerState = lowestPowerState;
for (i = 0; i < numberOfStates; i++) {
fMergedOutputPowerFlags |= fPowerStates[i].outputPowerFlags;
stateIndex = fPowerStates[i].stateOrderToIndex;
assert(stateIndex < numberOfStates);
if ((fDeviceUsablePowerState == lowestPowerState) &&
(fPowerStates[stateIndex].capabilityFlags & IOPMDeviceUsable)) {
fDeviceUsablePowerState = stateIndex;
}
}
root = getPlatform()->getProvider();
assert(root);
if (!root ||
((OSMemberFunctionCast(void (*)(void),
root, &IOService::powerStateDidChangeTo)) !=
((OSMemberFunctionCast(void (*)(void),
this, &IOService::powerStateDidChangeTo)))) ||
((OSMemberFunctionCast(void (*)(void),
root, &IOService::powerStateWillChangeTo)) !=
((OSMemberFunctionCast(void (*)(void),
this, &IOService::powerStateWillChangeTo))))) {
if (fInterestedDrivers->findItem(powerDriver) == NULL) {
PM_LOCK();
fInterestedDrivers->appendNewInformee(powerDriver);
PM_UNLOCK();
}
}
if (fPowerClients &&
(iter = OSCollectionIterator::withCollection(fPowerClients))) {
const OSSymbol * client;
while ((client = (const OSSymbol *) iter->getNextObject())) {
IOPMPowerStateIndex powerState = getPowerStateForClient(client);
if (powerState >= numberOfStates) {
updatePowerClient(client, fHighestPowerState);
}
}
iter->release();
}
if (inPlane(gIOPowerPlane) && fParentsKnowState) {
IOPMPowerStateIndex tempDesire;
fMaxPowerState = fControllingDriver->maxCapabilityForDomainState(fParentsCurrentPowerFlags);
tempDesire = fControllingDriver->initialPowerStateForDomainState(fParentsCurrentPowerFlags);
adjustPowerState(tempDesire);
}
} else {
OUR_PMLog(kPMLogControllingDriverErr2, numberOfStates, 0);
IODelete(powerStates, IOPMPSEntry, numberOfStates);
}
powerDriver->release();
}
IOPMPowerFlags
IOService::registerInterestedDriver( IOService * driver )
{
IOPMRequest * request;
bool signal;
if (!driver || !initialized || !fInterestedDrivers) {
return 0;
}
PM_LOCK();
signal = (!fInsertInterestSet && !fRemoveInterestSet);
if (fInsertInterestSet == NULL) {
fInsertInterestSet = OSSet::withCapacity(4);
}
if (fInsertInterestSet) {
fInsertInterestSet->setObject(driver);
if (fRemoveInterestSet) {
fRemoveInterestSet->removeObject(driver);
}
}
PM_UNLOCK();
if (signal) {
request = acquirePMRequest( this, kIOPMRequestTypeInterestChanged );
if (request) {
submitPMRequest( request );
}
}
OUR_PMLog(kPMLogInterestedDriver, kIOPMDeviceUsable, 2);
return kIOPMDeviceUsable;
}
IOReturn
IOService::deRegisterInterestedDriver( IOService * driver )
{
IOPMinformee * item;
IOPMRequest * request;
bool signal;
if (!driver) {
return kIOReturnBadArgument;
}
if (!initialized || !fInterestedDrivers) {
return IOPMNotPowerManaged;
}
PM_LOCK();
if (fInsertInterestSet) {
fInsertInterestSet->removeObject(driver);
}
item = fInterestedDrivers->findItem(driver);
if (!item) {
PM_UNLOCK();
return kIOReturnNotFound;
}
signal = (!fRemoveInterestSet && !fInsertInterestSet);
if (fRemoveInterestSet == NULL) {
fRemoveInterestSet = OSSet::withCapacity(4);
}
if (fRemoveInterestSet) {
fRemoveInterestSet->setObject(driver);
if (item->active) {
item->active = false;
waitForPMDriverCall( driver );
}
}
PM_UNLOCK();
if (signal) {
request = acquirePMRequest( this, kIOPMRequestTypeInterestChanged );
if (request) {
submitPMRequest( request );
}
}
return IOPMNoErr;
}
void
IOService::handleInterestChanged( IOPMRequest * request )
{
IOService * driver;
IOPMinformee * informee;
IOPMinformeeList * list = fInterestedDrivers;
PM_LOCK();
if (fInsertInterestSet) {
while ((driver = (IOService *) fInsertInterestSet->getAnyObject())) {
if (list->findItem(driver) == NULL) {
informee = list->appendNewInformee(driver);
}
fInsertInterestSet->removeObject(driver);
}
fInsertInterestSet->release();
fInsertInterestSet = NULL;
}
if (fRemoveInterestSet) {
while ((driver = (IOService *) fRemoveInterestSet->getAnyObject())) {
informee = list->findItem(driver);
if (informee) {
if (fHeadNotePendingAcks && informee->timer) {
informee->timer = 0;
fHeadNotePendingAcks--;
}
list->removeFromList(driver);
}
fRemoveInterestSet->removeObject(driver);
}
fRemoveInterestSet->release();
fRemoveInterestSet = NULL;
}
PM_UNLOCK();
}
IOReturn
IOService::acknowledgePowerChange( IOService * whichObject )
{
IOPMRequest * request;
if (!initialized) {
return IOPMNotYetInitialized;
}
if (!whichObject) {
return kIOReturnBadArgument;
}
request = acquirePMRequest( this, kIOPMRequestTypeAckPowerChange );
if (!request) {
return kIOReturnNoMemory;
}
whichObject->retain();
request->fArg0 = whichObject;
submitPMRequest( request );
return IOPMNoErr;
}
bool
IOService::handleAcknowledgePowerChange( IOPMRequest * request )
{
IOPMinformee * informee;
unsigned long childPower = kIOPMUnknown;
IOService * theChild;
IOService * whichObject;
bool all_acked = false;
PM_ASSERT_IN_GATE();
whichObject = (IOService *) request->fArg0;
assert(whichObject);
informee = fInterestedDrivers->findItem( whichObject );
if (informee == NULL) {
if (!isChild(whichObject, gIOPowerPlane)) {
OUR_PMLog(kPMLogAcknowledgeErr1, 0, 0);
goto no_err;
} else {
OUR_PMLog(kPMLogChildAcknowledge, fHeadNotePendingAcks, 0);
}
} else {
OUR_PMLog(kPMLogDriverAcknowledge, fHeadNotePendingAcks, 0);
}
if (fHeadNotePendingAcks != 0) {
assert(fPowerStates != NULL);
if (informee != NULL) {
if (informee->timer != 0) {
if (informee->timer > 0) {
uint64_t nsec = computeTimeDeltaNS(&informee->startTime);
if (nsec > LOG_SETPOWER_TIMES) {
getPMRootDomain()->pmStatsRecordApplicationResponse(
gIOPMStatsDriverPSChangeSlow, informee->whatObject->getName(),
fDriverCallReason, NS_TO_MS(nsec), informee->whatObject->getRegistryEntryID(),
NULL, fHeadNotePowerState);
}
}
informee->timer = 0;
fHeadNotePendingAcks--;
} else {
OUR_PMLog(kPMLogAcknowledgeErr2, 0, 0);
}
} else {
if (((IOPowerConnection *)whichObject)->getAwaitingAck()) {
fHeadNotePendingAcks--;
((IOPowerConnection *)whichObject)->setAwaitingAck(false);
theChild = (IOService *)whichObject->copyChildEntry(gIOPowerPlane);
if (theChild) {
childPower = theChild->currentPowerConsumption();
theChild->release();
}
if (childPower == kIOPMUnknown) {
fHeadNotePowerArrayEntry->staticPower = kIOPMUnknown;
} else {
if (fHeadNotePowerArrayEntry->staticPower != kIOPMUnknown) {
fHeadNotePowerArrayEntry->staticPower += childPower;
}
}
}
}
if (fHeadNotePendingAcks == 0) {
stop_ack_timer();
all_acked = true;
getPMRootDomain()->reset_watchdog_timer(this, 0);
}
} else {
OUR_PMLog(kPMLogAcknowledgeErr3, 0, 0); }
no_err:
if (whichObject) {
whichObject->release();
}
return all_acked;
}
IOReturn
IOService::acknowledgeSetPowerState( void )
{
IOPMRequest * request;
if (!initialized) {
return IOPMNotYetInitialized;
}
request = acquirePMRequest( this, kIOPMRequestTypeAckSetPowerState );
if (!request) {
return kIOReturnNoMemory;
}
submitPMRequest( request );
return kIOReturnSuccess;
}
void
IOService::adjustPowerState( uint32_t clamp )
{
PM_ASSERT_IN_GATE();
computeDesiredState(clamp, false);
if (fControllingDriver && fParentsKnowState && inPlane(gIOPowerPlane)) {
IOPMPowerChangeFlags changeFlags = kIOPMSelfInitiated;
if (getPMRequestType() == kIOPMRequestTypeRequestPowerStateOverride) {
changeFlags |= (kIOPMIgnoreChildren | kIOPMSkipAskPowerDown);
}
startPowerChange(
changeFlags,
fDesiredPowerState,
0,
NULL,
0);
}
}
IOReturn
IOService::synchronizePowerTree(
IOOptionBits options,
IOService * notifyRoot )
{
IOPMRequest * request_c = NULL;
IOPMRequest * request_s;
if (this != getPMRootDomain()) {
return kIOReturnBadArgument;
}
if (!initialized) {
return kIOPMNotYetInitialized;
}
OUR_PMLog(kPMLogCSynchronizePowerTree, options, (notifyRoot != NULL));
if (notifyRoot) {
IOPMRequest * nr;
nr = acquirePMRequest(notifyRoot, kIOPMRequestTypeChildNotifyDelayCancel);
if (nr) {
submitPMRequest(nr);
}
nr = acquirePMRequest(getPMRootDomain(), kIOPMRequestTypeChildNotifyDelayCancel);
if (nr) {
submitPMRequest(nr);
}
}
request_s = acquirePMRequest( this, kIOPMRequestTypeSynchronizePowerTree );
if (!request_s) {
goto error_no_memory;
}
if (options & kIOPMSyncCancelPowerDown) {
request_c = acquirePMRequest( this, kIOPMRequestTypeIdleCancel );
}
if (request_c) {
request_c->attachNextRequest( request_s );
submitPMRequest(request_c);
}
request_s->fArg0 = (void *)(uintptr_t) options;
submitPMRequest(request_s);
return kIOReturnSuccess;
error_no_memory:
if (request_c) {
releasePMRequest(request_c);
}
if (request_s) {
releasePMRequest(request_s);
}
return kIOReturnNoMemory;
}
void
IOService::handleSynchronizePowerTree( IOPMRequest * request )
{
PM_ASSERT_IN_GATE();
if (fControllingDriver && fParentsKnowState && inPlane(gIOPowerPlane) &&
(fCurrentPowerState == fHighestPowerState)) {
IOOptionBits options = (uintptr_t) request->fArg0;
startPowerChange(
kIOPMSelfInitiated | kIOPMSynchronize |
(options & kIOPMSyncNoChildNotify),
fCurrentPowerState,
0,
NULL,
0);
}
}
#ifndef __LP64__
IOReturn
IOService::powerDomainWillChangeTo(
IOPMPowerFlags newPowerFlags,
IOPowerConnection * whichParent )
{
assert(false);
return kIOReturnUnsupported;
}
#endif
void
IOService::handlePowerDomainWillChangeTo( IOPMRequest * request )
{
IOPMPowerFlags parentPowerFlags = (IOPMPowerFlags) request->fArg0;
IOPowerConnection * whichParent = (IOPowerConnection *) request->fArg1;
IOPMPowerChangeFlags parentChangeFlags = (IOPMPowerChangeFlags)(uintptr_t) request->fArg2;
IOPMPowerChangeFlags myChangeFlags;
OSIterator * iter;
OSObject * next;
IOPowerConnection * connection;
IOPMPowerStateIndex maxPowerState;
IOPMPowerFlags combinedPowerFlags;
bool savedParentsKnowState;
IOReturn result = IOPMAckImplied;
PM_ASSERT_IN_GATE();
OUR_PMLog(kPMLogWillChange, parentPowerFlags, 0);
if (!inPlane(gIOPowerPlane) || !whichParent || !whichParent->getAwaitingAck()) {
PM_LOG("%s::%s not in power tree\n", getName(), __FUNCTION__);
goto exit_no_ack;
}
savedParentsKnowState = fParentsKnowState;
combinedPowerFlags = 0;
iter = getParentIterator(gIOPowerPlane);
if (iter) {
while ((next = iter->getNextObject())) {
if ((connection = OSDynamicCast(IOPowerConnection, next))) {
if (connection == whichParent) {
combinedPowerFlags |= parentPowerFlags;
} else {
combinedPowerFlags |= connection->parentCurrentPowerFlags();
}
}
}
iter->release();
}
if (fControllingDriver && !fInitialPowerChange) {
maxPowerState = fControllingDriver->maxCapabilityForDomainState(
combinedPowerFlags);
if (parentChangeFlags & kIOPMDomainPowerDrop) {
fMaxPowerState = maxPowerState;
}
myChangeFlags = kIOPMParentInitiated | kIOPMDomainWillChange |
(parentChangeFlags & kIOPMSynchronize);
result = startPowerChange(
myChangeFlags,
maxPowerState,
combinedPowerFlags,
whichParent,
parentPowerFlags);
}
if (parentChangeFlags & kIOPMDomainPowerDrop) {
setParentInfo(parentPowerFlags, whichParent, true);
}
if (IOPMAckImplied == result) {
IOService * parent;
parent = (IOService *) whichParent->copyParentEntry(gIOPowerPlane);
assert(parent);
if (parent) {
parent->acknowledgePowerChange( whichParent );
parent->release();
}
}
exit_no_ack:
if (whichParent) {
whichParent->release();
}
}
#ifndef __LP64__
IOReturn
IOService::powerDomainDidChangeTo(
IOPMPowerFlags newPowerFlags,
IOPowerConnection * whichParent )
{
assert(false);
return kIOReturnUnsupported;
}
#endif
void
IOService::handlePowerDomainDidChangeTo( IOPMRequest * request )
{
IOPMPowerFlags parentPowerFlags = (IOPMPowerFlags) request->fArg0;
IOPowerConnection * whichParent = (IOPowerConnection *) request->fArg1;
IOPMPowerChangeFlags parentChangeFlags = (IOPMPowerChangeFlags)(uintptr_t) request->fArg2;
IOPMPowerChangeFlags myChangeFlags;
IOPMPowerStateIndex maxPowerState;
IOPMPowerStateIndex initialDesire = kPowerStateZero;
bool computeDesire = false;
bool desireChanged = false;
bool savedParentsKnowState;
IOReturn result = IOPMAckImplied;
PM_ASSERT_IN_GATE();
OUR_PMLog(kPMLogDidChange, parentPowerFlags, 0);
if (!inPlane(gIOPowerPlane) || !whichParent || !whichParent->getAwaitingAck()) {
PM_LOG("%s::%s not in power tree\n", getName(), __FUNCTION__);
goto exit_no_ack;
}
savedParentsKnowState = fParentsKnowState;
setParentInfo(parentPowerFlags, whichParent, true);
if (fControllingDriver) {
maxPowerState = fControllingDriver->maxCapabilityForDomainState(
fParentsCurrentPowerFlags);
if ((parentChangeFlags & kIOPMDomainPowerDrop) == 0) {
fMaxPowerState = maxPowerState;
}
if (fInitialPowerChange) {
computeDesire = true;
initialDesire = fControllingDriver->initialPowerStateForDomainState(
fParentsCurrentPowerFlags);
} else if (parentChangeFlags & kIOPMRootChangeUp) {
if (fAdvisoryTickleUsed) {
desireChanged = true;
}
if (fResetPowerStateOnWake) {
IOPMPowerStateIndex wakePowerState =
fControllingDriver->initialPowerStateForDomainState(
kIOPMRootDomainState | kIOPMPowerOn );
if (StateOrder(wakePowerState) > StateOrder(fDesiredPowerState)) {
updatePowerClient(gIOPMPowerClientDevice, wakePowerState);
desireChanged = true;
}
}
}
if (computeDesire || desireChanged) {
computeDesiredState(initialDesire, false);
}
myChangeFlags = kIOPMParentInitiated | kIOPMDomainDidChange |
(parentChangeFlags & kIOPMRootBroadcastFlags);
#if !(defined(RC_HIDE_N144) || defined(RC_HIDE_N146))
if (kIOPMAOTPower & fPowerStates[maxPowerState].inputPowerFlags) {
IOLog("aotPS %s0x%qx[%ld]\n", getName(), getRegistryEntryID(), maxPowerState);
}
#endif
result = startPowerChange(
myChangeFlags,
maxPowerState,
fParentsCurrentPowerFlags,
whichParent,
0);
}
if (IOPMAckImplied == result) {
IOService * parent;
parent = (IOService *) whichParent->copyParentEntry(gIOPowerPlane);
assert(parent);
if (parent) {
parent->acknowledgePowerChange( whichParent );
parent->release();
}
}
if (fControllingDriver &&
((!savedParentsKnowState && fParentsKnowState) || desireChanged)) {
PM_LOG1("%s::powerDomainDidChangeTo parentsKnowState %d\n",
getName(), fParentsKnowState);
requestDomainPower( fDesiredPowerState );
}
exit_no_ack:
if (whichParent) {
whichParent->release();
}
}
void
IOService::setParentInfo(
IOPMPowerFlags newPowerFlags,
IOPowerConnection * whichParent,
bool knowsState )
{
OSIterator * iter;
OSObject * next;
IOPowerConnection * conn;
PM_ASSERT_IN_GATE();
whichParent->setParentCurrentPowerFlags(newPowerFlags);
whichParent->setParentKnowsState(knowsState);
fParentsCurrentPowerFlags = 0;
fParentsKnowState = true;
iter = getParentIterator(gIOPowerPlane);
if (iter) {
while ((next = iter->getNextObject())) {
if ((conn = OSDynamicCast(IOPowerConnection, next))) {
fParentsKnowState &= conn->parentKnowsState();
fParentsCurrentPowerFlags |= conn->parentCurrentPowerFlags();
}
}
iter->release();
}
}
void
IOService::trackSystemSleepPreventers(
IOPMPowerStateIndex oldPowerState,
IOPMPowerStateIndex newPowerState,
IOPMPowerChangeFlags changeFlags __unused )
{
IOPMPowerFlags oldCapability, newCapability;
oldCapability = fPowerStates[oldPowerState].capabilityFlags &
(kIOPMPreventIdleSleep | kIOPMPreventSystemSleep);
newCapability = fPowerStates[newPowerState].capabilityFlags &
(kIOPMPreventIdleSleep | kIOPMPreventSystemSleep);
if (fHeadNoteChangeFlags & kIOPMInitialPowerChange) {
oldCapability = 0;
}
if (oldCapability == newCapability) {
return;
}
if ((oldCapability ^ newCapability) & kIOPMPreventIdleSleep) {
bool enablePrevention = ((oldCapability & kIOPMPreventIdleSleep) == 0);
bool idleCancelAllowed = getPMRootDomain()->updatePreventIdleSleepList(
this, enablePrevention);
#if SUPPORT_IDLE_CANCEL
if (idleCancelAllowed && enablePrevention) {
IOPMRequest * cancelRequest;
cancelRequest = acquirePMRequest( getPMRootDomain(), kIOPMRequestTypeIdleCancel );
if (cancelRequest) {
submitPMRequest( cancelRequest );
}
}
#endif
}
if ((oldCapability ^ newCapability) & kIOPMPreventSystemSleep) {
getPMRootDomain()->updatePreventSystemSleepList(this,
((oldCapability & kIOPMPreventSystemSleep) == 0));
}
}
IOReturn
IOService::requestPowerDomainState(
IOPMPowerFlags childRequestPowerFlags,
IOPowerConnection * childConnection,
unsigned long specification )
{
IOPMPowerStateIndex order, powerState;
IOPMPowerFlags outputPowerFlags;
IOService * child;
IOPMRequest * subRequest;
bool adjustPower = false;
if (!initialized) {
return IOPMNotYetInitialized;
}
if (gIOPMWorkLoop->onThread() == false) {
PM_LOG("%s::requestPowerDomainState\n", getName());
return kIOReturnSuccess;
}
OUR_PMLog(kPMLogRequestDomain, childRequestPowerFlags, specification);
if (!isChild(childConnection, gIOPowerPlane)) {
return kIOReturnNotAttached;
}
if (!fControllingDriver || !fNumberOfPowerStates) {
return kIOReturnNotReady;
}
child = (IOService *) childConnection->getChildEntry(gIOPowerPlane);
assert(child);
childRequestPowerFlags &= fMergedOutputPowerFlags;
outputPowerFlags = fPowerStates[fCurrentPowerState].outputPowerFlags;
if (fMachineState != kIOPM_Finished) {
if (IS_POWER_DROP && !IS_ROOT_DOMAIN) {
if ((fMachineState == kIOPM_OurChangeTellClientsPowerDown) ||
(fMachineState == kIOPM_OurChangeTellPriorityClientsPowerDown)) {
fDoNotPowerDown = true; adjustPower = true; PM_LOG1("%s: power drop cancelled in state %u by %s\n",
getName(), fMachineState, child->getName());
} else {
outputPowerFlags =
fPowerStates[fHeadNotePowerState].outputPowerFlags;
