IOPlatformExpert.cpp source code [codebrowser/iokit/Kernel/IOPlatformExpert.cpp]

1	/*
2	* Copyright (c) 1998-2017 Apple Inc. All rights reserved.
3	*
4	* @APPLE_OSREFERENCE_LICENSE_HEADER_START@
5	*
6	* This file contains Original Code and/or Modifications of Original Code
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13	* terms of an Apple operating system software license agreement.
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15	* Please obtain a copy of the License at
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18	* The Original Code and all software distributed under the License are
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27	*/
28
29	#include <IOKit/IOCPU.h>
30	#include <IOKit/IODeviceTreeSupport.h>
31	#include <IOKit/IOKitDebug.h>
32	#include <IOKit/IOMapper.h>
33	#include <IOKit/IOMessage.h>
34	#include <IOKit/IONVRAM.h>
35	#include <IOKit/IOPlatformExpert.h>
36	#include <IOKit/IORangeAllocator.h>
37	#include <IOKit/IOWorkLoop.h>
38	#include <IOKit/pwr_mgt/RootDomain.h>
39	#include <IOKit/IOKitKeys.h>
40	#include <IOKit/IOTimeStamp.h>
41	#include <IOKit/IOUserClient.h>
42	#include <IOKit/IOKitDiagnosticsUserClient.h>
43
44	#include <IOKit/system.h>
45	#include <sys/csr.h>
46
47	#include <libkern/c++/OSContainers.h>
48	#include <libkern/crypto/sha1.h>
49	#include <libkern/OSAtomic.h>
50
51	extern "C" {
52	#include <machine/machine_routines.h>
53	#include <pexpert/pexpert.h>
54	#include <uuid/uuid.h>
55	}
56
57	#define kShutdownTimeout 30 //in secs
58
59	#if !CONFIG_EMBEDDED
60
61	boolean_t coprocessor_cross_panic_enabled = TRUE;
62	#define APPLE_SECURE_BOOT_VARIABLE_GUID "94b73556-2197-4702-82a8-3e1337dafbfb"
63	#endif /* !CONFIG_EMBEDDED */
64
65	void printDictionaryKeys (OSDictionary * inDictionary, char * inMsg);
66	static void getCStringForObject(OSObject inObj, char* *outStr, size_t outStrLen);
67
68	/ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * /
69
70	#define super IOService
71
72	OSDefineMetaClassAndStructors(IOPlatformExpert, IOService)
73
74	OSMetaClassDefineReservedUsed(IOPlatformExpert, `0`);
75	OSMetaClassDefineReservedUsed(IOPlatformExpert, `1`);
76	OSMetaClassDefineReservedUsed(IOPlatformExpert, `2`);
77	OSMetaClassDefineReservedUsed(IOPlatformExpert, `3`);
78	OSMetaClassDefineReservedUsed(IOPlatformExpert, `4`);
79
80	OSMetaClassDefineReservedUnused(IOPlatformExpert, `5`);
81	OSMetaClassDefineReservedUnused(IOPlatformExpert, `6`);
82	OSMetaClassDefineReservedUnused(IOPlatformExpert, `7`);
83	OSMetaClassDefineReservedUnused(IOPlatformExpert, `8`);
84	OSMetaClassDefineReservedUnused(IOPlatformExpert, `9`);
85	OSMetaClassDefineReservedUnused(IOPlatformExpert, `10`);
86	OSMetaClassDefineReservedUnused(IOPlatformExpert, `11`);
87
88	static IOPlatformExpert * gIOPlatform;
89	static OSDictionary * gIOInterruptControllers;
90	static IOLock * gIOInterruptControllersLock;
91	static IODTNVRAM *gIOOptionsEntry;
92
93	OSSymbol * gPlatformInterruptControllerName;
94
95	/ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * /
96
97	bool IOPlatformExpert::attach( IOService * provider )
98	{
99
100	if( !super::attach( provider ))
101	return( false);
102
103	return( true);
104	}
105
106	bool IOPlatformExpert::start( IOService * provider )
107	{
108	IORangeAllocator * physicalRanges;
109	OSData * busFrequency;
110	uint32_t debugFlags;
111
112
113	if (!super::start(provider))
114	return false;
115
116	// Override the mapper present flag is requested by boot arguments, if SIP disabled.
117	#if CONFIG_CSR
118	if (csr_check(CSR_ALLOW_UNRESTRICTED_FS) == `0`)
119	#endif /* CONFIG_CSR */
120	{
121	if (PE_parse_boot_argn("dart", &debugFlags, sizeof (debugFlags)) && (debugFlags == `0`))
122	removeProperty(kIOPlatformMapperPresentKey);
123	#if DEBUG \|\| DEVELOPMENT
124	if (PE_parse_boot_argn("-x", &debugFlags, sizeof (debugFlags)))
125	removeProperty(kIOPlatformMapperPresentKey);
126	#endif /* DEBUG \|\| DEVELOPMENT */
127	}
128
129	// Register the presence or lack thereof a system
130	// PCI address mapper with the IOMapper class
131	IOMapper::setMapperRequired(`0` != getProperty(kIOPlatformMapperPresentKey));
132
133	gIOInterruptControllers = OSDictionary::withCapacity(`1`);
134	gIOInterruptControllersLock = IOLockAlloc();
135
136	// Correct the bus frequency in the device tree.
137	busFrequency = OSData::withBytesNoCopy((void *)&gPEClockFrequencyInfo.bus_clock_rate_hz, `4`);
138	provider->setProperty("clock-frequency", busFrequency);
139	busFrequency->release();
140
141	gPlatformInterruptControllerName = (OSSymbol *)OSSymbol::withCStringNoCopy("IOPlatformInterruptController");
142
143	physicalRanges = IORangeAllocator::withRange(`0xffffffff`, `1`, `16`,
144	IORangeAllocator::kLocking);
145	assert(physicalRanges);
146	setProperty("Platform Memory Ranges", physicalRanges);
147
148	setPlatform( this );
149	gIOPlatform = this;
150
151	PMInstantiatePowerDomains();
152
153	// Parse the serial-number data and publish a user-readable string
154	OSData* mydata = (OSData*) (provider->getProperty("serial-number"));
155	if (mydata != NULL) {
156	OSString *serNoString = createSystemSerialNumberString(mydata);
157	if (serNoString != NULL) {
158	provider->setProperty(kIOPlatformSerialNumberKey, serNoString);
159	serNoString->release();
160	}
161	}
162
163	#if !CONFIG_EMBEDDED
164	if (PEGetCoprocessorVersion() >= kCoprocessorVersion2) {
165	coprocessor_paniclog_flush = TRUE;
166	extended_debug_log_init();
167	}
168	#endif
169
170	return( configure(provider) );
171	}
172
173	bool IOPlatformExpert::configure( IOService * provider )
174	{
175	OSSet * topLevel;
176	OSDictionary * dict;
177	IOService * nub;
178
179	topLevel = OSDynamicCast( OSSet, getProperty("top-level"));
180
181	if( topLevel) {
182	while( (dict = OSDynamicCast( OSDictionary,
183	topLevel->getAnyObject()))) {
184	dict->retain();
185	topLevel->removeObject( dict );
186	nub = createNub( dict );
187	if( `0` == nub)
188	continue;
189	dict->release();
190	nub->attach( this );
191	nub->registerService();
192	}
193	}
194
195	return( true );
196	}
197
198	IOService * IOPlatformExpert::createNub( OSDictionary * from )
199	{
200	IOService * nub;
201
202	nub = new IOPlatformDevice;
203	if(nub) {
204	if( !nub->init( from )) {
205	nub->release();
206	nub = `0`;
207	}
208	}
209	return( nub);
210	}
211
212	bool IOPlatformExpert::compareNubName( const IOService * nub,
213	OSString * name, OSString ** matched ) const
214	{
215	return( nub->IORegistryEntry::compareName( name, matched ));
216	}
217
218	IOReturn IOPlatformExpert::getNubResources( IOService * nub )
219	{
220	return( kIOReturnSuccess );
221	}
222
223	long IOPlatformExpert::getBootROMType(void)
224	{
225	return _peBootROMType;
226	}
227
228	long IOPlatformExpert::getChipSetType(void)
229	{
230	return _peChipSetType;
231	}
232
233	long IOPlatformExpert::getMachineType(void)
234	{
235	return _peMachineType;
236	}
237
238	void IOPlatformExpert::setBootROMType(long peBootROMType)
239	{
240	_peBootROMType = peBootROMType;
241	}
242
243	void IOPlatformExpert::setChipSetType(long peChipSetType)
244	{
245	_peChipSetType = peChipSetType;
246	}
247
248	void IOPlatformExpert::setMachineType(long peMachineType)
249	{
250	_peMachineType = peMachineType;
251	}
252
253	bool IOPlatformExpert::getMachineName( char * /name/, int /maxLength/)
254	{
255	return( false );
256	}
257
258	bool IOPlatformExpert::getModelName( char * /name/, int /maxLength/)
259	{
260	return( false );
261	}
262
263	OSString* IOPlatformExpert::createSystemSerialNumberString(OSData* myProperty)
264	{
265	return NULL;
266	}
267
268	IORangeAllocator * IOPlatformExpert::getPhysicalRangeAllocator(void)
269	{
270	return(OSDynamicCast(IORangeAllocator,
271	getProperty("Platform Memory Ranges")));
272	}
273
274	int (PE_halt_restart)(unsigned* int type) = `0`;
275
276	int IOPlatformExpert::haltRestart(unsigned int type)
277	{
278	if (type == kPEPanicSync) return `0`;
279
280	if (type == kPEHangCPU) while (true) {}
281
282	if (type == kPEUPSDelayHaltCPU) {
283	// RestartOnPowerLoss feature was turned on, proceed with shutdown.
