/* $Id: MediumImpl.cpp 53354 2014-11-19 18:32:03Z vboxsync $ */ /** @file * VirtualBox COM class implementation */ /* * Copyright (C) 2008-2014 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 "MediumImpl.h" #include "TokenImpl.h" #include "ProgressImpl.h" #include "SystemPropertiesImpl.h" #include "VirtualBoxImpl.h" #include "AutoCaller.h" #include "Logging.h" #include "VBox/com/MultiResult.h" #include "VBox/com/ErrorInfo.h" #include #include #include #include #include #include #include #include #include #include typedef std::list GuidList; //////////////////////////////////////////////////////////////////////////////// // // Medium data definition // //////////////////////////////////////////////////////////////////////////////// /** Describes how a machine refers to this medium. */ struct BackRef { /** Equality predicate for stdc++. */ struct EqualsTo : public std::unary_function { explicit EqualsTo(const Guid &aMachineId) : machineId(aMachineId) {} bool operator()(const argument_type &aThat) const { return aThat.machineId == machineId; } const Guid machineId; }; BackRef(const Guid &aMachineId, const Guid &aSnapshotId = Guid::Empty) : machineId(aMachineId), fInCurState(aSnapshotId.isZero()) { if (aSnapshotId.isValid() && !aSnapshotId.isZero()) llSnapshotIds.push_back(aSnapshotId); } Guid machineId; bool fInCurState : 1; GuidList llSnapshotIds; }; typedef std::list BackRefList; struct Medium::Data { Data() : pVirtualBox(NULL), state(MediumState_NotCreated), variant(MediumVariant_Standard), size(0), readers(0), preLockState(MediumState_NotCreated), queryInfoSem(LOCKCLASS_MEDIUMQUERY), queryInfoRunning(false), type(MediumType_Normal), devType(DeviceType_HardDisk), logicalSize(0), hddOpenMode(OpenReadWrite), autoReset(false), hostDrive(false), implicit(false), uOpenFlagsDef(VD_OPEN_FLAGS_IGNORE_FLUSH), numCreateDiffTasks(0), vdDiskIfaces(NULL), vdImageIfaces(NULL) { } /** weak VirtualBox parent */ VirtualBox * const pVirtualBox; // pParent and llChildren are protected by VirtualBox::i_getMediaTreeLockHandle() ComObjPtr pParent; MediaList llChildren; // to add a child, just call push_back; to remove // a child, call child->deparent() which does a lookup GuidList llRegistryIDs; // media registries in which this medium is listed const Guid id; Utf8Str strDescription; MediumState_T state; MediumVariant_T variant; Utf8Str strLocationFull; uint64_t size; Utf8Str strLastAccessError; BackRefList backRefs; size_t readers; MediumState_T preLockState; /** Special synchronization for operations which must wait for * Medium::i_queryInfo in another thread to complete. Using a SemRW is * not quite ideal, but at least it is subject to the lock validator, * unlike the SemEventMulti which we had here for many years. Catching * possible deadlocks is more important than a tiny bit of efficiency. */ RWLockHandle queryInfoSem; bool queryInfoRunning : 1; const Utf8Str strFormat; ComObjPtr formatObj; MediumType_T type; DeviceType_T devType; uint64_t logicalSize; HDDOpenMode hddOpenMode; bool autoReset : 1; /** New UUID to be set on the next Medium::i_queryInfo call. */ const Guid uuidImage; /** New parent UUID to be set on the next Medium::i_queryInfo call. */ const Guid uuidParentImage; bool hostDrive : 1; settings::StringsMap mapProperties; bool implicit : 1; /** Default flags passed to VDOpen(). */ unsigned uOpenFlagsDef; uint32_t numCreateDiffTasks; Utf8Str vdError; /*< Error remembered by the VD error callback. */ VDINTERFACEERROR vdIfError; VDINTERFACECONFIG vdIfConfig; VDINTERFACETCPNET vdIfTcpNet; PVDINTERFACE vdDiskIfaces; PVDINTERFACE vdImageIfaces; }; typedef struct VDSOCKETINT { /** Socket handle. */ RTSOCKET hSocket; } VDSOCKETINT, *PVDSOCKETINT; //////////////////////////////////////////////////////////////////////////////// // // Globals // //////////////////////////////////////////////////////////////////////////////// /** * Medium::Task class for asynchronous operations. * * @note Instances of this class must be created using new() because the * task thread function will delete them when the task is complete. * * @note The constructor of this class adds a caller on the managed Medium * object which is automatically released upon destruction. */ class Medium::Task { public: Task(Medium *aMedium, Progress *aProgress) : mVDOperationIfaces(NULL), mMedium(aMedium), mMediumCaller(aMedium), mThread(NIL_RTTHREAD), mProgress(aProgress), mVirtualBoxCaller(NULL) { AssertReturnVoidStmt(aMedium, mRC = E_FAIL); mRC = mMediumCaller.rc(); if (FAILED(mRC)) return; /* Get strong VirtualBox reference, see below. */ VirtualBox *pVirtualBox = aMedium->m->pVirtualBox; mVirtualBox = pVirtualBox; mVirtualBoxCaller.attach(pVirtualBox); mRC = mVirtualBoxCaller.rc(); if (FAILED(mRC)) return; /* Set up a per-operation progress interface, can be used freely (for * binary operations you can use it either on the source or target). */ mVDIfProgress.pfnProgress = vdProgressCall; int vrc = VDInterfaceAdd(&mVDIfProgress.Core, "Medium::Task::vdInterfaceProgress", VDINTERFACETYPE_PROGRESS, mProgress, sizeof(VDINTERFACEPROGRESS), &mVDOperationIfaces); AssertRC(vrc); if (RT_FAILURE(vrc)) mRC = E_FAIL; } // Make all destructors virtual. Just in case. virtual ~Task() {} HRESULT rc() const { return mRC; } bool isOk() const { return SUCCEEDED(rc()); } static int fntMediumTask(RTTHREAD aThread, void *pvUser); bool isAsync() { return mThread != NIL_RTTHREAD; } PVDINTERFACE mVDOperationIfaces; const ComObjPtr mMedium; AutoCaller mMediumCaller; friend HRESULT Medium::i_runNow(Medium::Task*); protected: HRESULT mRC; RTTHREAD mThread; private: virtual HRESULT handler() = 0; const ComObjPtr mProgress; static DECLCALLBACK(int) vdProgressCall(void *pvUser, unsigned uPercent); VDINTERFACEPROGRESS mVDIfProgress; /* Must have a strong VirtualBox reference during a task otherwise the * reference count might drop to 0 while a task is still running. This * would result in weird behavior, including deadlocks due to uninit and * locking order issues. The deadlock often is not detectable because the * uninit uses event semaphores which sabotages deadlock detection. */ ComObjPtr mVirtualBox; AutoCaller mVirtualBoxCaller; }; class Medium::CreateBaseTask : public Medium::Task { public: CreateBaseTask(Medium *aMedium, Progress *aProgress, uint64_t aSize, MediumVariant_T aVariant) : Medium::Task(aMedium, aProgress), mSize(aSize), mVariant(aVariant) {} uint64_t mSize; MediumVariant_T mVariant; private: virtual HRESULT handler(); }; class Medium::CreateDiffTask : public Medium::Task { public: CreateDiffTask(Medium *aMedium, Progress *aProgress, Medium *aTarget, MediumVariant_T aVariant, MediumLockList *aMediumLockList, bool fKeepMediumLockList = false) : Medium::Task(aMedium, aProgress), mpMediumLockList(aMediumLockList), mTarget(aTarget), mVariant(aVariant), mTargetCaller(aTarget), mfKeepMediumLockList(fKeepMediumLockList) { AssertReturnVoidStmt(aTarget != NULL, mRC = E_FAIL); mRC = mTargetCaller.rc(); if (FAILED(mRC)) return; } ~CreateDiffTask() { if (!mfKeepMediumLockList && mpMediumLockList) delete mpMediumLockList; } MediumLockList *mpMediumLockList; const ComObjPtr mTarget; MediumVariant_T mVariant; private: virtual HRESULT handler(); AutoCaller mTargetCaller; bool mfKeepMediumLockList; }; class Medium::CloneTask : public Medium::Task { public: CloneTask(Medium *aMedium, Progress *aProgress, Medium *aTarget, MediumVariant_T aVariant, Medium *aParent, uint32_t idxSrcImageSame, uint32_t idxDstImageSame, MediumLockList *aSourceMediumLockList, MediumLockList *aTargetMediumLockList, bool fKeepSourceMediumLockList = false, bool fKeepTargetMediumLockList = false) : Medium::Task(aMedium, aProgress), mTarget(aTarget), mParent(aParent), mpSourceMediumLockList(aSourceMediumLockList), mpTargetMediumLockList(aTargetMediumLockList), mVariant(aVariant), midxSrcImageSame(idxSrcImageSame), midxDstImageSame(idxDstImageSame), mTargetCaller(aTarget), mParentCaller(aParent), mfKeepSourceMediumLockList(fKeepSourceMediumLockList), mfKeepTargetMediumLockList(fKeepTargetMediumLockList) { AssertReturnVoidStmt(aTarget != NULL, mRC = E_FAIL); mRC = mTargetCaller.rc(); if (FAILED(mRC)) return; /* aParent may be NULL */ mRC = mParentCaller.rc(); if (FAILED(mRC)) return; AssertReturnVoidStmt(aSourceMediumLockList != NULL, mRC = E_FAIL); AssertReturnVoidStmt(aTargetMediumLockList != NULL, mRC = E_FAIL); } ~CloneTask() { if (!mfKeepSourceMediumLockList && mpSourceMediumLockList) delete mpSourceMediumLockList; if (!mfKeepTargetMediumLockList && mpTargetMediumLockList) delete mpTargetMediumLockList; } const ComObjPtr mTarget; const ComObjPtr mParent; MediumLockList *mpSourceMediumLockList; MediumLockList *mpTargetMediumLockList; MediumVariant_T mVariant; uint32_t midxSrcImageSame; uint32_t midxDstImageSame; private: virtual HRESULT handler(); AutoCaller mTargetCaller; AutoCaller mParentCaller; bool mfKeepSourceMediumLockList; bool mfKeepTargetMediumLockList; }; class Medium::CompactTask : public Medium::Task { public: CompactTask(Medium *aMedium, Progress *aProgress, MediumLockList *aMediumLockList, bool fKeepMediumLockList = false) : Medium::Task(aMedium, aProgress), mpMediumLockList(aMediumLockList), mfKeepMediumLockList(fKeepMediumLockList) { AssertReturnVoidStmt(aMediumLockList != NULL, mRC = E_FAIL); } ~CompactTask() { if (!mfKeepMediumLockList && mpMediumLockList) delete mpMediumLockList; } MediumLockList *mpMediumLockList; private: virtual HRESULT handler(); bool mfKeepMediumLockList; }; class Medium::ResizeTask : public Medium::Task { public: ResizeTask(Medium *aMedium, uint64_t aSize, Progress *aProgress, MediumLockList *aMediumLockList, bool fKeepMediumLockList = false) : Medium::Task(aMedium, aProgress), mSize(aSize), mpMediumLockList(aMediumLockList), mfKeepMediumLockList(fKeepMediumLockList) { AssertReturnVoidStmt(aMediumLockList != NULL, mRC = E_FAIL); } ~ResizeTask() { if (!mfKeepMediumLockList && mpMediumLockList) delete mpMediumLockList; } uint64_t mSize; MediumLockList *mpMediumLockList; private: virtual HRESULT handler(); bool mfKeepMediumLockList; }; class Medium::ResetTask : public Medium::Task { public: ResetTask(Medium *aMedium, Progress *aProgress, MediumLockList *aMediumLockList, bool fKeepMediumLockList = false) : Medium::Task(aMedium, aProgress), mpMediumLockList(aMediumLockList), mfKeepMediumLockList(fKeepMediumLockList) {} ~ResetTask() { if (!mfKeepMediumLockList && mpMediumLockList) delete mpMediumLockList; } MediumLockList *mpMediumLockList; private: virtual HRESULT handler(); bool mfKeepMediumLockList; }; class Medium::DeleteTask : public Medium::Task { public: DeleteTask(Medium *aMedium, Progress *aProgress, MediumLockList *aMediumLockList, bool fKeepMediumLockList = false) : Medium::Task(aMedium, aProgress), mpMediumLockList(aMediumLockList), mfKeepMediumLockList(fKeepMediumLockList) {} ~DeleteTask() { if (!mfKeepMediumLockList && mpMediumLockList) delete mpMediumLockList; } MediumLockList *mpMediumLockList; private: virtual HRESULT handler(); bool mfKeepMediumLockList; }; class Medium::MergeTask : public Medium::Task { public: MergeTask(Medium *aMedium, Medium *aTarget, bool fMergeForward, Medium *aParentForTarget, MediumLockList *aChildrenToReparent, Progress *aProgress, MediumLockList *aMediumLockList, bool fKeepMediumLockList = false) : Medium::Task(aMedium, aProgress), mTarget(aTarget), mfMergeForward(fMergeForward), mParentForTarget(aParentForTarget), mpChildrenToReparent(aChildrenToReparent), mpMediumLockList(aMediumLockList), mTargetCaller(aTarget), mParentForTargetCaller(aParentForTarget), mfKeepMediumLockList(fKeepMediumLockList) { AssertReturnVoidStmt(aMediumLockList != NULL, mRC = E_FAIL); } ~MergeTask() { if (!mfKeepMediumLockList && mpMediumLockList) delete mpMediumLockList; if (mpChildrenToReparent) delete mpChildrenToReparent; } const ComObjPtr mTarget; bool mfMergeForward; /* When mpChildrenToReparent is null then mParentForTarget is non-null and * vice versa. In other words: they are used in different cases. */ const ComObjPtr mParentForTarget; MediumLockList *mpChildrenToReparent; MediumLockList *mpMediumLockList; private: virtual HRESULT handler(); AutoCaller mTargetCaller; AutoCaller mParentForTargetCaller; bool mfKeepMediumLockList; }; class Medium::ExportTask : public Medium::Task { public: ExportTask(Medium *aMedium, Progress *aProgress, const char *aFilename, MediumFormat *aFormat, MediumVariant_T aVariant, VDINTERFACEIO *aVDImageIOIf, void *aVDImageIOUser, MediumLockList *aSourceMediumLockList, bool fKeepSourceMediumLockList = false) : Medium::Task(aMedium, aProgress), mpSourceMediumLockList(aSourceMediumLockList), mFilename(aFilename), mFormat(aFormat), mVariant(aVariant), mfKeepSourceMediumLockList(fKeepSourceMediumLockList) { AssertReturnVoidStmt(aSourceMediumLockList != NULL, mRC = E_FAIL); mVDImageIfaces = aMedium->m->vdImageIfaces; if (aVDImageIOIf) { int vrc = VDInterfaceAdd(&aVDImageIOIf->Core, "Medium::vdInterfaceIO", VDINTERFACETYPE_IO, aVDImageIOUser, sizeof(VDINTERFACEIO), &mVDImageIfaces); AssertRCReturnVoidStmt(vrc, mRC = E_FAIL); } } ~ExportTask() { if (!mfKeepSourceMediumLockList && mpSourceMediumLockList) delete mpSourceMediumLockList; } MediumLockList *mpSourceMediumLockList; Utf8Str mFilename; ComObjPtr mFormat; MediumVariant_T mVariant; PVDINTERFACE mVDImageIfaces; private: virtual HRESULT handler(); bool mfKeepSourceMediumLockList; }; class Medium::ImportTask : public Medium::Task { public: ImportTask(Medium *aMedium, Progress *aProgress, const char *aFilename, MediumFormat *aFormat, MediumVariant_T aVariant, VDINTERFACEIO *aVDImageIOIf, void *aVDImageIOUser, Medium *aParent, MediumLockList *aTargetMediumLockList, bool fKeepTargetMediumLockList = false) : Medium::Task(aMedium, aProgress), mFilename(aFilename), mFormat(aFormat), mVariant(aVariant), mParent(aParent), mpTargetMediumLockList(aTargetMediumLockList), mParentCaller(aParent), mfKeepTargetMediumLockList(fKeepTargetMediumLockList) { AssertReturnVoidStmt(aTargetMediumLockList != NULL, mRC = E_FAIL); /* aParent may be NULL */ mRC = mParentCaller.rc(); if (FAILED(mRC)) return; mVDImageIfaces = aMedium->m->vdImageIfaces; if (aVDImageIOIf) { int vrc = VDInterfaceAdd(&aVDImageIOIf->Core, "Medium::vdInterfaceIO", VDINTERFACETYPE_IO, aVDImageIOUser, sizeof(VDINTERFACEIO), &mVDImageIfaces); AssertRCReturnVoidStmt(vrc, mRC = E_FAIL); } } ~ImportTask() { if (!mfKeepTargetMediumLockList && mpTargetMediumLockList) delete mpTargetMediumLockList; } Utf8Str mFilename; ComObjPtr mFormat; MediumVariant_T mVariant; const ComObjPtr mParent; MediumLockList *mpTargetMediumLockList; PVDINTERFACE mVDImageIfaces; private: virtual HRESULT handler(); AutoCaller mParentCaller; bool mfKeepTargetMediumLockList; }; /** * Thread function for time-consuming medium tasks. * * @param pvUser Pointer to the Medium::Task instance. */ /* static */ DECLCALLBACK(int) Medium::Task::fntMediumTask(RTTHREAD aThread, void *pvUser) { LogFlowFuncEnter(); AssertReturn(pvUser, (int)E_INVALIDARG); Medium::Task *pTask = static_cast(pvUser); pTask->mThread = aThread; HRESULT rc = pTask->handler(); /* complete the progress if run asynchronously */ if (pTask->isAsync()) if (!pTask->mProgress.isNull()) pTask->mProgress->i_notifyComplete(rc); /* pTask is no longer needed, delete it. */ delete pTask; LogFlowFunc(("rc=%Rhrc\n", rc)); LogFlowFuncLeave(); return (int)rc; } /** * PFNVDPROGRESS callback handler for Task operations. * * @param pvUser Pointer to the Progress instance. * @param uPercent Completion percentage (0-100). */ /*static*/ DECLCALLBACK(int) Medium::Task::vdProgressCall(void *pvUser, unsigned uPercent) { Progress *that = static_cast(pvUser); if (that != NULL) { /* update the progress object, capping it at 99% as the final percent * is used for additional operations like setting the UUIDs and similar. */ HRESULT rc = that->SetCurrentOperationProgress(uPercent * 99 / 100); if (FAILED(rc)) { if (rc == E_FAIL) return VERR_CANCELLED; else return VERR_INVALID_STATE; } } return VINF_SUCCESS; } /** * Implementation code for the "create base" task. */ HRESULT Medium::CreateBaseTask::handler() { return mMedium->i_taskCreateBaseHandler(*this); } /** * Implementation code for the "create diff" task. */ HRESULT Medium::CreateDiffTask::handler() { return mMedium->i_taskCreateDiffHandler(*this); } /** * Implementation code for the "clone" task. */ HRESULT Medium::CloneTask::handler() { return mMedium->i_taskCloneHandler(*this); } /** * Implementation code for the "compact" task. */ HRESULT Medium::CompactTask::handler() { return mMedium->i_taskCompactHandler(*this); } /** * Implementation code for the "resize" task. */ HRESULT Medium::ResizeTask::handler() { return mMedium->i_taskResizeHandler(*this); } /** * Implementation code for the "reset" task. */ HRESULT Medium::ResetTask::handler() { return mMedium->i_taskResetHandler(*this); } /** * Implementation code for the "delete" task. */ HRESULT Medium::DeleteTask::handler() { return mMedium->i_taskDeleteHandler(*this); } /** * Implementation code for the "merge" task. */ HRESULT Medium::MergeTask::handler() { return mMedium->i_taskMergeHandler(*this); } /** * Implementation code for the "export" task. */ HRESULT Medium::ExportTask::handler() { return mMedium->i_taskExportHandler(*this); } /** * Implementation code for the "import" task. */ HRESULT Medium::ImportTask::handler() { return mMedium->i_taskImportHandler(*this); } //////////////////////////////////////////////////////////////////////////////// // // Medium constructor / destructor // //////////////////////////////////////////////////////////////////////////////// DEFINE_EMPTY_CTOR_DTOR(Medium) HRESULT Medium::FinalConstruct() { m = new Data; /* Initialize the callbacks of the VD error interface */ m->vdIfError.pfnError = i_vdErrorCall; m->vdIfError.pfnMessage = NULL; /* Initialize the callbacks of the VD config interface */ m->vdIfConfig.pfnAreKeysValid = i_vdConfigAreKeysValid; m->vdIfConfig.pfnQuerySize = i_vdConfigQuerySize; m->vdIfConfig.pfnQuery = i_vdConfigQuery; m->vdIfConfig.pfnQueryBytes = NULL; /* Initialize the callbacks of the VD TCP interface (we always use the host * IP stack for now) */ m->vdIfTcpNet.pfnSocketCreate = i_vdTcpSocketCreate; m->vdIfTcpNet.pfnSocketDestroy = i_vdTcpSocketDestroy; m->vdIfTcpNet.pfnClientConnect = i_vdTcpClientConnect; m->vdIfTcpNet.pfnClientClose = i_vdTcpClientClose; m->vdIfTcpNet.pfnIsClientConnected = i_vdTcpIsClientConnected; m->vdIfTcpNet.pfnSelectOne = i_vdTcpSelectOne; m->vdIfTcpNet.pfnRead = i_vdTcpRead; m->vdIfTcpNet.pfnWrite = i_vdTcpWrite; m->vdIfTcpNet.pfnSgWrite = i_vdTcpSgWrite; m->vdIfTcpNet.pfnFlush = i_vdTcpFlush; m->vdIfTcpNet.pfnSetSendCoalescing = i_vdTcpSetSendCoalescing; m->vdIfTcpNet.pfnGetLocalAddress = i_vdTcpGetLocalAddress; m->vdIfTcpNet.pfnGetPeerAddress = i_vdTcpGetPeerAddress; m->vdIfTcpNet.pfnSelectOneEx = NULL; m->vdIfTcpNet.pfnPoke = NULL; /* Initialize the per-disk interface chain (could be done more globally, * but it's not wasting much time or space so it's not worth it). */ int vrc; vrc = VDInterfaceAdd(&m->vdIfError.Core, "Medium::vdInterfaceError", VDINTERFACETYPE_ERROR, this, sizeof(VDINTERFACEERROR), &m->vdDiskIfaces); AssertRCReturn(vrc, E_FAIL); /* Initialize the per-image interface chain */ vrc = VDInterfaceAdd(&m->vdIfConfig.Core, "Medium::vdInterfaceConfig", VDINTERFACETYPE_CONFIG, this, sizeof(VDINTERFACECONFIG), &m->vdImageIfaces); AssertRCReturn(vrc, E_FAIL); vrc = VDInterfaceAdd(&m->vdIfTcpNet.Core, "Medium::vdInterfaceTcpNet", VDINTERFACETYPE_TCPNET, this, sizeof(VDINTERFACETCPNET), &m->vdImageIfaces); AssertRCReturn(vrc, E_FAIL); return BaseFinalConstruct(); } void Medium::FinalRelease() { uninit(); delete m; BaseFinalRelease(); } /** * Initializes an empty hard disk object without creating or opening an associated * storage unit. * * This gets called by VirtualBox::CreateHardDisk() in which case uuidMachineRegistry * is empty since starting with VirtualBox 4.0, we no longer add opened media to a * registry automatically (this is deferred until the medium is attached to a machine). * * This also gets called when VirtualBox creates diff images; in this case uuidMachineRegistry * is set to the registry of the parent image to make sure they all end up in the same * file. * * For hard disks that don't have the MediumFormatCapabilities_CreateFixed or * MediumFormatCapabilities_CreateDynamic capability (and therefore cannot be created or deleted * with the means of VirtualBox) the associated storage unit is assumed to be * ready for use so the state of the hard disk object will be set to Created. * * @param aVirtualBox VirtualBox object. * @param aFormat * @param aLocation Storage unit location. * @param uuidMachineRegistry The registry to which this medium should be added * (global registry UUID or machine UUID or empty if none). * @param deviceType Device Type. */ HRESULT Medium::init(VirtualBox *aVirtualBox, const Utf8Str &aFormat, const Utf8Str &aLocation, const Guid &uuidMachineRegistry, const DeviceType_T aDeviceType) { AssertReturn(aVirtualBox != NULL, E_FAIL); AssertReturn(!aFormat.isEmpty(), E_FAIL); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan(this); AssertReturn(autoInitSpan.isOk(), E_FAIL); HRESULT rc = S_OK; unconst(m->pVirtualBox) = aVirtualBox; if (uuidMachineRegistry.isValid() && !uuidMachineRegistry.isZero()) m->llRegistryIDs.push_back(uuidMachineRegistry); /* no storage yet */ m->state = MediumState_NotCreated; /* cannot be a host drive */ m->hostDrive = false; m->devType = aDeviceType; /* No storage unit is created yet, no need to call Medium::i_queryInfo */ rc = i_setFormat(aFormat); if (FAILED(rc)) return rc; rc = i_setLocation(aLocation); if (FAILED(rc)) return rc; if (!(m->formatObj->i_getCapabilities() & ( MediumFormatCapabilities_CreateFixed | MediumFormatCapabilities_CreateDynamic)) ) { /* Storage for mediums of this format can neither be explicitly * created by VirtualBox nor deleted, so we place the medium to * Inaccessible state here and also add it to the registry. The * state means that one has to use RefreshState() to update the * medium format specific fields. */ m->state = MediumState_Inaccessible; // create new UUID unconst(m->id).create(); AutoWriteLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); ComObjPtr pMedium; /* * Check whether the UUID is taken already and create a new one * if required. * Try this only a limited amount of times in case the PRNG is broken * in some way to prevent an endless loop. */ for (unsigned i = 0; i < 5; i++) { bool fInUse; fInUse = m->pVirtualBox->i_isMediaUuidInUse(m->id, aDeviceType); if (fInUse) { // create new UUID unconst(m->id).create(); } else break; } rc = m->pVirtualBox->i_registerMedium(this, &pMedium, aDeviceType, treeLock); Assert(this == pMedium || FAILED(rc)); } /* Confirm a successful initialization when it's the case */ if (SUCCEEDED(rc)) autoInitSpan.setSucceeded(); return rc; } /** * Initializes the medium object by opening the storage unit at the specified * location. The enOpenMode parameter defines whether the medium will be opened * read/write or read-only. * * This gets called by VirtualBox::OpenMedium() and also by * Machine::AttachDevice() and createImplicitDiffs() when new diff * images are created. * * There is no registry for this case since starting with VirtualBox 4.0, we * no longer add opened media to a registry automatically (this is deferred * until the medium is attached to a machine). * * For hard disks, the UUID, format and the parent of this medium will be * determined when reading the medium storage unit. For DVD and floppy images, * which have no UUIDs in their storage units, new UUIDs are created. * If the detected or set parent is not known to VirtualBox, then this method * will fail. * * @param aVirtualBox VirtualBox object. * @param aLocation Storage unit location. * @param enOpenMode Whether to open the medium read/write or read-only. * @param fForceNewUuid Whether a new UUID should be set to avoid duplicates. * @param aDeviceType Device type of medium. */ HRESULT Medium::init(VirtualBox *aVirtualBox, const Utf8Str &aLocation, HDDOpenMode enOpenMode, bool fForceNewUuid, DeviceType_T aDeviceType) { AssertReturn(aVirtualBox, E_INVALIDARG); AssertReturn(!aLocation.isEmpty(), E_INVALIDARG); HRESULT rc = S_OK; { /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan(this); AssertReturn(autoInitSpan.isOk(), E_FAIL); unconst(m->pVirtualBox) = aVirtualBox; /* there must be a storage unit */ m->state = MediumState_Created; /* remember device type for correct unregistering later */ m->devType = aDeviceType; /* cannot be a host drive */ m->hostDrive = false; /* remember the open mode (defaults to ReadWrite) */ m->hddOpenMode = enOpenMode; if (aDeviceType == DeviceType_DVD) m->type = MediumType_Readonly; else if (aDeviceType == DeviceType_Floppy) m->type = MediumType_Writethrough; rc = i_setLocation(aLocation); if (FAILED(rc)) return rc; /* get all the information about the medium from the storage unit */ if (fForceNewUuid) unconst(m->uuidImage).create(); m->state = MediumState_Inaccessible; m->strLastAccessError = tr("Accessibility check was not yet performed"); /* Confirm a successful initialization before the call to i_queryInfo. * Otherwise we can end up with a AutoCaller deadlock because the * medium becomes visible but is not marked as initialized. Causes * locking trouble (e.g. trying to save media registries) which is * hard to solve. */ autoInitSpan.setSucceeded(); } /* we're normal code from now on, no longer init */ AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); /* need to call i_queryInfo immediately to correctly place the medium in * the respective media tree and update other information such as uuid */ rc = i_queryInfo(fForceNewUuid /* fSetImageId */, false /* fSetParentId */, autoCaller); if (SUCCEEDED(rc)) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); /* if the storage unit is not accessible, it's not acceptable for the * newly opened media so convert this into an error */ if (m->state == MediumState_Inaccessible) { Assert(!m->strLastAccessError.isEmpty()); rc = setError(E_FAIL, "%s", m->strLastAccessError.c_str()); alock.release(); autoCaller.release(); uninit(); } else { AssertStmt(!m->id.isZero(), alock.release(); autoCaller.release(); uninit(); return E_FAIL); /* storage format must be detected by Medium::i_queryInfo if the * medium is accessible */ AssertStmt(!m->strFormat.isEmpty(), alock.release(); autoCaller.release(); uninit(); return E_FAIL); } } else { /* opening this image failed, mark the object as dead */ autoCaller.release(); uninit(); } return rc; } /** * Initializes the medium object by loading its data from the given settings * node. In this mode, the medium will always be opened read/write. * * In this case, since we're loading from a registry, uuidMachineRegistry is * always set: it's either the global