}
} else if (IS_POWER_RISE) {
outputPowerFlags = childConnection->parentCurrentPowerFlags();
}
}
child->fHeadNoteDomainTargetFlags |= outputPowerFlags;
for (order = 0; order < fNumberOfPowerStates; order++) {
powerState = fPowerStates[order].stateOrderToIndex;
if ((fPowerStates[powerState].outputPowerFlags & childRequestPowerFlags)
== childRequestPowerFlags) {
break;
}
}
if (order >= fNumberOfPowerStates) {
powerState = kPowerStateZero;
}
if (!childConnection->childHasRequestedPower() ||
(powerState != childConnection->getDesiredDomainState())) {
adjustPower = true;
}
#if ENABLE_DEBUG_LOGS
if (adjustPower) {
PM_LOG("requestPowerDomainState[%s]: %s, init %d, %u->%u\n",
getName(), child->getName(),
!childConnection->childHasRequestedPower(),
(uint32_t) childConnection->getDesiredDomainState(),
(uint32_t) powerState);
}
#endif
childConnection->setChildHasRequestedPower();
childConnection->setDesiredDomainState( powerState );
if (adjustPower && !fDeviceOverrideEnabled &&
(!fAdjustPowerScheduled || gIOPMRequest->getRootRequest())) {
subRequest = acquirePMRequest(
this, kIOPMRequestTypeAdjustPowerState, gIOPMRequest );
if (subRequest) {
submitPMRequest( subRequest );
fAdjustPowerScheduled = true;
}
}
return kIOReturnSuccess;
}
IOReturn
IOService::temporaryPowerClampOn( void )
{
return requestPowerState( gIOPMPowerClientChildProxy, kIOPMPowerStateMax );
}
IOReturn
IOService::makeUsable( void )
{
OUR_PMLog(kPMLogMakeUsable, 0, 0);
return requestPowerState( gIOPMPowerClientDevice, kIOPMPowerStateMax );
}
IOPMPowerFlags
IOService::currentCapability( void )
{
if (!initialized) {
return IOPMNotPowerManaged;
}
return fCurrentCapabilityFlags;
}
IOReturn
IOService::changePowerStateTo( unsigned long ordinal )
{
OUR_PMLog(kPMLogChangeStateTo, ordinal, 0);
return requestPowerState( gIOPMPowerClientDriver, ordinal );
}
IOReturn
IOService::changePowerStateToPriv( unsigned long ordinal )
{
OUR_PMLog(kPMLogChangeStateToPriv, ordinal, 0);
return requestPowerState( gIOPMPowerClientDevice, ordinal );
}
IOReturn
IOService::changePowerStateWithOverrideTo( IOPMPowerStateIndex ordinal,
IOPMRequestTag tag )
{
IOPMRequest * request;
if (!initialized) {
return kIOPMNotYetInitialized;
}
OUR_PMLog(kPMLogChangeStateToPriv, ordinal, 0);
request = acquirePMRequest( this, kIOPMRequestTypeRequestPowerStateOverride );
if (!request) {
return kIOReturnNoMemory;
}
gIOPMPowerClientDevice->retain();
request->fRequestTag = tag;
request->fArg0 = (void *) ordinal;
request->fArg1 = (void *) gIOPMPowerClientDevice;
request->fArg2 = NULL;
#if NOT_READY
if (action) {
request->installCompletionAction( action, target, param );
}
#endif
if (gIOPMWorkLoop->inGate() && (ordinal < fNumberOfPowerStates)) {
fTempClampPowerState = StateMax(fTempClampPowerState, ordinal);
fTempClampCount++;
fOverrideMaxPowerState = ordinal;
request->fArg2 = (void *) (uintptr_t) true;
}
submitPMRequest( request );
return IOPMNoErr;
}
IOReturn
IOService::changePowerStateForRootDomain( IOPMPowerStateIndex ordinal )
{
OUR_PMLog(kPMLogChangeStateForRootDomain, ordinal, 0);
return requestPowerState( gIOPMPowerClientRootDomain, ordinal );
}
IOReturn
IOService::quiescePowerTree(
void * target, IOPMCompletionAction action, void * param )
{
IOPMRequest * request;
if (!initialized) {
return kIOPMNotYetInitialized;
}
if (!target || !action) {
return kIOReturnBadArgument;
}
OUR_PMLog(kPMLogQuiescePowerTree, 0, 0);
request = acquirePMRequest(gIOPMRootNode, kIOPMRequestTypeQuiescePowerTree);
if (!request) {
return kIOReturnNoMemory;
}
request->installCompletionAction(target, action, param);
submitPMRequest( request );
return kIOReturnSuccess;
}
IOReturn
IOService::requestPowerState(
const OSSymbol * client,
uint32_t state )
{
IOPMRequest * request;
if (!client) {
return kIOReturnBadArgument;
}
if (!initialized) {
return kIOPMNotYetInitialized;
}
request = acquirePMRequest( this, kIOPMRequestTypeRequestPowerState );
if (!request) {
return kIOReturnNoMemory;
}
client->retain();
request->fArg0 = (void *)(uintptr_t) state;
request->fArg1 = (void *) client;
request->fArg2 = NULL;
#if NOT_READY
if (action) {
request->installCompletionAction( action, target, param );
}
#endif
if (gIOPMWorkLoop->inGate() && (state < fNumberOfPowerStates)) {
fTempClampPowerState = StateMax(fTempClampPowerState, state);
fTempClampCount++;
request->fArg2 = (void *) (uintptr_t) true;
}
submitPMRequest( request );
return IOPMNoErr;
}
void
IOService::handleRequestPowerState( IOPMRequest * request )
{
const OSSymbol * client = (const OSSymbol *) request->fArg1;
uint32_t state = (uint32_t)(uintptr_t) request->fArg0;
PM_ASSERT_IN_GATE();
if (request->fArg2) {
assert(fTempClampCount != 0);
if (fTempClampCount) {
fTempClampCount--;
}
if (!fTempClampCount) {
fTempClampPowerState = kPowerStateZero;
}
}
if (fNumberOfPowerStates && (state >= fNumberOfPowerStates)) {
state = fHighestPowerState;
}
if ((getPMRequestType() != kIOPMRequestTypeRequestPowerStateOverride) &&
(client == gIOPMPowerClientDevice)) {
fOverrideMaxPowerState = kIOPMPowerStateMax;
}
if ((state == kPowerStateZero) &&
(client != gIOPMPowerClientDevice) &&
(client != gIOPMPowerClientDriver) &&
(client != gIOPMPowerClientChildProxy)) {
removePowerClient(client);
} else {
updatePowerClient(client, state);
}
adjustPowerState();
client->release();
}
void
IOService::updatePowerClient( const OSSymbol * client, uint32_t powerState )
{
IOPMPowerStateIndex oldPowerState = kPowerStateZero;
if (!fPowerClients) {
fPowerClients = OSDictionary::withCapacity(4);
}
if (fPowerClients && client) {
OSNumber * num = (OSNumber *) fPowerClients->getObject(client);
if (num) {
oldPowerState = num->unsigned32BitValue();
num->setValue(powerState);
} else {
num = OSNumber::withNumber(powerState, 32);
if (num) {
fPowerClients->setObject(client, num);
num->release();
}
}
PM_ACTION_3(actionUpdatePowerClient, client, oldPowerState, powerState);
}
}
void
IOService::removePowerClient( const OSSymbol * client )
{
if (fPowerClients && client) {
fPowerClients->removeObject(client);
}
}
uint32_t
IOService::getPowerStateForClient( const OSSymbol * client )
{
uint32_t powerState = kPowerStateZero;
if (fPowerClients && client) {
OSNumber * num = (OSNumber *) fPowerClients->getObject(client);
if (num) {
powerState = num->unsigned32BitValue();
}
}
return powerState;
}
IOReturn
IOService::powerOverrideOnPriv( void )
{
IOPMRequest * request;
if (!initialized) {
return IOPMNotYetInitialized;
}
if (gIOPMWorkLoop->inGate()) {
fDeviceOverrideEnabled = true;
return IOPMNoErr;
}
request = acquirePMRequest( this, kIOPMRequestTypePowerOverrideOnPriv );
if (!request) {
return kIOReturnNoMemory;
}
submitPMRequest( request );
return IOPMNoErr;
}
IOReturn
IOService::powerOverrideOffPriv( void )
{
IOPMRequest * request;
if (!initialized) {
return IOPMNotYetInitialized;
}
if (gIOPMWorkLoop->inGate()) {
fDeviceOverrideEnabled = false;
return IOPMNoErr;
}
request = acquirePMRequest( this, kIOPMRequestTypePowerOverrideOffPriv );
if (!request) {
return kIOReturnNoMemory;
}
submitPMRequest( request );
return IOPMNoErr;
}
void
IOService::handlePowerOverrideChanged( IOPMRequest * request )
{
PM_ASSERT_IN_GATE();
if (request->getType() == kIOPMRequestTypePowerOverrideOnPriv) {
OUR_PMLog(kPMLogOverrideOn, 0, 0);
fDeviceOverrideEnabled = true;
} else {
OUR_PMLog(kPMLogOverrideOff, 0, 0);
fDeviceOverrideEnabled = false;
}
adjustPowerState();
}
void
IOService::computeDesiredState( unsigned long localClamp, bool computeOnly )
{
OSIterator * iter;
OSObject * next;
IOPowerConnection * connection;
uint32_t desiredState = kPowerStateZero;
uint32_t newPowerState = kPowerStateZero;
bool hasChildren = false;
if (!fNumberOfPowerStates) {
fDesiredPowerState = kPowerStateZero;
return;
}
iter = getChildIterator(gIOPowerPlane);
if (iter) {
while ((next = iter->getNextObject())) {
if ((connection = OSDynamicCast(IOPowerConnection, next))) {
if (connection->getReadyFlag() == false) {
PM_LOG3("[%s] %s: connection not ready\n",
getName(), __FUNCTION__);
continue;
}
if (connection->childHasRequestedPower()) {
hasChildren = true;
}
desiredState = StateMax(connection->getDesiredDomainState(), desiredState);
}
}
iter->release();
}
if (hasChildren) {
updatePowerClient(gIOPMPowerClientChildren, desiredState);
} else {
removePowerClient(gIOPMPowerClientChildren);
}
iter = OSCollectionIterator::withCollection(fPowerClients);
if (iter) {
const OSSymbol * client;
while ((client = (const OSSymbol *) iter->getNextObject())) {
if ((fDeviceOverrideEnabled ||
(getPMRequestType() == kIOPMRequestTypeRequestPowerStateOverride)) &&
((client == gIOPMPowerClientChildren) ||
(client == gIOPMPowerClientDriver))) {
continue;
}
if (hasChildren && (client == gIOPMPowerClientChildProxy)) {
continue;
}
if (client == gIOPMPowerClientAdvisoryTickle &&
!gIOPMAdvisoryTickleEnabled) {
continue;
}
desiredState = getPowerStateForClient(client);
assert(desiredState < fNumberOfPowerStates);
PM_LOG1(" %u %s\n",
desiredState, client->getCStringNoCopy());
newPowerState = StateMax(newPowerState, desiredState);
if (client == gIOPMPowerClientDevice) {
fDeviceDesire = desiredState;
}
}
iter->release();
}
newPowerState = StateMax(newPowerState, localClamp);
newPowerState = StateMax(newPowerState, fTempClampPowerState);
newPowerState = StateMin(newPowerState, fOverrideMaxPowerState);
if (newPowerState >= fNumberOfPowerStates) {
newPowerState = fHighestPowerState;
}
#if !(defined(RC_HIDE_N144) || defined(RC_HIDE_N146))
if (getPMRootDomain()->isAOTMode()) {
if ((kIOPMPreventIdleSleep & fPowerStates[newPowerState].capabilityFlags)
&& !(kIOPMPreventIdleSleep & fPowerStates[fDesiredPowerState].capabilityFlags)) {
getPMRootDomain()->claimSystemWakeEvent(this, kIOPMWakeEventAOTExit, getName(), NULL);
}
}
#endif
fDesiredPowerState = newPowerState;
PM_LOG1(" temp %u, clamp %u, current %u, new %u\n",
(uint32_t) localClamp, (uint32_t) fTempClampPowerState,
(uint32_t) fCurrentPowerState, newPowerState);
if (!computeOnly) {
if (fIdleTimerPeriod && fIdleTimerStopped) {
restartIdleTimer();
}
if ((getPMRequestType() != kIOPMRequestTypeActivityTickle) &&
(fActivityTicklePowerState != kInvalidTicklePowerState)) {
IOLockLock(fActivityLock);
fActivityTicklePowerState = kInvalidTicklePowerState;
IOLockUnlock(fActivityLock);
}
}
}
unsigned long
IOService::currentPowerConsumption( void )
{
if (!initialized) {
return kIOPMUnknown;
}
return fCurrentPowerConsumption;
}
#ifndef __LP64__
IOWorkLoop *
IOService::getPMworkloop( void )
{
return gIOPMWorkLoop;
}
#endif
#if NOT_YET
static void
applyToPowerChildren(
IOService * service,
IOServiceApplierFunction applier,
void * context,
IOOptionBits options )
{
PM_ASSERT_IN_GATE();
IORegistryEntry * entry;
IORegistryIterator * iter;
IOPowerConnection * connection;
IOService * child;
iter = IORegistryIterator::iterateOver(service, gIOPowerPlane, options);
if (iter) {
while ((entry = iter->getNextObject())) {
if ((connection = OSDynamicCast(IOPowerConnection, entry))) {
child = (IOService *) connection->copyChildEntry(gIOPowerPlane);
if (child) {
(*applier)(child, context);
child->release();
}
}
}
iter->release();
}
}
static void
applyToPowerParent(
IOService * service,
IOServiceApplierFunction applier,
void * context,
IOOptionBits options )
{
PM_ASSERT_IN_GATE();
IORegistryEntry * entry;
IORegistryIterator * iter;
IOPowerConnection * connection;
IOService * parent;
iter = IORegistryIterator::iterateOver(service, gIOPowerPlane,
options | kIORegistryIterateParents);
if (iter) {
while ((entry = iter->getNextObject())) {
if ((connection = OSDynamicCast(IOPowerConnection, entry))) {
parent = (IOService *) connection->copyParentEntry(gIOPowerPlane);
if (parent) {
(*applier)(parent, context);
parent->release();
}
}
}
iter->release();
}
}
#endif
void
IOService::setAdvisoryTickleEnable( bool enable )
{
gIOPMAdvisoryTickleEnabled = enable;
}
bool
IOService::activityTickle( unsigned long type, unsigned long stateNumber )
{
IOPMRequest * request;
bool noPowerChange = true;
uint32_t tickleFlags;
if (!initialized) {
return true; }
if ((type == kIOPMSuperclassPolicy1) && StateOrder(stateNumber)) {
IOLockLock(fActivityLock);
fDeviceWasActive = true;
fActivityTickleCount++;
clock_get_uptime(&fDeviceActiveTimestamp);
PM_ACTION_0(actionActivityTickle);
if ((fActivityTicklePowerState == kInvalidTicklePowerState)
|| StateOrder(fActivityTicklePowerState) < StateOrder(stateNumber)) {
fActivityTicklePowerState = stateNumber;
noPowerChange = false;
tickleFlags = kTickleTypeActivity | kTickleTypePowerRise;
request = acquirePMRequest( this, kIOPMRequestTypeActivityTickle );
if (request) {
request->fArg0 = (void *) stateNumber;
request->fArg1 = (void *)(uintptr_t) tickleFlags;
request->fArg2 = (void *)(uintptr_t) gIOPMTickleGeneration;
submitPMRequest(request);
}
}
IOLockUnlock(fActivityLock);
} else if ((type == kIOPMActivityTickleTypeAdvisory) &&
((stateNumber = fDeviceUsablePowerState) != kPowerStateZero)) {
IOLockLock(fActivityLock);
fAdvisoryTickled = true;
if (fAdvisoryTicklePowerState != stateNumber) {
fAdvisoryTicklePowerState = stateNumber;
noPowerChange = false;
tickleFlags = kTickleTypeAdvisory | kTickleTypePowerRise;
request = acquirePMRequest( this, kIOPMRequestTypeActivityTickle );
if (request) {
request->fArg0 = (void *) stateNumber;
request->fArg1 = (void *)(uintptr_t) tickleFlags;
request->fArg2 = (void *)(uintptr_t) gIOPMTickleGeneration;
submitPMRequest(request);
}
}
IOLockUnlock(fActivityLock);
}
return noPowerChange;
}
void
IOService::handleActivityTickle( IOPMRequest * request )
{
uint32_t ticklePowerState = (uint32_t)(uintptr_t) request->fArg0;
uint32_t tickleFlags = (uint32_t)(uintptr_t) request->fArg1;
uint32_t tickleGeneration = (uint32_t)(uintptr_t) request->fArg2;
bool adjustPower = false;
PM_ASSERT_IN_GATE();
if (fResetPowerStateOnWake && (tickleGeneration != gIOPMTickleGeneration)) {
return;
}
if (tickleFlags & kTickleTypeActivity) {
IOPMPowerStateIndex deviceDesireOrder = StateOrder(fDeviceDesire);
uint32_t idleTimerGeneration = ticklePowerState;
if (tickleFlags & kTickleTypePowerRise) {
if ((StateOrder(ticklePowerState) > deviceDesireOrder) &&
(ticklePowerState < fNumberOfPowerStates)) {
fIdleTimerMinPowerState = ticklePowerState;
updatePowerClient(gIOPMPowerClientDevice, ticklePowerState);
adjustPower = true;
}
} else if ((deviceDesireOrder > StateOrder(fIdleTimerMinPowerState)) &&
(idleTimerGeneration == fIdleTimerGeneration)) {
deviceDesireOrder--;
if (deviceDesireOrder < fNumberOfPowerStates) {
ticklePowerState = fPowerStates[deviceDesireOrder].stateOrderToIndex;
updatePowerClient(gIOPMPowerClientDevice, ticklePowerState);
adjustPower = true;
}
}
} else { if (tickleFlags & kTickleTypePowerRise) {
if ((ticklePowerState == fDeviceUsablePowerState) &&
(ticklePowerState < fNumberOfPowerStates)) {
updatePowerClient(gIOPMPowerClientAdvisoryTickle, ticklePowerState);
fHasAdvisoryDesire = true;
fAdvisoryTickleUsed = true;
adjustPower = true;
} else {
IOLockLock(fActivityLock);
fAdvisoryTicklePowerState = kInvalidTicklePowerState;
IOLockUnlock(fActivityLock);
}
} else if (fHasAdvisoryDesire) {
removePowerClient(gIOPMPowerClientAdvisoryTickle);
fHasAdvisoryDesire = false;
adjustPower = true;
}
}
if (adjustPower) {
adjustPowerState();
}
}
IOReturn
IOService::setIdleTimerPeriod( unsigned long period )
{
if (!initialized) {
return IOPMNotYetInitialized;
}
OUR_PMLog(kPMLogSetIdleTimerPeriod, period, fIdleTimerPeriod);
IOPMRequest * request =
acquirePMRequest( this, kIOPMRequestTypeSetIdleTimerPeriod );
if (!request) {
return kIOReturnNoMemory;
}
request->fArg0 = (void *) period;
submitPMRequest( request );
return kIOReturnSuccess;
}
IOReturn
IOService::setIgnoreIdleTimer( bool ignore )
{
if (!initialized) {
return IOPMNotYetInitialized;
}
OUR_PMLog(kIOPMRequestTypeIgnoreIdleTimer, ignore, 0);
IOPMRequest * request =
acquirePMRequest( this, kIOPMRequestTypeIgnoreIdleTimer );
if (!request) {
return kIOReturnNoMemory;
}
request->fArg0 = (void *) ignore;
submitPMRequest( request );
return kIOReturnSuccess;
}
SInt32
IOService::nextIdleTimeout(
AbsoluteTime currentTime,
AbsoluteTime lastActivity,
unsigned int powerState)
{
AbsoluteTime delta;
UInt64 delta_ns;
SInt32 delta_secs;
SInt32 delay_secs;
delta = currentTime;
SUB_ABSOLUTETIME(&delta, &lastActivity);
absolutetime_to_nanoseconds(delta, &delta_ns);
delta_secs = (SInt32)(delta_ns / NSEC_PER_SEC);
if (delta_secs < (int) fIdleTimerPeriod) {
delay_secs = (int) fIdleTimerPeriod - delta_secs;
} else {
delay_secs = (int) fIdleTimerPeriod;
}
return (SInt32)delay_secs;
}
void
IOService::start_PM_idle_timer( void )
{
static const int maxTimeout = 100000;
static const int minTimeout = 1;
AbsoluteTime uptime, deadline;
SInt32 idle_in = 0;
boolean_t pending;
if (!initialized || !fIdleTimerPeriod) {
return;
}
IOLockLock(fActivityLock);
clock_get_uptime(&uptime);
idle_in = nextIdleTimeout(uptime, fDeviceActiveTimestamp, fCurrentPowerState);
if (idle_in > maxTimeout) {
idle_in = IOService::nextIdleTimeout(uptime,
fDeviceActiveTimestamp,
fCurrentPowerState);