284	type = kPEHaltCPU;
285	}
286
287	#if !CONFIG_EMBEDDED
288	// On ARM kPEPanicRestartCPU is supported in the drivers
289	if (type == kPEPanicRestartCPU)
290	type = kPERestartCPU;
291	#endif
292
293	if (PE_halt_restart) return (*PE_halt_restart)(type);
294	else return -`1`;
295	}
296
297	void IOPlatformExpert::sleepKernel(void)
298	{
299	#if 0
300	long cnt;
301	boolean_t intState;
302
303	intState = ml_set_interrupts_enabled(false);
304
305	for (cnt = `0`; cnt < `10000`; cnt++) {
306	IODelay(`1000`);
307	}
308
309	ml_set_interrupts_enabled(intState);
310	#else
311	// PE_initialize_console(0, kPEDisableScreen);
312
313	IOCPUSleepKernel();
314
315	// PE_initialize_console(0, kPEEnableScreen);
316	#endif
317	}
318
319	long IOPlatformExpert::getGMTTimeOfDay(void)
320	{
321	return(`0`);
322	}
323
324	void IOPlatformExpert::setGMTTimeOfDay(long secs)
325	{
326	}
327
328
329	IOReturn IOPlatformExpert::getConsoleInfo( PE_Video * consoleInfo )
330	{
331	return( PE_current_console( consoleInfo));
332	}
333
334	IOReturn IOPlatformExpert::setConsoleInfo( PE_Video * consoleInfo,
335	unsigned int op)
336	{
337	return( PE_initialize_console( consoleInfo, op ));
338	}
339
340	IOReturn IOPlatformExpert::registerInterruptController(OSSymbol name, IOInterruptController interruptController)
341	{
342	IOLockLock(gIOInterruptControllersLock);
343
344	gIOInterruptControllers->setObject(name, interruptController);
345
346	IOLockWakeup(gIOInterruptControllersLock,
347	gIOInterruptControllers, / one-thread / false);
348
349	IOLockUnlock(gIOInterruptControllersLock);
350
351	return kIOReturnSuccess;
352	}
353
354	IOReturn IOPlatformExpert::deregisterInterruptController(OSSymbol *name)
355	{
356	IOLockLock(gIOInterruptControllersLock);
357
358	gIOInterruptControllers->removeObject(name);
359
360	IOLockUnlock(gIOInterruptControllersLock);
361
362	return kIOReturnSuccess;
363	}
364
365	IOInterruptController IOPlatformExpert::lookUpInterruptController(OSSymbol name)
366	{
367	OSObject *object;
368
369	IOLockLock(gIOInterruptControllersLock);
370	while (`1`) {
371
372	object = gIOInterruptControllers->getObject(name);
373
374	if (object != `0`)
375	break;
376
377	IOLockSleep(gIOInterruptControllersLock,
378	gIOInterruptControllers, THREAD_UNINT);
379	}
380
381	IOLockUnlock(gIOInterruptControllersLock);
382	return OSDynamicCast(IOInterruptController, object);
383	}
384
385
386	void IOPlatformExpert::setCPUInterruptProperties(IOService *service)
387	{
388	IOCPUInterruptController *controller;
389
390	controller = OSDynamicCast(IOCPUInterruptController, waitForService(serviceMatching("IOCPUInterruptController")));
391	if (controller) controller->setCPUInterruptProperties(service);
392	}
393
394	bool IOPlatformExpert::atInterruptLevel(void)
395	{
396	return ml_at_interrupt_context();
397	}
398
399	bool IOPlatformExpert::platformAdjustService(IOService */service/)
400	{
401	return true;
402	}
403
404	void IOPlatformExpert::getUTCTimeOfDay(clock_sec_t * secs, clock_nsec_t * nsecs)
405	{
406	*secs = getGMTTimeOfDay();
407	*nsecs = `0`;
408	}
409
410	void IOPlatformExpert::setUTCTimeOfDay(clock_sec_t secs, __unused clock_nsec_t nsecs)
411	{
412	setGMTTimeOfDay(secs);
413	}
414
415
416	//*********************************************************************************
417	// PMLog
418	//
419	//*********************************************************************************
420
421	void IOPlatformExpert::
422	PMLog(const char who, unsigned* long event,
423	unsigned long param1, unsigned long param2)
424	{
425	clock_sec_t nows;
426	clock_usec_t nowus;
427	clock_get_system_microtime(&nows, &nowus);
428	nowus += (nows % `1000`) * `1000000`;
429
430	kprintf("pm%u %p %.30s %d %lx %lx\n",
431	nowus, OBFUSCATE(current_thread()), who, // Identity
432	(int) event, (long)OBFUSCATE(param1), (long)OBFUSCATE(param2)); // Args
433	}
434
435
436	//*********************************************************************************
437	// PMInstantiatePowerDomains
438	//
439	// In this vanilla implementation, a Root Power Domain is instantiated.
440	// All other objects which register will be children of this Root.
441	// Where this is inappropriate, PMInstantiatePowerDomains is overridden
442	// in a platform-specific subclass.
443	//*********************************************************************************
444
445	void IOPlatformExpert::PMInstantiatePowerDomains ( void )
446	{
447	root = new IOPMrootDomain;
448	root->init();
449	root->attach(this);
450	root->start(this);
451	}
452
453
454	//*********************************************************************************
455	// PMRegisterDevice
456	//
457	// In this vanilla implementation, all callers are made children of the root power domain.
458	// Where this is inappropriate, PMRegisterDevice is overridden in a platform-specific subclass.
