void db_dumpiojunk( const IORegistryPlane * plane ) { IORegistryEntry * next; IORegistryIterator * iter; OSOrderedSet * all; char format[] = "%xxxs"; IOService * service; iter = IORegistryIterator::iterateOver( plane ); all = iter->iterateAll(); if( all) { dbugprintf("Count %d\n", all->getCount() ); all->release(); } else dbugprintf("Empty\n"); iter->reset(); while( (next = iter->getNextObjectRecursive())) { snprintf(format + 1, sizeof(format) - 1, "%ds", 2 * next->getDepth( plane )); dbugprintf( format, ""); dbugprintf( "%s", next->getName( plane )); if( (next->getLocation( plane ))) dbugprintf("@%s", next->getLocation( plane )); dbugprintf(" <class %s", next->getMetaClass()->getClassName()); if( (service = OSDynamicCast(IOService, next))) dbugprintf(", busy %ld", service->getBusyState()); dbugprintf( ">\n"); } iter->release(); }
void IOPrintPlane( const IORegistryPlane * plane ) { IORegistryEntry * next; IORegistryIterator * iter; OSOrderedSet * all; char format[] = "%xxxs"; IOService * service; iter = IORegistryIterator::iterateOver( plane ); assert( iter ); all = iter->iterateAll(); if( all) { DEBG("Count %d\n", all->getCount() ); all->release(); } else DEBG("Empty\n"); iter->reset(); while( (next = iter->getNextObjectRecursive())) { snprintf(format + 1, sizeof(format) - 1, "%ds", 2 * next->getDepth( plane )); DEBG( format, ""); DEBG( "\033[33m%s", next->getName( plane )); if( (next->getLocation( plane ))) DEBG("@%s", next->getLocation( plane )); DEBG("\033[0m <class %s", next->getMetaClass()->getClassName()); if( (service = OSDynamicCast(IOService, next))) DEBG(", busy %ld", (long) service->getBusyState()); DEBG( ">\n"); // IOSleep(250); } iter->release(); }
/* * Copyright (c) 1998-2013 Apple Inc. All rights reserved. * * @APPLE_LICENSE_HEADER_START@ * * This file contains Original Code and/or Modifications of Original Code * as defined in and that are subject to the Apple Public Source License * Version 2.0 (the 'License'). You may not use this file except in * compliance with the License. Please obtain a copy of the License at * http://www.opensource.apple.com/apsl/ and read it before using this * file. * * The Original Code and all software distributed under the License are * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT. * Please see the License for the specific language governing rights and * limitations under the License. * * @APPLE_LICENSE_HEADER_END@ */ #include <IOKit/IODeviceTreeSupport.h> #include <IOKit/IOMessage.h> #include <IOKit/storage/IOPartitionScheme.h> #define super IOStorage OSDefineMetaClassAndStructors(IOPartitionScheme, IOStorage) #ifndef __LP64__ extern IOStorageAttributes gIOStorageAttributesUnsupported; #endif /* !__LP64__ */ static SInt32 partitionComparison( const OSMetaClassBase * object1, const OSMetaClassBase * object2, void * context ) { // // Internal comparison routine for sorting partitions in an ordered set. // UInt64 base1 = ( ( IOMedia * ) object1 )->getBase( ); UInt64 base2 = ( ( IOMedia * ) object2 )->getBase( ); #if TARGET_OS_EMBEDDED OSString * uuid1 = OSDynamicCast( OSString, ( ( IOMedia * ) object1 )->getProperty( kIOMediaUUIDKey ) ); OSString * uuid2 = OSDynamicCast( OSString, ( ( IOMedia * ) object2 )->getProperty( kIOMediaUUIDKey ) ); if ( uuid1 || uuid2 ) { if ( uuid1 == 0 ) return -1; if ( uuid2 == 0 ) return 1; return strcmp( uuid2->getCStringNoCopy( ), uuid1->getCStringNoCopy( ) ); } #endif /* TARGET_OS_EMBEDDED */ if ( base1 < base2 ) return 1; if ( base1 > base2 ) return -1; return 0; } IOMedia * IOPartitionScheme::getProvider() const { // // Obtain this object's provider. We override the superclass's method // to return a more specific subclass of OSObject -- an IOMedia. This // method serves simply as a convenience to subclass developers. // return (IOMedia *) IOService::getProvider(); } bool IOPartitionScheme::init(OSDictionary * properties) { // // Initialize this object's minimal state. // if (super::init(properties) == false) return false; _openLevel = kIOStorageAccessNone; _openReaders = OSSet::withCapacity(16); _openReaderWriters = OSSet::withCapacity(16); if (_openReaders == 0 || _openReaderWriters == 0) return false; return true; } void IOPartitionScheme::free() { // // Free all of this object's outstanding resources. // if (_openReaders) _openReaders->release(); if (_openReaderWriters) _openReaderWriters->release(); super::free(); } bool IOPartitionScheme::handleOpen(IOService * client, IOOptionBits options, void * argument) { // // The handleOpen method grants or denies permission to access this object // to an interested client. The argument is an IOStorageAccess value that // specifies the level of access desired -- reader or reader-writer. // // This method can be invoked to upgrade or downgrade the access level for // an existing client as well. The previous access level will prevail for // upgrades that fail, of course. A downgrade should never fail. If the // new access level should be the same as the old for a given client, this // method will do nothing and return success. In all cases, one, singular // close-per-client is expected for all opens-per-client received. // // This implementation replaces the IOService definition of handleOpen(). // // We are guaranteed that no other opens or closes will be processed until // we make our decision, change our state, and return from this method. // IOStorageAccess access = (uintptr_t) argument; IOStorageAccess level; assert(client); assert( access == kIOStorageAccessReader || access == kIOStorageAccessReaderWriter ); // // A partition scheme multiplexes the opens it receives from several clients // and sends one open to the level below that satisfies the highest level of // access. // unsigned writers = _openReaderWriters->getCount(); if (_openReaderWriters->containsObject(client)) writers--; if (access == kIOStorageAccessReaderWriter) writers++; level = (writers) ? kIOStorageAccessReaderWriter : kIOStorageAccessReader; // // Determine whether the levels below us accept this open or not (we avoid // the open if the required access is the access we already hold). // if ( _openLevel != level ) { IOStorage * provider; provider = OSDynamicCast( IOStorage, getProvider( ) ); if ( provider ) { bool success; level = ( level | kIOStorageAccessSharedLock ); success = provider->open( this, options, level ); level = ( level & kIOStorageAccessReaderWriter ); if ( success == false ) { return false; } } } // // Process the open. // if (access == kIOStorageAccessReader) { _openReaders->setObject(client); _openReaderWriters->removeObject(client); // (for a downgrade) } else // (access == kIOStorageAccessReaderWriter) { _openReaderWriters->setObject(client); _openReaders->removeObject(client); // (for an upgrade) } _openLevel = level; return true; } bool IOPartitionScheme::handleIsOpen(const IOService * client) const { // // The handleIsOpen method determines whether the specified client, or any // client if none is specificed, presently has an open on this object. // // This implementation replaces the IOService definition of handleIsOpen(). // // We are guaranteed that no other opens or closes will be processed until // we return from this method. // if (client == 0) return (_openLevel != kIOStorageAccessNone); return ( _openReaderWriters->containsObject(client) || _openReaders->containsObject(client) ); } void IOPartitionScheme::handleClose(IOService * client, IOOptionBits options) { // // The handleClose method closes the client's access to this object. // // This implementation replaces the IOService definition of handleClose(). // // We are guaranteed that no other opens or closes will be processed until // we change our state and return from this method. // assert(client); // // Process the close. // if (_openReaderWriters->containsObject(client)) // (is it a reader-writer?) { _openReaderWriters->removeObject(client); } else if (_openReaders->containsObject(client)) // (is the client a reader?) { _openReaders->removeObject(client); } else // (is the client is an imposter?) { assert(0); return; } // // Reevaluate the open we have on the level below us. If no opens remain, // we close, or if no reader-writer remains, but readers do, we downgrade. // IOStorageAccess level; if (_openReaderWriters->getCount()) level = kIOStorageAccessReaderWriter; else if (_openReaders->getCount()) level = kIOStorageAccessReader; else level = kIOStorageAccessNone; if ( _openLevel != level ) { IOStorage * provider; provider = OSDynamicCast( IOStorage, getProvider( ) ); if ( provider ) { if ( level == kIOStorageAccessNone ) { provider->close( this, options ); } else { bool success; level = ( level | kIOStorageAccessSharedLock ); success = provider->open( this, 0, level ); level = ( level & kIOStorageAccessReaderWriter ); assert( success ); } } _openLevel = level; } } void IOPartitionScheme::read(IOService * client, UInt64 byteStart, IOMemoryDescriptor * buffer, IOStorageAttributes * attributes, IOStorageCompletion * completion) { // // Read data from the storage object at the specified byte offset into the // specified buffer, asynchronously. When the read completes, the caller // will be notified via the specified completion action. // // The buffer will be retained for the duration of the read. // // For simple partition schemes, the default behavior is to simply pass the // read through to the provider media. More complex partition schemes such // as RAID will need to do extra processing here. // #ifndef __LP64__ if ( IOStorage::_expansionData ) { if ( attributes == &gIOStorageAttributesUnsupported ) { attributes = NULL; } else { IOStorage::read( client, byteStart, buffer, attributes, completion ); return; } } #endif /* !