} else if (idle_in < minTimeout) {
idle_in = fIdleTimerPeriod;
}
IOLockUnlock(fActivityLock);
fNextIdleTimerPeriod = idle_in;
fIdleTimerStartTime = uptime;
retain();
clock_interval_to_absolutetime_interval(idle_in, kSecondScale, &deadline);
ADD_ABSOLUTETIME(&deadline, &uptime);
pending = thread_call_enter_delayed(fIdleTimer, deadline);
if (pending) {
release();
}
}
void
IOService::restartIdleTimer( void )
{
if (fDeviceDesire != kPowerStateZero) {
fIdleTimerStopped = false;
fActivityTickleCount = 0;
start_PM_idle_timer();
} else if (fHasAdvisoryDesire) {
fIdleTimerStopped = false;
start_PM_idle_timer();
} else {
fIdleTimerStopped = true;
}
}
static void
idle_timer_expired(
thread_call_param_t arg0, thread_call_param_t arg1 )
{
IOService * me = (IOService *) arg0;
if (gIOPMWorkLoop) {
gIOPMWorkLoop->runAction(
OSMemberFunctionCast(IOWorkLoop::Action, me,
&IOService::idleTimerExpired),
me);
}
me->release();
}
void
IOService::idleTimerExpired( void )
{
IOPMRequest * request;
bool restartTimer = true;
uint32_t tickleFlags;
if (!initialized || !fIdleTimerPeriod || fIdleTimerStopped ||
fLockedFlags.PMStop) {
return;
}
fIdleTimerStartTime = 0;
IOLockLock(fActivityLock);
if (fDeviceWasActive) {
fDeviceWasActive = false;
} else if (!fIdleTimerIgnored) {
if ((fActivityTicklePowerState != kInvalidTicklePowerState) &&
(fActivityTicklePowerState != kPowerStateZero)) {
fActivityTicklePowerState--;
}
tickleFlags = kTickleTypeActivity | kTickleTypePowerDrop;
request = acquirePMRequest( this, kIOPMRequestTypeActivityTickle );
if (request) {
request->fArg0 = (void *)(uintptr_t) fIdleTimerGeneration;
request->fArg1 = (void *)(uintptr_t) tickleFlags;
request->fArg2 = (void *)(uintptr_t) gIOPMTickleGeneration;
submitPMRequest( request );
restartTimer = false;
}
}
if (fAdvisoryTickled) {
fAdvisoryTickled = false;
} else if (fHasAdvisoryDesire) {
fAdvisoryTicklePowerState = kInvalidTicklePowerState;
tickleFlags = kTickleTypeAdvisory | kTickleTypePowerDrop;
request = acquirePMRequest( this, kIOPMRequestTypeActivityTickle );
if (request) {
request->fArg0 = (void *)(uintptr_t) fIdleTimerGeneration;
request->fArg1 = (void *)(uintptr_t) tickleFlags;
request->fArg2 = (void *)(uintptr_t) gIOPMTickleGeneration;
submitPMRequest( request );
restartTimer = false;
}
}
IOLockUnlock(fActivityLock);
if (restartTimer) {
start_PM_idle_timer();
}
}
#ifndef __LP64__
void
IOService::PM_idle_timer_expiration( void )
{
}
void
IOService::command_received( void *statePtr, void *, void *, void * )
{
}
#endif
IOReturn
IOService::setAggressiveness( unsigned long type, unsigned long newLevel )
{
return kIOReturnSuccess;
}
IOReturn
IOService::getAggressiveness( unsigned long type, unsigned long * currentLevel )
{
IOPMrootDomain * rootDomain = getPMRootDomain();
if (!rootDomain) {
return kIOReturnNotReady;
}
return rootDomain->getAggressiveness( type, currentLevel );
}
UInt32
IOService::getPowerState( void )
{
if (!initialized) {
return kPowerStateZero;
}
return fCurrentPowerState;
}
#ifndef __LP64__
IOReturn
IOService::systemWake( void )
{
OSIterator * iter;
OSObject * next;
IOPowerConnection * connection;
IOService * theChild;
iter = getChildIterator(gIOPowerPlane);
if (iter) {
while ((next = iter->getNextObject())) {
if ((connection = OSDynamicCast(IOPowerConnection, next))) {
if (connection->getReadyFlag() == false) {
PM_LOG3("[%s] %s: connection not ready\n",
getName(), __FUNCTION__);
continue;
}
theChild = (IOService *)connection->copyChildEntry(gIOPowerPlane);
if (theChild) {
theChild->systemWake();
theChild->release();
}
}
}
iter->release();
}
if (fControllingDriver != NULL) {
if (fControllingDriver->didYouWakeSystem()) {
makeUsable();
}
}
return IOPMNoErr;
}
IOReturn
IOService::temperatureCriticalForZone( IOService * whichZone )
{
IOService * theParent;
IOService * theNub;
OUR_PMLog(kPMLogCriticalTemp, 0, 0);
if (inPlane(gIOPowerPlane) && !IS_PM_ROOT) {
theNub = (IOService *)copyParentEntry(gIOPowerPlane);
if (theNub) {
theParent = (IOService *)theNub->copyParentEntry(gIOPowerPlane);
theNub->release();
if (theParent) {
theParent->temperatureCriticalForZone(whichZone);
theParent->release();
}
}
}
return IOPMNoErr;
}
#endif
IOReturn
IOService::startPowerChange(
IOPMPowerChangeFlags changeFlags,
IOPMPowerStateIndex powerState,
IOPMPowerFlags domainFlags,
IOPowerConnection * parentConnection,
IOPMPowerFlags parentFlags )
{
uint32_t savedPMActionsParam;
PM_ASSERT_IN_GATE();
assert( fMachineState == kIOPM_Finished );
assert( powerState < fNumberOfPowerStates );
if (powerState >= fNumberOfPowerStates) {
return IOPMAckImplied;
}
fIsPreChange = true;
savedPMActionsParam = fPMActions.parameter;
PM_ACTION_2(actionPowerChangeOverride, &powerState, &changeFlags);
if (!fAdjustPowerScheduled &&
((changeFlags & kIOPMSelfInitiated) == 0) &&
((fPMActions.parameter & kPMActionsFlagLimitPower) == 0) &&
((savedPMActionsParam & kPMActionsFlagLimitPower) != 0)) {
IOPMRequest * request = acquirePMRequest(this, kIOPMRequestTypeAdjustPowerState);
if (request) {
submitPMRequest(request);
fAdjustPowerScheduled = true;
}
}
if (changeFlags & kIOPMExpireIdleTimer) {
if (StateOrder(fDeviceDesire) > StateOrder(powerState)) {
updatePowerClient(gIOPMPowerClientDevice, powerState);
computeDesiredState(kPowerStateZero, true);
IOLockLock(fActivityLock);
fDeviceWasActive = false;
fActivityTicklePowerState = kInvalidTicklePowerState;
IOLockUnlock(fActivityLock);
fIdleTimerMinPowerState = kPowerStateZero;
}
}
if (changeFlags & kIOPMNotDone) {
return IOPMAckImplied;
}
fHeadNoteChangeFlags = changeFlags;
fHeadNotePowerState = powerState;
fHeadNotePowerArrayEntry = &fPowerStates[powerState];
fHeadNoteParentConnection = NULL;
if (changeFlags & kIOPMSelfInitiated) {
if (changeFlags & kIOPMSynchronize) {
OurSyncStart();
} else {
OurChangeStart();
}
return 0;
} else {
assert(changeFlags & kIOPMParentInitiated);
fHeadNoteDomainFlags = domainFlags;
fHeadNoteParentFlags = parentFlags;
fHeadNoteParentConnection = parentConnection;
return ParentChangeStart();
}
}
bool
IOService::notifyInterestedDrivers( void )
{
IOPMinformee * informee;
IOPMinformeeList * list = fInterestedDrivers;
DriverCallParam * param;
IOItemCount count;
IOItemCount skipCnt = 0;
PM_ASSERT_IN_GATE();
assert( fDriverCallParamCount == 0 );
assert( fHeadNotePendingAcks == 0 );
fHeadNotePendingAcks = 0;
count = list->numberOfItems();
if (!count) {
goto done; }
param = (DriverCallParam *) fDriverCallParamPtr;
if (count > fDriverCallParamSlots) {
if (fDriverCallParamSlots) {
assert(fDriverCallParamPtr);
IODelete(fDriverCallParamPtr, DriverCallParam, fDriverCallParamSlots);
fDriverCallParamPtr = NULL;
fDriverCallParamSlots = 0;
}
param = IONew(DriverCallParam, count);
if (!param) {
goto done; }
fDriverCallParamPtr = (void *) param;
fDriverCallParamSlots = count;
}
informee = list->firstInList();
assert(informee);
for (IOItemCount i = 0; i < count; i++) {
if (fInitialSetPowerState || (fHeadNoteChangeFlags & kIOPMInitialPowerChange)) {
if ((this == informee->whatObject) &&
(fHeadNotePowerArrayEntry->capabilityFlags & kIOPMInitialDeviceState)) {
skipCnt++;
continue;
}
}
informee->timer = -1;
param[i].Target = informee;
informee->retain();
informee = list->nextInList( informee );
}
count -= skipCnt;
if (!count) {
goto done;
}
fDriverCallParamCount = count;
fHeadNotePendingAcks = count;
assert(!fDriverCallBusy);
fDriverCallBusy = true;
thread_call_enter( fDriverCallEntry );
return true;
done:
return false;
}
void
IOService::notifyInterestedDriversDone( void )
{
IOPMinformee * informee;
IOItemCount count;
DriverCallParam * param;
IOReturn result;
int maxTimeout = 0;
PM_ASSERT_IN_GATE();
assert( fDriverCallBusy == false );
assert( fMachineState == kIOPM_DriverThreadCallDone );
param = (DriverCallParam *) fDriverCallParamPtr;
count = fDriverCallParamCount;
if (param && count) {
for (IOItemCount i = 0; i < count; i++, param++) {
informee = (IOPMinformee *) param->Target;
result = param->Result;
if ((result == IOPMAckImplied) || (result < 0)) {
if (fHeadNotePendingAcks && informee->timer) {
fHeadNotePendingAcks--;
}
informee->timer = 0;
} else if (informee->timer) {
assert(informee->timer == -1);
if (result < kMinAckTimeoutTicks) {
result = kMinAckTimeoutTicks;
}
informee->timer = (result / (ACK_TIMER_PERIOD / ns_per_us)) + 1;
if (result > maxTimeout) {
maxTimeout = result;
}
}
informee->release();
}
fDriverCallParamCount = 0;
if (fHeadNotePendingAcks) {
OUR_PMLog(kPMLogStartAckTimer, 0, 0);
start_ack_timer();
getPMRootDomain()->reset_watchdog_timer(this, maxTimeout / USEC_PER_SEC + 1);
}
}
MS_POP();
if (!fHeadNotePendingAcks) {
notifyRootDomain();
} else {
MS_PUSH(fMachineState);
fMachineState = kIOPM_NotifyChildrenStart;
}
}
void
IOService::notifyRootDomain( void )
{
assert( fDriverCallBusy == false );
if (!IS_ROOT_DOMAIN || (fMachineState != kIOPM_OurChangeSetPowerState)) {
notifyChildren();
return;
}
MS_PUSH(fMachineState); fMachineState = kIOPM_DriverThreadCallDone;
fDriverCallReason = kRootDomainInformPreChange;
fDriverCallBusy = true;
thread_call_enter( fDriverCallEntry );
}
void
IOService::notifyRootDomainDone( void )
{
assert( fDriverCallBusy == false );
assert( fMachineState == kIOPM_DriverThreadCallDone );
MS_POP(); notifyChildren();
}
void
IOService::notifyChildren( void )
{
OSIterator * iter;
OSObject * next;
IOPowerConnection * connection;
OSArray * children = NULL;
IOPMrootDomain * rootDomain;
bool delayNotify = false;
if ((fHeadNotePowerState != fCurrentPowerState) &&
(IS_POWER_DROP == fIsPreChange) &&
((rootDomain = getPMRootDomain()) == this)) {
rootDomain->tracePoint( IS_POWER_DROP ?
kIOPMTracePointSleepPowerPlaneDrivers :
kIOPMTracePointWakePowerPlaneDrivers );
}
if (fStrictTreeOrder) {
children = OSArray::withCapacity(8);
}
fHeadNotePowerArrayEntry->staticPower = 0;
iter = getChildIterator(gIOPowerPlane);
if (iter) {
while ((next = iter->getNextObject())) {
if ((connection = OSDynamicCast(IOPowerConnection, next))) {
if (connection->getReadyFlag() == false) {
PM_LOG3("[%s] %s: connection not ready\n",
getName(), __FUNCTION__);
continue;
}
if (!fIsPreChange &&
connection->delayChildNotification &&
getPMRootDomain()->shouldDelayChildNotification(this)) {
if (!children) {
children = OSArray::withCapacity(8);
if (children) {
delayNotify = true;
}
}
if (delayNotify) {
children->setObject( connection );
continue;
}
}
if (!delayNotify && children) {
children->setObject( connection );
} else {
notifyChild( connection );
}
}
}
iter->release();
}
if (children && (children->getCount() == 0)) {
children->release();
children = NULL;
}
if (children) {
assert(fNotifyChildArray == NULL);
fNotifyChildArray = children;
MS_PUSH(fMachineState);
if (delayNotify) {
fMachineState = kIOPM_NotifyChildrenDelayed;
PM_LOG2("%s: %d children in delayed array\n",
getName(), children->getCount());
} else {
fMachineState = kIOPM_NotifyChildrenOrdered;
}
}
}
void
IOService::notifyChildrenOrdered( void )
{
PM_ASSERT_IN_GATE();
assert(fNotifyChildArray);
assert(fMachineState == kIOPM_NotifyChildrenOrdered);
if (fNotifyChildArray->getCount()) {
IOPowerConnection * connection;
connection = (IOPowerConnection *) fNotifyChildArray->getObject(0);
notifyChild( connection );
fNotifyChildArray->removeObject(0);
} else {
fNotifyChildArray->release();
fNotifyChildArray = NULL;
MS_POP(); }
}
void
IOService::notifyChildrenDelayed( void )
{
IOPowerConnection * connection;
PM_ASSERT_IN_GATE();
assert(fNotifyChildArray);
assert(fMachineState == kIOPM_NotifyChildrenDelayed);
for (int i = 0;; i++) {
connection = (IOPowerConnection *) fNotifyChildArray->getObject(i);
if (!connection) {
break;
}
notifyChild( connection );
}
PM_LOG2("%s: notified delayed children\n", getName());
fNotifyChildArray->release();
fNotifyChildArray = NULL;
MS_POP(); }
IOReturn
IOService::notifyAll( uint32_t nextMS )
{
PM_ASSERT_IN_GATE();
MS_PUSH(nextMS);
fMachineState = kIOPM_DriverThreadCallDone;
fDriverCallReason = fIsPreChange ?
kDriverCallInformPreChange : kDriverCallInformPostChange;
if (!notifyInterestedDrivers()) {
notifyInterestedDriversDone();
}
return IOPMWillAckLater;
}
IOReturn
IOService::actionDriverCalloutDone(
OSObject * target,
void * arg0, void * arg1,
void * arg2, void * arg3 )
{
IOServicePM * pwrMgt = (IOServicePM *) arg0;
assert( fDriverCallBusy );
fDriverCallBusy = false;
assert(gIOPMWorkQueue);
gIOPMWorkQueue->signalWorkAvailable();
return kIOReturnSuccess;
}
void
IOService::pmDriverCallout( IOService * from )
{
assert(from);
switch (from->fDriverCallReason) {
case kDriverCallSetPowerState:
from->driverSetPowerState();
break;
case kDriverCallInformPreChange:
case kDriverCallInformPostChange:
from->driverInformPowerChange();
break;
case kRootDomainInformPreChange:
getPMRootDomain()->willNotifyPowerChildren(from->fHeadNotePowerState);
break;
default:
panic("IOService::pmDriverCallout bad machine state %x",
from->fDriverCallReason);
}
gIOPMWorkLoop->runAction(actionDriverCalloutDone,
from,
(void *) from->pwrMgt );
}
void
IOService::driverSetPowerState( void )
{
IOPMPowerStateIndex powerState;
DriverCallParam * param;
IOPMDriverCallEntry callEntry;
AbsoluteTime end;
IOReturn result;
uint32_t oldPowerState = getPowerState();
assert( fDriverCallBusy );
assert( fDriverCallParamPtr );
assert( fDriverCallParamCount == 1 );
param = (DriverCallParam *) fDriverCallParamPtr;
powerState = fHeadNotePowerState;
if (assertPMDriverCall(&callEntry, kIOPMDriverCallMethodSetPowerState)) {
OUR_PMLogFuncStart(kPMLogProgramHardware, (uintptr_t) this, powerState);
clock_get_uptime(&fDriverCallStartTime);
result = fControllingDriver->setPowerState( powerState, this );
clock_get_uptime(&end);
OUR_PMLogFuncEnd(kPMLogProgramHardware, (uintptr_t) this, (UInt32) result);
deassertPMDriverCall(&callEntry);
if (powerState == fHighestPowerState) {
fMaxPowerStateEntryTime = end;
} else if (oldPowerState == fHighestPowerState) {
fMaxPowerStateExitTime = end;
}
if (result < 0) {
PM_LOG("%s::setPowerState(%p, %lu -> %lu) returned 0x%x\n",
fName, OBFUSCATE(this), fCurrentPowerState, powerState, result);
}
if ((result == IOPMAckImplied) || (result < 0)) {
uint64_t nsec;
SUB_ABSOLUTETIME(&end, &fDriverCallStartTime);
absolutetime_to_nanoseconds(end, &nsec);
if (nsec > LOG_SETPOWER_TIMES) {
getPMRootDomain()->pmStatsRecordApplicationResponse(
gIOPMStatsDriverPSChangeSlow,
fName, kDriverCallSetPowerState, NS_TO_MS(nsec), getRegistryEntryID(),
NULL, powerState);
}
}
} else {
result = kIOPMAckImplied;
}
param->Result = result;
}
void
IOService::driverInformPowerChange( void )
{
IOPMinformee * informee;
IOService * driver;
DriverCallParam * param;
IOPMDriverCallEntry callEntry;
IOPMPowerFlags powerFlags;
IOPMPowerStateIndex powerState;
AbsoluteTime end;
IOReturn result;
IOItemCount count;
IOOptionBits callMethod = (fDriverCallReason == kDriverCallInformPreChange) ?
kIOPMDriverCallMethodWillChange : kIOPMDriverCallMethodDidChange;
assert( fDriverCallBusy );
assert( fDriverCallParamPtr );
assert( fDriverCallParamCount );
param = (DriverCallParam *) fDriverCallParamPtr;
count = fDriverCallParamCount;
powerFlags = fHeadNotePowerArrayEntry->capabilityFlags;
powerState = fHeadNotePowerState;
for (IOItemCount i = 0; i < count; i++) {
informee = (IOPMinformee *) param->Target;
driver = informee->whatObject;
if (assertPMDriverCall(&callEntry, callMethod, informee)) {
if (fDriverCallReason == kDriverCallInformPreChange) {
OUR_PMLogFuncStart(kPMLogInformDriverPreChange, (uintptr_t) this, powerState);
clock_get_uptime(&informee->startTime);
result = driver->powerStateWillChangeTo(powerFlags, powerState, this);
clock_get_uptime(&end);
OUR_PMLogFuncEnd(kPMLogInformDriverPreChange, (uintptr_t) this, result);
} else {
OUR_PMLogFuncStart(kPMLogInformDriverPostChange, (uintptr_t) this, powerState);
clock_get_uptime(&informee->startTime);
result = driver->powerStateDidChangeTo(powerFlags, powerState, this);
clock_get_uptime(&end);
OUR_PMLogFuncEnd(kPMLogInformDriverPostChange, (uintptr_t) this, result);
}
deassertPMDriverCall(&callEntry);
if ((result == IOPMAckImplied) || (result < 0)) {
uint64_t nsec;
SUB_ABSOLUTETIME(&end, &informee->startTime);
absolutetime_to_nanoseconds(end, &nsec);
if (nsec > LOG_SETPOWER_TIMES) {
getPMRootDomain()->pmStatsRecordApplicationResponse(
gIOPMStatsDriverPSChangeSlow, driver->getName(),
fDriverCallReason, NS_TO_MS(nsec), driver->getRegistryEntryID(),
NULL, powerState);
}
}
} else {
result = kIOPMAckImplied;
}
param->Result = result;
param++;
}
}
bool
IOService::notifyChild( IOPowerConnection * theNub )
{
IOReturn ret = IOPMAckImplied;
unsigned long childPower;
IOService * theChild;
IOPMRequest * childRequest;
IOPMPowerChangeFlags requestArg2;
int requestType;
PM_ASSERT_IN_GATE();
theChild = (IOService *)(theNub->copyChildEntry(gIOPowerPlane));
if (!theChild) {
return true;
}
fHeadNotePendingAcks++;
theNub->setAwaitingAck(true);
requestArg2 = fHeadNoteChangeFlags;
if (StateOrder(fHeadNotePowerState) < StateOrder(fCurrentPowerState)) {
requestArg2 |= kIOPMDomainPowerDrop;
}
requestType = fIsPreChange ?