459	//*********************************************************************************
460
461	void IOPlatformExpert::PMRegisterDevice(IOService * theNub, IOService * theDevice)
462	{
463	root->addPowerChild ( theDevice );
464	}
465
466	//*********************************************************************************
467	// hasPMFeature
468	//
469	//*********************************************************************************
470
471	bool IOPlatformExpert::hasPMFeature (unsigned long featureMask)
472	{
473	return ((_pePMFeatures & featureMask) != `0`);
474	}
475
476	//*********************************************************************************
477	// hasPrivPMFeature
478	//
479	//*********************************************************************************
480
481	bool IOPlatformExpert::hasPrivPMFeature (unsigned long privFeatureMask)
482	{
483	return ((_pePrivPMFeatures & privFeatureMask) != `0`);
484	}
485
486	//*********************************************************************************
487	// numBatteriesSupported
488	//
489	//*********************************************************************************
490
491	int IOPlatformExpert::numBatteriesSupported (void)
492	{
493	return (_peNumBatteriesSupported);
494	}
495
496	//*********************************************************************************
497	// CheckSubTree
498	//
499	// This method is called by the instantiated sublass of the platform expert to
500	// determine how a device should be inserted into the Power Domain. The subclass
501	// provides an XML power tree description against which a device is matched based
502	// on class and provider. If a match is found this routine returns true in addition
503	// to flagging the description tree at the appropriate node that a device has been
504	// registered for the given service.
505	//*********************************************************************************
506
507	bool IOPlatformExpert::CheckSubTree (OSArray * inSubTree, IOService * theNub, IOService * theDevice, OSDictionary * theParent)
508	{
509	unsigned int i;
510	unsigned int numPowerTreeNodes;
511	OSDictionary * entry;
512	OSDictionary * matchingDictionary;
513	OSDictionary * providerDictionary;
514	OSDictionary * deviceDictionary;
515	OSDictionary * nubDictionary;
516	OSArray * children;
517	bool nodeFound = false;
518	bool continueSearch = false;
519	bool deviceMatch = false;
520	bool providerMatch = false;
521	bool multiParentMatch = false;
522
523	if ( (NULL == theDevice) \|\| (NULL == inSubTree) )
524	return false;
525
526	numPowerTreeNodes = inSubTree->getCount ();
527
528	// iterate through the power tree to find a home for this device
529
530	for ( i = `0`; i < numPowerTreeNodes; i++ ) {
531
532	entry = (OSDictionary *) inSubTree->getObject (i);
533
534	matchingDictionary = (OSDictionary *) entry->getObject ("device");
535	providerDictionary = (OSDictionary *) entry->getObject ("provider");
536
537	deviceMatch = true; // if no matching dictionary, this is not a criteria and so must match
538	if ( matchingDictionary ) {
539	deviceMatch = false;
540	if ( NULL != (deviceDictionary = theDevice->dictionaryWithProperties ())) {
541	deviceMatch = deviceDictionary->isEqualTo ( matchingDictionary, matchingDictionary );
542	deviceDictionary->release ();
543	}
544	}
545
546	providerMatch = true; // we indicate a match if there is no nub or provider
547	if ( theNub && providerDictionary ) {
548	providerMatch = false;
549	if ( NULL != (nubDictionary = theNub->dictionaryWithProperties ()) ) {
550	providerMatch = nubDictionary->isEqualTo ( providerDictionary, providerDictionary );
551	nubDictionary->release ();
552	}
553	}
554
555	multiParentMatch = true; // again we indicate a match if there is no multi-parent node
556	if (deviceMatch && providerMatch) {
557	if (NULL != multipleParentKeyValue) {
558	OSNumber * aNumber = (OSNumber *) entry->getObject ("multiple-parent");
559	multiParentMatch = (NULL != aNumber) ? multipleParentKeyValue->isEqualTo (aNumber) : false;
560	}
561	}
562
563	nodeFound = (deviceMatch && providerMatch && multiParentMatch);
564
565	// if the power tree specifies a provider dictionary but theNub is
566	// NULL then we cannot match with this entry.
567
568	if ( theNub == NULL && providerDictionary != NULL )
569	nodeFound = false;
570
571	// if this node is THE ONE...then register the device
572
573	if ( nodeFound ) {
574	if (RegisterServiceInTree (theDevice, entry, theParent, theNub) ) {
575
576	if ( kIOLogPower & gIOKitDebug)
577	IOLog ("PMRegisterDevice/CheckSubTree - service registered!\n");
578
579	numInstancesRegistered++;
580
581	// determine if we need to search for additional nodes for this item
582	multipleParentKeyValue = (OSNumber *) entry->getObject ("multiple-parent");
583	}
584	else
585	nodeFound = false;
586	}
587
588	continueSearch = ( (false == nodeFound) \|\| (NULL != multipleParentKeyValue) );
589
590	if ( continueSearch && (NULL != (children = (OSArray *) entry->getObject ("children"))) ) {
591	nodeFound = CheckSubTree ( children, theNub, theDevice, entry );
592	continueSearch = ( (false == nodeFound) \|\| (NULL != multipleParentKeyValue) );
593	}
594
595	if ( false == continueSearch )
596	break;
597	}
598
599	return ( nodeFound );
600	}
601
602	//*********************************************************************************
603	// RegisterServiceInTree
604	//
605	// Register a device at the specified node of our power tree.
606	//*********************************************************************************
607
608	bool IOPlatformExpert::RegisterServiceInTree (IOService * theService, OSDictionary * theTreeNode, OSDictionary * theTreeParentNode, IOService * theProvider)
609	{
610	IOService * aService;
611	bool registered = false;
612	OSArray * children;
613	unsigned int numChildren;
614	OSDictionary * child;
615
616	// make sure someone is not already registered here
617
618	if ( NULL == theTreeNode->getObject ("service") ) {
619
620	if ( theTreeNode->setObject ("service", OSDynamicCast ( OSObject, theService)) ) {
621
622	// 1. CHILDREN ------------------
623
624	// we registered the node in the tree...now if the node has children
625	// registered we must tell this service to add them.
626
627	if ( NULL != (children = (OSArray *) theTreeNode->getObject ("children")) ) {
628	numChildren = children->getCount ();
629	for ( unsigned int i = `0`; i < numChildren; i++ ) {
630	if ( NULL != (child = (OSDictionary *) children->getObject (i)) ) {
631	if ( NULL != (aService = (IOService *) child->getObject ("service")) )
632	theService->addPowerChild (aService);
633	}
634	}
635	}
636
637	// 2. PARENT --------------------
638
639	// also we must notify the parent of this node (if a registered service
640	// exists there) of a new child.
641
642	if ( theTreeParentNode ) {
643	if ( NULL != (aService = (IOService *) theTreeParentNode->getObject ("service")) )
644	if (aService != theProvider)
645	aService->addPowerChild (theService);
646	}
647
648	registered = true;
649	}
650	}
651
652	return registered;
653	}
654
655	//*********************************************************************************
656	// printDictionaryKeys
657	//
658	// Print the keys for the given dictionary and selected contents.