registry UUID or a machine UUID when * loading from a per-machine registry. * * @param aVirtualBox VirtualBox object. * @param aParent Parent medium disk or NULL for a root (base) medium. * @param aDeviceType Device type of the medium. * @param uuidMachineRegistry The registry to which this medium should be * added (global registry UUID or machine UUID). * @param aNode Configuration settings. * @param strMachineFolder The machine folder with which to resolve relative paths; * if empty, then we use the VirtualBox home directory * * @note Locks the medium tree for writing. */ HRESULT Medium::init(VirtualBox *aVirtualBox, Medium *aParent, DeviceType_T aDeviceType, const Guid &uuidMachineRegistry, const settings::Medium &data, const Utf8Str &strMachineFolder) { using namespace settings; AssertReturn(aVirtualBox, E_INVALIDARG); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan(this); AssertReturn(autoInitSpan.isOk(), E_FAIL); HRESULT rc = S_OK; unconst(m->pVirtualBox) = aVirtualBox; if (uuidMachineRegistry.isValid() && !uuidMachineRegistry.isZero()) m->llRegistryIDs.push_back(uuidMachineRegistry); /* register with VirtualBox/parent early, since uninit() will * unconditionally unregister on failure */ if (aParent) { // differencing medium: add to parent AutoWriteLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); m->pParent = aParent; aParent->m->llChildren.push_back(this); } /* see below why we don't call Medium::i_queryInfo (and therefore treat * the medium as inaccessible for now */ m->state = MediumState_Inaccessible; m->strLastAccessError = tr("Accessibility check was not yet performed"); /* required */ unconst(m->id) = data.uuid; /* assume not a host drive */ m->hostDrive = false; /* optional */ m->strDescription = data.strDescription; /* required */ if (aDeviceType == DeviceType_HardDisk) { AssertReturn(!data.strFormat.isEmpty(), E_FAIL); rc = i_setFormat(data.strFormat); if (FAILED(rc)) return rc; } else { /// @todo handle host drive settings here as well? if (!data.strFormat.isEmpty()) rc = i_setFormat(data.strFormat); else rc = i_setFormat("RAW"); if (FAILED(rc)) return rc; } /* optional, only for diffs, default is false; we can only auto-reset * diff media so they must have a parent */ if (aParent != NULL) m->autoReset = data.fAutoReset; else m->autoReset = false; /* properties (after setting the format as it populates the map). Note that * if some properties are not supported but present in the settings file, * they will still be read and accessible (for possible backward * compatibility; we can also clean them up from the XML upon next * XML format version change if we wish) */ for (settings::StringsMap::const_iterator it = data.properties.begin(); it != data.properties.end(); ++it) { const Utf8Str &name = it->first; const Utf8Str &value = it->second; m->mapProperties[name] = value; } /* try to decrypt an optional iSCSI initiator secret */ settings::StringsMap::const_iterator itCph = data.properties.find("InitiatorSecretEncrypted"); if ( itCph != data.properties.end() && !itCph->second.isEmpty()) { Utf8Str strPlaintext; int vrc = m->pVirtualBox->i_decryptSetting(&strPlaintext, itCph->second); if (RT_SUCCESS(vrc)) m->mapProperties["InitiatorSecret"] = strPlaintext; } Utf8Str strFull; if (m->formatObj->i_getCapabilities() & MediumFormatCapabilities_File) { // compose full path of the medium, if it's not fully qualified... // slightly convoluted logic here. If the caller has given us a // machine folder, then a relative path will be relative to that: if ( !strMachineFolder.isEmpty() && !RTPathStartsWithRoot(data.strLocation.c_str()) ) { strFull = strMachineFolder; strFull += RTPATH_SLASH; strFull += data.strLocation; } else { // Otherwise use the old VirtualBox "make absolute path" logic: rc = m->pVirtualBox->i_calculateFullPath(data.strLocation, strFull); if (FAILED(rc)) return rc; } } else strFull = data.strLocation; rc = i_setLocation(strFull); if (FAILED(rc)) return rc; if (aDeviceType == DeviceType_HardDisk) { /* type is only for base hard disks */ if (m->pParent.isNull()) m->type = data.hdType; } else if (aDeviceType == DeviceType_DVD) m->type = MediumType_Readonly; else m->type = MediumType_Writethrough; /* remember device type for correct unregistering later */ m->devType = aDeviceType; LogFlowThisFunc(("m->strLocationFull='%s', m->strFormat=%s, m->id={%RTuuid}\n", m->strLocationFull.c_str(), m->strFormat.c_str(), m->id.raw())); /* Don't call Medium::i_queryInfo for registered media to prevent the calling * thread (i.e. the VirtualBox server startup thread) from an unexpected * freeze but mark it as initially inaccessible instead. The vital UUID, * location and format properties are read from the registry file above; to * get the actual state and the rest of the data, the user will have to call * COMGETTER(State). */ /* load all children */ for (settings::MediaList::const_iterator it = data.llChildren.begin(); it != data.llChildren.end(); ++it) { const settings::Medium &med = *it; ComObjPtr pHD; pHD.createObject(); rc = pHD->init(aVirtualBox, this, // parent aDeviceType, uuidMachineRegistry, med, // child data strMachineFolder); if (FAILED(rc)) break; AutoWriteLock treeLock(aVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); rc = m->pVirtualBox->i_registerMedium(pHD, &pHD, DeviceType_HardDisk, treeLock); if (FAILED(rc)) break; } /* Confirm a successful initialization when it's the case */ if (SUCCEEDED(rc)) autoInitSpan.setSucceeded(); return rc; } /** * Initializes the medium object by providing the host drive information. * Not used for anything but the host floppy/host DVD case. * * There is no registry for this case. * * @param aVirtualBox VirtualBox object. * @param aDeviceType Device type of the medium. * @param aLocation Location of the host drive. * @param aDescription Comment for this host drive. * * @note Locks VirtualBox lock for writing. */ HRESULT Medium::init(VirtualBox *aVirtualBox, DeviceType_T aDeviceType, const Utf8Str &aLocation, const Utf8Str &aDescription /* = Utf8Str::Empty */) { ComAssertRet(aDeviceType == DeviceType_DVD || aDeviceType == DeviceType_Floppy, E_INVALIDARG); ComAssertRet(!aLocation.isEmpty(), E_INVALIDARG); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan(this); AssertReturn(autoInitSpan.isOk(), E_FAIL); unconst(m->pVirtualBox) = aVirtualBox; // We do not store host drives in VirtualBox.xml or anywhere else, so if we want // host drives to be identifiable by UUID and not give the drive a different UUID // every time VirtualBox starts, we need to fake a reproducible UUID here: RTUUID uuid; RTUuidClear(&uuid); if (aDeviceType == DeviceType_DVD) memcpy(&uuid.au8[0], "DVD", 3); else memcpy(&uuid.au8[0], "FD", 2); /* use device name, adjusted to the end of uuid, shortened if necessary */ size_t lenLocation = aLocation.length(); if (lenLocation > 12) memcpy(&uuid.au8[4], aLocation.c_str() + (lenLocation - 12), 12); else memcpy(&uuid.au8[4 + 12 - lenLocation], aLocation.c_str(), lenLocation); unconst(m->id) = uuid; if (aDeviceType == DeviceType_DVD) m->type = MediumType_Readonly; else m->type = MediumType_Writethrough; m->devType = aDeviceType; m->state = MediumState_Created; m->hostDrive = true; HRESULT rc = i_setFormat("RAW"); if (FAILED(rc)) return rc; rc = i_setLocation(aLocation); if (FAILED(rc)) return rc; m->strDescription = aDescription; autoInitSpan.setSucceeded(); return S_OK; } /** * Uninitializes the instance. * * Called either from FinalRelease() or by the parent when it gets destroyed. * * @note All children of this medium get uninitialized by calling their * uninit() methods. */ void Medium::uninit() { /* It is possible that some previous/concurrent uninit has already cleared * the pVirtualBox reference, and in this case we don't need to continue. * Normally this would be handled through the AutoUninitSpan magic, * however this cannot be done at this point as the media tree must be * locked before reaching the AutoUninitSpan, otherwise deadlocks can * happen due to*/ ComObjPtr pVirtualBox(m->pVirtualBox); if (!pVirtualBox) return; /* Caller must not hold the object or media tree lock over uninit(). */ Assert(!isWriteLockOnCurrentThread()); Assert(!pVirtualBox->i_getMediaTreeLockHandle().isWriteLockOnCurrentThread()); AutoWriteLock treeLock(pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); /* Enclose the state transition Ready->InUninit->NotReady */ AutoUninitSpan autoUninitSpan(this); if (autoUninitSpan.uninitDone()) return; if (!m->formatObj.isNull()) m->formatObj.setNull(); if (m->state == MediumState_Deleting) { /* This medium has been already deleted (directly or as part of a * merge). Reparenting has already been done. */ Assert(m->pParent.isNull()); } else { MediaList llChildren(m->llChildren); m->llChildren.clear(); autoUninitSpan.setSucceeded(); while (!llChildren.empty()) { ComObjPtr pChild = llChildren.front(); llChildren.pop_front(); pChild->m->pParent.setNull(); treeLock.release(); pChild->uninit(); treeLock.acquire(); } if (m->pParent) { // this is a differencing disk: then remove it from the parent's children list i_deparent(); } } unconst(m->pVirtualBox) = NULL; } /** * Internal helper that removes "this" from the list of children of its * parent. Used in uninit() and other places when reparenting is necessary. * * The caller must hold the medium tree lock! */ void Medium::i_deparent() { MediaList &llParent = m->pParent->m->llChildren; for (MediaList::iterator it = llParent.begin(); it != llParent.end(); ++it) { Medium *pParentsChild = *it; if (this == pParentsChild) { llParent.erase(it); break; } } m->pParent.setNull(); } /** * Internal helper that removes "this" from the list of children of its * parent. Used in uninit() and other places when reparenting is necessary. * * The caller must hold the medium tree lock! */ void Medium::i_setParent(const ComObjPtr &pParent) { m->pParent = pParent; if (pParent) pParent->m->llChildren.push_back(this); } //////////////////////////////////////////////////////////////////////////////// // // IMedium public methods // //////////////////////////////////////////////////////////////////////////////// HRESULT Medium::getId(com::Guid &aId) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); aId = m->id; return S_OK; } HRESULT Medium::getDescription(com::Utf8Str &aDescription) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); aDescription = m->strDescription; return S_OK; } HRESULT Medium::setDescription(const com::Utf8Str &aDescription) { // AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); /// @todo update m->description and save the global registry (and local /// registries of portable VMs referring to this medium), this will also /// require to add the mRegistered flag to data NOREF(aDescription); ReturnComNotImplemented(); } HRESULT Medium::getState(MediumState_T *aState) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aState = m->state; return S_OK; } HRESULT Medium::getVariant(std::vector &aVariant) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); const size_t cBits = sizeof(MediumVariant_T) * 8; aVariant.resize(cBits); for (size_t i = 0; i < cBits; ++i) aVariant[i] = (MediumVariant_T)(m->variant & RT_BIT(i)); return S_OK; } HRESULT Medium::getLocation(com::Utf8Str &aLocation) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); aLocation = m->strLocationFull; return S_OK; } HRESULT Medium::getName(com::Utf8Str &aName) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); aName = i_getName(); return S_OK; } HRESULT Medium::getDeviceType(DeviceType_T *aDeviceType) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aDeviceType = m->devType; return S_OK; } HRESULT Medium::getHostDrive(BOOL *aHostDrive) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aHostDrive = m->hostDrive; return S_OK; } HRESULT Medium::getSize(LONG64 *aSize) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aSize = m->size; return S_OK; } HRESULT Medium::getFormat(com::Utf8Str &aFormat) { /* no need to lock, m->strFormat is const */ aFormat = m->strFormat; return S_OK; } HRESULT Medium::getMediumFormat(ComPtr &aMediumFormat) { /* no need to lock, m->formatObj is const */ m->formatObj.queryInterfaceTo(aMediumFormat.asOutParam()); return S_OK; } HRESULT Medium::getType(MediumType_T *aType) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aType = m->type; return S_OK; } HRESULT Medium::setType(MediumType_T aType) { // we access mParent and members AutoWriteLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); AutoWriteLock mlock(this COMMA_LOCKVAL_SRC_POS); switch (m->state) { case MediumState_Created: case MediumState_Inaccessible: break; default: return i_setStateError(); } if (m->type == aType) { /* Nothing to do */ return S_OK; } DeviceType_T devType = i_getDeviceType(); // DVD media can only be readonly. if (devType == DeviceType_DVD && aType != MediumType_Readonly) return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Cannot change the type of DVD medium '%s'"), m->strLocationFull.c_str()); // Floppy media can only be writethrough or readonly. if ( devType == DeviceType_Floppy && aType != MediumType_Writethrough && aType != MediumType_Readonly) return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Cannot change the type of floppy medium '%s'"), m->strLocationFull.c_str()); /* cannot change the type of a differencing medium */ if (m->pParent) return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Cannot change the type of medium '%s' because it is a differencing medium"), m->strLocationFull.c_str()); /* Cannot change the type of a medium being in use by more than one VM. * If the change is to Immutable or MultiAttach then it must not be * directly attached to any VM, otherwise the assumptions about indirect * attachment elsewhere are violated and the VM becomes inaccessible. * Attaching an immutable medium triggers the diff creation, and this is * vital for the correct operation. */ if ( m->backRefs.size() > 1 || ( ( aType == MediumType_Immutable || aType == MediumType_MultiAttach) && m->backRefs.size() > 0)) return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Cannot change the type of medium '%s' because it is attached to %d virtual machines"), m->strLocationFull.c_str(), m->backRefs.size()); switch (aType) { case MediumType_Normal: case MediumType_Immutable: case MediumType_MultiAttach: { /* normal can be easily converted to immutable and vice versa even * if they have children as long as they are not attached to any * machine themselves */ break; } case MediumType_Writethrough: case MediumType_Shareable: case MediumType_Readonly: { /* cannot change to writethrough, shareable or readonly * if there are children */ if (i_getChildren().size() != 0) return setError(VBOX_E_OBJECT_IN_USE, tr("Cannot change type for medium '%s' since it has %d child media"), m->strLocationFull.c_str(), i_getChildren().size()); if (aType == MediumType_Shareable) { MediumVariant_T variant = i_getVariant(); if (!(variant & MediumVariant_Fixed)) return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Cannot change type for medium '%s' to 'Shareable' since it is a dynamic medium storage unit"), m->strLocationFull.c_str()); } else if (aType == MediumType_Readonly && devType == DeviceType_HardDisk) { // Readonly hard disks are not allowed, this medium type is reserved for // DVDs and floppy images at the moment. Later we might allow readonly hard // disks, but that's extremely unusual and many guest OSes will have trouble. return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Cannot change type for medium '%s' to 'Readonly' since it is a hard disk"), m->strLocationFull.c_str()); } break; } default: AssertFailedReturn(E_FAIL); } if (aType == MediumType_MultiAttach) { // This type is new with VirtualBox 4.0 and therefore requires settings // version 1.11 in the settings backend. Unfortunately it is not enough to do // the usual routine in MachineConfigFile::bumpSettingsVersionIfNeeded() for // two reasons: The medium type is a property of the media registry tree, which // can reside in the global config file (for pre-4.0 media); we would therefore // possibly need to bump the global config version. We don't want to do that though // because that might make downgrading to pre-4.0 impossible. // As a result, we can only use these two new types if the medium is NOT in the // global registry: const Guid &uuidGlobalRegistry = m->pVirtualBox->i_getGlobalRegistryId(); if (i_isInRegistry(uuidGlobalRegistry)) return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Cannot change type for medium '%s': the media type 'MultiAttach' can only be used " "on media registered with a machine that was created with VirtualBox 4.0 or later"), m->strLocationFull.c_str()); } m->type = aType; // save the settings mlock.release(); treeLock.release(); i_markRegistriesModified(); m->pVirtualBox->i_saveModifiedRegistries(); return S_OK; } HRESULT Medium::getAllowedTypes(std::vector &aAllowedTypes) { NOREF(aAllowedTypes); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); ReturnComNotImplemented(); } HRESULT Medium::getParent(AutoCaller &autoCaller, ComPtr &aParent) { autoCaller.release(); /* It is possible that some previous/concurrent uninit has already cleared * the pVirtualBox reference, see #uninit(). */ ComObjPtr pVirtualBox(m->pVirtualBox); /* we access mParent */ AutoReadLock treeLock(!pVirtualBox.isNull() ? &pVirtualBox->i_getMediaTreeLockHandle() : NULL COMMA_LOCKVAL_SRC_POS); autoCaller.add(); if (FAILED(autoCaller.rc())) return autoCaller.rc(); m->pParent.queryInterfaceTo(aParent.asOutParam()); return S_OK; } HRESULT Medium::getChildren(AutoCaller &autoCaller, std::vector > &aChildren) { autoCaller.release(); /* It is possible that some previous/concurrent uninit has already cleared * the pVirtualBox reference, see #uninit(). */ ComObjPtr pVirtualBox(m->pVirtualBox); /* we access children */ AutoReadLock