/* $Id: StorageControllerImpl.cpp 37926 2011-07-13 15:36:59Z vboxsync $ */ /** @file * * Implementation of IStorageController. */ /* * Copyright (C) 2008-2010 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ #include "StorageControllerImpl.h" #include "MachineImpl.h" #include "VirtualBoxImpl.h" #include "SystemPropertiesImpl.h" #include #include #include #include #include #include "AutoStateDep.h" #include "AutoCaller.h" #include "Logging.h" // defines ///////////////////////////////////////////////////////////////////////////// struct BackupableStorageControllerData { /* Constructor. */ BackupableStorageControllerData() : mStorageBus(StorageBus_IDE), mStorageControllerType(StorageControllerType_PIIX4), mInstance(0), mPortCount(2), fUseHostIOCache(true), fBootable(false), mPortIde0Master(0), mPortIde0Slave(1), mPortIde1Master(2), mPortIde1Slave(3) { } /** Unique name of the storage controller. */ Utf8Str strName; /** The connection type of the storage controller. */ StorageBus_T mStorageBus; /** Type of the Storage controller. */ StorageControllerType_T mStorageControllerType; /** Instance number of the storage controller. */ ULONG mInstance; /** Number of usable ports. */ ULONG mPortCount; /** Whether to use the host IO caches. */ BOOL fUseHostIOCache; /** Whether it is possible to boot from disks attached to this controller. */ BOOL fBootable; /** The following is only for the SATA controller atm. */ /** Port which acts as primary master for ide emulation. */ ULONG mPortIde0Master; /** Port which acts as primary slave for ide emulation. */ ULONG mPortIde0Slave; /** Port which acts as secondary master for ide emulation. */ ULONG mPortIde1Master; /** Port which acts as secondary slave for ide emulation. */ ULONG mPortIde1Slave; }; struct StorageController::Data { Data(Machine * const aMachine) : pVirtualBox(NULL), pSystemProperties(NULL), pParent(aMachine) { unconst(pVirtualBox) = aMachine->getVirtualBox(); unconst(pSystemProperties) = pVirtualBox->getSystemProperties(); } VirtualBox * const pVirtualBox; SystemProperties * const pSystemProperties; Machine * const pParent; const ComObjPtr pPeer; Backupable bd; }; // constructor / destructor ///////////////////////////////////////////////////////////////////////////// HRESULT StorageController::FinalConstruct() { return BaseFinalConstruct(); } void StorageController::FinalRelease() { uninit(); BaseFinalRelease(); } // public initializer/uninitializer for internal purposes only ///////////////////////////////////////////////////////////////////////////// /** * Initializes the storage controller object. * * @returns COM result indicator. * @param aParent Pointer to our parent object. * @param aName Name of the storage controller. * @param aInstance Instance number of the storage controller. */ HRESULT StorageController::init(Machine *aParent, const Utf8Str &aName, StorageBus_T aStorageBus, ULONG aInstance, bool fBootable) { LogFlowThisFunc(("aParent=%p aName=\"%s\" aInstance=%u\n", aParent, aName.c_str(), aInstance)); ComAssertRet(aParent && !aName.isEmpty(), E_INVALIDARG); if ( (aStorageBus <= StorageBus_Null) || (aStorageBus > StorageBus_SAS)) return setError(E_INVALIDARG, tr("Invalid storage connection type")); ULONG maxInstances; ChipsetType_T chipsetType; HRESULT rc = aParent->COMGETTER(ChipsetType)(&chipsetType); if (FAILED(rc)) return rc; rc = aParent->getVirtualBox()->getSystemProperties()->GetMaxInstancesOfStorageBus(chipsetType, aStorageBus, &maxInstances); if (FAILED(rc)) return rc; if (aInstance >= maxInstances) return setError(E_INVALIDARG, tr("Too many storage controllers of this type")); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan(this); AssertReturn(autoInitSpan.isOk(), E_FAIL); m = new Data(aParent); /* m->pPeer is left null */ m->bd.allocate(); m->bd->strName = aName; m->bd->mInstance = aInstance; m->bd->fBootable = fBootable; m->bd->mStorageBus = aStorageBus; if ( aStorageBus != StorageBus_IDE && aStorageBus != StorageBus_Floppy) m->bd->fUseHostIOCache = false; else m->bd->fUseHostIOCache = true; switch (aStorageBus) { case StorageBus_IDE: m->bd->mPortCount = 2; m->bd->mStorageControllerType = StorageControllerType_PIIX4; break; case StorageBus_SATA: m->bd->mPortCount = 30; m->bd->mStorageControllerType = StorageControllerType_IntelAhci; break; case StorageBus_SCSI: m->bd->mPortCount = 16; m->bd->mStorageControllerType = StorageControllerType_LsiLogic; break; case StorageBus_Floppy: m->bd->mPortCount = 1; m->bd->mStorageControllerType = StorageControllerType_I82078; break; case StorageBus_SAS: m->bd->mPortCount = 8; m->bd->mStorageControllerType = StorageControllerType_LsiLogicSas; break; } /* Confirm a successful initialization */ autoInitSpan.setSucceeded(); return S_OK; } /** * Initializes the object given another object * (a kind of copy constructor). This object shares data with * the object passed as an argument. * * @param aReshare * When false, the original object will remain a data owner. * Otherwise, data ownership will be transferred from the original * object to this one. * * @note This object must be destroyed before the original object * it shares data with is destroyed. * * @note Locks @a aThat object for writing if @a aReshare is @c true, or for * reading if @a aReshare is false. */ HRESULT StorageController::init(Machine *aParent, StorageController *aThat, bool aReshare /* = false */) { LogFlowThisFunc(("aParent=%p, aThat=%p, aReshare=%RTbool\n", aParent, aThat, aReshare)); ComAssertRet(aParent && aThat, E_INVALIDARG); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan(this); AssertReturn(autoInitSpan.isOk(), E_FAIL); m = new Data(aParent); /* sanity */ AutoCaller thatCaller(aThat); AssertComRCReturnRC(thatCaller.rc()); if (aReshare) { AutoWriteLock thatLock(aThat COMMA_LOCKVAL_SRC_POS); unconst(aThat->m->pPeer) = this; m->bd.attach (aThat->m->bd); } else { unconst(m->pPeer) = aThat; AutoReadLock thatLock(aThat COMMA_LOCKVAL_SRC_POS); m->bd.share (aThat->m->bd); } /* Confirm successful initialization */ autoInitSpan.setSucceeded(); return S_OK; } /** * Initializes the storage controller object given another guest object * (a kind of copy constructor). This object makes a private copy of data * of the original object passed as an argument. */ HRESULT StorageController::initCopy(Machine *aParent, StorageController *aThat) { LogFlowThisFunc(("aParent=%p, aThat=%p\n", aParent, aThat)); ComAssertRet(aParent && aThat, E_INVALIDARG); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan(this); AssertReturn(autoInitSpan.isOk(), E_FAIL); m = new Data(aParent); /* m->pPeer is left null */ AutoCaller thatCaller(aThat); AssertComRCReturnRC(thatCaller.rc()); AutoReadLock thatlock(aThat COMMA_LOCKVAL_SRC_POS); m->bd.attachCopy(aThat->m->bd); /* Confirm a successful initialization */ autoInitSpan.setSucceeded(); return S_OK; } /** * Uninitializes the instance and sets the ready flag to FALSE. * Called either from FinalRelease() or by the parent when it gets destroyed. */ void StorageController::uninit() { LogFlowThisFunc(("\n")); /* Enclose the state transition Ready->InUninit->NotReady */ AutoUninitSpan autoUninitSpan(this); if (autoUninitSpan.uninitDone()) return; m->bd.free(); unconst(m->pPeer) = NULL; unconst(m->pParent) = NULL; delete m; m = NULL; } // IStorageController properties ///////////////////////////////////////////////////////////////////////////// STDMETHODIMP StorageController::COMGETTER(Name) (BSTR *aName) { CheckComArgOutPointerValid(aName); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); /* mName is constant during life time, no need to lock */ m->bd.data()->strName.cloneTo(aName); return S_OK; } STDMETHODIMP StorageController::COMGETTER(Bus) (StorageBus_T *aBus) { CheckComArgOutPointerValid(aBus); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aBus = m->bd->mStorageBus; return S_OK; } STDMETHODIMP StorageController::COMGETTER(ControllerType) (StorageControllerType_T *aControllerType) { CheckComArgOutPointerValid(aControllerType); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aControllerType = m->bd->mStorageControllerType; return S_OK; } STDMETHODIMP StorageController::COMSETTER(ControllerType) (StorageControllerType_T aControllerType) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); HRESULT rc = S_OK; switch (m->bd->mStorageBus) { case StorageBus_IDE: { if ( (aControllerType != StorageControllerType_PIIX3) && (aControllerType != StorageControllerType_PIIX4) && (aControllerType != StorageControllerType_ICH6)) rc = E_INVALIDARG; break; } case StorageBus_SATA: { if (aControllerType != StorageControllerType_IntelAhci) rc = E_INVALIDARG; break; } case StorageBus_SCSI: { if ( (aControllerType != StorageControllerType_LsiLogic) && (aControllerType != StorageControllerType_BusLogic)) rc = E_INVALIDARG; break; } case StorageBus_Floppy: { if (aControllerType != StorageControllerType_I82078) rc = E_INVALIDARG; break; } case StorageBus_SAS: { if (aControllerType != StorageControllerType_LsiLogicSas) rc = E_INVALIDARG; break; } default: AssertMsgFailed(("Invalid controller type %d\n", m->bd->mStorageBus)); } if (!SUCCEEDED(rc)) return setError(rc, tr ("Invalid controller type %d"), aControllerType); m->bd->mStorageControllerType = aControllerType; return S_OK; } STDMETHODIMP StorageController::COMGETTER(MaxDevicesPerPortCount) (ULONG *aMaxDevices) { CheckComArgOutPointerValid(aMaxDevices); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); HRESULT rc = m->pSystemProperties->GetMaxDevicesPerPortForStorageBus(m->bd->mStorageBus, aMaxDevices); return rc; } STDMETHODIMP StorageController::COMGETTER(MinPortCount) (ULONG *aMinPortCount) { CheckComArgOutPointerValid(aMinPortCount); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); HRESULT rc = m->pSystemProperties->GetMinPortCountForStorageBus(m->bd->mStorageBus, aMinPortCount); return rc; } STDMETHODIMP StorageController::COMGETTER(MaxPortCount) (ULONG *aMaxPortCount) { CheckComArgOutPointerValid(aMaxPortCount); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); HRESULT rc = m->pSystemProperties->GetMaxPortCountForStorageBus(m->bd->mStorageBus, aMaxPortCount); return rc; } STDMETHODIMP StorageController::COMGETTER(PortCount) (ULONG *aPortCount) { CheckComArgOutPointerValid(aPortCount); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aPortCount = m->bd->mPortCount; return S_OK; } STDMETHODIMP StorageController::COMSETTER(PortCount) (ULONG aPortCount) { LogFlowThisFunc(("aPortCount=%u\n", aPortCount)); switch (m->bd->mStorageBus) { case StorageBus_SATA: { /* AHCI SATA supports a maximum of 30 ports. */ if (aPortCount < 1 || aPortCount > 30) return setError(E_INVALIDARG, tr("Invalid port count: %lu (must be in range [%lu, %lu])"), aPortCount, 1, 30); break; } case StorageBus_SCSI: { /* * SCSI does not support setting different ports. * (doesn't make sense here either). * The maximum and minimum is 16 and unless the callee * tries to set a different value we return an error. */ if (aPortCount != 16) return setError(E_INVALIDARG, tr("Invalid port count: %lu (must be in range [%lu, %lu])"), aPortCount, 16, 16); break; } case StorageBus_IDE: { /* * The port count is fixed to 2. */ if (aPortCount != 2) return setError(E_INVALIDARG, tr("Invalid port count: %lu (must be in range [%lu, %lu])"), aPortCount, 2, 2); break; } case StorageBus_Floppy: { /* * The port count is fixed to 1. */ if (aPortCount != 1) return setError(E_INVALIDARG, tr("Invalid port count: %lu (must be in range [%lu, %lu])"), aPortCount, 1, 1); break; } case StorageBus_SAS: { /* * The port count is fixed to 8. */ if (aPortCount != 8) return