659	//*********************************************************************************
660	void printDictionaryKeys (OSDictionary * inDictionary, char * inMsg)
661	{
662	OSCollectionIterator * mcoll = OSCollectionIterator::withCollection (inDictionary);
663	OSSymbol * mkey;
664	OSString * ioClass;
665	unsigned int i = `0`;
666
667	mcoll->reset ();
668
669	mkey = OSDynamicCast (OSSymbol, mcoll->getNextObject ());
670
671	while (mkey) {
672
673	// kprintf ("dictionary key #%d: %s\n", i, mkey->getCStringNoCopy () );
674
675	// if this is the IOClass key, print it's contents
676
677	if ( mkey->isEqualTo ("IOClass") ) {
678	ioClass = (OSString *) inDictionary->getObject ("IOClass");
679	if ( ioClass ) IOLog ("%s IOClass is %s\n", inMsg, ioClass->getCStringNoCopy () );
680	}
681
682	// if this is an IOProviderClass key print it
683
684	if ( mkey->isEqualTo ("IOProviderClass") ) {
685	ioClass = (OSString *) inDictionary->getObject ("IOProviderClass");
686	if ( ioClass ) IOLog ("%s IOProviderClass is %s\n", inMsg, ioClass->getCStringNoCopy () );
687
688	}
689
690	// also print IONameMatch keys
691	if ( mkey->isEqualTo ("IONameMatch") ) {
692	ioClass = (OSString *) inDictionary->getObject ("IONameMatch");
693	if ( ioClass ) IOLog ("%s IONameMatch is %s\n", inMsg, ioClass->getCStringNoCopy () );
694	}
695
696	// also print IONameMatched keys
697
698	if ( mkey->isEqualTo ("IONameMatched") ) {
699	ioClass = (OSString *) inDictionary->getObject ("IONameMatched");
700	if ( ioClass ) IOLog ("%s IONameMatched is %s\n", inMsg, ioClass->getCStringNoCopy () );
701	}
702
703	#if 0
704	// print clock-id
705
706	if ( mkey->isEqualTo ("AAPL,clock-id") ) {
707	char * cstr;
708	cstr = getCStringForObject (inDictionary->getObject ("AAPL,clock-id"));
709	if (cstr)
710	kprintf (" ===> AAPL,clock-id is %s\n", cstr );
711	}
712	#endif
713
714	// print name
715
716	if ( mkey->isEqualTo ("name") ) {
717	char nameStr[`64`];
718	nameStr[`0`] = `0`;
719	getCStringForObject(inDictionary->getObject("name"), nameStr,
720	sizeof(nameStr));
721	if (strlen(nameStr) > `0`)
722	IOLog ("%s name is %s\n", inMsg, nameStr);
723	}
724
725	mkey = (OSSymbol *) mcoll->getNextObject ();
726
727	i++;
728	}
729
730	mcoll->release ();
731	}
732
733	static void
734	getCStringForObject(OSObject inObj, char* *outStr, size_t outStrLen)
735	{
736	char * buffer;
737	unsigned int len, i;
738
739	if ( (NULL == inObj) \|\| (NULL == outStr))
740	return;
741
742	char * objString = (char *) (inObj->getMetaClass())->getClassName();
743
744	if ((`0` == strncmp(objString, "OSString", sizeof("OSString"))) \|\|
745	(`0` == strncmp(objString, "OSSymbol", sizeof("OSSymbol"))))
746	strlcpy(outStr, ((OSString *)inObj)->getCStringNoCopy(), outStrLen);
747
748	else if (`0` == strncmp(objString, "OSData", sizeof("OSData"))) {
749	len = ((OSData *)inObj)->getLength();
750	buffer = (char )((OSData )inObj)->getBytesNoCopy();
751	if (buffer && (len > `0`)) {
752	for (i=`0`; i < len; i++) {
753	outStr[i] = buffer[i];
754	}
755	outStr[len] = `0`;
756	}
757	}
758	}
759
760	/ IOShutdownNotificationsTimedOut*
761	* - Called from a timer installed by PEHaltRestart
762	*/
763	static void IOShutdownNotificationsTimedOut(
764	thread_call_param_t p0,
765	thread_call_param_t p1)
766	{
767	#ifdef CONFIG_EMBEDDED
768	/ 30 seconds has elapsed - panic /
769	panic("Halt/Restart Timed Out");
770
771	#else /* ! CONFIG_EMBEDDED */
772	int type = (int)(long)p0;
773	uint32_t timeout = (uint32_t)(uintptr_t)p1;
774
775	IOPMrootDomain *pmRootDomain = IOService::getPMRootDomain();
776	if (pmRootDomain) {
777	if ((PEGetCoprocessorVersion() >= kCoprocessorVersion2) \|\| pmRootDomain->checkShutdownTimeout()) {
778	pmRootDomain->panicWithShutdownLog(timeout * `1000`);
779	}
780	}
781
782	/ 30 seconds has elapsed - resume shutdown /
783	if(gIOPlatform) gIOPlatform->haltRestart(type);
784	#endif /* CONFIG_EMBEDDED */
785	}
786
787
788	extern "C" {
789
790	/*
791	* Callouts from BSD for machine name & model
792	*/
793
794	boolean_t PEGetMachineName( char * name, int maxLength )
795	{
796	if( gIOPlatform)
797	return( gIOPlatform->getMachineName( name, maxLength ));
798	else
799	return( false );
800	}
801
802	boolean_t PEGetModelName( char * name, int maxLength )
803	{
804	if( gIOPlatform)
805	return( gIOPlatform->getModelName( name, maxLength ));
806	else
807	return( false );
808	}
809
810	int PEGetPlatformEpoch(void)
811	{
812	if( gIOPlatform)
813	return( gIOPlatform->getBootROMType());
814	else
815	return( -`1` );
816	}
817
818	int PEHaltRestart(unsigned int type)
819	{
820	IOPMrootDomain *pmRootDomain;
821	AbsoluteTime deadline;
822	thread_call_t shutdown_hang;
823	IORegistryEntry *node;
824	OSData *data;
825	uint32_t timeout = kShutdownTimeout;
826	static boolean_t panic_begin_called = FALSE;
827
828	if(type == kPEHaltCPU \|\| type == kPERestartCPU \|\| type == kPEUPSDelayHaltCPU)
829	{
830	pmRootDomain = IOService::getPMRootDomain();
831	/ Notify IOKit PM clients of shutdown/restart*
832	Clients subscribe to this message with a call to
833	IOService::registerInterest()
834	*/
835
836	/ Spawn a thread that will panic in 30 seconds.*
837	If all goes well the machine will be off by the time
838	the timer expires. If the device wants a different
839	timeout, use that value instead of 30 seconds.
840	*/
841	#if CONFIG_EMBEDDED
842	#define RESTART_NODE_PATH "/defaults"
843	#else
844	#define RESTART_NODE_PATH "/chosen"
845	#endif
846	node = IORegistryEntry::fromPath( RESTART_NODE_PATH, gIODTPlane );
847	if ( node ) {
848	data = OSDynamicCast( OSData, node->getProperty( "halt-restart-timeout" ) );
849	if ( data && data->getLength() == `4` )
850	timeout = ((uint32_t ) data->getBytesNoCopy());
851	}
852
853	shutdown_hang = thread_call_allocate( &IOShutdownNotificationsTimedOut,
854	(thread_call_param_t)(uintptr_t) type);
855	clock_interval_to_deadline( timeout, kSecondScale, &deadline );
856	thread_call_enter1_delayed( shutdown_hang, (thread_call_param_t)(uintptr_t)timeout, deadline );
857
858	pmRootDomain->handlePlatformHaltRestart(type);
859	/ This notification should have few clients who all do*
860	their work synchronously.
861
862	In this "shutdown notification" context we don't give
863	drivers the option of working asynchronously and responding
864	later. PM internals make it very hard to wait for asynchronous
865	replies.
866	*/
867	}
868	else if(type == kPEPanicRestartCPU \|\| type == kPEPanicSync)
869	{
870	if (type == kPEPanicRestartCPU) {
871	// Notify any listeners that we're done collecting
872	// panic data before we call through to do the restart
873	#if !CONFIG_EMBEDDED
874	if (coprocessor_cross_panic_enabled)
875	#endif
876	IOCPURunPlatformPanicActions(kPEPanicEnd);
877
878	// Callout to shutdown the disk driver once we've returned from the
879	// kPEPanicEnd callback (and we know all core dumps on this system
880	// are complete).