treeLock(!pVirtualBox.isNull() ? &pVirtualBox->i_getMediaTreeLockHandle() : NULL COMMA_LOCKVAL_SRC_POS); autoCaller.add(); if (FAILED(autoCaller.rc())) return autoCaller.rc(); MediaList children(this->i_getChildren()); aChildren.resize(children.size()); size_t i = 0; for (MediaList::const_iterator it = children.begin(); it != children.end(); ++it, ++i) (*it).queryInterfaceTo(aChildren[i].asOutParam()); return S_OK; } HRESULT Medium::getBase(AutoCaller &autoCaller, ComPtr &aBase) { autoCaller.release(); /* i_getBase() will do callers/locking */ i_getBase().queryInterfaceTo(aBase.asOutParam()); return S_OK; } HRESULT Medium::getReadOnly(BOOL *aReadOnly) { /* isReadOnly() will do locking */ *aReadOnly = i_isReadOnly(); return S_OK; } HRESULT Medium::getLogicalSize(LONG64 *aLogicalSize) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aLogicalSize = m->logicalSize; return S_OK; } HRESULT Medium::getAutoReset(BOOL *aAutoReset) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); if (m->pParent.isNull()) *aAutoReset = FALSE; else *aAutoReset = m->autoReset; return S_OK; } HRESULT Medium::setAutoReset(BOOL aAutoReset) { AutoWriteLock mlock(this COMMA_LOCKVAL_SRC_POS); if (m->pParent.isNull()) return setError(VBOX_E_NOT_SUPPORTED, tr("Medium '%s' is not differencing"), m->strLocationFull.c_str()); if (m->autoReset != !!aAutoReset) { m->autoReset = !!aAutoReset; // save the settings mlock.release(); i_markRegistriesModified(); m->pVirtualBox->i_saveModifiedRegistries(); } return S_OK; } HRESULT Medium::getLastAccessError(com::Utf8Str &aLastAccessError) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); aLastAccessError = m->strLastAccessError; return S_OK; } HRESULT Medium::getMachineIds(std::vector &aMachineIds) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); if (m->backRefs.size() != 0) { BackRefList brlist(m->backRefs); aMachineIds.resize(brlist.size()); size_t i = 0; for (BackRefList::const_iterator it = brlist.begin(); it != brlist.end(); ++it, ++i) aMachineIds[i] = it->machineId; } return S_OK; } HRESULT Medium::setIds(AutoCaller &autoCaller, BOOL aSetImageId, const com::Guid &aImageId, BOOL aSetParentId, const com::Guid &aParentId) { AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); switch (m->state) { case MediumState_Created: break; default: return i_setStateError(); } Guid imageId, parentId; if (aSetImageId) { if (aImageId.toUtf16().isEmpty()) imageId.create(); else { imageId = aImageId; if (!imageId.isValid()) return setError(E_INVALIDARG, tr("Argument %s is invalid"), "aImageId"); } } if (aSetParentId) { if (aParentId.toUtf16().isEmpty()) parentId.create(); else parentId = aParentId; } unconst(m->uuidImage) = imageId; unconst(m->uuidParentImage) = parentId; // must not hold any locks before calling Medium::i_queryInfo alock.release(); HRESULT rc = i_queryInfo(!!aSetImageId /* fSetImageId */, !!aSetParentId /* fSetParentId */, autoCaller); return rc; } HRESULT Medium::refreshState(AutoCaller &autoCaller, MediumState_T *aState) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); HRESULT rc = S_OK; switch (m->state) { case MediumState_Created: case MediumState_Inaccessible: case MediumState_LockedRead: { // must not hold any locks before calling Medium::i_queryInfo alock.release(); rc = i_queryInfo(false /* fSetImageId */, false /* fSetParentId */, autoCaller); alock.acquire(); break; } default: break; } *aState = m->state; return rc; } HRESULT Medium::getSnapshotIds(const com::Guid &aMachineId, std::vector &aSnapshotIds) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); for (BackRefList::const_iterator it = m->backRefs.begin(); it != m->backRefs.end(); ++it) { if (it->machineId == aMachineId) { size_t size = it->llSnapshotIds.size(); /* if the medium is attached to the machine in the current state, we * return its ID as the first element of the array */ if (it->fInCurState) ++size; if (size > 0) { aSnapshotIds.resize(size); size_t j = 0; if (it->fInCurState) aSnapshotIds[j++] = it->machineId.toUtf16(); for(GuidList::const_iterator jt = it->llSnapshotIds.begin(); jt != it->llSnapshotIds.end(); ++jt, ++j) aSnapshotIds[j] = (*jt); } break; } } return S_OK; } HRESULT Medium::lockRead(ComPtr &aToken) { AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); /* Wait for a concurrently running Medium::i_queryInfo to complete. */ if (m->queryInfoRunning) { /* Must not hold the media tree lock, as Medium::i_queryInfo needs this * lock and thus we would run into a deadlock here. */ Assert(!m->pVirtualBox->i_getMediaTreeLockHandle().isWriteLockOnCurrentThread()); while (m->queryInfoRunning) { alock.release(); /* must not hold the object lock now */ Assert(!isWriteLockOnCurrentThread()); { AutoReadLock qlock(m->queryInfoSem COMMA_LOCKVAL_SRC_POS); } alock.acquire(); } } HRESULT rc = S_OK; switch (m->state) { case MediumState_Created: case MediumState_Inaccessible: case MediumState_LockedRead: { ++m->readers; ComAssertMsgBreak(m->readers != 0, ("Counter overflow"), rc = E_FAIL); /* Remember pre-lock state */ if (m->state != MediumState_LockedRead) m->preLockState = m->state; LogFlowThisFunc(("Okay - prev state=%d readers=%d\n", m->state, m->readers)); m->state = MediumState_LockedRead; ComObjPtr pToken; rc = pToken.createObject(); if (SUCCEEDED(rc)) rc = pToken->init(this, false /* fWrite */); if (FAILED(rc)) { --m->readers; if (m->readers == 0) m->state = m->preLockState; return rc; } pToken.queryInterfaceTo(aToken.asOutParam()); break; } default: { LogFlowThisFunc(("Failing - state=%d\n", m->state)); rc = i_setStateError(); break; } } return rc; } /** * @note @a aState may be NULL if the state value is not needed (only for * in-process calls). */ HRESULT Medium::i_unlockRead(MediumState_T *aState) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); HRESULT rc = S_OK; switch (m->state) { case MediumState_LockedRead: { ComAssertMsgBreak(m->readers != 0, ("Counter underflow"), rc = E_FAIL); --m->readers; /* Reset the state after the last reader */ if (m->readers == 0) { m->state = m->preLockState; /* There are cases where we inject the deleting state into * a medium locked for reading. Make sure #unmarkForDeletion() * gets the right state afterwards. */ if (m->preLockState == MediumState_Deleting) m->preLockState = MediumState_Created; } LogFlowThisFunc(("new state=%d\n", m->state)); break; } default: { LogFlowThisFunc(("Failing - state=%d\n", m->state)); rc = setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is not locked for reading"), m->strLocationFull.c_str()); break; } } /* return the current state after */ if (aState) *aState = m->state; return rc; } HRESULT Medium::lockWrite(ComPtr &aToken) { AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); /* Wait for a concurrently running Medium::i_queryInfo to complete. */ if (m->queryInfoRunning) { /* Must not hold the media tree lock, as Medium::i_queryInfo needs this * lock and thus we would run into a deadlock here. */ Assert(!m->pVirtualBox->i_getMediaTreeLockHandle().isWriteLockOnCurrentThread()); while (m->queryInfoRunning) { alock.release(); /* must not hold the object lock now */ Assert(!isWriteLockOnCurrentThread()); { AutoReadLock qlock(m->queryInfoSem COMMA_LOCKVAL_SRC_POS); } alock.acquire(); } } HRESULT rc = S_OK; switch (m->state) { case MediumState_Created: case MediumState_Inaccessible: { m->preLockState = m->state; LogFlowThisFunc(("Okay - prev state=%d locationFull=%s\n", m->state, i_getLocationFull().c_str())); m->state = MediumState_LockedWrite; ComObjPtr pToken; rc = pToken.createObject(); if (SUCCEEDED(rc)) rc = pToken->init(this, true /* fWrite */); if (FAILED(rc)) { m->state = m->preLockState; return rc; } pToken.queryInterfaceTo(aToken.asOutParam()); break; } default: { LogFlowThisFunc(("Failing - state=%d locationFull=%s\n", m->state, i_getLocationFull().c_str())); rc = i_setStateError(); break; } } return rc; } /** * @note @a aState may be NULL if the state value is not needed (only for * in-process calls). */ HRESULT Medium::i_unlockWrite(MediumState_T *aState) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); HRESULT rc = S_OK; switch (m->state) { case MediumState_LockedWrite: { m->state = m->preLockState; /* There are cases where we inject the deleting state into * a medium locked for writing. Make sure #unmarkForDeletion() * gets the right state afterwards. */ if (m->preLockState == MediumState_Deleting) m->preLockState = MediumState_Created; LogFlowThisFunc(("new state=%d locationFull=%s\n", m->state, i_getLocationFull().c_str())); break; } default: { LogFlowThisFunc(("Failing - state=%d locationFull=%s\n", m->state, i_getLocationFull().c_str())); rc = setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is not locked for writing"), m->strLocationFull.c_str()); break; } } /* return the current state after */ if (aState) *aState = m->state; return rc; } HRESULT Medium::close(AutoCaller &aAutoCaller) { // make a copy of VirtualBox pointer which gets nulled by uninit() ComObjPtr pVirtualBox(m->pVirtualBox); MultiResult