kIOPMRequestTypePowerDomainWillChange :
kIOPMRequestTypePowerDomainDidChange;
childRequest = acquirePMRequest( theChild, requestType );
if (childRequest) {
theNub->retain();
childRequest->fArg0 = (void *) fHeadNotePowerArrayEntry->outputPowerFlags;
childRequest->fArg1 = (void *) theNub;
childRequest->fArg2 = (void *)(uintptr_t) requestArg2;
theChild->submitPMRequest( childRequest );
ret = IOPMWillAckLater;
} else {
ret = IOPMAckImplied;
fHeadNotePendingAcks--;
theNub->setAwaitingAck(false);
childPower = theChild->currentPowerConsumption();
if (childPower == kIOPMUnknown) {
fHeadNotePowerArrayEntry->staticPower = kIOPMUnknown;
} else {
if (fHeadNotePowerArrayEntry->staticPower != kIOPMUnknown) {
fHeadNotePowerArrayEntry->staticPower += childPower;
}
}
}
theChild->release();
return IOPMAckImplied == ret;
}
bool
IOService::notifyControllingDriver( void )
{
DriverCallParam * param;
PM_ASSERT_IN_GATE();
assert( fDriverCallParamCount == 0 );
assert( fControllingDriver );
if (fInitialSetPowerState) {
fInitialSetPowerState = false;
fHeadNoteChangeFlags |= kIOPMInitialPowerChange;
if (fHeadNotePowerArrayEntry->capabilityFlags & kIOPMInitialDeviceState) {
return false;
}
}
param = (DriverCallParam *) fDriverCallParamPtr;
if (!param) {
param = IONew(DriverCallParam, 1);
if (!param) {
return false; }
fDriverCallParamPtr = (void *) param;
fDriverCallParamSlots = 1;
}
param->Target = fControllingDriver;
fDriverCallParamCount = 1;
fDriverTimer = -1;
assert(!fDriverCallBusy);
fDriverCallBusy = true;
thread_call_enter( fDriverCallEntry );
return true;
}
void
IOService::notifyControllingDriverDone( void )
{
DriverCallParam * param;
IOReturn result;
PM_ASSERT_IN_GATE();
param = (DriverCallParam *) fDriverCallParamPtr;
assert( fDriverCallBusy == false );
assert( fMachineState == kIOPM_DriverThreadCallDone );
if (param && fDriverCallParamCount) {
assert(fDriverCallParamCount == 1);
result = param->Result;
if ((result == IOPMAckImplied) || (result < 0)) {
fDriverTimer = 0;
} else if (fDriverTimer) {
assert(fDriverTimer == -1);
if (result < kMinAckTimeoutTicks) {
result = kMinAckTimeoutTicks;
}
fDriverTimer = (result / (ACK_TIMER_PERIOD / ns_per_us)) + 1;
}
fDriverCallParamCount = 0;
if (fDriverTimer) {
OUR_PMLog(kPMLogStartAckTimer, 0, 0);
start_ack_timer();
getPMRootDomain()->reset_watchdog_timer(this, result / USEC_PER_SEC + 1);
}
}
MS_POP(); fIsPreChange = false;
}
void
IOService::all_done( void )
{
IOPMPowerStateIndex prevPowerState;
const IOPMPSEntry * powerStatePtr;
IOPMDriverCallEntry callEntry;
uint32_t prevMachineState = fMachineState;
bool actionCalled = false;
uint64_t ts;
fMachineState = kIOPM_Finished;
if ((fHeadNoteChangeFlags & kIOPMSynchronize) &&
((prevMachineState == kIOPM_Finished) ||
(prevMachineState == kIOPM_SyncFinish))) {
PM_ACTION_2(actionPowerChangeDone,
fHeadNotePowerState, fHeadNoteChangeFlags);
if (getPMRequestType() == kIOPMRequestTypeSynchronizePowerTree) {
powerChangeDone(fCurrentPowerState);
} else if (fAdvisoryTickleUsed) {
if (!fAdjustPowerScheduled &&
(fHeadNoteChangeFlags & kIOPMDomainDidChange)) {
IOPMRequest * request;
request = acquirePMRequest( this, kIOPMRequestTypeAdjustPowerState );
if (request) {
submitPMRequest( request );
fAdjustPowerScheduled = true;
}
}
}
return;
}
if (fHeadNoteChangeFlags & kIOPMSelfInitiated) {
if ((fHeadNoteChangeFlags & kIOPMNotDone) == 0) {
trackSystemSleepPreventers(
fCurrentPowerState, fHeadNotePowerState, fHeadNoteChangeFlags);
requestDomainPower(fHeadNotePowerState);
if (StateOrder(fCurrentPowerState) < StateOrder(fHeadNotePowerState)) {
tellChangeUp(fHeadNotePowerState);
}
prevPowerState = fCurrentPowerState;
fCurrentPowerState = fHeadNotePowerState;
PM_LOCK();
if (fReportBuf) {
ts = mach_absolute_time();
STATEREPORT_SETSTATE(fReportBuf, fCurrentPowerState, ts);
}
PM_UNLOCK();
#if PM_VARS_SUPPORT
fPMVars->myCurrentState = fCurrentPowerState;
#endif
OUR_PMLog(kPMLogChangeDone, fCurrentPowerState, prevPowerState);
PM_ACTION_2(actionPowerChangeDone,
fHeadNotePowerState, fHeadNoteChangeFlags);
actionCalled = true;
powerStatePtr = &fPowerStates[fCurrentPowerState];
fCurrentCapabilityFlags = powerStatePtr->capabilityFlags;
if (fCurrentCapabilityFlags & kIOPMStaticPowerValid) {
fCurrentPowerConsumption = powerStatePtr->staticPower;
}
if (fHeadNoteChangeFlags & kIOPMRootChangeDown) {
gIOPMTickleGeneration++;
}
if (fPCDFunctionOverride && fParentsKnowState &&
assertPMDriverCall(&callEntry, kIOPMDriverCallMethodChangeDone, NULL, kIOPMDriverCallNoInactiveCheck)) {
powerChangeDone(prevPowerState);
deassertPMDriverCall(&callEntry);
}
} else if (getPMRequestType() == kIOPMRequestTypeRequestPowerStateOverride) {
fOverrideMaxPowerState = kIOPMPowerStateMax;
}
}
if (fHeadNoteChangeFlags & kIOPMParentInitiated) {
if (fHeadNoteChangeFlags & kIOPMRootChangeDown) {
ParentChangeRootChangeDown();
}
if ((fHeadNoteChangeFlags & kIOPMNotDone) == 0) {
trackSystemSleepPreventers(
fCurrentPowerState, fHeadNotePowerState, fHeadNoteChangeFlags);
if (StateOrder(fCurrentPowerState) < StateOrder(fHeadNotePowerState)) {
tellChangeUp(fHeadNotePowerState);
}
prevPowerState = fCurrentPowerState;
fCurrentPowerState = fHeadNotePowerState;
PM_LOCK();
if (fReportBuf) {
ts = mach_absolute_time();
STATEREPORT_SETSTATE(fReportBuf, fCurrentPowerState, ts);
}
PM_UNLOCK();
#if PM_VARS_SUPPORT
fPMVars->myCurrentState = fCurrentPowerState;
#endif
OUR_PMLog(kPMLogChangeDone, fCurrentPowerState, prevPowerState);
PM_ACTION_2(actionPowerChangeDone,
fHeadNotePowerState, fHeadNoteChangeFlags);
actionCalled = true;
powerStatePtr = &fPowerStates[fCurrentPowerState];
fCurrentCapabilityFlags = powerStatePtr->capabilityFlags;
if (fCurrentCapabilityFlags & kIOPMStaticPowerValid) {
fCurrentPowerConsumption = powerStatePtr->staticPower;
}
if (fPCDFunctionOverride && fParentsKnowState &&
assertPMDriverCall(&callEntry, kIOPMDriverCallMethodChangeDone, NULL, kIOPMDriverCallNoInactiveCheck)) {
powerChangeDone(prevPowerState);
deassertPMDriverCall(&callEntry);
}
}
}
if (StateOrder(fCurrentPowerState) >= StateOrder(fIdleTimerMinPowerState)) {
fIdleTimerMinPowerState = kPowerStateZero;
}
if (!actionCalled) {
PM_ACTION_2(actionPowerChangeDone,
fHeadNotePowerState, fHeadNoteChangeFlags);
}
}
void
IOService::OurChangeStart( void )
{
PM_ASSERT_IN_GATE();
OUR_PMLog( kPMLogStartDeviceChange, fHeadNotePowerState, fCurrentPowerState );
if (!IS_PM_ROOT && (StateOrder(fMaxPowerState) < StateOrder(fHeadNotePowerState))) {
fHeadNoteChangeFlags |= kIOPMNotDone;
requestDomainPower(fHeadNotePowerState);
OurChangeFinish();
return;
}
if (!fInitialPowerChange && (fHeadNotePowerState == fCurrentPowerState)) {
OurChangeFinish();
return;
}
fInitialPowerChange = false;
PM_ACTION_2(actionPowerChangeStart, fHeadNotePowerState, &fHeadNoteChangeFlags);
if (IS_POWER_DROP) {
fDoNotPowerDown = false;
fMachineState = kIOPM_OurChangeTellClientsPowerDown;
fOutOfBandParameter = kNotifyApps;
askChangeDown(fHeadNotePowerState);
} else {
IOReturn ret;
ret = requestDomainPower( fHeadNotePowerState, kReserveDomainPower );
if (ret != kIOReturnSuccess) {
fHeadNoteChangeFlags |= kIOPMNotDone;
OurChangeFinish();
return;
}
OurChangeTellCapabilityWillChange();
}
}
struct IOPMRequestDomainPowerContext {
IOService * child; IOPMPowerFlags requestPowerFlags;};
static void
requestDomainPowerApplier(
IORegistryEntry * entry,
void * inContext )
{
IOPowerConnection * connection;
IOService * parent;
IOPMRequestDomainPowerContext * context;
if ((connection = OSDynamicCast(IOPowerConnection, entry)) == NULL) {
return;
}
parent = (IOService *) connection->copyParentEntry(gIOPowerPlane);
if (!parent) {
return;
}
assert(inContext);
context = (IOPMRequestDomainPowerContext *) inContext;
if (connection->parentKnowsState() && connection->getReadyFlag()) {
parent->requestPowerDomainState(
context->requestPowerFlags,
connection,
IOPMLowestState);
}
parent->release();
}
IOReturn
IOService::requestDomainPower(
IOPMPowerStateIndex ourPowerState,
IOOptionBits options )
{
IOPMPowerFlags requestPowerFlags;
IOPMPowerStateIndex maxPowerState;
IOPMRequestDomainPowerContext context;
PM_ASSERT_IN_GATE();
assert(ourPowerState < fNumberOfPowerStates);
if (ourPowerState >= fNumberOfPowerStates) {
return kIOReturnBadArgument;
}
if (IS_PM_ROOT) {
return kIOReturnSuccess;
}
requestPowerFlags = fPowerStates[ourPowerState].inputPowerFlags;
if (((options & kReserveDomainPower) == 0) &&
(fPreviousRequestPowerFlags == requestPowerFlags)) {
goto done;
}
fPreviousRequestPowerFlags = requestPowerFlags;
context.child = this;
context.requestPowerFlags = requestPowerFlags;
fHeadNoteDomainTargetFlags = 0;
applyToParents(requestDomainPowerApplier, &context, gIOPowerPlane);
if (options & kReserveDomainPower) {
maxPowerState = fControllingDriver->maxCapabilityForDomainState(
fHeadNoteDomainTargetFlags );
if (StateOrder(maxPowerState) < StateOrder(ourPowerState)) {
PM_LOG1("%s: power desired %u:0x%x got %u:0x%x\n",
getName(),
(uint32_t) ourPowerState, (uint32_t) requestPowerFlags,
(uint32_t) maxPowerState, (uint32_t) fHeadNoteDomainTargetFlags);
return kIOReturnNoPower;
}
}
done:
return kIOReturnSuccess;
}
void
IOService::OurSyncStart( void )
{
PM_ASSERT_IN_GATE();
if (fInitialPowerChange) {
return;
}
PM_ACTION_2(actionPowerChangeStart, fHeadNotePowerState, &fHeadNoteChangeFlags);
if (fHeadNoteChangeFlags & kIOPMNotDone) {
OurChangeFinish();
return;
}
if (fHeadNoteChangeFlags & kIOPMSyncTellPowerDown) {
fDoNotPowerDown = false;
fMachineState = kIOPM_SyncTellClientsPowerDown;
fOutOfBandParameter = kNotifyApps;
askChangeDown(fHeadNotePowerState);
} else {
tellSystemCapabilityChange( kIOPM_SyncNotifyWillChange );
}
}
void
IOService::OurChangeTellClientsPowerDown( void )
{
if (!IS_ROOT_DOMAIN) {
fMachineState = kIOPM_OurChangeTellPriorityClientsPowerDown;
} else {
fMachineState = kIOPM_OurChangeTellUserPMPolicyPowerDown;
}
tellChangeDown1(fHeadNotePowerState);
}
void
IOService::OurChangeTellUserPMPolicyPowerDown( void )
{
fMachineState = kIOPM_OurChangeTellPriorityClientsPowerDown;
fOutOfBandParameter = kNotifyApps;
tellClientsWithResponse(kIOPMMessageLastCallBeforeSleep);
}
void
IOService::OurChangeTellPriorityClientsPowerDown( void )
{
fMachineState = kIOPM_OurChangeNotifyInterestedDriversWillChange;
tellChangeDown2(fHeadNotePowerState);
}
void
IOService::OurChangeTellCapabilityWillChange( void )
{
if (!IS_ROOT_DOMAIN) {
return OurChangeNotifyInterestedDriversWillChange();
}
tellSystemCapabilityChange( kIOPM_OurChangeNotifyInterestedDriversWillChange );
}
void
IOService::OurChangeNotifyInterestedDriversWillChange( void )
{
IOPMrootDomain * rootDomain;
if ((rootDomain = getPMRootDomain()) == this) {
if (IS_POWER_DROP) {
rootDomain->tracePoint( kIOPMTracePointSleepWillChangeInterests );
} else {
rootDomain->tracePoint( kIOPMTracePointWakeWillChangeInterests );
}
}
notifyAll( kIOPM_OurChangeSetPowerState );
}
void
IOService::OurChangeSetPowerState( void )
{
MS_PUSH( kIOPM_OurChangeWaitForPowerSettle );
fMachineState = kIOPM_DriverThreadCallDone;
fDriverCallReason = kDriverCallSetPowerState;
if (notifyControllingDriver() == false) {
notifyControllingDriverDone();
}
}
void
IOService::OurChangeWaitForPowerSettle( void )
{
fMachineState = kIOPM_OurChangeNotifyInterestedDriversDidChange;
startSettleTimer();
}
void
IOService::OurChangeNotifyInterestedDriversDidChange( void )
{
IOPMrootDomain * rootDomain;
if ((rootDomain = getPMRootDomain()) == this) {
rootDomain->tracePoint( IS_POWER_DROP ?
kIOPMTracePointSleepDidChangeInterests :
kIOPMTracePointWakeDidChangeInterests );
}
notifyAll( kIOPM_OurChangeTellCapabilityDidChange );
}
void
IOService::OurChangeTellCapabilityDidChange( void )
{
if (!IS_ROOT_DOMAIN) {
return OurChangeFinish();
}
getPMRootDomain()->tracePoint( IS_POWER_DROP ?
kIOPMTracePointSleepCapabilityClients :
kIOPMTracePointWakeCapabilityClients );
tellSystemCapabilityChange( kIOPM_OurChangeFinish );
}
void
IOService::OurChangeFinish( void )
{
all_done();
}
IOReturn
IOService::ParentChangeStart( void )
{
PM_ASSERT_IN_GATE();
OUR_PMLog( kPMLogStartParentChange, fHeadNotePowerState, fCurrentPowerState );
if ((fHeadNoteChangeFlags & (kIOPMDomainDidChange | kIOPMRootChangeUp)) ==
(kIOPMDomainDidChange | kIOPMRootChangeUp)) {
if (fIdleTimerPeriod && fIdleTimerStopped) {
restartIdleTimer();
}
}
if (StateOrder(fHeadNotePowerState) < StateOrder(fCurrentPowerState)) {
PM_ACTION_2(actionPowerChangeStart, fHeadNotePowerState, &fHeadNoteChangeFlags);
fInitialPowerChange = false;
fMachineState = kIOPM_ParentChangeTellPriorityClientsPowerDown;
tellChangeDown1(fHeadNotePowerState);
return IOPMWillAckLater;
}
if (StateOrder(fHeadNotePowerState) > StateOrder(fCurrentPowerState)) {
if (StateOrder(fDesiredPowerState) > StateOrder(fCurrentPowerState)) {
if (StateOrder(fDesiredPowerState) < StateOrder(fHeadNotePowerState)) {
fHeadNotePowerState = fDesiredPowerState;
fHeadNotePowerArrayEntry = &fPowerStates[fDesiredPowerState];
OUR_PMLog(kPMLogAmendParentChange, fHeadNotePowerState, 0);
}
} else {
fHeadNotePowerState = fCurrentPowerState;
fHeadNotePowerArrayEntry = &fPowerStates[fCurrentPowerState];
OUR_PMLog(kPMLogAmendParentChange, fHeadNotePowerState, 0);
}
}
if (fHeadNoteChangeFlags & kIOPMDomainDidChange) {
if (StateOrder(fHeadNotePowerState) > StateOrder(fCurrentPowerState)) {
PM_ACTION_2(actionPowerChangeStart,
fHeadNotePowerState, &fHeadNoteChangeFlags);
fInitialPowerChange = false;
ParentChangeTellCapabilityWillChange();
return IOPMWillAckLater;
} else if (fHeadNoteChangeFlags & kIOPMRootBroadcastFlags) {
fMachineState = kIOPM_SyncNotifyDidChange;
fDriverCallReason = kDriverCallInformPreChange;
fHeadNoteChangeFlags |= kIOPMNotDone;
notifyChildren();
return IOPMWillAckLater;
}
}
fHeadNoteChangeFlags |= kIOPMNotDone;
all_done();
return IOPMAckImplied;
}
void
IOService::ParentChangeRootChangeDown( void )
{
if (fIdleTimerPeriod && !fIdleTimerStopped) {
fIdleTimerStopped = true;
if (fIdleTimer && thread_call_cancel(fIdleTimer)) {
release();
}
}
if (fResetPowerStateOnWake) {
if (fDeviceDesire != kPowerStateZero) {
updatePowerClient(gIOPMPowerClientDevice, kPowerStateZero);
computeDesiredState(kPowerStateZero, true);
requestDomainPower( fDesiredPowerState );
PM_LOG1("%s: tickle desire removed\n", fName);
}
IOLockLock(fActivityLock);
fDeviceWasActive = false;
fActivityTicklePowerState = kInvalidTicklePowerState;
IOLockUnlock(fActivityLock);
fIdleTimerMinPowerState = kPowerStateZero;
} else if (fAdvisoryTickleUsed) {
AbsoluteTime now;
uint64_t nsec;
bool dropTickleDesire = false;
if (fIdleTimerPeriod && !fIdleTimerIgnored &&
(fIdleTimerMinPowerState == kPowerStateZero) &&
(fDeviceDesire != kPowerStateZero)) {
IOLockLock(fActivityLock);
if (!fDeviceWasActive) {
dropTickleDesire = true;
} else {
clock_get_uptime(&now);
SUB_ABSOLUTETIME(&now, &fDeviceActiveTimestamp);
absolutetime_to_nanoseconds(now, &nsec);
if (nsec >= kNoTickleCancelWindow) {
dropTickleDesire = true;
}
}
if (dropTickleDesire) {
fDeviceWasActive = false;
fActivityTicklePowerState = kInvalidTicklePowerState;
}
IOLockUnlock(fActivityLock);
}
if (dropTickleDesire) {
updatePowerClient(gIOPMPowerClientDevice, kPowerStateZero);
computeDesiredState(kPowerStateZero, true);
PM_LOG1("%s: tickle desire dropped\n", fName);
}
}
}
void
IOService::ParentChangeTellPriorityClientsPowerDown( void )
{
fMachineState = kIOPM_ParentChangeNotifyInterestedDriversWillChange;
tellChangeDown2(fHeadNotePowerState);
}
void
IOService::ParentChangeTellCapabilityWillChange( void )
{
if (!IS_ROOT_DOMAIN) {
return ParentChangeNotifyInterestedDriversWillChange();
}
tellSystemCapabilityChange( kIOPM_ParentChangeNotifyInterestedDriversWillChange );
}
void
IOService::ParentChangeNotifyInterestedDriversWillChange( void )
{
notifyAll( kIOPM_ParentChangeSetPowerState );
}
void
IOService::ParentChangeSetPowerState( void )
{
MS_PUSH( kIOPM_ParentChangeWaitForPowerSettle );
fMachineState = kIOPM_DriverThreadCallDone;
fDriverCallReason = kDriverCallSetPowerState;
if (notifyControllingDriver() == false) {
notifyControllingDriverDone();
}
}
void
IOService::ParentChangeWaitForPowerSettle( void )
{
fMachineState = kIOPM_ParentChangeNotifyInterestedDriversDidChange;
startSettleTimer();
}
void
IOService::ParentChangeNotifyInterestedDriversDidChange( void )
{
notifyAll( kIOPM_ParentChangeTellCapabilityDidChange );
}
void
IOService::ParentChangeTellCapabilityDidChange( void )
{
if (!IS_ROOT_DOMAIN) {
return ParentChangeAcknowledgePowerChange();
}
tellSystemCapabilityChange( kIOPM_ParentChangeAcknowledgePowerChange );
}
void
IOService::ParentChangeAcknowledgePowerChange( void )
{
IORegistryEntry * nub;
IOService * parent;
nub = fHeadNoteParentConnection;
nub->retain();
all_done();
parent = (IOService *)nub->copyParentEntry(gIOPowerPlane);
if (parent) {
parent->acknowledgePowerChange((IOService *)nub);
parent->release();
}
nub->release();
}
void
IOService::settleTimerExpired( void )
{
fSettleTimeUS = 0;
gIOPMWorkQueue->signalWorkAvailable();
}
static void
settle_timer_expired( thread_call_param_t arg0, thread_call_param_t arg1 )
{
IOService * me = (IOService *) arg0;
if (gIOPMWorkLoop && gIOPMWorkQueue) {
gIOPMWorkLoop->runAction(
OSMemberFunctionCast(IOWorkLoop::Action, me, &IOService::settleTimerExpired),
me);
}
me->release();
}
void
IOService::startSettleTimer( void )
{
#if NOT_USEFUL
AbsoluteTime deadline;
IOPMPowerStateIndex stateIndex;
IOPMPowerStateIndex currentOrder, newOrder, i;
uint32_t settleTime = 0;
boolean_t pending;
PM_ASSERT_IN_GATE();
currentOrder = StateOrder(fCurrentPowerState);
newOrder = StateOrder(fHeadNotePowerState);
i = currentOrder;
if (newOrder < currentOrder) {
while (i > newOrder) {
stateIndex = fPowerStates[i].stateOrderToIndex;
settleTime += (uint32_t) fPowerStates[stateIndex].settleDownTime;
i--;
}
}
if (newOrder > currentOrder) {
while (i < newOrder) {
stateIndex = fPowerStates[i + 1].stateOrderToIndex;
settleTime += (uint32_t) fPowerStates[stateIndex].settleUpTime;
i++;
}
}
if (settleTime) {
retain();
clock_interval_to_deadline(settleTime, kMicrosecondScale, &deadline);
pending = thread_call_enter_delayed(fSettleTimer, deadline);
if (pending) {
release();
}
}
#endif
}
#ifndef __LP64__
#if MACH_ASSERT
__dead2
#endif
void
IOService::ack_timer_ticked( void )
{
assert(false);
}
#endif
bool
IOService::ackTimerTick( void )
{
IOPMinformee * nextObject;
bool done = false;
PM_ASSERT_IN_GATE();
switch (fMachineState) {
case kIOPM_OurChangeWaitForPowerSettle:
case kIOPM_ParentChangeWaitForPowerSettle:
if (fDriverTimer > 0) {
fDriverTimer--;
if (fDriverTimer == 0) {
uint64_t nsec = computeTimeDeltaNS(&fDriverCallStartTime);
OUR_PMLog(kPMLogCtrlDriverTardy, 0, 0);
setProperty(kIOPMTardyAckSPSKey, kOSBooleanTrue);
PM_ERROR("%s::setPowerState(%p, %lu -> %lu) timed out after %d ms\n",
fName, OBFUSCATE(this), fCurrentPowerState, fHeadNotePowerState, NS_TO_MS(nsec));
#if DEBUG || DEVELOPMENT || CONFIG_EMBEDDED
uint32_t panic_allowed = -1;
PE_parse_boot_argn("setpowerstate_panic", &panic_allowed, sizeof(panic_allowed));
if (panic_allowed != 0) {
const char *whitelist = "AppleSEPManager";
if (strncmp(fName, whitelist, strlen(whitelist))) {
panic("%s::setPowerState(%p, %lu -> %lu) timed out after %d ms",
fName, this, fCurrentPowerState, fHeadNotePowerState, NS_TO_MS(nsec));
}
} else {
PM_ERROR("setPowerState panic disabled by setpowerstate_panic boot-arg\n");
}
#else
if (gIOKitDebug & kIOLogDebugPower) {
panic("%s::setPowerState(%p, %lu -> %lu) timed out after %d ms",
fName, this, fCurrentPowerState, fHeadNotePowerState, NS_TO_MS(nsec));
} else {
const void *function_addr = NULL;
OSKext *kext = NULL;
function_addr = OSMemberFunctionCast(const void *, fControllingDriver, &IOService::setPowerState);
kext = OSKext::lookupKextWithAddress((vm_address_t)function_addr);
if (kext) {
const char *bundleID = kext->getIdentifierCString();
const char *apple_prefix = "com.apple";
const char *kernel_prefix = "__kernel__";
if (strncmp(bundleID, apple_prefix, strlen(apple_prefix)) == 0 || strncmp(bundleID, kernel_prefix, strlen(kernel_prefix)) == 0) {
panic("%s::setPowerState(%p : %p, %lu -> %lu) timed out after %d ms",
fName, this, function_addr, fCurrentPowerState, fHeadNotePowerState, NS_TO_MS(nsec));
}
kext->release();
}
done = true;
}
#endif
getPMRootDomain()->reset_watchdog_timer(this, 0);
} else {
start_ack_timer();
}
}
break;
case kIOPM_NotifyChildrenStart:
if (fHeadNotePendingAcks != 0) {
nextObject = fInterestedDrivers->firstInList();
while (nextObject != NULL) {
if (nextObject->timer > 0) {
nextObject->timer--;
if (nextObject->timer == 0) {
uint64_t nsec = computeTimeDeltaNS(&nextObject->startTime);
OUR_PMLog(kPMLogIntDriverTardy, 0, 0);
nextObject->whatObject->setProperty(kIOPMTardyAckPSCKey, kOSBooleanTrue);
PM_ERROR("%s::powerState%sChangeTo(%p, %s, %lu -> %lu) timed out after %d ms\n",
nextObject->whatObject->getName(),
(fDriverCallReason == kDriverCallInformPreChange) ? "Will" : "Did",
OBFUSCATE(nextObject->whatObject), fName, fCurrentPowerState, fHeadNotePowerState,
NS_TO_MS(nsec));
fHeadNotePendingAcks--;
}
}
nextObject = fInterestedDrivers->nextInList(nextObject);
}
if (fHeadNotePendingAcks == 0) {
done = true;
getPMRootDomain()->reset_watchdog_timer(this, 0);
} else {
start_ack_timer();
}
}
break;
case kIOPM_OurChangeTellClientsPowerDown:
case kIOPM_OurChangeTellUserPMPolicyPowerDown:
case kIOPM_OurChangeTellPriorityClientsPowerDown:
case kIOPM_OurChangeNotifyInterestedDriversWillChange:
case kIOPM_ParentChangeTellPriorityClientsPowerDown:
case kIOPM_ParentChangeNotifyInterestedDriversWillChange:
case kIOPM_SyncTellClientsPowerDown:
case kIOPM_SyncTellPriorityClientsPowerDown:
case kIOPM_SyncNotifyWillChange:
case kIOPM_TellCapabilityChangeDone:
cleanClientResponses(true);
OUR_PMLog(kPMLogClientTardy, 0, 1);
done = true;
break;
default:
PM_LOG1("%s: unexpected ack timer tick (state = %d)\n",
getName(), fMachineState);
break;
}
return done;
}
void
IOService::start_watchdog_timer( void )
{
int timeout;
uint64_t deadline;
if (!fWatchdogTimer || (kIOSleepWakeWdogOff & gIOKitDebug)) {
return;
}
IOLockLock(fWatchdogLock);
timeout = getPMRootDomain()->getWatchdogTimeout();
clock_interval_to_deadline(timeout, kSecondScale, &deadline);
fWatchdogDeadline = deadline;
start_watchdog_timer(deadline);
IOLockUnlock(fWatchdogLock);
}
void
IOService::start_watchdog_timer(uint64_t deadline)
{
IOLockAssert(fWatchdogLock, kIOLockAssertOwned);
if (!thread_call_isactive(fWatchdogTimer)) {
thread_call_enter_delayed(fWatchdogTimer, deadline);
}
}
void
IOService::stop_watchdog_timer( void )
{
if (!fWatchdogTimer || (kIOSleepWakeWdogOff & gIOKitDebug)) {
return;
}
IOLockLock(fWatchdogLock);
thread_call_cancel(fWatchdogTimer);
fWatchdogDeadline = 0;
while (fBlockedArray->getCount()) {
IOService *obj = OSDynamicCast(IOService, fBlockedArray->getObject(0));
if (obj) {
PM_ERROR("WDOG:Object %s unexpected in blocked array\n", obj->fName);
fBlockedArray->removeObject(0);
}
}
IOLockUnlock(fWatchdogLock);
}
void
IOService::reset_watchdog_timer(IOService *blockedObject, int pendingResponseTimeout)
{
unsigned int i;
uint64_t deadline;
IOService *obj;
if (!fWatchdogTimer || (kIOSleepWakeWdogOff & gIOKitDebug)) {
return;
}
IOLockLock(fWatchdogLock);
if (!fWatchdogDeadline) {
goto exit;
}
i = fBlockedArray->getNextIndexOfObject(blockedObject, 0);
if (pendingResponseTimeout == 0) {
blockedObject->fPendingResponseDeadline = 0;
if (i == (unsigned int)-1) {
goto exit;
}
fBlockedArray->removeObject(i);
} else {
clock_interval_to_deadline(pendingResponseTimeout + 2, kSecondScale, &deadline);
if (i != (unsigned int)-1) {
PM_ERROR("WDOG:Object %s is already blocked for responses. Ignoring timeout %d\n",
fName, pendingResponseTimeout);
goto exit;
}
for (i = 0; i < fBlockedArray->getCount(); i++) {
obj = OSDynamicCast(IOService, fBlockedArray->getObject(i));
if (obj && (obj->fPendingResponseDeadline < deadline)) {
blockedObject->fPendingResponseDeadline = deadline;
fBlockedArray->setObject(i, blockedObject);
break;
}
}
if (i == fBlockedArray->getCount()) {
blockedObject->fPendingResponseDeadline = deadline;
fBlockedArray->setObject(blockedObject);
}
}
obj = OSDynamicCast(IOService, fBlockedArray->getObject(0));
if (!obj) {
int timeout = getPMRootDomain()->getWatchdogTimeout();
clock_interval_to_deadline(timeout, kSecondScale, &deadline);
} else {
deadline = obj->fPendingResponseDeadline;
}
thread_call_cancel(fWatchdogTimer);
start_watchdog_timer(deadline);
exit:
IOLockUnlock(fWatchdogLock);
}
void
IOService::watchdog_timer_expired( thread_call_param_t arg0, thread_call_param_t arg1 )
{
IOService * me = (IOService *) arg0;
gIOPMWatchDogThread = current_thread();
getPMRootDomain()->sleepWakeDebugTrig(true);
gIOPMWatchDogThread = NULL;
thread_call_free(me->fWatchdogTimer);
me->fWatchdogTimer = NULL;
return;
}
IOWorkLoop *
IOService::getIOPMWorkloop( void )
{
return gIOPMWorkLoop;
}
void
IOService::start_ack_timer( void )
{
start_ack_timer( ACK_TIMER_PERIOD, kNanosecondScale );
}
void
IOService::start_ack_timer( UInt32 interval, UInt32 scale )
{
AbsoluteTime deadline;
boolean_t pending;
clock_interval_to_deadline(interval, scale, &deadline);
retain();
pending = thread_call_enter_delayed(fAckTimer, deadline);
if (pending) {
release();
}
}
void
IOService::stop_ack_timer( void )
{
boolean_t pending;
pending = thread_call_cancel(fAckTimer);
if (pending) {
release();
}
}
IOReturn
IOService::actionAckTimerExpired(
OSObject * target,
void * arg0, void * arg1,
void * arg2, void * arg3 )
{
IOService * me = (IOService *) target;
bool done;
done = me->ackTimerTick();
if (done && gIOPMWorkQueue) {
gIOPMWorkQueue->signalWorkAvailable();
}
return kIOReturnSuccess;
}
void
IOService::ack_timer_expired( thread_call_param_t arg0, thread_call_param_t arg1 )
{
IOService * me = (IOService *) arg0;
if (gIOPMWorkLoop) {
gIOPMWorkLoop->runAction(&actionAckTimerExpired, me);
}
me->release();
}
void
IOService::tellSystemCapabilityChange( uint32_t nextMS )
{
MS_PUSH( nextMS );
fMachineState = kIOPM_TellCapabilityChangeDone;
fOutOfBandMessage = kIOMessageSystemCapabilityChange;
if (fIsPreChange) {
fOutOfBandParameter = kNotifyCapabilityChangeApps;
} else {
fOutOfBandParameter = kNotifyCapabilityChangePriority;
}
tellClientsWithResponse( fOutOfBandMessage );
}
bool
IOService::askChangeDown( unsigned long stateNum )
{
return tellClientsWithResponse( kIOMessageCanDevicePowerOff );
}
bool
IOService::tellChangeDown1( unsigned long stateNum )
{
fOutOfBandParameter = kNotifyApps;
return tellChangeDown(stateNum);
}
bool
IOService::tellChangeDown2( unsigned long stateNum )
{
fOutOfBandParameter = kNotifyPriority;
return tellChangeDown(stateNum);
}
bool
IOService::tellChangeDown( unsigned long stateNum )
{
return tellClientsWithResponse( kIOMessageDeviceWillPowerOff );
}
static void
logAppTimeouts( OSObject * object, void * arg )
{
IOPMInterestContext * context = (IOPMInterestContext *) arg;
OSObject * flag;
unsigned int clientIndex;
int pid = 0;
char name[128];
if (OSDynamicCast(_IOServiceInterestNotifier, object)) {
clientIndex = context->notifyClients->getNextIndexOfObject(object, 0);
if ((clientIndex != (unsigned int) -1) &&
(flag = context->responseArray->getObject(clientIndex)) &&
(flag != kOSBooleanTrue)) {
OSNumber *clientID = copyClientIDForNotification(object, context);
name[0] = '\0';
if (clientID) {
pid = clientID->unsigned32BitValue();
proc_name(pid, name, sizeof(name));
clientID->release();
}
PM_ERROR(context->errorLog, pid, name);
IOService::getPMRootDomain()->pmStatsRecordApplicationResponse(
gIOPMStatsResponseTimedOut,
name, 0, (30 * 1000), pid, object);
}
}
}
void
IOService::cleanClientResponses( bool logErrors )
{
if (logErrors && fResponseArray) {
switch (fOutOfBandParameter) {
case kNotifyApps:
case kNotifyCapabilityChangeApps:
if (fNotifyClientArray) {
IOPMInterestContext context;
context.responseArray = fResponseArray;
context.notifyClients = fNotifyClientArray;
context.serialNumber = fSerialNumber;
context.messageType = kIOMessageCopyClientID;
context.notifyType = kNotifyApps;
context.isPreChange = fIsPreChange;
context.enableTracing = false;
context.us = this;
context.maxTimeRequested = 0;
context.stateNumber = fHeadNotePowerState;
context.stateFlags = fHeadNotePowerArrayEntry->capabilityFlags;
context.changeFlags = fHeadNoteChangeFlags;
context.errorLog = "PM notification timeout (pid %d, %s)\n";
applyToInterested(gIOAppPowerStateInterest, logAppTimeouts, (void *) &context);
}
break;
default:
PM_ERROR("PM priority notification timeout\n");
if (gIOKitDebug & kIOLogDebugPower) {
panic("PM priority notification timeout");
}
break;
}
}
if (IS_ROOT_DOMAIN) {
getPMRootDomain()->reset_watchdog_timer(this, 0);
}
if (fResponseArray) {
fResponseArray->release();
fResponseArray = NULL;
}
if (fNotifyClientArray) {
fNotifyClientArray->release();
fNotifyClientArray = NULL;
}
}
bool
IOService::tellClientsWithResponse( int messageType )
{
IOPMInterestContext context;
bool isRootDomain = IS_ROOT_DOMAIN;
uint32_t maxTimeOut = kMaxTimeRequested;
PM_ASSERT_IN_GATE();
assert( fResponseArray == NULL );
assert( fNotifyClientArray == NULL );
if (messageType == (int)kIOPMMessageLastCallBeforeSleep) {
RD_LOG("tellClientsWithResponse( kIOPMMessageLastCallBeforeSleep, %d )\n",
fOutOfBandParameter);
} else {
RD_LOG("tellClientsWithResponse( %s, %d )\n",
getIOMessageString(messageType), fOutOfBandParameter);
}
fResponseArray = OSArray::withCapacity( 1 );
if (!fResponseArray) {
goto exit;
}
fResponseArray->setCapacityIncrement(8);
if (++fSerialNumber == 0) {
fSerialNumber++;
}
context.responseArray = fResponseArray;
context.notifyClients = NULL;
context.serialNumber = fSerialNumber;
context.messageType = messageType;
context.notifyType = fOutOfBandParameter;
context.skippedInDark = 0;
context.notSkippedInDark = 0;
context.isPreChange = fIsPreChange;
context.enableTracing = false;
context.us = this;
context.maxTimeRequested = 0;
context.stateNumber = fHeadNotePowerState;
context.stateFlags = fHeadNotePowerArrayEntry->capabilityFlags;
context.changeFlags = fHeadNoteChangeFlags;
context.messageFilter = (isRootDomain) ?
OSMemberFunctionCast(
IOPMMessageFilter,
this,
&IOPMrootDomain::systemMessageFilter) : NULL;
switch (fOutOfBandParameter) {
case kNotifyApps:
applyToInterested( gIOAppPowerStateInterest,
pmTellAppWithResponse, (void *) &context );
if (isRootDomain &&
(fMachineState != kIOPM_OurChangeTellClientsPowerDown) &&
(fMachineState != kIOPM_SyncTellClientsPowerDown) &&
(context.messageType != kIOPMMessageLastCallBeforeSleep)) {
context.notifyType = kNotifyCapabilityChangeApps;
context.messageType = kIOMessageSystemCapabilityChange;
applyToInterested( gIOAppPowerStateInterest,
pmTellCapabilityAppWithResponse, (void *) &context );
context.notifyType = fOutOfBandParameter;
context.messageType = messageType;
}
if (context.messageType == kIOMessageCanSystemSleep) {
maxTimeOut = kCanSleepMaxTimeReq;
if (gCanSleepTimeout) {
maxTimeOut = (gCanSleepTimeout * us_per_s);
}
}
context.maxTimeRequested = maxTimeOut;
context.enableTracing = isRootDomain;
applyToInterested( gIOGeneralInterest,
pmTellClientWithResponse, (void *) &context );
break;
case kNotifyPriority:
context.enableTracing = isRootDomain;
applyToInterested( gIOPriorityPowerStateInterest,
pmTellClientWithResponse, (void *) &context );
if (isRootDomain) {
context.notifyType = kNotifyCapabilityChangePriority;
context.messageType = kIOMessageSystemCapabilityChange;
applyToInterested( gIOPriorityPowerStateInterest,
pmTellCapabilityClientWithResponse, (void *) &context );
}
break;
case kNotifyCapabilityChangeApps:
applyToInterested( gIOAppPowerStateInterest,
pmTellCapabilityAppWithResponse, (void *) &context );
if (context.messageType == kIOMessageCanSystemSleep) {
maxTimeOut = kCanSleepMaxTimeReq;
if (gCanSleepTimeout) {
maxTimeOut = (gCanSleepTimeout * us_per_s);
}
}
context.maxTimeRequested = maxTimeOut;
break;
case kNotifyCapabilityChangePriority:
context.enableTracing = isRootDomain;
applyToInterested( gIOPriorityPowerStateInterest,
pmTellCapabilityClientWithResponse, (void *) &context );
break;
}
fNotifyClientArray = context.notifyClients;
if (context.skippedInDark) {
IOLog("tellClientsWithResponse(%s, %d) %d of %d skipped in dark\n",
getIOMessageString(messageType), fOutOfBandParameter,
context.skippedInDark, context.skippedInDark + context.notSkippedInDark);
}
if (!checkForDone()) {
OUR_PMLog(kPMLogStartAckTimer, context.maxTimeRequested, 0);
if (context.enableTracing) {
getPMRootDomain()->traceDetail(context.messageType, 0, context.maxTimeRequested / 1000);
getPMRootDomain()->reset_watchdog_timer(this, context.maxTimeRequested / USEC_PER_SEC + 1);
}
start_ack_timer( context.maxTimeRequested / 1000, kMillisecondScale );
return false;
}
exit:
if (fResponseArray) {
fResponseArray->release();
fResponseArray = NULL;
}
if (fNotifyClientArray) {
fNotifyClientArray->release();
fNotifyClientArray = NULL;
}
return true;
}
void
IOService::pmTellAppWithResponse( OSObject * object, void * arg )
{
IOPMInterestContext * context = (IOPMInterestContext *) arg;
IOServicePM * pwrMgt = context->us->pwrMgt;
uint32_t msgIndex, msgRef, msgType;
OSNumber *clientID = NULL;
proc_t proc = NULL;
boolean_t proc_suspended = FALSE;
OSObject * waitForReply = kOSBooleanTrue;
#if LOG_APP_RESPONSE_TIMES
AbsoluteTime now;
#endif
if (!OSDynamicCast(_IOServiceInterestNotifier, object)) {
return;
}
if (context->us == getPMRootDomain()) {
if ((clientID = copyClientIDForNotification(object, context))) {
uint32_t clientPID = clientID->unsigned32BitValue();
clientID->release();
proc = proc_find(clientPID);
if (proc) {
proc_suspended = get_task_pidsuspended((task_t) proc->task);
if (proc_suspended) {
logClientIDForNotification(object, context, "PMTellAppWithResponse - Suspended");
#if !(defined(RC_HIDE_N144) || defined(RC_HIDE_N146))
} else if (getPMRootDomain()->isAOTMode() && get_task_suspended((task_t) proc->task)) {
proc_suspended = true;
context->skippedInDark++;
#endif
}
proc_rele(proc);
if (proc_suspended) {
return;
}
}
}
}
if (context->messageFilter &&
!context->messageFilter(context->us, object, context, NULL, &waitForReply)) {
if (kIOLogDebugPower & gIOKitDebug) {
logClientIDForNotification(object, context, "DROP App");
}
return;
}
context->notSkippedInDark++;
if (NULL == context->notifyClients) {
context->notifyClients = OSArray::withCapacity( 32 );
}
msgType = context->messageType;
msgIndex = context->responseArray->getCount();
msgRef = ((context->serialNumber & 0xFFFF) << 16) + (msgIndex & 0xFFFF);
OUR_PMLog(kPMLogAppNotify, msgType, msgRef);
if (kIOLogDebugPower & gIOKitDebug) {
logClientIDForNotification(object, context, "MESG App");
}
if (waitForReply == kOSBooleanTrue) {
OSNumber * num;
clock_get_uptime(&now);
num = OSNumber::withNumber(AbsoluteTime_to_scalar(&now), sizeof(uint64_t) * 8);
if (num) {
context->responseArray->setObject(msgIndex, num);
num->release();
} else {
context->responseArray->setObject(msgIndex, kOSBooleanFalse);
}
} else {
context->responseArray->setObject(msgIndex, kOSBooleanTrue);
if (kIOLogDebugPower & gIOKitDebug) {
logClientIDForNotification(object, context, "App response ignored");
}
}
if (context->notifyClients) {
context->notifyClients->setObject(msgIndex, object);
}
context->us->messageClient(msgType, object, (void *)(uintptr_t) msgRef);
}
void
IOService::pmTellClientWithResponse( OSObject * object, void * arg )
{
IOPowerStateChangeNotification notify;
IOPMInterestContext * context = (IOPMInterestContext *) arg;
OSObject * replied = kOSBooleanTrue;
_IOServiceInterestNotifier * notifier;
uint32_t msgIndex, msgRef, msgType;
IOReturn retCode;
AbsoluteTime start, end;
uint64_t nsec;
if (context->messageFilter &&
!context->messageFilter(context->us, object, context, NULL, NULL)) {
if ((kIOLogDebugPower & gIOKitDebug) &&
(OSDynamicCast(_IOServiceInterestNotifier, object))) {
_IOServiceInterestNotifier *n = (_IOServiceInterestNotifier *) object;
PM_LOG("%s DROP Client %s, notifier %p, handler %p\n",
context->us->getName(),
getIOMessageString(context->messageType),
OBFUSCATE(object), OBFUSCATE(n->handler));
}
return;
}
notifier = OSDynamicCast(_IOServiceInterestNotifier, object);
msgType = context->messageType;
msgIndex = context->responseArray->getCount();
msgRef = ((context->serialNumber & 0xFFFF) << 16) + (msgIndex & 0xFFFF);
IOServicePM * pwrMgt = context->us->pwrMgt;
if (gIOKitDebug & kIOLogPower) {
OUR_PMLog(kPMLogClientNotify, msgRef, msgType);
if (OSDynamicCast(IOService, object)) {
const char *who = ((IOService *) object)->getName();
gPlatform->PMLog(who, kPMLogClientNotify, (uintptr_t) object, 0);
} else if (notifier) {
OUR_PMLog(kPMLogClientNotify, (uintptr_t) notifier->handler, 0);
}
}
if ((kIOLogDebugPower & gIOKitDebug) && notifier) {
PM_LOG("%s MESG Client %s, notifier %p, handler %p\n",
context->us->getName(),
getIOMessageString(msgType),
OBFUSCATE(object), OBFUSCATE(notifier->handler));