881	IOCPURunPlatformPanicActions(kPEPanicDiskShutdown);
882	}
883
884	// Do an initial sync to flush as much panic data as possible,
885	// in case we have a problem in one of the platorm panic handlers.
886	// After running the platform handlers, do a final sync w/
887	// platform hardware quiesced for the panic.
888	PE_sync_panic_buffers();
889	IOCPURunPlatformPanicActions(type);
890	PE_sync_panic_buffers();
891	}
892	else if (type == kPEPanicEnd) {
893	#if !CONFIG_EMBEDDED
894	if (coprocessor_cross_panic_enabled)
895	#endif
896	IOCPURunPlatformPanicActions(type);
897
898	} else if (type == kPEPanicBegin) {
899	#if !CONFIG_EMBEDDED
900	if (coprocessor_cross_panic_enabled)
901	#endif
902	{
903	// Only call the kPEPanicBegin callout once
904	if (!panic_begin_called) {
905	panic_begin_called = TRUE;
906	IOCPURunPlatformPanicActions(type);
907	}
908	}
909	}
910
911	if (gIOPlatform) return gIOPlatform->haltRestart(type);
912	else return -`1`;
913	}
914
915	UInt32 PESavePanicInfo(UInt8 *buffer, UInt32 length)
916	{
917	if (gIOPlatform != `0`) return gIOPlatform->savePanicInfo(buffer, length);
918	else return `0`;
919	}
920
921	void PESavePanicInfoAction(void *buffer, UInt32 offset, UInt32 length)
922	{
923	IOCPURunPlatformPanicSyncAction(buffer, offset, length);
924	return;
925	}
926
927
928	inline static int init_gIOOptionsEntry(void)
929	{
930	IORegistryEntry *entry;
931	void *nvram_entry;
932	volatile void **options;
933	int ret = -`1`;
934
935	if (gIOOptionsEntry)
936	return `0`;
937
938	entry = IORegistryEntry::fromPath( "/options", gIODTPlane );
939	if (!entry)
940	return -`1`;
941
942	nvram_entry = (void *) OSDynamicCast(IODTNVRAM, entry);
943	if (!nvram_entry)
944	goto release;
945
946	options = (volatile void **) &gIOOptionsEntry;
947	if (!OSCompareAndSwapPtr(NULL, nvram_entry, options)) {
948	ret = `0`;
949	goto release;
950	}
951
952	return `0`;
953
954	release:
955	entry->release();
956	return ret;
957
958	}
959
960	/ pass in a NULL value if you just want to figure out the len /
961	boolean_t PEReadNVRAMProperty(const char symbol, void* *value,
962	unsigned int *len)
963	{
964	OSObject *obj;
965	OSData *data;
966	unsigned int vlen;
967
968	if (!symbol \|\| !len)
969	goto err;
970
971	if (init_gIOOptionsEntry() < `0`)
972	goto err;
973
974	vlen = *len;
975	*len = `0`;
976
977	obj = gIOOptionsEntry->getProperty(symbol);
978	if (!obj)
979	goto err;
980
981	/ convert to data /
982	data = OSDynamicCast(OSData, obj);
983	if (!data)
984	goto err;
985
986	*len = data->getLength();
987	vlen = min(vlen, *len);
988	if (value && vlen)
989	memcpy((void *) value, data->getBytesNoCopy(), vlen);
990
991	return TRUE;
992
993	err:
994	return FALSE;
995	}
996
997	boolean_t
998	PEWriteNVRAMBooleanProperty(const char *symbol, boolean_t value)
999	{
1000	const OSSymbol *sym = NULL;
1001	OSBoolean *data = NULL;
1002	bool ret = false;
1003
1004	if (symbol == NULL) {
1005	goto exit;
1006	}
1007
1008	if (init_gIOOptionsEntry() < `0`) {
1009	goto exit;
1010	}
1011
1012	if ((sym = OSSymbol::withCStringNoCopy(symbol)) == NULL) {
1013	goto exit;
1014	}
1015
1016	data = value ? kOSBooleanTrue : kOSBooleanFalse;
1017	ret = gIOOptionsEntry->setProperty(sym, data);
1018
1019	sym->release();
1020
1021	/ success, force the NVRAM to flush writes /
1022	if (ret == true) {
1023	gIOOptionsEntry->sync();
1024	}
1025
1026	exit:
1027	return ret;
1028	}
1029
1030	boolean_t PEWriteNVRAMProperty(const char symbol, const* void *value,
1031	const unsigned int len)
1032	{
1033	const OSSymbol *sym;
1034	OSData *data;
1035	bool ret = false;
1036
1037	if (!symbol \|\| !value \|\| !len)
1038	goto err;
1039
1040	if (init_gIOOptionsEntry() < `0`)
1041	goto err;
1042
1043	sym = OSSymbol::withCStringNoCopy(symbol);
1044	if (!sym)
1045	goto err;
1046
1047	data = OSData::withBytes((void *) value, len);
1048	if (!data)
1049	goto sym_done;
1050
1051	ret = gIOOptionsEntry->setProperty(sym, data);
1052	data->release();
1053
1054	sym_done:
1055	sym->release();
1056
1057	if (ret == true) {
1058	gIOOptionsEntry->sync();
1059	return TRUE;
1060	}
1061
1062	err:
1063	return FALSE;
1064	}
1065
1066
1067	boolean_t PERemoveNVRAMProperty(const char *symbol)
1068	{
1069	const OSSymbol *sym;
1070
1071	if (!symbol)
1072	goto err;
1073
1074	if (init_gIOOptionsEntry() < `0`)
1075	goto err;
1076
1077	sym = OSSymbol::withCStringNoCopy(symbol);
1078	if (!sym)
1079	goto err;
1080
1081	gIOOptionsEntry->removeProperty(sym);
1082
1083	sym->release();
1084
1085	gIOOptionsEntry->sync();
1086	return TRUE;
1087
1088	err:
1089	return FALSE;
1090
1091	}
1092
1093	long PEGetGMTTimeOfDay(void)
1094	{
1095	clock_sec_t secs;
1096	clock_usec_t usecs;
1097
1098	PEGetUTCTimeOfDay(&secs, &usecs);
1099	return secs;
1100	}
1101
1102	void PESetGMTTimeOfDay(long secs)
1103	{
1104	PESetUTCTimeOfDay(secs, `0`);
1105	}
1106
1107	void PEGetUTCTimeOfDay(clock_sec_t * secs, clock_usec_t * usecs)
1108	{
1109	clock_nsec_t nsecs = `0`;
1110
1111	*secs = `0`;
1112	if (gIOPlatform)
1113	gIOPlatform->getUTCTimeOfDay(secs, &nsecs);
1114
1115	assert(nsecs < NSEC_PER_SEC);
1116	*usecs = nsecs / NSEC_PER_USEC;
1117	}
1118
1119	void PESetUTCTimeOfDay(clock_sec_t secs, clock_usec_t usecs)
1120	{
1121	assert(usecs < USEC_PER_SEC);
1122	if (gIOPlatform)
1123	gIOPlatform->setUTCTimeOfDay(secs, usecs * NSEC_PER_USEC);
1124	}
1125
1126	coprocessor_type_t PEGetCoprocessorVersion( void )
1127	{
1128	coprocessor_type_t coprocessor_version = kCoprocessorVersionNone;
1129	#if !CONFIG_EMBEDDED
1130	IORegistryEntry *platform_entry = NULL;
1131	OSData *coprocessor_version_obj = NULL;
1132
1133	platform_entry = IORegistryEntry::fromPath(kIODeviceTreePlane ":/efi/platform");
1134	if (platform_entry != NULL) {
1135	coprocessor_version_obj = OSDynamicCast(OSData, platform_entry->getProperty("apple-coprocessor-version"));
1136	if ((coprocessor_version_obj != NULL) && (coprocessor_version_obj->getLength() <= sizeof(uint64_t))) {
1137	memcpy(&coprocessor_version, coprocessor_version_obj->getBytesNoCopy(), coprocessor_version_obj->getLength());
1138	}
1139	platform_entry->release();
1140	}
1141	#endif
1142	return coprocessor_version;
1143	}
1144
1145	} / extern "C" /
1146
1147	void IOPlatformExpert::registerNVRAMController(IONVRAMController * caller)