mrc = i_close(aAutoCaller); pVirtualBox->i_saveModifiedRegistries(); return mrc; } HRESULT Medium::getProperty(const com::Utf8Str &aName, com::Utf8Str &aValue) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); settings::StringsMap::const_iterator it = m->mapProperties.find(aName); if (it == m->mapProperties.end()) { if (!aName.startsWith("Special/")) return setError(VBOX_E_OBJECT_NOT_FOUND, tr("Property '%s' does not exist"), aName.c_str()); else /* be more silent here */ return VBOX_E_OBJECT_NOT_FOUND; } aValue = it->second; return S_OK; } HRESULT Medium::setProperty(const com::Utf8Str &aName, const com::Utf8Str &aValue) { AutoWriteLock mlock(this COMMA_LOCKVAL_SRC_POS); switch (m->state) { case MediumState_Created: case MediumState_Inaccessible: break; default: return i_setStateError(); } settings::StringsMap::iterator it = m->mapProperties.find(aName); if ( !aName.startsWith("Special/") && !i_isPropertyForFilter(aName)) { if (it == m->mapProperties.end()) return setError(VBOX_E_OBJECT_NOT_FOUND, tr("Property '%s' does not exist"), aName.c_str()); it->second = aValue; } else { if (it == m->mapProperties.end()) { if (!aValue.isEmpty()) m->mapProperties[aName] = aValue; } else { if (!aValue.isEmpty()) it->second = aValue; else m->mapProperties.erase(it); } } // save the settings mlock.release(); i_markRegistriesModified(); m->pVirtualBox->i_saveModifiedRegistries(); return S_OK; } HRESULT Medium::getProperties(const com::Utf8Str &aNames, std::vector &aReturnNames, std::vector &aReturnValues) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); /// @todo make use of aNames according to the documentation NOREF(aNames); aReturnNames.resize(m->mapProperties.size()); aReturnValues.resize(m->mapProperties.size()); size_t i = 0; for (settings::StringsMap::const_iterator it = m->mapProperties.begin(); it != m->mapProperties.end(); ++it, ++i) { aReturnNames[i] = it->first; aReturnValues[i] = it->second; } return S_OK; } HRESULT Medium::setProperties(const std::vector &aNames, const std::vector &aValues) { AutoWriteLock mlock(this COMMA_LOCKVAL_SRC_POS); /* first pass: validate names */ for (size_t i = 0; i < aNames.size(); ++i) { Utf8Str strName(aNames[i]); if ( !strName.startsWith("Special/") && !i_isPropertyForFilter(strName) && m->mapProperties.find(strName) == m->mapProperties.end()) return setError(VBOX_E_OBJECT_NOT_FOUND, tr("Property '%s' does not exist"), strName.c_str()); } /* second pass: assign */ for (size_t i = 0; i < aNames.size(); ++i) { Utf8Str strName(aNames[i]); Utf8Str strValue(aValues[i]); settings::StringsMap::iterator it = m->mapProperties.find(strName); if ( !strName.startsWith("Special/") && !i_isPropertyForFilter(strName)) { AssertReturn(it != m->mapProperties.end(), E_FAIL); it->second = strValue; } else { if (it == m->mapProperties.end()) { if (!strValue.isEmpty()) m->mapProperties[strName] = strValue; } else { if (!strValue.isEmpty()) it->second = strValue; else m->mapProperties.erase(it); } } } // save the settings mlock.release(); i_markRegistriesModified(); m->pVirtualBox->i_saveModifiedRegistries(); return S_OK; } HRESULT Medium::createBaseStorage(LONG64 aLogicalSize, const std::vector &aVariant, ComPtr &aProgress) { if (aLogicalSize < 0) return setError(E_INVALIDARG, tr("The medium size argument (%lld) is negative"), aLogicalSize); HRESULT rc = S_OK; ComObjPtr pProgress; Medium::Task *pTask = NULL; try { AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); ULONG mediumVariantFlags = 0; if (aVariant.size()) { for (size_t i = 0; i < aVariant.size(); i++) mediumVariantFlags |= (ULONG)aVariant[i]; } mediumVariantFlags &= ((unsigned)~MediumVariant_Diff); if ( !(mediumVariantFlags & MediumVariant_Fixed) && !(m->formatObj->i_getCapabilities() & MediumFormatCapabilities_CreateDynamic)) throw setError(VBOX_E_NOT_SUPPORTED, tr("Medium format '%s' does not support dynamic storage creation"), m->strFormat.c_str()); if ( (mediumVariantFlags & MediumVariant_Fixed) && !(m->formatObj->i_getCapabilities() & MediumFormatCapabilities_CreateDynamic)) throw setError(VBOX_E_NOT_SUPPORTED, tr("Medium format '%s' does not support fixed storage creation"), m->strFormat.c_str()); if (m->state != MediumState_NotCreated) throw i_setStateError(); pProgress.createObject(); rc = pProgress->init(m->pVirtualBox, static_cast(this), (mediumVariantFlags & MediumVariant_Fixed) ? BstrFmt(tr("Creating fixed medium storage unit '%s'"), m->strLocationFull.c_str()).raw() : BstrFmt(tr("Creating dynamic medium storage unit '%s'"), m->strLocationFull.c_str()).raw(), TRUE /* aCancelable */); if (FAILED(rc)) throw rc; /* setup task object to carry out the operation asynchronously */ pTask = new Medium::CreateBaseTask(this, pProgress, aLogicalSize, (MediumVariant_T)mediumVariantFlags); //(MediumVariant_T)aVariant); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; m->state = MediumState_Creating; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { rc = i_startThread(pTask); if (SUCCEEDED(rc)) pProgress.queryInterfaceTo(aProgress.asOutParam()); } else if (pTask != NULL) delete pTask; return rc; } HRESULT Medium::deleteStorage(ComPtr &aProgress) { ComObjPtr pProgress; MultiResult mrc = i_deleteStorage(&pProgress, false /* aWait */); /* Must save the registries in any case, since an entry was removed. */ m->pVirtualBox->i_saveModifiedRegistries(); if (SUCCEEDED(mrc)) pProgress.queryInterfaceTo(aProgress.asOutParam()); return mrc; } HRESULT Medium::createDiffStorage(const ComPtr &aTarget, const std::vector &aVariant, ComPtr &aProgress) { IMedium *aT = aTarget; ComObjPtr diff = static_cast(aT); // locking: we need the tree lock first because we access parent pointers AutoMultiWriteLock3 alock(&m->pVirtualBox->i_getMediaTreeLockHandle(), this->lockHandle(), diff->lockHandle() COMMA_LOCKVAL_SRC_POS); if (m->type == MediumType_Writethrough) return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium type of '%s' is Writethrough"), m->strLocationFull.c_str()); else if (m->type == MediumType_Shareable) return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium type of '%s' is Shareable"), m->strLocationFull.c_str()); else if (m->type == MediumType_Readonly) return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium type of '%s' is Readonly"), m->strLocationFull.c_str()); /* Apply the normal locking logic to the entire chain. */ MediumLockList *pMediumLockList(new MediumLockList()); alock.release(); HRESULT rc = diff->i_createMediumLockList(true /* fFailIfInaccessible */, true /* fMediumLockWrite */, this, *pMediumLockList); alock.acquire(); if (FAILED(rc)) { delete pMediumLockList; return rc; } alock.release(); rc = pMediumLockList->Lock(); alock.acquire(); if (FAILED(rc)) { delete pMediumLockList; return setError(rc, tr("Could not lock medium when creating diff '%s'"), diff->i_getLocationFull().c_str()); } Guid parentMachineRegistry; if (i_getFirstRegistryMachineId(parentMachineRegistry)) { /* since this medium has been just created it isn't associated yet */ diff->m->llRegistryIDs.push_back(parentMachineRegistry); alock.release(); diff->i_markRegistriesModified(); alock.acquire(); } alock.release(); ComObjPtr pProgress; ULONG mediumVariantFlags = 0; if (aVariant.size()) { for (size_t i = 0; i < aVariant.size(); i++) mediumVariantFlags |= (ULONG)aVariant[i]; } rc = i_createDiffStorage(diff, (MediumVariant_T)mediumVariantFlags, pMediumLockList, &pProgress, false /* aWait */); if (FAILED(rc)) delete pMediumLockList; else pProgress.queryInterfaceTo(aProgress.asOutParam()); return rc; } HRESULT Medium::mergeTo(const ComPtr &aTarget, ComPtr &aProgress) { IMedium *aT = aTarget; ComAssertRet(aT != this, E_INVALIDARG); ComObjPtr pTarget = static_cast(aT); bool fMergeForward = false; ComObjPtr pParentForTarget; MediumLockList *pChildrenToReparent = NULL; MediumLockList *pMediumLockList = NULL; HRESULT rc = S_OK; rc = i_prepareMergeTo(pTarget, NULL, NULL, true, fMergeForward, pParentForTarget, pChildrenToReparent, pMediumLockList); if (FAILED(rc)) return rc; ComObjPtr pProgress; rc = i_mergeTo(pTarget, fMergeForward, pParentForTarget, pChildrenToReparent, pMediumLockList, &pProgress, false /* aWait */); if (FAILED(rc)) i_cancelMergeTo(pChildrenToReparent, pMediumLockList); else pProgress.queryInterfaceTo(aProgress.asOutParam()); return rc; } HRESULT Medium::cloneToBase(const ComPtr &aTarget, const std::vector &aVariant, ComPtr &aProgress) { int rc = S_OK; rc = cloneTo(aTarget, aVariant, NULL, aProgress); return rc; } HRESULT Medium::cloneTo(const ComPtr &aTarget, const std::vector &aVariant, const ComPtr &aParent, ComPtr &aProgress) { ComAssertRet(aTarget != this, E_INVALIDARG); IMedium *aT = aTarget; ComObjPtr pTarget = static_cast(aT); ComObjPtr pParent; if (aParent) { IMedium *aP = aParent; pParent = static_cast(aP); } HRESULT rc = S_OK; ComObjPtr pProgress; Medium::Task *pTask = NULL; try { // locking: we need the tree lock first because we access parent pointers // and we need to write-lock