setError(E_INVALIDARG, tr("Invalid port count: %lu (must be in range [%lu, %lu])"), aPortCount, 8, 8); break; } default: AssertMsgFailed(("Invalid controller type %d\n", m->bd->mStorageBus)); } AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); /* the machine needs to be mutable */ AutoMutableStateDependency adep(m->pParent); if (FAILED(adep.rc())) return adep.rc(); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); if (m->bd->mPortCount != aPortCount) { m->bd.backup(); m->bd->mPortCount = aPortCount; alock.release(); AutoWriteLock mlock(m->pParent COMMA_LOCKVAL_SRC_POS); // m->pParent is const, needs no locking m->pParent->setModified(Machine::IsModified_Storage); mlock.release(); m->pParent->onStorageControllerChange(); } return S_OK; } STDMETHODIMP StorageController::COMGETTER(Instance) (ULONG *aInstance) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); /* The machine doesn't need to be mutable. */ AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aInstance = m->bd->mInstance; return S_OK; } STDMETHODIMP StorageController::COMSETTER(Instance) (ULONG aInstance) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); /* The machine doesn't need to be mutable. */ AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); m->bd->mInstance = aInstance; return S_OK; } STDMETHODIMP StorageController::COMGETTER(UseHostIOCache) (BOOL *fUseHostIOCache) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); /* The machine doesn't need to be mutable. */ AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *fUseHostIOCache = m->bd->fUseHostIOCache; return S_OK; } STDMETHODIMP StorageController::COMSETTER(UseHostIOCache) (BOOL fUseHostIOCache) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); /* the machine needs to be mutable */ AutoMutableStateDependency adep(m->pParent); if (FAILED(adep.rc())) return adep.rc(); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); if (m->bd->fUseHostIOCache != !!fUseHostIOCache) { m->bd.backup(); m->bd->fUseHostIOCache = !!fUseHostIOCache; alock.release(); AutoWriteLock mlock(m->pParent COMMA_LOCKVAL_SRC_POS); // m->pParent is const, needs no locking m->pParent->setModified(Machine::IsModified_Storage); mlock.release(); m->pParent->onStorageControllerChange(); } return S_OK; } STDMETHODIMP StorageController::COMGETTER(Bootable) (BOOL *fBootable) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); /* The machine doesn't need to be mutable. */ AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *fBootable = m->bd->fBootable; return S_OK; } // IStorageController methods ///////////////////////////////////////////////////////////////////////////// STDMETHODIMP StorageController::GetIDEEmulationPort(LONG DevicePosition, LONG *aPortNumber) { CheckComArgOutPointerValid(aPortNumber); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); if (m->bd->mStorageControllerType != StorageControllerType_IntelAhci) return setError(E_NOTIMPL, tr("Invalid controller type")); switch (DevicePosition) { case 0: *aPortNumber = m->bd->mPortIde0Master; break; case 1: *aPortNumber = m->bd->mPortIde0Slave; break; case 2: *aPortNumber = m->bd->mPortIde1Master; break; case 3: *aPortNumber = m->bd->mPortIde1Slave; break; default: return E_INVALIDARG; } return S_OK; } STDMETHODIMP StorageController::SetIDEEmulationPort(LONG DevicePosition, LONG aPortNumber) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); /* the machine needs to be mutable */ AutoMutableStateDependency adep(m->pParent); if (FAILED(adep.rc())) return adep.rc(); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); if (m->bd->mStorageControllerType != StorageControllerType_IntelAhci) return setError(E_NOTIMPL, tr("Invalid controller type")); if (aPortNumber < 0 || aPortNumber >= 30) return setError(E_INVALIDARG, tr("Invalid port number: %ld (must be in range [%lu, %lu])"), aPortNumber, 0, 29); switch (DevicePosition) { case 0: m->bd->mPortIde0Master = aPortNumber; break; case 1: m->bd->mPortIde0Slave = aPortNumber; break; case 2: m->bd->mPortIde1Master = aPortNumber; break; case 3: m->bd->mPortIde1Slave = aPortNumber; break; default: return E_INVALIDARG; } return S_OK; } // public methods only for internal purposes ///////////////////////////////////////////////////////////////////////////// const Utf8Str& StorageController::getName() const { return m->bd->strName; } StorageControllerType_T StorageController::getControllerType() const { return m->bd->mStorageControllerType; } StorageBus_T StorageController::getStorageBus() const { return m->bd->mStorageBus; } ULONG StorageController::getInstance() const { return m->bd->mInstance; } bool StorageController::getBootable() const { return !!m->bd->fBootable; } /** * Returns S_OK if the given port and device numbers are within the range supported * by this controller. If not, it sets an error and returns E_INVALIDARG. * @param ulPort * @param ulDevice * @return */ HRESULT StorageController::checkPortAndDeviceValid(LONG aControllerPort, LONG aDevice) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); ULONG portCount = m->bd->mPortCount; ULONG devicesPerPort; HRESULT rc = m->pSystemProperties->GetMaxDevicesPerPortForStorageBus(m->bd->mStorageBus, &devicesPerPort); if (FAILED(rc)) return rc; if ( aControllerPort < 0 || aControllerPort >= (LONG)portCount || aDevice < 0 || aDevice >= (LONG)devicesPerPort ) return setError(E_INVALIDARG, tr("The port and/or device parameter are out of range: port=%d (must be in range [0, %d]), device=%d (must be in range [0, %d])"), (int)aControllerPort, (int)portCount-1, (int)aDevice, (int)devicesPerPort-1); return S_OK; } /** @note Locks objects for writing! */ void StorageController::setBootable(BOOL fBootable) { AutoCaller autoCaller(this); AssertComRCReturnVoid(autoCaller.rc()); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); m->bd.backup(); m->bd->fBootable = fBootable; } /** @note Locks objects for writing! */ void StorageController::rollback() { AutoCaller autoCaller(this); AssertComRCReturnVoid(autoCaller.rc()); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); m->bd.rollback(); } /** * @note Locks this object for writing, together with the peer object (also * for writing) if there is one. */ void StorageController::commit() { /* sanity */ AutoCaller autoCaller(this); AssertComRCReturnVoid (autoCaller.rc()); /* sanity too */ AutoCaller peerCaller (m->pPeer); AssertComRCReturnVoid (peerCaller.rc()); /* lock both for writing since we modify both (m->pPeer is "master" so locked * first) */ AutoMultiWriteLock2 alock(m->pPeer, this COMMA_LOCKVAL_SRC_POS); if (m->bd.isBackedUp()) { m->bd.commit(); if (m->pPeer) { // attach new data to the peer and reshare it m->pPeer->m->bd.attach (m->bd); } } } /** * Cancels sharing (if any) by making an independent copy of data. * This operation also resets this object's peer to NULL. * * @note Locks this object for writing, together with the peer object * represented by @a aThat (locked for reading). */ void StorageController::unshare() { /* sanity */ AutoCaller autoCaller(this); AssertComRCReturnVoid (autoCaller.rc()); /* sanity too */ AutoCaller peerCaller (m->pPeer); AssertComRCReturnVoid (peerCaller.rc()); /* peer is not modified, lock it for reading (m->pPeer is "master" so locked * first) */ AutoReadLock rl(m->pPeer COMMA_LOCKVAL_SRC_POS); AutoWriteLock wl(this COMMA_LOCKVAL_SRC_POS); if (m->bd.isShared()) { if (!m->bd.isBackedUp()) m->bd.backup(); m->bd.commit(); } unconst(m->pPeer) = NULL; } Machine* StorageController::getMachine() { return m->pParent; } ComObjPtr StorageController::getPeer() { return m->pPeer; } // private methods ///////////////////////////////////////////////////////////////////////////// /* vi: set tabstop=4 shiftwidth=4 expandtab: */