}
if (NULL == context->notifyClients) {
context->notifyClients = OSArray::withCapacity( 32 );
}
notify.powerRef = (void *)(uintptr_t) msgRef;
notify.returnValue = 0;
notify.stateNumber = context->stateNumber;
notify.stateFlags = context->stateFlags;
if (context->enableTracing && (notifier != NULL)) {
getPMRootDomain()->traceDetail(notifier, true);
}
clock_get_uptime(&start);
retCode = context->us->messageClient(msgType, object, (void *) ¬ify, sizeof(notify));
clock_get_uptime(&end);
if (context->enableTracing && (notifier != NULL)) {
getPMRootDomain()->traceDetail(notifier, false);
}
if (kIOReturnSuccess == retCode) {
if (0 == notify.returnValue) {
OUR_PMLog(kPMLogClientAcknowledge, msgRef, (uintptr_t) object);
context->responseArray->setObject(msgIndex, replied);
} else {
replied = kOSBooleanFalse;
if (notify.returnValue > context->maxTimeRequested) {
if (notify.returnValue > kPriorityClientMaxWait) {
context->maxTimeRequested = kPriorityClientMaxWait;
PM_ERROR("%s: client %p returned %llu for %s\n",
context->us->getName(),
notifier ? (void *) OBFUSCATE(notifier->handler) : OBFUSCATE(object),
(uint64_t) notify.returnValue,
getIOMessageString(msgType));
} else {
context->maxTimeRequested = notify.returnValue;
}
}
OSNumber * num;
num = OSNumber::withNumber(AbsoluteTime_to_scalar(&end), sizeof(uint64_t) * 8);
if (num) {
context->responseArray->setObject(msgIndex, num);
num->release();
} else {
context->responseArray->setObject(msgIndex, replied);
}
}
if (context->enableTracing) {
SUB_ABSOLUTETIME(&end, &start);
absolutetime_to_nanoseconds(end, &nsec);
if ((nsec > LOG_KEXT_RESPONSE_TIMES) || (notify.returnValue != 0)) {
getPMRootDomain()->traceAckDelay(notifier, notify.returnValue / 1000, NS_TO_MS(nsec));
}
}
} else {
OUR_PMLog(kPMLogClientAcknowledge, msgRef, 0);
context->responseArray->setObject(msgIndex, replied);
}
if (context->notifyClients) {
context->notifyClients->setObject(msgIndex, object);
}
}
void
IOService::pmTellCapabilityAppWithResponse( OSObject * object, void * arg )
{
IOPMSystemCapabilityChangeParameters msgArg;
IOPMInterestContext * context = (IOPMInterestContext *) arg;
OSObject * replied = kOSBooleanTrue;
IOServicePM * pwrMgt = context->us->pwrMgt;
uint32_t msgIndex, msgRef, msgType;
#if LOG_APP_RESPONSE_TIMES
AbsoluteTime now;
#endif
if (!OSDynamicCast(_IOServiceInterestNotifier, object)) {
return;
}
memset(&msgArg, 0, sizeof(msgArg));
if (context->messageFilter &&
!context->messageFilter(context->us, object, context, &msgArg, &replied)) {
return;
}
if (context->us == getPMRootDomain() &&
#if !(defined(RC_HIDE_N144) || defined(RC_HIDE_N146))
getPMRootDomain()->isAOTMode()
#else
false
#endif
) {
OSNumber *clientID = NULL;
boolean_t proc_suspended = FALSE;
proc_t proc = NULL;
if ((clientID = copyClientIDForNotification(object, context))) {
uint32_t clientPID = clientID->unsigned32BitValue();
clientID->release();
proc = proc_find(clientPID);
if (proc) {
proc_suspended = get_task_pidsuspended((task_t) proc->task);
if (proc_suspended) {
logClientIDForNotification(object, context, "PMTellCapablityAppWithResponse - Suspended");
} else if (get_task_suspended((task_t) proc->task)) {
proc_suspended = true;
context->skippedInDark++;
}
proc_rele(proc);
if (proc_suspended) {
return;
}
}
}
}
context->notSkippedInDark++;
if (NULL == context->notifyClients) {
context->notifyClients = OSArray::withCapacity( 32 );
}
msgType = context->messageType;
msgIndex = context->responseArray->getCount();
msgRef = ((context->serialNumber & 0xFFFF) << 16) + (msgIndex & 0xFFFF);
OUR_PMLog(kPMLogAppNotify, msgType, msgRef);
if (kIOLogDebugPower & gIOKitDebug) {
OSNumber * clientID = NULL;
OSString * clientIDString = NULL;;
context->us->messageClient(kIOMessageCopyClientID, object, &clientID);
if (clientID) {
clientIDString = IOCopyLogNameForPID(clientID->unsigned32BitValue());
}
PM_LOG("%s MESG App(%u) %s, wait %u, %s\n",
context->us->getName(),
msgIndex, getIOMessageString(msgType),
(replied != kOSBooleanTrue),
clientIDString ? clientIDString->getCStringNoCopy() : "");
if (clientID) {
clientID->release();
}
if (clientIDString) {
clientIDString->release();
}
}
msgArg.notifyRef = msgRef;
msgArg.maxWaitForReply = 0;
if (replied == kOSBooleanTrue) {
msgArg.notifyRef = 0;
context->responseArray->setObject(msgIndex, kOSBooleanTrue);
if (context->notifyClients) {
context->notifyClients->setObject(msgIndex, kOSBooleanTrue);
}
} else {
OSNumber * num;
clock_get_uptime(&now);
num = OSNumber::withNumber(AbsoluteTime_to_scalar(&now), sizeof(uint64_t) * 8);
if (num) {
context->responseArray->setObject(msgIndex, num);
num->release();
} else {
context->responseArray->setObject(msgIndex, kOSBooleanFalse);
}
if (context->notifyClients) {
context->notifyClients->setObject(msgIndex, object);
}
}
context->us->messageClient(msgType, object, (void *) &msgArg, sizeof(msgArg));
}
void
IOService::pmTellCapabilityClientWithResponse(
OSObject * object, void * arg )
{
IOPMSystemCapabilityChangeParameters msgArg;
IOPMInterestContext * context = (IOPMInterestContext *) arg;
OSObject * replied = kOSBooleanTrue;
_IOServiceInterestNotifier * notifier;
uint32_t msgIndex, msgRef, msgType;
IOReturn retCode;
AbsoluteTime start, end;
uint64_t nsec;
memset(&msgArg, 0, sizeof(msgArg));
if (context->messageFilter &&
!context->messageFilter(context->us, object, context, &msgArg, NULL)) {
if ((kIOLogDebugPower & gIOKitDebug) &&
(OSDynamicCast(_IOServiceInterestNotifier, object))) {
_IOServiceInterestNotifier *n = (_IOServiceInterestNotifier *) object;
PM_LOG("%s DROP Client %s, notifier %p, handler %p\n",
context->us->getName(),
getIOMessageString(context->messageType),
OBFUSCATE(object), OBFUSCATE(n->handler));
}
return;
}
if (NULL == context->notifyClients) {
context->notifyClients = OSArray::withCapacity( 32 );
}
notifier = OSDynamicCast(_IOServiceInterestNotifier, object);
msgType = context->messageType;
msgIndex = context->responseArray->getCount();
msgRef = ((context->serialNumber & 0xFFFF) << 16) + (msgIndex & 0xFFFF);
IOServicePM * pwrMgt = context->us->pwrMgt;
if (gIOKitDebug & kIOLogPower) {
OUR_PMLog(kPMLogClientNotify, msgRef, msgType);
if (OSDynamicCast(IOService, object)) {
const char *who = ((IOService *) object)->getName();
gPlatform->PMLog(who, kPMLogClientNotify, (uintptr_t) object, 0);
} else if (notifier) {
OUR_PMLog(kPMLogClientNotify, (uintptr_t) notifier->handler, 0);
}
}
if ((kIOLogDebugPower & gIOKitDebug) && notifier) {
PM_LOG("%s MESG Client %s, notifier %p, handler %p\n",
context->us->getName(),
getIOMessageString(msgType),
OBFUSCATE(object), OBFUSCATE(notifier->handler));
}
msgArg.notifyRef = msgRef;
msgArg.maxWaitForReply = 0;
if (context->enableTracing && (notifier != NULL)) {
getPMRootDomain()->traceDetail(notifier, true);
}
clock_get_uptime(&start);
retCode = context->us->messageClient(
msgType, object, (void *) &msgArg, sizeof(msgArg));
clock_get_uptime(&end);
if (context->enableTracing && (notifier != NULL)) {
getPMRootDomain()->traceDetail(notifier, false);
}
if (kIOReturnSuccess == retCode) {
if (0 == msgArg.maxWaitForReply) {
OUR_PMLog(kPMLogClientAcknowledge, msgRef, (uintptr_t) object);
context->responseArray->setObject(msgIndex, replied);
} else {
replied = kOSBooleanFalse;
if (msgArg.maxWaitForReply > context->maxTimeRequested) {
if (msgArg.maxWaitForReply > kCapabilityClientMaxWait) {
context->maxTimeRequested = kCapabilityClientMaxWait;
PM_ERROR("%s: client %p returned %u for %s\n",
context->us->getName(),
notifier ? (void *) OBFUSCATE(notifier->handler) : OBFUSCATE(object),
msgArg.maxWaitForReply,
getIOMessageString(msgType));
} else {
context->maxTimeRequested = msgArg.maxWaitForReply;
}
}
OSNumber * num;
num = OSNumber::withNumber(AbsoluteTime_to_scalar(&end), sizeof(uint64_t) * 8);
if (num) {
context->responseArray->setObject(msgIndex, num);
num->release();
} else {
context->responseArray->setObject(msgIndex, replied);
}
}
if (context->enableTracing) {
SUB_ABSOLUTETIME(&end, &start);
absolutetime_to_nanoseconds(end, &nsec);
if ((nsec > LOG_KEXT_RESPONSE_TIMES) || (msgArg.maxWaitForReply != 0)) {
getPMRootDomain()->traceAckDelay(notifier, msgArg.maxWaitForReply / 1000, NS_TO_MS(nsec));
}
}
} else {
OUR_PMLog(kPMLogClientAcknowledge, msgRef, 0);
context->responseArray->setObject(msgIndex, replied);
}
if (context->notifyClients) {
context->notifyClients->setObject(msgIndex, object);
}
}
void
IOService::tellNoChangeDown( unsigned long )
{
return tellClients( kIOMessageDeviceWillNotPowerOff );
}
void
IOService::tellChangeUp( unsigned long )
{
return tellClients( kIOMessageDeviceHasPoweredOn );
}
void
IOService::tellClients( int messageType )
{
IOPMInterestContext context;
RD_LOG("tellClients( %s )\n", getIOMessageString(messageType));
memset(&context, 0, sizeof(context));
context.messageType = messageType;
context.isPreChange = fIsPreChange;
context.us = this;
context.stateNumber = fHeadNotePowerState;
context.stateFlags = fHeadNotePowerArrayEntry->capabilityFlags;
context.changeFlags = fHeadNoteChangeFlags;
context.enableTracing = IS_ROOT_DOMAIN;
context.messageFilter = (IS_ROOT_DOMAIN) ?
OSMemberFunctionCast(
IOPMMessageFilter,
this,
&IOPMrootDomain::systemMessageFilter) : NULL;
context.notifyType = kNotifyPriority;
applyToInterested( gIOPriorityPowerStateInterest,
tellKernelClientApplier, (void *) &context );
context.notifyType = kNotifyApps;
applyToInterested( gIOAppPowerStateInterest,
tellAppClientApplier, (void *) &context );
applyToInterested( gIOGeneralInterest,
tellKernelClientApplier, (void *) &context );
}
static void
tellKernelClientApplier( OSObject * object, void * arg )
{
IOPowerStateChangeNotification notify;
IOPMInterestContext * context = (IOPMInterestContext *) arg;
if (context->messageFilter &&
!context->messageFilter(context->us, object, context, NULL, NULL)) {
if ((kIOLogDebugPower & gIOKitDebug) &&
(OSDynamicCast(_IOServiceInterestNotifier, object))) {
_IOServiceInterestNotifier *n = (_IOServiceInterestNotifier *) object;
PM_LOG("%s DROP Client %s, notifier %p, handler %p\n",
context->us->getName(),
IOService::getIOMessageString(context->messageType),
OBFUSCATE(object), OBFUSCATE(n->handler));
}
return;
}
notify.powerRef = (void *) NULL;
notify.returnValue = 0;
notify.stateNumber = context->stateNumber;
notify.stateFlags = context->stateFlags;
if (context->enableTracing && object) {
IOService::getPMRootDomain()->traceDetail(object, true);
}
context->us->messageClient(context->messageType, object, ¬ify, sizeof(notify));
if (context->enableTracing && object) {
IOService::getPMRootDomain()->traceDetail(object, false);
}
if ((kIOLogDebugPower & gIOKitDebug) &&
(OSDynamicCast(_IOServiceInterestNotifier, object))) {
_IOServiceInterestNotifier *n = (_IOServiceInterestNotifier *) object;
PM_LOG("%s MESG Client %s, notifier %p, handler %p\n",
context->us->getName(),
IOService::getIOMessageString(context->messageType),
OBFUSCATE(object), OBFUSCATE(n->handler));
}
}
static OSNumber *
copyClientIDForNotification(
OSObject *object,
IOPMInterestContext *context)
{
OSNumber *clientID = NULL;
context->us->messageClient(kIOMessageCopyClientID, object, &clientID);
return clientID;
}
static void
logClientIDForNotification(
OSObject *object,
IOPMInterestContext *context,
const char *logString)
{
OSString *logClientID = NULL;
OSNumber *clientID = copyClientIDForNotification(object, context);
if (logString) {
if (clientID) {
logClientID = IOCopyLogNameForPID(clientID->unsigned32BitValue());
}
PM_LOG("%s %s %s, %s\n",
context->us->getName(), logString,
IOService::getIOMessageString(context->messageType),
logClientID ? logClientID->getCStringNoCopy() : "");
if (logClientID) {
logClientID->release();
}
}
if (clientID) {
clientID->release();
}
return;
}
static void
tellAppClientApplier( OSObject * object, void * arg )
{
IOPMInterestContext * context = (IOPMInterestContext *) arg;
OSNumber * clientID = NULL;
proc_t proc = NULL;
boolean_t proc_suspended = FALSE;
if (context->us == IOService::getPMRootDomain()) {
if ((clientID = copyClientIDForNotification(object, context))) {
uint32_t clientPID = clientID->unsigned32BitValue();
clientID->release();
proc = proc_find(clientPID);
if (proc) {
proc_suspended = get_task_pidsuspended((task_t) proc->task);
if (proc_suspended) {
logClientIDForNotification(object, context, "tellAppClientApplier - Suspended");
#if !(defined(RC_HIDE_N144) || defined(RC_HIDE_N146))
} else if (IOService::getPMRootDomain()->isAOTMode() && get_task_suspended((task_t) proc->task)) {
proc_suspended = true;
context->skippedInDark++;
#endif
}
proc_rele(proc);
if (proc_suspended) {
return;
}
}
}
}
if (context->messageFilter &&
!context->messageFilter(context->us, object, context, NULL, NULL)) {
if (kIOLogDebugPower & gIOKitDebug) {
logClientIDForNotification(object, context, "DROP App");
}
return;
}
context->notSkippedInDark++;
if (kIOLogDebugPower & gIOKitDebug) {
logClientIDForNotification(object, context, "MESG App");
}
context->us->messageClient(context->messageType, object, NULL);
}
bool
IOService::checkForDone( void )
{
int i = 0;
OSObject * theFlag;
if (fResponseArray == NULL) {
return true;
}
for (i = 0;; i++) {
theFlag = fResponseArray->getObject(i);
if (NULL == theFlag) {
break;
}
if (kOSBooleanTrue != theFlag) {
return false;
}
}
return true;
}
bool
IOService::responseValid( uint32_t refcon, int pid )
{
UInt16 serialComponent;
UInt16 ordinalComponent;
OSObject * theFlag;
OSObject *object = NULL;
serialComponent = (refcon >> 16) & 0xFFFF;
ordinalComponent = (refcon & 0xFFFF);
if (serialComponent != fSerialNumber) {
return false;
}
if (fResponseArray == NULL) {
return false;
}
theFlag = fResponseArray->getObject(ordinalComponent);
if (theFlag == NULL) {
return false;
}
if (fNotifyClientArray) {
object = fNotifyClientArray->getObject(ordinalComponent);
}
OSNumber * num;
if ((num = OSDynamicCast(OSNumber, theFlag))) {
AbsoluteTime now;
AbsoluteTime start;
uint64_t nsec;
char name[128];
clock_get_uptime(&now);
AbsoluteTime_to_scalar(&start) = num->unsigned64BitValue();
SUB_ABSOLUTETIME(&now, &start);
absolutetime_to_nanoseconds(now, &nsec);
if (pid != 0) {
name[0] = '\0';
proc_name(pid, name, sizeof(name));
if (nsec > LOG_APP_RESPONSE_TIMES) {
IOLog("PM response took %d ms (%d, %s)\n", NS_TO_MS(nsec),
pid, name);
}
if (nsec > LOG_APP_RESPONSE_MSG_TRACER) {
getPMRootDomain()->pmStatsRecordApplicationResponse(
gIOPMStatsResponseSlow,
name, 0, NS_TO_MS(nsec), pid, object);
} else {
getPMRootDomain()->pmStatsRecordApplicationResponse(
gIOPMStatsResponsePrompt,
name, 0, NS_TO_MS(nsec), pid, object);
}
} else {
getPMRootDomain()->traceAckDelay(object, 0, NS_TO_MS(nsec));
}
if (kIOLogDebugPower & gIOKitDebug) {
PM_LOG("Ack(%u) %u ms\n",
(uint32_t) ordinalComponent,
NS_TO_MS(nsec));
}
theFlag = kOSBooleanFalse;
} else if (object) {
getPMRootDomain()->pmStatsRecordApplicationResponse(
gIOPMStatsResponsePrompt,
NULL, 0, 0, pid, object);
}
if (kOSBooleanFalse == theFlag) {
fResponseArray->replaceObject(ordinalComponent, kOSBooleanTrue);
}
return true;
}
IOReturn
IOService::allowPowerChange( unsigned long refcon )
{
IOPMRequest * request;
if (!initialized) {
return kIOReturnSuccess;
}
request = acquirePMRequest( this, kIOPMRequestTypeAllowPowerChange );
if (!request) {
return kIOReturnNoMemory;
}
request->fArg0 = (void *) refcon;
request->fArg1 = (void *)(uintptr_t) proc_selfpid();
request->fArg2 = (void *) NULL;
submitPMRequest( request );
return kIOReturnSuccess;
}
#ifndef __LP64__
IOReturn
IOService::serializedAllowPowerChange2( unsigned long refcon )
{
return kIOReturnUnsupported;
}
#endif
IOReturn
IOService::cancelPowerChange( unsigned long refcon )
{
IOPMRequest * request;
char name[128];
pid_t pid = proc_selfpid();
if (!initialized) {
return kIOReturnSuccess;
}
name[0] = '\0';
proc_name(pid, name, sizeof(name));
PM_ERROR("PM notification cancel (pid %d, %s)\n", pid, name);
request = acquirePMRequest( this, kIOPMRequestTypeCancelPowerChange );
if (!request) {
return kIOReturnNoMemory;
}
request->fArg0 = (void *) refcon;
request->fArg1 = (void *)(uintptr_t) proc_selfpid();
request->fArg2 = (void *) OSString::withCString(name);
submitPMRequest( request );
return kIOReturnSuccess;
}
void
IOService::cancelIdlePowerDown( IOService * service )
{
IOPMRequest * request;
request = acquirePMRequest(service, kIOPMRequestTypeIdleCancel);
if (request) {
submitPMRequest(request);
}
}
#ifndef __LP64__
IOReturn
IOService::serializedCancelPowerChange2( unsigned long refcon )
{
return kIOReturnUnsupported;
}
void
IOService::PM_Clamp_Timer_Expired( void )
{
}
void
IOService::clampPowerOn( unsigned long duration )
{
}
#endif
IOReturn
IOService::configurePowerStatesReport( IOReportConfigureAction action, void *result )
{
IOReturn rc = kIOReturnSuccess;
size_t reportSize;
unsigned long i;
uint64_t ts;
if (!pwrMgt) {
return kIOReturnUnsupported;
}
if (!fNumberOfPowerStates) {
return kIOReturnSuccess; }
PM_LOCK();
switch (action) {
case kIOReportEnable:
if (fReportBuf) {
fReportClientCnt++;
break;
}
reportSize = STATEREPORT_BUFSIZE(fNumberOfPowerStates);
fReportBuf = IOMalloc(reportSize);
if (!fReportBuf) {
rc = kIOReturnNoMemory;
break;
}
memset(fReportBuf, 0, reportSize);
STATEREPORT_INIT(fNumberOfPowerStates, fReportBuf, reportSize,
getRegistryEntryID(), kPMPowerStatesChID, kIOReportCategoryPower);
for (i = 0; i < fNumberOfPowerStates; i++) {
unsigned bits = 0;
if (fPowerStates[i].capabilityFlags & kIOPMPowerOn) {
bits |= kPMReportPowerOn;
}
if (fPowerStates[i].capabilityFlags & kIOPMDeviceUsable) {
bits |= kPMReportDeviceUsable;
}
if (fPowerStates[i].capabilityFlags & kIOPMLowPower) {
bits |= kPMReportLowPower;
}
STATEREPORT_SETSTATEID(fReportBuf, i, ((bits & 0xff) << 8) |
((StateOrder(fMaxPowerState) & 0xf) << 4) | (StateOrder(i) & 0xf));
}
ts = mach_absolute_time();
STATEREPORT_SETSTATE(fReportBuf, fCurrentPowerState, ts);
break;
case kIOReportDisable:
if (fReportClientCnt == 0) {
rc = kIOReturnBadArgument;
break;
}
if (fReportClientCnt == 1) {
IOFree(fReportBuf, STATEREPORT_BUFSIZE(fNumberOfPowerStates));
fReportBuf = NULL;
}
fReportClientCnt--;
break;
case kIOReportGetDimensions:
if (fReportBuf) {
STATEREPORT_UPDATERES(fReportBuf, kIOReportGetDimensions, result);
}
break;
}
PM_UNLOCK();
return rc;
}
IOReturn
IOService::updatePowerStatesReport( IOReportConfigureAction action, void *result, void *destination )
{
uint32_t size2cpy;
void *data2cpy;
uint64_t ts;
IOReturn rc = kIOReturnSuccess;