1148	{
1149	OSData * data;
1150	IORegistryEntry * entry;
1151	OSString * string = `0`;
1152	uuid_string_t uuid;
1153
1154	#if CONFIG_EMBEDDED
1155	entry = IORegistryEntry::fromPath( "/chosen", gIODTPlane );
1156	if ( entry )
1157	{
1158	OSData * data1;
1159
1160	data1 = OSDynamicCast( OSData, entry->getProperty( "unique-chip-id" ) );
1161	if ( data1 && data1->getLength( ) == `8` )
1162	{
1163	OSData * data2;
1164
1165	data2 = OSDynamicCast( OSData, entry->getProperty( "chip-id" ) );
1166	if ( data2 && data2->getLength( ) == `4` )
1167	{
1168	SHA1_CTX context;
1169	uint8_t digest[ SHA_DIGEST_LENGTH ];
1170	const uuid_t space = { `0xA6`, `0xDD`, `0x4C`, `0xCB`, `0xB5`, `0xE8`, `0x4A`, `0xF5`, `0xAC`, `0xDD`, `0xB6`, `0xDC`, `0x6A`, `0x05`, `0x42`, `0xB8` };
1171
1172	SHA1Init( &context );
1173	SHA1Update( &context, space, sizeof( space ) );
1174	SHA1Update( &context, data1->getBytesNoCopy( ), data1->getLength( ) );
1175	SHA1Update( &context, data2->getBytesNoCopy( ), data2->getLength( ) );
1176	SHA1Final( digest, &context );
1177
1178	digest[ `6` ] = ( digest[ `6` ] & `0x0F` ) \| `0x50`;
1179	digest[ `8` ] = ( digest[ `8` ] & `0x3F` ) \| `0x80`;
1180
1181	uuid_unparse( digest, uuid );
1182	string = OSString::withCString( uuid );
1183	}
1184	}
1185
1186	entry->release( );
1187	}
1188	#else /* !CONFIG_EMBEDDED */
1189	/*
1190	* If we have panic debugging enabled and a prod-fused coprocessor,
1191	* disable cross panics so that the co-processor doesn't cause the system
1192	* to reset when we enter the debugger or hit a panic on the x86 side.
1193	*/
1194	if ( panicDebugging )
1195	{
1196	entry = IORegistryEntry::fromPath( "/options", gIODTPlane );
1197	if ( entry )
1198	{
1199	data = OSDynamicCast( OSData, entry->getProperty( APPLE_SECURE_BOOT_VARIABLE_GUID":EffectiveProductionStatus" ) );
1200	if ( data && ( data->getLength( ) == sizeof( UInt8 ) ) ) {
1201	UInt8 isProdFused = (UInt8 ) data->getBytesNoCopy( );
1202	UInt32 debug_flags = `0`;
1203	if ( *isProdFused \|\| ( PE_i_can_has_debugger(&debug_flags) &&
1204	( debug_flags & DB_DISABLE_CROSS_PANIC ) ) ) {
1205	coprocessor_cross_panic_enabled = FALSE;
1206	}
1207	}
1208	entry->release( );
1209	}
1210	}
1211
1212	entry = IORegistryEntry::fromPath( "/efi/platform", gIODTPlane );
1213	if ( entry )
1214	{
1215	data = OSDynamicCast( OSData, entry->getProperty( "system-id" ) );
1216	if ( data && data->getLength( ) == `16` )
1217	{
1218	SHA1_CTX context;
1219	uint8_t digest[ SHA_DIGEST_LENGTH ];
1220	const uuid_t space = { `0x2A`, `0x06`, `0x19`, `0x90`, `0xD3`, `0x8D`, `0x44`, `0x40`, `0xA1`, `0x39`, `0xC4`, `0x97`, `0x70`, `0x37`, `0x65`, `0xAC` };
1221
1222	SHA1Init( &context );
1223	SHA1Update( &context, space, sizeof( space ) );
1224	SHA1Update( &context, data->getBytesNoCopy( ), data->getLength( ) );
1225	SHA1Final( digest, &context );
1226
1227	digest[ `6` ] = ( digest[ `6` ] & `0x0F` ) \| `0x50`;
1228	digest[ `8` ] = ( digest[ `8` ] & `0x3F` ) \| `0x80`;
1229
1230	uuid_unparse( digest, uuid );
1231	string = OSString::withCString( uuid );
1232	}
1233
1234	entry->release( );
1235	}
1236	#endif /* !CONFIG_EMBEDDED */
1237
1238	if ( string == `0` )
1239	{
1240	entry = IORegistryEntry::fromPath( "/options", gIODTPlane );
1241	if ( entry )
1242	{
1243	data = OSDynamicCast( OSData, entry->getProperty( "platform-uuid" ) );
1244	if ( data && data->getLength( ) == sizeof( uuid_t ) )
1245	{
1246	uuid_unparse( ( uint8_t * ) data->getBytesNoCopy( ), uuid );
1247	string = OSString::withCString( uuid );
1248	}
1249
1250	entry->release( );
1251	}
1252	}
1253
1254	if ( string )
1255	{
1256	getProvider( )->setProperty( kIOPlatformUUIDKey, string );
1257	publishResource( kIOPlatformUUIDKey, string );
1258
1259	string->release( );
1260	}
1261
1262	publishResource("IONVRAM");
1263	}
1264
1265	IOReturn IOPlatformExpert::callPlatformFunction(const OSSymbol *functionName,
1266	bool waitForFunction,
1267	void param1, void* *param2,
1268	void param3, void* *param4)
1269	{
1270	IOService service, _resources;
1271
1272	if (waitForFunction) {
1273	_resources = waitForService(resourceMatching(functionName));
1274	} else {
1275	_resources = getResourceService();
1276	}
1277	if (_resources == `0`) return kIOReturnUnsupported;
1278
1279	service = OSDynamicCast(IOService, _resources->getProperty(functionName));
1280	if (service == `0`) return kIOReturnUnsupported;
1281
1282	return service->callPlatformFunction(functionName, waitForFunction,
1283	param1, param2, param3, param4);
1284	}
1285
1286	IOByteCount IOPlatformExpert::savePanicInfo(UInt8 *buffer, IOByteCount length)
1287	{
1288	return `0`;
1289	}
1290
1291	/ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * /
1292
1293	#undef super
1294	#define super IOPlatformExpert
1295
1296	OSDefineMetaClassAndAbstractStructors( IODTPlatformExpert, IOPlatformExpert )
1297
1298	OSMetaClassDefineReservedUnused(IODTPlatformExpert, `0`);
1299	OSMetaClassDefineReservedUnused(IODTPlatformExpert, `1`);
1300	OSMetaClassDefineReservedUnused(IODTPlatformExpert, `2`);
1301	OSMetaClassDefineReservedUnused(IODTPlatformExpert, `3`);
1302	OSMetaClassDefineReservedUnused(IODTPlatformExpert, `4`);
1303	OSMetaClassDefineReservedUnused(IODTPlatformExpert, `5`);
1304	OSMetaClassDefineReservedUnused(IODTPlatformExpert, `6`);
1305	OSMetaClassDefineReservedUnused(IODTPlatformExpert, `7`);
1306
1307	/ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * /
1308
1309	IOService * IODTPlatformExpert::probe( IOService * provider,
1310	SInt32 * score )
1311	{
1312	if( !super::probe( provider, score))
1313	return( `0` );
1314
1315	// check machine types
1316	if( !provider->compareNames( getProperty( gIONameMatchKey ) ))
1317	return( `0` );
1318
1319	return( this);
1320	}
1321
1322	bool IODTPlatformExpert::configure( IOService * provider )
1323	{
1324	if( !super::configure( provider))
1325	return( false);
1326
1327	processTopLevel( provider );
1328
1329	return( true );
1330	}
1331
1332	IOService * IODTPlatformExpert::createNub( IORegistryEntry * from )
1333	{
1334	IOService * nub;
1335
1336	nub = new IOPlatformDevice;
1337	if( nub) {
1338	if( !nub->init( from, gIODTPlane )) {
1339	nub->free();
1340	nub = `0`;
1341	}
1342	}
1343	return( nub);
1344	}
1345