__LP64__ */ getProvider( )->read( this, byteStart, buffer, attributes, completion ); } void IOPartitionScheme::write(IOService * client, UInt64 byteStart, IOMemoryDescriptor * buffer, IOStorageAttributes * attributes, IOStorageCompletion * completion) { // // Write data into the storage object at the specified byte offset from the // specified buffer, asynchronously. When the write completes, the caller // will be notified via the specified completion action. // // The buffer will be retained for the duration of the write. // // For simple partition schemes, the default behavior is to simply pass the // write through to the provider media. More complex partition schemes such // as RAID will need to do extra processing here. // #ifndef __LP64__ if ( IOStorage::_expansionData ) { if ( attributes == &gIOStorageAttributesUnsupported ) { attributes = NULL; } else { IOStorage::write( client, byteStart, buffer, attributes, completion ); return; } } #endif /* !__LP64__ */ getProvider( )->write( this, byteStart, buffer, attributes, completion ); } IOReturn IOPartitionScheme::synchronizeCache(IOService * client) { // // Flush the cached data in the storage object, if any, synchronously. // return getProvider()->synchronizeCache(this); } IOReturn IOPartitionScheme::unmap(IOService * client, IOStorageExtent * extents, UInt32 extentsCount, UInt32 options) { // // Delete unused data from the storage object at the specified byte offsets, // synchronously. // return getProvider( )->unmap( this, extents, extentsCount, options ); } bool IOPartitionScheme::lockPhysicalExtents(IOService * client) { // // Lock the contents of the storage object against relocation temporarily, // for the purpose of getting physical extents. // return getProvider( )->lockPhysicalExtents( this ); } IOStorage * IOPartitionScheme::copyPhysicalExtent(IOService * client, UInt64 * byteStart, UInt64 * byteCount) { // // Convert the specified byte offset into a physical byte offset, relative // to a physical storage object. This call should only be made within the // context of lockPhysicalExtents(). // return getProvider( )->copyPhysicalExtent( this, byteStart, byteCount ); } void IOPartitionScheme::unlockPhysicalExtents(IOService * client) { // // Unlock the contents of the storage object for relocation again. This // call must balance a successful call to lockPhysicalExtents(). // getProvider( )->unlockPhysicalExtents( this ); } #ifdef __LP64__ bool IOPartitionScheme::attachMediaObjectToDeviceTree(IOMedia * media) #else /* !__LP64__ */ bool IOPartitionScheme::attachMediaObjectToDeviceTree(IOMedia * media, IOOptionBits options) #endif /* !__LP64__ */ { // // Attach the given media object to the device tree plane. // IORegistryEntry * parent = this; while ( (parent = parent->getParentEntry(gIOServicePlane)) ) { if ( parent->inPlane(gIODTPlane) ) { char location[ 32 ]; const char * locationOfParent = parent->getLocation(gIODTPlane); const char * nameOfParent = parent->getName(gIODTPlane); if ( locationOfParent == 0 ) break; if ( OSDynamicCast(IOMedia, parent) == 0 ) break; parent = parent->getParentEntry(gIODTPlane); if ( parent == 0 ) break; if ( media->attachToParent(parent, gIODTPlane) == false ) break; strlcpy(location, locationOfParent, sizeof(location)); if ( strchr(location, ':') ) *(strchr(location, ':') + 1) = 0; strlcat(location, media->getLocation(), sizeof(location) - strlen(location)); media->setLocation(location, gIODTPlane); media->setName(nameOfParent, gIODTPlane); return true; } } return false; }
IORegistryEntry * AppleIntelPIIXATARoot::getDTChannelEntry( int channelID ) { IORegistryEntry * entry = 0; const char * location; OSIterator * iter = _provider->getChildIterator( gIODTPlane ); if (iter == 0) return 0; while (( entry = (IORegistryEntry *) iter->getNextObject() )) { location = entry->getLocation(); if ( location && strtol(location, 0, 10) == channelID ) { entry->retain(); break; } } iter->release(); return entry; // retain held on the entry }