IOBufferMemoryDescriptor *dest = OSDynamicCast(IOBufferMemoryDescriptor, (OSObject *)destination);
if (!pwrMgt) {
return kIOReturnUnsupported;
}
if (!fNumberOfPowerStates) {
return kIOReturnSuccess;
}
if (!result || !dest) {
return kIOReturnBadArgument;
}
PM_LOCK();
switch (action) {
case kIOReportCopyChannelData:
if (!fReportBuf) {
rc = kIOReturnNotOpen;
break;
}
ts = mach_absolute_time();
STATEREPORT_UPDATEPREP(fReportBuf, ts, data2cpy, size2cpy);
if (size2cpy > (dest->getCapacity() - dest->getLength())) {
rc = kIOReturnOverrun;
break;
}
STATEREPORT_UPDATERES(fReportBuf, kIOReportCopyChannelData, result);
dest->appendBytes(data2cpy, size2cpy);
break;
default:
break;
}
PM_UNLOCK();
return rc;
}
IOReturn
IOService::configureSimplePowerReport(IOReportConfigureAction action, void *result )
{
IOReturn rc = kIOReturnSuccess;
if (!pwrMgt) {
return kIOReturnUnsupported;
}
if (!fNumberOfPowerStates) {
return rc;
}
switch (action) {
case kIOReportEnable:
case kIOReportDisable:
break;
case kIOReportGetDimensions:
SIMPLEREPORT_UPDATERES(kIOReportGetDimensions, result);
break;
}
return rc;
}
IOReturn
IOService::updateSimplePowerReport( IOReportConfigureAction action, void *result, void *destination )
{
uint32_t size2cpy;
void *data2cpy;
uint64_t buf[SIMPLEREPORT_BUFSIZE / sizeof(uint64_t) + 1]; IOBufferMemoryDescriptor *dest = OSDynamicCast(IOBufferMemoryDescriptor, (OSObject *)destination);
IOReturn rc = kIOReturnSuccess;
unsigned bits = 0;
if (!pwrMgt) {
return kIOReturnUnsupported;
}
if (!result || !dest) {
return kIOReturnBadArgument;
}
if (!fNumberOfPowerStates) {
return rc;
}
PM_LOCK();
switch (action) {
case kIOReportCopyChannelData:
SIMPLEREPORT_INIT(buf, sizeof(buf), getRegistryEntryID(), kPMCurrStateChID, kIOReportCategoryPower);
if (fPowerStates[fCurrentPowerState].capabilityFlags & kIOPMPowerOn) {
bits |= kPMReportPowerOn;
}
if (fPowerStates[fCurrentPowerState].capabilityFlags & kIOPMDeviceUsable) {
bits |= kPMReportDeviceUsable;
}
if (fPowerStates[fCurrentPowerState].capabilityFlags & kIOPMLowPower) {
bits |= kPMReportLowPower;
}
SIMPLEREPORT_SETVALUE(buf, ((bits & 0xff) << 8) | ((StateOrder(fMaxPowerState) & 0xf) << 4) |
(StateOrder(fCurrentPowerState) & 0xf));
SIMPLEREPORT_UPDATEPREP(buf, data2cpy, size2cpy);
if (size2cpy > (dest->getCapacity() - dest->getLength())) {
rc = kIOReturnOverrun;
break;
}
SIMPLEREPORT_UPDATERES(kIOReportCopyChannelData, result);
dest->appendBytes(data2cpy, size2cpy);
break;
default:
break;
}
PM_UNLOCK();
return kIOReturnSuccess;
}
IOReturn
IOService::setPowerState(
unsigned long powerStateOrdinal, IOService * whatDevice )
{
return IOPMNoErr;
}
IOPMPowerStateIndex
IOService::getPowerStateForDomainFlags( IOPMPowerFlags flags )
{
IOPMPowerStateIndex stateIndex;
if (!fNumberOfPowerStates) {
return kPowerStateZero;
}
for (int order = fNumberOfPowerStates - 1; order >= 0; order--) {
stateIndex = fPowerStates[order].stateOrderToIndex;
if ((flags & fPowerStates[stateIndex].inputPowerFlags) ==
fPowerStates[stateIndex].inputPowerFlags) {
return stateIndex;
}
}
return kPowerStateZero;
}
unsigned long
IOService::maxCapabilityForDomainState( IOPMPowerFlags domainState )
{
return getPowerStateForDomainFlags(domainState);
}
unsigned long
IOService::initialPowerStateForDomainState( IOPMPowerFlags domainState )
{
if (fResetPowerStateOnWake && (domainState & kIOPMRootDomainState)) {
return kPowerStateZero;
}
return getPowerStateForDomainFlags(domainState);
}
unsigned long
IOService::powerStateForDomainState( IOPMPowerFlags domainState )
{
return getPowerStateForDomainFlags(domainState);
}
#ifndef __LP64__
bool
IOService::didYouWakeSystem( void )
{
return false;
}
#endif
IOReturn
IOService::powerStateWillChangeTo( IOPMPowerFlags, unsigned long, IOService * )
{
return kIOPMAckImplied;
}
IOReturn
IOService::powerStateDidChangeTo( IOPMPowerFlags, unsigned long, IOService * )
{
return kIOPMAckImplied;
}
void
IOService::powerChangeDone( unsigned long )
{
}
#ifndef __LP64__
IOReturn
IOService::newTemperature( long currentTemp, IOService * whichZone )
{
return IOPMNoErr;
}
#endif
void
IOService::systemWillShutdown( IOOptionBits specifier )
{
IOPMrootDomain * rootDomain = IOService::getPMRootDomain();
if (rootDomain) {
rootDomain->acknowledgeSystemWillShutdown( this );
}
}
IOPMRequest *
IOService::acquirePMRequest( IOService * target, IOOptionBits requestType,
IOPMRequest * active )
{
IOPMRequest * request;
assert(target);
request = IOPMRequest::create();
if (request) {
request->init( target, requestType );
if (active) {
IOPMRequest * root = active->getRootRequest();
if (root) {
request->attachRootRequest(root);
}
}
} else {
PM_ERROR("%s: No memory for PM request type 0x%x\n",
target->getName(), (uint32_t) requestType);
}
return request;
}
void
IOService::releasePMRequest( IOPMRequest * request )
{
if (request) {
request->reset();
request->release();
}
}
void
IOService::submitPMRequest( IOPMRequest * request )
{
assert( request );
assert( gIOPMReplyQueue );
assert( gIOPMRequestQueue );
PM_LOG1("[+ %02lx] %p [%p %s] %p %p %p\n",
(long)request->getType(), OBFUSCATE(request),
OBFUSCATE(request->getTarget()), request->getTarget()->getName(),
OBFUSCATE(request->fArg0),
OBFUSCATE(request->fArg1), OBFUSCATE(request->fArg2));
if (request->isReplyType()) {
gIOPMReplyQueue->queuePMRequest( request );
} else {
gIOPMRequestQueue->queuePMRequest( request );
}
}
void
IOService::submitPMRequests( IOPMRequest ** requests, IOItemCount count )
{
assert( requests );
assert( count > 0 );
assert( gIOPMRequestQueue );
for (IOItemCount i = 0; i < count; i++) {
IOPMRequest * req = requests[i];
PM_LOG1("[+ %02lx] %p [%p %s] %p %p %p\n",
(long)req->getType(), OBFUSCATE(req),
OBFUSCATE(req->getTarget()), req->getTarget()->getName(),
OBFUSCATE(req->fArg0),
OBFUSCATE(req->fArg1), OBFUSCATE(req->fArg2));
}
gIOPMRequestQueue->queuePMRequestChain( requests, count );
}
bool
IOService::actionPMRequestQueue(
IOPMRequest * request,
IOPMRequestQueue * queue )
{
bool more;
if (initialized) {
more = gIOPMWorkQueue->queuePMRequest(request, pwrMgt);
} else {
PM_LOG("%s: PM not initialized\n", getName());
PM_LOG1("[- %02x] %p [%p %s] !initialized\n",
request->getType(), OBFUSCATE(request),
OBFUSCATE(this), getName());
more = gIOPMCompletionQueue->queuePMRequest(request);
if (more) {
gIOPMWorkQueue->incrementProducerCount();
}
}
return more;
}
bool
IOService::actionPMCompletionQueue(
IOPMRequest * request,
IOPMCompletionQueue * queue )
{
bool more = (request->getNextRequest() != NULL);
IOPMRequest * root = request->getRootRequest();
if (root && (root != request)) {
more = true;
}
if (more) {
gIOPMWorkQueue->incrementProducerCount();
}
releasePMRequest( request );
return more;
}
bool
IOService::actionPMWorkQueueRetire( IOPMRequest * request, IOPMWorkQueue * queue )
{
assert(request && queue);
PM_LOG1("[- %02x] %p [%p %s] state %d, busy %d\n",
request->getType(), OBFUSCATE(request),
OBFUSCATE(this), getName(),
fMachineState, gIOPMBusyRequestCount);
if (request->getType() == kIOPMRequestTypeActivityTickle) {
uint32_t tickleFlags = (uint32_t)(uintptr_t) request->fArg1;
if ((tickleFlags & kTickleTypePowerDrop) && fIdleTimerPeriod) {
restartIdleTimer();
} else if (tickleFlags == (kTickleTypeActivity | kTickleTypePowerRise)) {
fIdleTimerGeneration++;
}
}
return gIOPMCompletionQueue->queuePMRequest( request );
}
bool
IOService::isPMBlocked( IOPMRequest * request, int count )
{
int reason = 0;
do {
if (kIOPM_Finished == fMachineState) {
break;
}
if (kIOPM_DriverThreadCallDone == fMachineState) {
if (fDriverCallBusy) {
reason = 5 + fDriverCallReason;
}
break;
}
if (fDriverTimer) {
reason = 1; break;
}
if (fHeadNotePendingAcks) {
reason = 2; break;
}
if (fResponseArray) {
reason = 3; break;
}
if (fSettleTimeUS) {
reason = 4; break;
}
} while (false);
fWaitReason = reason;
if (reason) {
if (count) {
PM_LOG1("[B %02x] %p [%p %s] state %d, reason %d\n",
request->getType(), OBFUSCATE(request),
OBFUSCATE(this), getName(),
fMachineState, reason);
}
return true;
}
return false;
}
bool
IOService::actionPMWorkQueueInvoke( IOPMRequest * request, IOPMWorkQueue * queue )
{
bool done = false;
int loop = 0;
assert(request && queue);
while (isPMBlocked(request, loop++) == false) {
PM_LOG1("[W %02x] %p [%p %s] state %d\n",
request->getType(), OBFUSCATE(request),
OBFUSCATE(this), getName(), fMachineState);
gIOPMRequest = request;
gIOPMWorkInvokeCount++;
switch (fMachineState) {
case kIOPM_Finished:
start_watchdog_timer();
executePMRequest( request );
break;
case kIOPM_OurChangeTellClientsPowerDown:
if (IS_ROOT_DOMAIN) {
bool cancel = (bool) fDoNotPowerDown;
getPMRootDomain()->askChangeDownDone(
&fHeadNoteChangeFlags, &cancel);
fDoNotPowerDown = cancel;
}
if (!fDoNotPowerDown) {
OurChangeTellClientsPowerDown();
} else {
OUR_PMLog(kPMLogIdleCancel, (uintptr_t) this, fMachineState);
PM_ERROR("%s: idle cancel, state %u\n", fName, fMachineState);
if (IS_ROOT_DOMAIN) {
tellChangeUp(fCurrentPowerState);
} else {
tellNoChangeDown(fHeadNotePowerState);
}
fHeadNoteChangeFlags |= kIOPMNotDone;
OurChangeFinish();
}
break;
case kIOPM_OurChangeTellUserPMPolicyPowerDown:
if (fDoNotPowerDown) {
OUR_PMLog(kPMLogIdleCancel, (uintptr_t) this, fMachineState);
PM_ERROR("%s: idle cancel, state %u\n", fName, fMachineState);
if (IS_ROOT_DOMAIN) {
tellChangeUp(fCurrentPowerState);
} else {
tellNoChangeDown(fHeadNotePowerState);
}
fHeadNoteChangeFlags |= kIOPMNotDone;
OurChangeFinish();
} else {
OurChangeTellUserPMPolicyPowerDown();
}
break;
case kIOPM_OurChangeTellPriorityClientsPowerDown:
if (fDoNotPowerDown) {
OUR_PMLog(kPMLogIdleCancel, (uintptr_t) this, fMachineState);
PM_ERROR("%s: idle revert, state %u\n", fName, fMachineState);
tellChangeUp(fCurrentPowerState);
fHeadNoteChangeFlags |= kIOPMNotDone;
OurChangeFinish();
} else {
OurChangeTellPriorityClientsPowerDown();
}
break;
case kIOPM_OurChangeNotifyInterestedDriversWillChange:
OurChangeNotifyInterestedDriversWillChange();
break;
case kIOPM_OurChangeSetPowerState:
OurChangeSetPowerState();
break;
case kIOPM_OurChangeWaitForPowerSettle:
OurChangeWaitForPowerSettle();
break;
case kIOPM_OurChangeNotifyInterestedDriversDidChange:
OurChangeNotifyInterestedDriversDidChange();
break;
case kIOPM_OurChangeTellCapabilityDidChange:
OurChangeTellCapabilityDidChange();
break;
case kIOPM_OurChangeFinish:
OurChangeFinish();
break;
case kIOPM_ParentChangeTellPriorityClientsPowerDown:
ParentChangeTellPriorityClientsPowerDown();
break;
case kIOPM_ParentChangeNotifyInterestedDriversWillChange:
ParentChangeNotifyInterestedDriversWillChange();
break;
case kIOPM_ParentChangeSetPowerState:
ParentChangeSetPowerState();
break;
case kIOPM_ParentChangeWaitForPowerSettle:
ParentChangeWaitForPowerSettle();
break;
case kIOPM_ParentChangeNotifyInterestedDriversDidChange:
ParentChangeNotifyInterestedDriversDidChange();
break;
case kIOPM_ParentChangeTellCapabilityDidChange:
ParentChangeTellCapabilityDidChange();
break;
case kIOPM_ParentChangeAcknowledgePowerChange:
ParentChangeAcknowledgePowerChange();
break;
case kIOPM_DriverThreadCallDone:
switch (fDriverCallReason) {
case kDriverCallInformPreChange:
case kDriverCallInformPostChange:
notifyInterestedDriversDone();
break;
case kDriverCallSetPowerState:
notifyControllingDriverDone();
break;
case kRootDomainInformPreChange:
notifyRootDomainDone();
break;
default:
panic("%s: bad call reason %x",
getName(), fDriverCallReason);
}
break;
case kIOPM_NotifyChildrenOrdered:
notifyChildrenOrdered();
break;
case kIOPM_NotifyChildrenDelayed:
notifyChildrenDelayed();
break;
case kIOPM_NotifyChildrenStart:
MS_POP();
notifyRootDomain();
break;
case kIOPM_SyncTellClientsPowerDown:
if (IS_ROOT_DOMAIN) {
bool cancel = (bool) fDoNotPowerDown;
getPMRootDomain()->askChangeDownDone(
&fHeadNoteChangeFlags, &cancel);
fDoNotPowerDown = cancel;
}
if (!fDoNotPowerDown) {
fMachineState = kIOPM_SyncTellPriorityClientsPowerDown;
fOutOfBandParameter = kNotifyApps;
tellChangeDown(fHeadNotePowerState);
} else {
OUR_PMLog(kPMLogIdleCancel, (uintptr_t) this, fMachineState);
PM_ERROR("%s: idle cancel, state %u\n", fName, fMachineState);
tellNoChangeDown(fHeadNotePowerState);
fHeadNoteChangeFlags |= kIOPMNotDone;
OurChangeFinish();
}
break;
case kIOPM_SyncTellPriorityClientsPowerDown:
if (!fDoNotPowerDown) {
fMachineState = kIOPM_SyncNotifyWillChange;
fOutOfBandParameter = kNotifyPriority;
tellChangeDown(fHeadNotePowerState);
} else {
OUR_PMLog(kPMLogIdleCancel, (uintptr_t) this, fMachineState);
PM_ERROR("%s: idle revert, state %u\n", fName, fMachineState);
tellChangeUp(fCurrentPowerState);
fHeadNoteChangeFlags |= kIOPMNotDone;
OurChangeFinish();
}
break;
case kIOPM_SyncNotifyWillChange:
if (kIOPMSyncNoChildNotify & fHeadNoteChangeFlags) {
fMachineState = kIOPM_SyncFinish;
continue;
}
fMachineState = kIOPM_SyncNotifyDidChange;
fDriverCallReason = kDriverCallInformPreChange;
notifyChildren();
break;
case kIOPM_SyncNotifyDidChange:
fIsPreChange = false;
if (fHeadNoteChangeFlags & kIOPMParentInitiated) {
fMachineState = kIOPM_SyncFinish;
} else {
assert(IS_ROOT_DOMAIN);
fMachineState = kIOPM_SyncTellCapabilityDidChange;
}
fDriverCallReason = kDriverCallInformPostChange;
notifyChildren();
break;
case kIOPM_SyncTellCapabilityDidChange:
tellSystemCapabilityChange( kIOPM_SyncFinish );
break;
case kIOPM_SyncFinish:
if (fHeadNoteChangeFlags & kIOPMParentInitiated) {
ParentChangeAcknowledgePowerChange();
} else {
OurChangeFinish();
}
break;
case kIOPM_TellCapabilityChangeDone:
if (fIsPreChange) {
if (fOutOfBandParameter == kNotifyCapabilityChangePriority) {
MS_POP(); continue;
}
fOutOfBandParameter = kNotifyCapabilityChangePriority;
} else {
if (fOutOfBandParameter == kNotifyCapabilityChangeApps) {
MS_POP(); continue;
}
fOutOfBandParameter = kNotifyCapabilityChangeApps;
}
tellClientsWithResponse( fOutOfBandMessage );
break;
default:
panic("PMWorkQueueInvoke: unknown machine state %x",
fMachineState);
}
gIOPMRequest = NULL;
if (fMachineState == kIOPM_Finished) {
stop_watchdog_timer();
done = true;
break;
}
}
return done;
}
void
IOService::executePMRequest( IOPMRequest * request )
{
assert( kIOPM_Finished == fMachineState );
switch (request->getType()) {
case kIOPMRequestTypePMStop:
handlePMstop( request );
break;
case kIOPMRequestTypeAddPowerChild1:
addPowerChild1( request );
break;
case kIOPMRequestTypeAddPowerChild2:
addPowerChild2( request );
break;
case kIOPMRequestTypeAddPowerChild3:
addPowerChild3( request );
break;
case kIOPMRequestTypeRegisterPowerDriver:
handleRegisterPowerDriver( request );
break;
case kIOPMRequestTypeAdjustPowerState:
fAdjustPowerScheduled = false;
adjustPowerState();
break;
case kIOPMRequestTypePowerDomainWillChange:
handlePowerDomainWillChangeTo( request );
break;
case kIOPMRequestTypePowerDomainDidChange:
handlePowerDomainDidChangeTo( request );
break;
case kIOPMRequestTypeRequestPowerState:
case kIOPMRequestTypeRequestPowerStateOverride:
handleRequestPowerState( request );
break;
case kIOPMRequestTypePowerOverrideOnPriv:
case kIOPMRequestTypePowerOverrideOffPriv:
handlePowerOverrideChanged( request );
break;
case kIOPMRequestTypeActivityTickle:
handleActivityTickle( request );
break;
case kIOPMRequestTypeSynchronizePowerTree:
handleSynchronizePowerTree( request );
break;
case kIOPMRequestTypeSetIdleTimerPeriod:
{
fIdleTimerPeriod = (uintptr_t) request->fArg0;
fNextIdleTimerPeriod = fIdleTimerPeriod;
if ((false == fLockedFlags.PMStop) && (fIdleTimerPeriod > 0)) {
restartIdleTimer();
}
}
break;
case kIOPMRequestTypeIgnoreIdleTimer:
fIdleTimerIgnored = request->fArg0 ? 1 : 0;
break;
case kIOPMRequestTypeQuiescePowerTree:
gIOPMWorkQueue->finishQuiesceRequest(request);
break;
default:
panic("executePMRequest: unknown request type %x", request->getType());
}
}
bool
IOService::actionPMReplyQueue( IOPMRequest * request, IOPMRequestQueue * queue )
{
bool more = false;
assert( request && queue );
assert( request->isReplyType());
PM_LOG1("[A %02x] %p [%p %s] state %d\n",
request->getType(), OBFUSCATE(request),
OBFUSCATE(this), getName(), fMachineState);
switch (request->getType()) {
case kIOPMRequestTypeAllowPowerChange:
case kIOPMRequestTypeCancelPowerChange:
if (responseValid((uint32_t)(uintptr_t) request->fArg0,
(int)(uintptr_t) request->fArg1)) {
if (kIOPMRequestTypeCancelPowerChange == request->getType()) {
if ((fMachineState == kIOPM_OurChangeTellUserPMPolicyPowerDown)
|| (fMachineState == kIOPM_OurChangeTellPriorityClientsPowerDown)
|| ((fHeadNoteChangeFlags & kIOPMSkipAskPowerDown) == 0)) {
fDoNotPowerDown = true;
OSString * name = (OSString *) request->fArg2;
getPMRootDomain()->pmStatsRecordApplicationResponse(
gIOPMStatsResponseCancel,
name ? name->getCStringNoCopy() : "", 0,
0, (int)(uintptr_t) request->fArg1, NULL);
}
}
if (checkForDone()) {
stop_ack_timer();
cleanClientResponses(false);
more = true;
}
}
if (request->getType() == kIOPMRequestTypeCancelPowerChange) {
OSObject * obj = (OSObject *) request->fArg2;
if (obj) {
obj->release();
}
}
break;
case kIOPMRequestTypeAckPowerChange:
more = handleAcknowledgePowerChange( request );
break;
case kIOPMRequestTypeAckSetPowerState:
if (fDriverTimer == -1) {
OUR_PMLog(kPMLogDriverAcknowledgeSet,
(uintptr_t) this, fDriverTimer);
fDriverTimer = 0;
} else if (fDriverTimer > 0) {
stop_ack_timer();
getPMRootDomain()->reset_watchdog_timer(this, 0);
uint64_t nsec = computeTimeDeltaNS(&fDriverCallStartTime);
if (nsec > LOG_SETPOWER_TIMES) {
getPMRootDomain()->pmStatsRecordApplicationResponse(
gIOPMStatsDriverPSChangeSlow,
fName, kDriverCallSetPowerState, NS_TO_MS(nsec), getRegistryEntryID(),
NULL, fHeadNotePowerState);
}
OUR_PMLog(kPMLogDriverAcknowledgeSet, (uintptr_t) this, fDriverTimer);
fDriverTimer = 0;
more = true;
} else {
OUR_PMLog(kPMLogAcknowledgeErr4, (uintptr_t) this, 0);
}
break;
case kIOPMRequestTypeInterestChanged:
handleInterestChanged( request );
more = true;
break;
case kIOPMRequestTypeIdleCancel:
if ((fMachineState == kIOPM_OurChangeTellClientsPowerDown)
|| (fMachineState == kIOPM_OurChangeTellUserPMPolicyPowerDown)
|| (fMachineState == kIOPM_OurChangeTellPriorityClientsPowerDown)
|| (fMachineState == kIOPM_SyncTellClientsPowerDown)
|| (fMachineState == kIOPM_SyncTellPriorityClientsPowerDown)) {
OUR_PMLog(kPMLogIdleCancel, (uintptr_t) this, fMachineState);
PM_LOG2("%s: cancel from machine state %d\n",
getName(), fMachineState);
fDoNotPowerDown = true;
if ((fMachineState == kIOPM_OurChangeTellPriorityClientsPowerDown) ||
(fMachineState == kIOPM_OurChangeTellUserPMPolicyPowerDown) ||