1346	bool IODTPlatformExpert::createNubs( IOService * parent, OSIterator * iter )
1347	{
1348	IORegistryEntry * next;
1349	IOService * nub;
1350	bool ok = true;
1351
1352	if( iter) {
1353	while( (next = (IORegistryEntry *) iter->getNextObject())) {
1354
1355	if( `0` == (nub = createNub( next )))
1356	continue;
1357
1358	nub->attach( parent );
1359	nub->registerService();
1360	}
1361	iter->release();
1362	}
1363
1364	return( ok );
1365	}
1366
1367	void IODTPlatformExpert::processTopLevel( IORegistryEntry * rootEntry )
1368	{
1369	OSIterator * kids;
1370	IORegistryEntry * next;
1371	IORegistryEntry * cpus;
1372	IORegistryEntry * options;
1373
1374	// infanticide
1375	kids = IODTFindMatchingEntries( rootEntry, `0`, deleteList() );
1376	if( kids) {
1377	while( (next = (IORegistryEntry *)kids->getNextObject())) {
1378	next->detachAll( gIODTPlane);
1379	}
1380	kids->release();
1381	}
1382
1383	// Publish an IODTNVRAM class on /options.
1384	options = rootEntry->childFromPath("options", gIODTPlane);
1385	if (options) {
1386	dtNVRAM = new IODTNVRAM;
1387	if (dtNVRAM) {
1388	if (!dtNVRAM->init(options, gIODTPlane)) {
1389	dtNVRAM->release();
1390	dtNVRAM = `0`;
1391	} else {
1392	dtNVRAM->attach(this);
1393	dtNVRAM->registerService();
1394	options->release();
1395	}
1396	}
1397	}
1398
1399	// Publish the cpus.
1400	cpus = rootEntry->childFromPath( "cpus", gIODTPlane);
1401	if ( cpus)
1402	{
1403	createNubs( this, IODTFindMatchingEntries( cpus, kIODTExclusive, `0`));
1404	cpus->release();
1405	}
1406
1407	// publish top level, minus excludeList
1408	createNubs( this, IODTFindMatchingEntries( rootEntry, kIODTExclusive, excludeList()));
1409	}
1410
1411	IOReturn IODTPlatformExpert::getNubResources( IOService * nub )
1412	{
1413	if( nub->getDeviceMemory())
1414	return( kIOReturnSuccess );
1415
1416	IODTResolveAddressing( nub, "reg", `0`);
1417
1418	return( kIOReturnSuccess);
1419	}
1420
1421	bool IODTPlatformExpert::compareNubName( const IOService * nub,
1422	OSString * name, OSString ** matched ) const
1423	{
1424	return( IODTCompareNubName( nub, name, matched )
1425	\|\| super::compareNubName( nub, name, matched) );
1426	}
1427
1428	bool IODTPlatformExpert::getModelName( char * name, int maxLength )
1429	{
1430	OSData * prop;
1431	const char * str;
1432	int len;
1433	char c;
1434	bool ok = false;
1435
1436	maxLength--;
1437
1438	prop = (OSData *) getProvider()->getProperty( gIODTCompatibleKey );
1439	if( prop ) {
1440	str = (const char *) prop->getBytesNoCopy();
1441
1442	if( `0` == strncmp( str, "AAPL,", strlen( "AAPL," ) ))
1443	str += strlen( "AAPL," );
1444
1445	len = `0`;
1446	while( (c = *str++)) {
1447	if( (c == `'/'`) \|\| (c == `' '`))
1448	c = `'-'`;
1449
1450	name[ len++ ] = c;
1451	if( len >= maxLength)
1452	break;
1453	}
1454
1455	name[ len ] = `0`;
1456	ok = true;
1457	}
1458	return( ok );
1459	}
1460
1461	bool IODTPlatformExpert::getMachineName( char * name, int maxLength )
1462	{
1463	OSData * prop;
1464	bool ok = false;
1465
1466	maxLength--;
1467	prop = (OSData *) getProvider()->getProperty( gIODTModelKey );
1468	ok = (`0` != prop);
1469
1470	if( ok )
1471	strlcpy( name, (const char *) prop->getBytesNoCopy(), maxLength );
1472
1473	return( ok );
1474	}
1475
1476	/ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * /
1477
1478	void IODTPlatformExpert::registerNVRAMController( IONVRAMController * nvram )
1479	{
1480	if (dtNVRAM) dtNVRAM->registerNVRAMController(nvram);
1481
1482	super::registerNVRAMController(nvram);
1483	}
1484
1485	int IODTPlatformExpert::haltRestart(unsigned int type)
1486	{
1487	if (dtNVRAM) dtNVRAM->sync();
1488
1489	return super::haltRestart(type);
1490	}
1491
1492	IOReturn IODTPlatformExpert::readXPRAM(IOByteCount offset, UInt8 * buffer,
1493	IOByteCount length)
1494	{
1495	if (dtNVRAM) return dtNVRAM->readXPRAM(offset, buffer, length);
1496	else return kIOReturnNotReady;
1497	}
1498
1499	IOReturn IODTPlatformExpert::writeXPRAM(IOByteCount offset, UInt8 * buffer,
1500	IOByteCount length)
1501	{
1502	if (dtNVRAM) return dtNVRAM->writeXPRAM(offset, buffer, length);
1503	else return kIOReturnNotReady;
1504	}
1505
1506	IOReturn IODTPlatformExpert::readNVRAMProperty(
1507	IORegistryEntry * entry,
1508	const OSSymbol name, OSData value )
1509	{
1510	if (dtNVRAM) return dtNVRAM->readNVRAMProperty(entry, name, value);
1511	else return kIOReturnNotReady;
1512	}
1513
1514	IOReturn IODTPlatformExpert::writeNVRAMProperty(
1515	IORegistryEntry * entry,
1516	const OSSymbol * name, OSData * value )
1517	{
1518	if (dtNVRAM) return dtNVRAM->writeNVRAMProperty(entry, name, value);
1519	else return kIOReturnNotReady;
1520	}
1521
1522	OSDictionary IODTPlatformExpert::getNVRAMPartitions(void*)
1523	{
1524	if (dtNVRAM) return dtNVRAM->getNVRAMPartitions();
1525	else return `0`;
1526	}
1527
1528	IOReturn IODTPlatformExpert::readNVRAMPartition(const OSSymbol * partitionID,
1529	IOByteCount offset, UInt8 * buffer,
1530	IOByteCount length)
1531	{
1532	if (dtNVRAM) return dtNVRAM->readNVRAMPartition(partitionID, offset,
1533	buffer, length);
1534	else return kIOReturnNotReady;
1535	}
1536
1537	IOReturn IODTPlatformExpert::writeNVRAMPartition(const OSSymbol * partitionID,
1538	IOByteCount offset, UInt8 * buffer,
1539	IOByteCount length)
1540	{
1541	if (dtNVRAM) return dtNVRAM->writeNVRAMPartition(partitionID, offset,
1542	buffer, length);
1543	else return kIOReturnNotReady;
1544	}
1545
1546	IOByteCount IODTPlatformExpert::savePanicInfo(UInt8 *buffer, IOByteCount length)
1547	{
1548	IOByteCount lengthSaved = `0`;
1549
1550	if (dtNVRAM) lengthSaved = dtNVRAM->savePanicInfo(buffer, length);
1551
1552	if (lengthSaved == `0`) lengthSaved = super::savePanicInfo(buffer, length);
1553
1554	return lengthSaved;
1555	}
1556
1557	OSString* IODTPlatformExpert::createSystemSerialNumberString(OSData* myProperty) {
1558	UInt8* serialNumber;
1559	unsigned int serialNumberSize;
1560	unsigned short pos = `0`;
1561	char* temp;
1562	char SerialNo[`30`];
1563
1564	if (myProperty != NULL) {
1565	serialNumberSize = myProperty->getLength();
1566	serialNumber = (UInt8*)(myProperty->getBytesNoCopy());
1567	temp = (char*)serialNumber;
1568	if (serialNumberSize > `0`) {
1569	// check to see if this is a CTO serial number...