(fMachineState == kIOPM_SyncTellPriorityClientsPowerDown) ||
(fMachineState == kIOPM_SyncTellClientsPowerDown)) {
cleanClientResponses(false);
}
more = true;
}
break;
case kIOPMRequestTypeChildNotifyDelayCancel:
if (fMachineState == kIOPM_NotifyChildrenDelayed) {
PM_LOG2("%s: delay notify cancelled\n", getName());
notifyChildrenDelayed();
}
break;
default:
panic("PMReplyQueue: unknown reply type %x", request->getType());
}
more |= gIOPMCompletionQueue->queuePMRequest(request);
if (more) {
gIOPMWorkQueue->incrementProducerCount();
}
return more;
}
bool
IOService::assertPMDriverCall(
IOPMDriverCallEntry * entry,
IOOptionBits method,
const IOPMinformee * inform,
IOOptionBits options )
{
IOService * target = NULL;
bool ok = false;
if (!initialized) {
return false;
}
PM_LOCK();
if (fLockedFlags.PMStop) {
goto fail;
}
if (((options & kIOPMDriverCallNoInactiveCheck) == 0) && isInactive()) {
goto fail;
}
if (inform) {
if (!inform->active) {
goto fail;
}
target = inform->whatObject;
if (target->isInactive()) {
goto fail;
}
}
switch (method) {
case kIOPMDriverCallMethodSetPowerState:
entry->callMethod = OSMemberFunctionCast(const void *, fControllingDriver, &IOService::setPowerState);
break;
case kIOPMDriverCallMethodWillChange:
entry->callMethod = OSMemberFunctionCast(const void *, target, &IOService::powerStateWillChangeTo);
break;
case kIOPMDriverCallMethodDidChange:
entry->callMethod = OSMemberFunctionCast(const void *, target, &IOService::powerStateDidChangeTo);
break;
case kIOPMDriverCallMethodUnknown:
case kIOPMDriverCallMethodSetAggressive:
default:
entry->callMethod = NULL;
break;
}
entry->thread = current_thread();
entry->target = target;
queue_enter(&fPMDriverCallQueue, entry, IOPMDriverCallEntry *, link);
ok = true;
fail:
PM_UNLOCK();
return ok;
}
void
IOService::deassertPMDriverCall( IOPMDriverCallEntry * entry )
{
bool wakeup = false;
PM_LOCK();
assert( !queue_empty(&fPMDriverCallQueue));
queue_remove(&fPMDriverCallQueue, entry, IOPMDriverCallEntry *, link);
if (fLockedFlags.PMDriverCallWait) {
wakeup = true;
}
PM_UNLOCK();
if (wakeup) {
PM_LOCK_WAKEUP(&fPMDriverCallQueue);
}
}
bool
IOService::getBlockingDriverCall(thread_t *thread, const void **callMethod)
{
const IOPMDriverCallEntry * entry = NULL;
bool blocked = false;
if (!initialized) {
return false;
}
if (current_thread() != gIOPMWatchDogThread) {
return false;
}
PM_LOCK();
entry = qe_queue_first(&fPMDriverCallQueue, IOPMDriverCallEntry, link);
if (entry) {
*thread = entry->thread;
*callMethod = entry->callMethod;
blocked = true;
}
PM_UNLOCK();
return blocked;
}
void
IOService::waitForPMDriverCall( IOService * target )
{
const IOPMDriverCallEntry * entry;
thread_t thread = current_thread();
AbsoluteTime deadline;
int waitResult;
bool log = true;
bool wait;
do {
wait = false;
queue_iterate(&fPMDriverCallQueue, entry, const IOPMDriverCallEntry *, link)
{
if (target && (target != entry->target)) {
continue;
}
if (entry->thread == thread) {
if (log) {
PM_LOG("%s: %s(%s) on PM thread\n",
fName, __FUNCTION__, target ? target->getName() : "");
OSReportWithBacktrace("%s: %s(%s) on PM thread\n",
fName, __FUNCTION__, target ? target->getName() : "");
log = false;
}
continue;
}
wait = true;
break;
}
if (wait) {
fLockedFlags.PMDriverCallWait = true;
clock_interval_to_deadline(15, kSecondScale, &deadline);
waitResult = PM_LOCK_SLEEP(&fPMDriverCallQueue, deadline);
fLockedFlags.PMDriverCallWait = false;
if (THREAD_TIMED_OUT == waitResult) {
PM_ERROR("%s: waitForPMDriverCall timeout\n", fName);
wait = false;
}
}
} while (wait);
}
const char *
IOService::getIOMessageString( uint32_t msg )
{
#define MSG_ENTRY(x) {(int) x, #x}
static const IONamedValue msgNames[] = {
MSG_ENTRY( kIOMessageCanDevicePowerOff ),
MSG_ENTRY( kIOMessageDeviceWillPowerOff ),
MSG_ENTRY( kIOMessageDeviceWillNotPowerOff ),
MSG_ENTRY( kIOMessageDeviceHasPoweredOn ),
MSG_ENTRY( kIOMessageCanSystemPowerOff ),
MSG_ENTRY( kIOMessageSystemWillPowerOff ),
MSG_ENTRY( kIOMessageSystemWillNotPowerOff ),
MSG_ENTRY( kIOMessageCanSystemSleep ),
MSG_ENTRY( kIOMessageSystemWillSleep ),
MSG_ENTRY( kIOMessageSystemWillNotSleep ),
MSG_ENTRY( kIOMessageSystemHasPoweredOn ),
MSG_ENTRY( kIOMessageSystemWillRestart ),
MSG_ENTRY( kIOMessageSystemWillPowerOn ),
MSG_ENTRY( kIOMessageSystemCapabilityChange ),
MSG_ENTRY( kIOPMMessageLastCallBeforeSleep ),
MSG_ENTRY( kIOMessageSystemPagingOff ),
{ 0, NULL }
};
return IOFindNameForValue(msg, msgNames);
}
OSDefineMetaClassAndStructors( IOPMRequest, IOCommand );
IOPMRequest *
IOPMRequest::create( void )
{
IOPMRequest * me = OSTypeAlloc(IOPMRequest);
if (me && !me->init(NULL, kIOPMRequestTypeInvalid)) {
me->release();
me = NULL;
}
return me;
}
bool
IOPMRequest::init( IOService * target, IOOptionBits type )
{
if (!IOCommand::init()) {
return false;
}
fRequestType = type;
fTarget = target;
if (fTarget) {
fTarget->retain();
}
fIsQuiesceBlocker = ((fTarget != gIOPMRootNode) &&
(fTarget != IOService::getPMRootDomain()));
return true;
}
void
IOPMRequest::reset( void )
{
assert( fWorkWaitCount == 0 );
assert( fFreeWaitCount == 0 );
detachNextRequest();
detachRootRequest();
if (fCompletionAction && (fRequestType == kIOPMRequestTypeQuiescePowerTree)) {
fCompletionAction(fCompletionTarget, fCompletionParam);
fCompletionAction = NULL;
}
fRequestType = kIOPMRequestTypeInvalid;
if (fTarget) {
fTarget->release();
fTarget = NULL;
}
}
bool
IOPMRequest::attachNextRequest( IOPMRequest * next )
{
bool ok = false;
if (!fRequestNext) {
fRequestNext = next;
fRequestNext->fWorkWaitCount++;
#if LOG_REQUEST_ATTACH
PM_LOG("Attached next: %p [0x%x] -> %p [0x%x, %u] %s\n",
OBFUSCATE(this), fRequestType, OBFUSCATE(fRequestNext),
fRequestNext->fRequestType,
(uint32_t) fRequestNext->fWorkWaitCount,
fTarget->getName());
#endif
ok = true;
}
return ok;
}
bool
IOPMRequest::detachNextRequest( void )
{
bool ok = false;
if (fRequestNext) {
assert(fRequestNext->fWorkWaitCount);
if (fRequestNext->fWorkWaitCount) {
fRequestNext->fWorkWaitCount--;
}
#if LOG_REQUEST_ATTACH
PM_LOG("Detached next: %p [0x%x] -> %p [0x%x, %u] %s\n",
OBFUSCATE(this), fRequestType, OBFUSCATE(fRequestNext),
fRequestNext->fRequestType,
(uint32_t) fRequestNext->fWorkWaitCount,
fTarget->getName());
#endif
fRequestNext = NULL;
ok = true;
}
return ok;
}
bool
IOPMRequest::attachRootRequest( IOPMRequest * root )
{
bool ok = false;
if (!fRequestRoot) {
fRequestRoot = root;
fRequestRoot->fFreeWaitCount++;
#if LOG_REQUEST_ATTACH
PM_LOG("Attached root: %p [0x%x] -> %p [0x%x, %u] %s\n",
OBFUSCATE(this), (uint32_t) fType, OBFUSCATE(fRequestRoot),
(uint32_t) fRequestRoot->fType,
(uint32_t) fRequestRoot->fFreeWaitCount,
fTarget->getName());
#endif
ok = true;
}
return ok;
}
bool
IOPMRequest::detachRootRequest( void )
{
bool ok = false;
if (fRequestRoot) {
assert(fRequestRoot->fFreeWaitCount);
if (fRequestRoot->fFreeWaitCount) {
fRequestRoot->fFreeWaitCount--;
}
#if LOG_REQUEST_ATTACH
PM_LOG("Detached root: %p [0x%x] -> %p [0x%x, %u] %s\n",
OBFUSCATE(this), (uint32_t) fType, OBFUSCATE(fRequestRoot),
(uint32_t) fRequestRoot->fType,
(uint32_t) fRequestRoot->fFreeWaitCount,
fTarget->getName());
#endif
fRequestRoot = NULL;
ok = true;
}
return ok;
}
OSDefineMetaClassAndStructors( IOPMRequestQueue, IOEventSource );
IOPMRequestQueue *
IOPMRequestQueue::create( IOService * inOwner, Action inAction )
{
IOPMRequestQueue * me = OSTypeAlloc(IOPMRequestQueue);
if (me && !me->init(inOwner, inAction)) {
me->release();
me = NULL;
}
return me;
}
bool
IOPMRequestQueue::init( IOService * inOwner, Action inAction )
{
if (!inAction || !IOEventSource::init(inOwner, (IOEventSourceAction)inAction)) {
return false;
}
queue_init(&fQueue);
fLock = IOLockAlloc();
return fLock != NULL;
}
void
IOPMRequestQueue::free( void )
{
if (fLock) {
IOLockFree(fLock);
fLock = NULL;
}
return IOEventSource::free();
}
void
IOPMRequestQueue::queuePMRequest( IOPMRequest * request )
{
assert(request);
IOLockLock(fLock);
queue_enter(&fQueue, request, typeof(request), fCommandChain);
IOLockUnlock(fLock);
if (workLoop) {
signalWorkAvailable();
}
}
void
IOPMRequestQueue::queuePMRequestChain( IOPMRequest ** requests, IOItemCount count )
{
IOPMRequest * next;
assert(requests && count);
IOLockLock(fLock);
while (count--) {
next = *requests;
requests++;
queue_enter(&fQueue, next, typeof(next), fCommandChain);
}
IOLockUnlock(fLock);
if (workLoop) {
signalWorkAvailable();
}
}
bool
IOPMRequestQueue::checkForWork( void )
{
Action dqAction = (Action) action;
IOPMRequest * request;
IOService * target;
int dequeueCount = 0;
bool more = false;
IOLockLock( fLock );
while (!queue_empty(&fQueue)) {
if (dequeueCount++ >= kMaxDequeueCount) {
more = true;
break;
}
queue_remove_first(&fQueue, request, typeof(request), fCommandChain);
IOLockUnlock(fLock);
target = request->getTarget();
assert(target);
more |= (*dqAction)( target, request, this );
IOLockLock( fLock );
}
IOLockUnlock( fLock );
return more;
}
OSDefineMetaClassAndStructors( IOPMWorkQueue, IOEventSource );
IOPMWorkQueue *
IOPMWorkQueue::create( IOService * inOwner, Action invoke, Action retire )
{
IOPMWorkQueue * me = OSTypeAlloc(IOPMWorkQueue);
if (me && !me->init(inOwner, invoke, retire)) {
me->release();
me = NULL;
}
return me;
}
bool
IOPMWorkQueue::init( IOService * inOwner, Action invoke, Action retire )
{
if (!invoke || !retire ||
!IOEventSource::init(inOwner, (IOEventSourceAction)NULL)) {
return false;
}
queue_init(&fWorkQueue);
fInvokeAction = invoke;
fRetireAction = retire;
fConsumerCount = fProducerCount = 0;
return true;
}
bool
IOPMWorkQueue::queuePMRequest( IOPMRequest * request, IOServicePM * pwrMgt )
{
queue_head_t * requestQueue;
bool more = false;
bool empty;
assert( request );
assert( pwrMgt );
assert( onThread());
assert( queue_next(&request->fCommandChain) ==
queue_prev(&request->fCommandChain));
gIOPMBusyRequestCount++;
if (request->isQuiesceType()) {
if ((request->getTarget() == gIOPMRootNode) && !fQuiesceStartTime) {
fQuiesceStartTime = mach_absolute_time();
attachQuiesceRequest(request);
fQuiesceRequest = request;
}
} else if (fQuiesceRequest && request->isQuiesceBlocker()) {
request->attachNextRequest(fQuiesceRequest);
}
requestQueue = &pwrMgt->RequestHead;
empty = queue_empty(requestQueue);
queue_enter(requestQueue, request, typeof(request), fCommandChain);
if (empty) {
more = checkRequestQueue(requestQueue, &empty);
if (!empty) {
assert( queue_next(&pwrMgt->WorkChain) ==
queue_prev(&pwrMgt->WorkChain));
queue_enter(&fWorkQueue, pwrMgt, typeof(pwrMgt), WorkChain);
fQueueLength++;
PM_LOG3("IOPMWorkQueue: [%u] added %s@%p to queue\n",
fQueueLength, pwrMgt->Name, OBFUSCATE(pwrMgt));
}
}
return more;
}
bool
IOPMWorkQueue::checkRequestQueue( queue_head_t * requestQueue, bool * empty )
{
IOPMRequest * request;
IOService * target;
bool more = false;
bool done = false;
assert(!queue_empty(requestQueue));
do {
request = (typeof(request))queue_first(requestQueue);
if (request->isWorkBlocked()) {
break; }
target = request->getTarget();
if (fInvokeAction) {
done = (*fInvokeAction)( target, request, this );
} else {
PM_LOG("PM request 0x%x dropped\n", request->getType());
done = true;
}
if (!done) {
break; }
assert(gIOPMBusyRequestCount > 0);
if (gIOPMBusyRequestCount) {
gIOPMBusyRequestCount--;
}
if (request == fQuiesceRequest) {
fQuiesceRequest = NULL;
}
queue_remove_first(requestQueue, request, typeof(request), fCommandChain);
more |= (*fRetireAction)( target, request, this );
done = queue_empty(requestQueue);
} while (!done);
*empty = done;
if (more) {
fProducerCount++;
}
return more;
}
bool
IOPMWorkQueue::checkForWork( void )
{
IOServicePM * entry;
IOServicePM * next;
bool more = false;
bool empty;
#if WORK_QUEUE_STATS
fStatCheckForWork++;
#endif
while (fConsumerCount != fProducerCount) {
PM_LOG3("IOPMWorkQueue: checkForWork %u %u\n",
fProducerCount, fConsumerCount);
fConsumerCount = fProducerCount;
#if WORK_QUEUE_STATS
if (queue_empty(&fWorkQueue)) {
fStatQueueEmpty++;
break;
}
fStatScanEntries++;
uint32_t cachedWorkCount = gIOPMWorkInvokeCount;
#endif
__IGNORE_WCASTALIGN(entry = (typeof(entry))queue_first(&fWorkQueue));
while (!queue_end(&fWorkQueue, (queue_entry_t) entry)) {
more |= checkRequestQueue(&entry->RequestHead, &empty);
__IGNORE_WCASTALIGN(next = (typeof(next))queue_next(&entry->WorkChain));
if (empty) {
assert(fQueueLength);
if (fQueueLength) {
fQueueLength--;
}
PM_LOG3("IOPMWorkQueue: [%u] removed %s@%p from queue\n",
fQueueLength, entry->Name, OBFUSCATE(entry));
queue_remove(&fWorkQueue, entry, typeof(entry), WorkChain);
}
entry = next;
}
#if WORK_QUEUE_STATS
if (cachedWorkCount == gIOPMWorkInvokeCount) {
fStatNoWorkDone++;
}
#endif
}
return more;
}
void
IOPMWorkQueue::signalWorkAvailable( void )
{
fProducerCount++;
IOEventSource::signalWorkAvailable();
}
void
IOPMWorkQueue::incrementProducerCount( void )
{
fProducerCount++;
}
void
IOPMWorkQueue::attachQuiesceRequest( IOPMRequest * quiesceRequest )
{
IOServicePM * entry;
IOPMRequest * request;
if (queue_empty(&fWorkQueue)) {
return;
}
queue_iterate(&fWorkQueue, entry, typeof(entry), WorkChain)
{
queue_iterate(&entry->RequestHead, request, typeof(request), fCommandChain)
{
if (request->isQuiesceBlocker()) {
request->attachNextRequest(quiesceRequest);
}
}
}
}
void
IOPMWorkQueue::finishQuiesceRequest( IOPMRequest * quiesceRequest )
{
if (fQuiesceRequest && (quiesceRequest == fQuiesceRequest) &&
(fQuiesceStartTime != 0)) {
fInvokeAction = NULL;
fQuiesceFinishTime = mach_absolute_time();
}
}
OSDefineMetaClassAndStructors( IOPMCompletionQueue, IOEventSource );
IOPMCompletionQueue *
IOPMCompletionQueue::create( IOService * inOwner, Action inAction )
{
IOPMCompletionQueue * me = OSTypeAlloc(IOPMCompletionQueue);
if (me && !me->init(inOwner, inAction)) {
me->release();
me = NULL;
}
return me;
}
bool
IOPMCompletionQueue::init( IOService * inOwner, Action inAction )
{
if (!inAction || !IOEventSource::init(inOwner, (IOEventSourceAction)inAction)) {
return false;
}
queue_init(&fQueue);
return true;
}
bool
IOPMCompletionQueue::queuePMRequest( IOPMRequest * request )
{
bool more;
assert(request);
more = request->detachNextRequest();
queue_enter(&fQueue, request, typeof(request), fCommandChain);
return more;
}
bool
IOPMCompletionQueue::checkForWork( void )
{
Action dqAction = (Action) action;
IOPMRequest * request;
IOPMRequest * next;
IOService * target;
bool more = false;
request = (typeof(request))queue_first(&fQueue);
while (!queue_end(&fQueue, (queue_entry_t) request)) {
next = (typeof(next))queue_next(&request->fCommandChain);
if (!request->isFreeBlocked()) {
queue_remove(&fQueue, request, typeof(request), fCommandChain);
target = request->getTarget();
assert(target);
more |= (*dqAction)( target, request, this );
}
request = next;
}
return more;
}
OSDefineMetaClassAndStructors(IOServicePM, OSObject)
static void
setPMProperty( OSDictionary * dict, const char * key, uint64_t value )
{
OSNumber * num = OSNumber::withNumber(value, sizeof(value) * 8);
if (num) {
dict->setObject(key, num);
num->release();
}
}
IOReturn
IOServicePM::gatedSerialize( OSSerialize * s ) const
{
OSDictionary * dict;
bool ok = false;
int powerClamp = -1;
int dictSize = 6;
if (IdleTimerPeriod) {
dictSize += 4;
}
if (PMActions.parameter & kPMActionsFlagLimitPower) {
dictSize += 1;
powerClamp = 0;
if (PMActions.parameter &
(kPMActionsFlagIsDisplayWrangler | kPMActionsFlagIsGraphicsDevice)) {
powerClamp++;
}
}
#if WORK_QUEUE_STATS
if (gIOPMRootNode == ControllingDriver) {
dictSize += 4;
}
#endif
if (PowerClients) {
dict = OSDictionary::withDictionary(
PowerClients, PowerClients->getCount() + dictSize);
} else {
dict = OSDictionary::withCapacity(dictSize);
}
if (dict) {
setPMProperty(dict, "CurrentPowerState", CurrentPowerState);
setPMProperty(dict, "CapabilityFlags", CurrentCapabilityFlags);
if (NumberOfPowerStates) {
setPMProperty(dict, "MaxPowerState", NumberOfPowerStates - 1);
}
if (DesiredPowerState != CurrentPowerState) {
setPMProperty(dict, "DesiredPowerState", DesiredPowerState);
}
if (kIOPM_Finished != MachineState) {
setPMProperty(dict, "MachineState", MachineState);
}
if (DeviceOverrideEnabled) {
dict->setObject("PowerOverrideOn", kOSBooleanTrue);
}
if (powerClamp >= 0) {
setPMProperty(dict, "PowerClamp", powerClamp);
}
if (IdleTimerPeriod) {
AbsoluteTime now;
AbsoluteTime delta;
uint64_t nsecs;
clock_get_uptime(&now);
setPMProperty(dict, "IdleTimerPeriod", NextIdleTimerPeriod * 1000ULL);
setPMProperty(dict, "ActivityTickles", ActivityTickleCount);
if (AbsoluteTime_to_scalar(&DeviceActiveTimestamp)) {
delta = now;
SUB_ABSOLUTETIME(&delta, &DeviceActiveTimestamp);
absolutetime_to_nanoseconds(delta, &nsecs);
setPMProperty(dict, "TimeSinceLastTickle", NS_TO_MS(nsecs));
}
if (!IdleTimerStopped && AbsoluteTime_to_scalar(&IdleTimerStartTime)) {
delta = now;
SUB_ABSOLUTETIME(&delta, &IdleTimerStartTime);
absolutetime_to_nanoseconds(delta, &nsecs);
setPMProperty(dict, "IdleTimerElapsedTime", NS_TO_MS(nsecs));
}
}
#if WORK_QUEUE_STATS
if (gIOPMRootNode == Owner) {
setPMProperty(dict, "WQ-CheckForWork",
gIOPMWorkQueue->fStatCheckForWork);
setPMProperty(dict, "WQ-ScanEntries",
gIOPMWorkQueue->fStatScanEntries);
setPMProperty(dict, "WQ-QueueEmpty",
gIOPMWorkQueue->fStatQueueEmpty);
setPMProperty(dict, "WQ-NoWorkDone",
gIOPMWorkQueue->fStatNoWorkDone);
}
#endif
if (HasAdvisoryDesire && !gIOPMAdvisoryTickleEnabled) {
dict->removeObject(gIOPMPowerClientAdvisoryTickle);
}
ok = dict->serialize(s);
dict->release();
}
return ok ? kIOReturnSuccess : kIOReturnNoMemory;
}
bool
IOServicePM::serialize( OSSerialize * s ) const
{
IOReturn ret = kIOReturnNotReady;
if (gIOPMWatchDogThread == current_thread()) {
ret = gatedSerialize(s);
} else if (gIOPMWorkLoop) {
ret = gIOPMWorkLoop->runAction(
OSMemberFunctionCast(IOWorkLoop::Action, this, &IOServicePM::gatedSerialize),
(OSObject *) this, (void *) s);
}
return kIOReturnSuccess == ret;
}
void
IOServicePM::pmPrint(
uint32_t event,
uintptr_t param1,
uintptr_t param2 ) const
{
gPlatform->PMLog(Name, event, param1, param2);
}
void
IOServicePM::pmTrace(
uint32_t event,
uint32_t eventFunc,
uintptr_t param1,
uintptr_t param2 ) const
{
uintptr_t nameAsArg = 0;
assert(event < KDBG_CODE_MAX);
assert((eventFunc & ~KDBG_FUNC_MASK) == 0);
strncpy((char*)&nameAsArg, Name, sizeof(nameAsArg));
IOTimeStampConstant(IODBG_POWER(event) | eventFunc, nameAsArg, (uintptr_t)Owner->getRegistryEntryID(), (uintptr_t)(OBFUSCATE(param1)), (uintptr_t)(OBFUSCATE(param2)));
}