1570	while (pos < serialNumberSize && temp[pos] != `'-'`) pos++;
1571
1572	if (pos < serialNumberSize) { // there was a hyphen, so it's a CTO serial number
1573	memcpy(SerialNo, serialNumber + `12`, `8`);
1574	memcpy(&SerialNo[`8`], serialNumber, `3`);
1575	SerialNo[`11`] = `'-'`;
1576	memcpy(&SerialNo[`12`], serialNumber + `3`, `8`);
1577	SerialNo[`20`] = `0`;
1578	} else { // just a normal serial number
1579	memcpy(SerialNo, serialNumber + `13`, `8`);
1580	memcpy(&SerialNo[`8`], serialNumber, `3`);
1581	SerialNo[`11`] = `0`;
1582	}
1583	return OSString::withCString(SerialNo);
1584	}
1585	}
1586	return NULL;
1587	}
1588
1589
1590	/ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * /
1591
1592	#undef super
1593	#define super IOService
1594
1595	OSDefineMetaClassAndStructors(IOPlatformExpertDevice, IOService)
1596
1597	OSMetaClassDefineReservedUnused(IOPlatformExpertDevice, `0`);
1598	OSMetaClassDefineReservedUnused(IOPlatformExpertDevice, `1`);
1599	OSMetaClassDefineReservedUnused(IOPlatformExpertDevice, `2`);
1600	OSMetaClassDefineReservedUnused(IOPlatformExpertDevice, `3`);
1601
1602	/ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * /
1603
1604	bool IOPlatformExpertDevice::compareName( OSString * name,
1605	OSString ** matched ) const
1606	{
1607	return( IODTCompareNubName( this, name, matched ));
1608	}
1609
1610	bool
1611	IOPlatformExpertDevice::initWithArgs(
1612	void * dtTop, void * p2, void * p3, void * p4 )
1613	{
1614	IORegistryEntry * dt = `0`;
1615	bool ok;
1616
1617	// dtTop may be zero on non- device tree systems
1618	if( dtTop && (dt = IODeviceTreeAlloc( dtTop )))
1619	ok = super::init( dt, gIODTPlane );
1620	else
1621	ok = super::init();
1622
1623	if( !ok)
1624	return( false);
1625
1626	workLoop = IOWorkLoop::workLoop();
1627	if (!workLoop)
1628	return false;
1629
1630	return( true);
1631	}
1632
1633	IOWorkLoop IOPlatformExpertDevice::getWorkLoop() const*
1634	{
1635	return workLoop;
1636	}
1637
1638	IOReturn IOPlatformExpertDevice::setProperties( OSObject * properties )
1639	{
1640	return kIOReturnUnsupported;
1641	}
1642
1643	IOReturn IOPlatformExpertDevice::newUserClient( task_t owningTask, void * securityID,
1644	UInt32 type, OSDictionary * properties,
1645	IOUserClient ** handler )
1646	{
1647	IOReturn err = kIOReturnSuccess;
1648	IOUserClient * newConnect = `0`;
1649	IOUserClient * theConnect = `0`;
1650
1651	switch (type)
1652	{
1653	case kIOKitDiagnosticsClientType:
1654	newConnect = IOKitDiagnosticsClient::withTask(owningTask);
1655	if (!newConnect) err = kIOReturnNotPermitted;
1656	break;
1657	default:
1658	err = kIOReturnBadArgument;
1659	}
1660
1661	if (newConnect)
1662	{
1663	if ((false == newConnect->attach(this))
1664	\|\| (false == newConnect->start(this)))
1665	{
1666	newConnect->detach( this );
1667	newConnect->release();
1668	err = kIOReturnNotPermitted;
1669	}
1670	else
1671	theConnect = newConnect;
1672	}
1673
1674	*handler = theConnect;
1675	return (err);
1676	}
1677
1678	void IOPlatformExpertDevice::free()
1679	{
1680	if (workLoop)
1681	workLoop->release();
1682	}
1683
1684	/ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * /
1685
1686	#undef super
1687	#define super IOService
1688
1689	OSDefineMetaClassAndStructors(IOPlatformDevice, IOService)
1690
1691	OSMetaClassDefineReservedUnused(IOPlatformDevice, `0`);
1692	OSMetaClassDefineReservedUnused(IOPlatformDevice, `1`);
1693	OSMetaClassDefineReservedUnused(IOPlatformDevice, `2`);
1694	OSMetaClassDefineReservedUnused(IOPlatformDevice, `3`);
1695
1696	/ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * /
1697
1698	bool IOPlatformDevice::compareName( OSString * name,
1699	OSString ** matched ) const
1700	{
1701	return( ((IOPlatformExpert *)getProvider())->
1702	compareNubName( this, name, matched ));
1703	}
1704
1705	IOService * IOPlatformDevice::matchLocation( IOService * / client / )
1706	{
1707	return( this );
1708	}
1709
1710	IOReturn IOPlatformDevice::getResources( void )
1711	{
1712	return( ((IOPlatformExpert )getProvider())->getNubResources( this* ));
1713	}
1714
1715	/ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * /
1716
1717	/*********************************************************************
1718	* IOPanicPlatform class
1719	*
1720	* If no legitimate IOPlatformDevice matches, this one does and panics
1721	* the kernel with a suitable message.
1722	*********************************************************************/
1723
1724	class IOPanicPlatform : IOPlatformExpert {
1725	OSDeclareDefaultStructors(IOPanicPlatform);
1726
1727	public:
1728	bool start(IOService * provider) APPLE_KEXT_OVERRIDE;
1729	};
1730
1731
1732	OSDefineMetaClassAndStructors(IOPanicPlatform, IOPlatformExpert);
1733
1734
1735	bool IOPanicPlatform::start(IOService * provider) {
1736	const char * platform_name = "(unknown platform name)";
1737
1738	if (provider) platform_name = provider->getName();
1739
1740	panic("Unable to find driver for this platform: \"%s\".\n",
1741	platform_name);
1742
1743	return false;
1744	}
1745
1746

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