the media involved uint32_t cHandles = 3; LockHandle* pHandles[4] = { &m->pVirtualBox->i_getMediaTreeLockHandle(), this->lockHandle(), pTarget->lockHandle() }; /* Only add parent to the lock if it is not null */ if (!pParent.isNull()) pHandles[cHandles++] = pParent->lockHandle(); AutoWriteLock alock(cHandles, pHandles COMMA_LOCKVAL_SRC_POS); if ( pTarget->m->state != MediumState_NotCreated && pTarget->m->state != MediumState_Created) throw pTarget->i_setStateError(); /* Build the source lock list. */ MediumLockList *pSourceMediumLockList(new MediumLockList()); alock.release(); rc = i_createMediumLockList(true /* fFailIfInaccessible */, false /* fMediumLockWrite */, NULL, *pSourceMediumLockList); alock.acquire(); if (FAILED(rc)) { delete pSourceMediumLockList; throw rc; } /* Build the target lock list (including the to-be parent chain). */ MediumLockList *pTargetMediumLockList(new MediumLockList()); alock.release(); rc = pTarget->i_createMediumLockList(true /* fFailIfInaccessible */, true /* fMediumLockWrite */, pParent, *pTargetMediumLockList); alock.acquire(); if (FAILED(rc)) { delete pSourceMediumLockList; delete pTargetMediumLockList; throw rc; } alock.release(); rc = pSourceMediumLockList->Lock(); alock.acquire(); if (FAILED(rc)) { delete pSourceMediumLockList; delete pTargetMediumLockList; throw setError(rc, tr("Failed to lock source media '%s'"), i_getLocationFull().c_str()); } alock.release(); rc = pTargetMediumLockList->Lock(); alock.acquire(); if (FAILED(rc)) { delete pSourceMediumLockList; delete pTargetMediumLockList; throw setError(rc, tr("Failed to lock target media '%s'"), pTarget->i_getLocationFull().c_str()); } pProgress.createObject(); rc = pProgress->init(m->pVirtualBox, static_cast (this), BstrFmt(tr("Creating clone medium '%s'"), pTarget->m->strLocationFull.c_str()).raw(), TRUE /* aCancelable */); if (FAILED(rc)) { delete pSourceMediumLockList; delete pTargetMediumLockList; throw rc; } ULONG mediumVariantFlags = 0; if (aVariant.size()) { for (size_t i = 0; i < aVariant.size(); i++) mediumVariantFlags |= (ULONG)aVariant[i]; } /* setup task object to carry out the operation asynchronously */ pTask = new Medium::CloneTask(this, pProgress, pTarget, (MediumVariant_T)mediumVariantFlags, pParent, UINT32_MAX, UINT32_MAX, pSourceMediumLockList, pTargetMediumLockList); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; if (pTarget->m->state == MediumState_NotCreated) pTarget->m->state = MediumState_Creating; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { rc = i_startThread(pTask); if (SUCCEEDED(rc)) pProgress.queryInterfaceTo(aProgress.asOutParam()); } else if (pTask != NULL) delete pTask; return rc; } HRESULT Medium::setLocation(const com::Utf8Str &aLocation, ComPtr &aProgress) { AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); NOREF(aLocation); NOREF(aProgress); /// @todo NEWMEDIA for file names, add the default extension if no extension /// is present (using the information from the VD backend which also implies /// that one more parameter should be passed to setLocation() requesting /// that functionality since it is only allowed when called from this method /// @todo NEWMEDIA rename the file and set m->location on success, then save /// the global registry (and local registries of portable VMs referring to /// this medium), this will also require to add the mRegistered flag to data ReturnComNotImplemented(); } HRESULT Medium::compact(ComPtr &aProgress) { HRESULT rc = S_OK; ComObjPtr pProgress; Medium::Task *pTask = NULL; try { AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); /* Build the medium lock list. */ MediumLockList *pMediumLockList(new MediumLockList()); alock.release(); rc = i_createMediumLockList(true /* fFailIfInaccessible */ , true /* fMediumLockWrite */, NULL, *pMediumLockList); alock.acquire(); if (FAILED(rc)) { delete pMediumLockList; throw rc; } alock.release(); rc = pMediumLockList->Lock(); alock.acquire(); if (FAILED(rc)) { delete pMediumLockList; throw setError(rc, tr("Failed to lock media when compacting '%s'"), i_getLocationFull().c_str()); } pProgress.createObject(); rc = pProgress->init(m->pVirtualBox, static_cast (this), BstrFmt(tr("Compacting medium '%s'"), m->strLocationFull.c_str()).raw(), TRUE /* aCancelable */); if (FAILED(rc)) { delete pMediumLockList; throw rc; } /* setup task object to carry out the operation asynchronously */ pTask = new Medium::CompactTask(this, pProgress, pMediumLockList); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { rc = i_startThread(pTask); if (SUCCEEDED(rc)) pProgress.queryInterfaceTo(aProgress.asOutParam()); } else if (pTask != NULL) delete pTask; return rc; } HRESULT Medium::resize(LONG64 aLogicalSize, ComPtr &aProgress) { HRESULT rc = S_OK; ComObjPtr pProgress; Medium::Task *pTask = NULL; try { AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); /* Build the medium lock list. */ MediumLockList *pMediumLockList(new MediumLockList()); alock.release(); rc = i_createMediumLockList(true /* fFailIfInaccessible */ , true /* fMediumLockWrite */, NULL, *pMediumLockList); alock.acquire(); if (FAILED(rc)) { delete pMediumLockList; throw rc; } alock.release(); rc = pMediumLockList->Lock(); alock.acquire(); if (FAILED(rc)) { delete pMediumLockList; throw setError(rc, tr("Failed to lock media when compacting '%s'"), i_getLocationFull().c_str()); } pProgress.createObject(); rc = pProgress->init(m->pVirtualBox, static_cast (this), BstrFmt(tr("Compacting medium '%s'"), m->strLocationFull.c_str()).raw(), TRUE /* aCancelable */); if (FAILED(rc)) { delete pMediumLockList; throw rc; } /* setup task object to carry out the operation asynchronously */ pTask = new Medium::ResizeTask(this, aLogicalSize, pProgress, pMediumLockList); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { rc = i_startThread(pTask); if (SUCCEEDED(rc)) pProgress.queryInterfaceTo(aProgress.asOutParam()); } else if (pTask != NULL) delete pTask; return rc; } HRESULT Medium::reset(ComPtr &aProgress) { HRESULT rc = S_OK; ComObjPtr pProgress; Medium::Task *pTask = NULL; try { /* canClose() needs the tree lock */ AutoMultiWriteLock2 multilock(&m->pVirtualBox->i_getMediaTreeLockHandle(), this->lockHandle() COMMA_LOCKVAL_SRC_POS); LogFlowThisFunc(("ENTER for medium %s\n", m->strLocationFull.c_str())); if (m->pParent.isNull()) throw setError(VBOX_E_NOT_SUPPORTED, tr("Medium type of '%s' is not differencing"), m->strLocationFull.c_str()); rc = i_canClose(); if (FAILED(rc)) throw rc; /* Build the medium lock list. */ MediumLockList *pMediumLockList(new MediumLockList()); multilock.release(); rc = i_createMediumLockList(true /* fFailIfInaccessible */, true /* fMediumLockWrite */, NULL, *pMediumLockList); multilock.acquire(); if (FAILED(rc)) { delete pMediumLockList; throw rc; } multilock.release(); rc = pMediumLockList->Lock(); multilock.acquire(); if (FAILED(rc)) { delete pMediumLockList; throw setError(rc, tr("Failed to lock media when resetting '%s'"), i_getLocationFull().c_str()); } pProgress.createObject(); rc = pProgress->init(m->pVirtualBox, static_cast(this), BstrFmt(tr("Resetting differencing medium '%s'"), m->strLocationFull.c_str()).raw(), FALSE /* aCancelable */); if (FAILED(rc)) throw rc; /* setup task object to carry out the operation asynchronously */ pTask = new Medium::ResetTask(this, pProgress, pMediumLockList); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { rc = i_startThread(pTask); if (SUCCEEDED(rc)) pProgress.queryInterfaceTo(aProgress.asOutParam()); } else if (pTask != NULL) delete pTask; LogFlowThisFunc(("LEAVE, rc=%Rhrc\n", rc)); return rc; } //////////////////////////////////////////////////////////////////////////////// // // Medium public internal methods // //////////////////////////////////////////////////////////////////////////////// /** * Internal method to return the medium's parent medium. Must have caller + locking! * @return */ const ComObjPtr& Medium::i_getParent() const { return m->pParent; } /** * Internal method to return the medium's list of child media. Must have caller + locking! * @return */ const MediaList& Medium::i_getChildren() const { return m->llChildren; } /** * Internal method to return the medium's GUID. Must have caller + locking! * @return */ const Guid& Medium::i_getId() const { return m->id; } /** * Internal method to return the medium's state. Must have caller + locking! * @return */ MediumState_T Medium::i_getState() const { return m->state; } /** * Internal method to return the medium's variant. Must have caller + locking! * @return */ MediumVariant_T Medium::i_getVariant() const { return m->variant; } /** * Internal method which returns true if this medium represents a host drive. * @return */ bool Medium::i_isHostDrive() const { return m->hostDrive; } /** * Internal method to return the medium's full location. Must have caller + locking! * @return */ const Utf8Str& Medium::i_getLocationFull() const { return m->strLocationFull; } /** * Internal method to return the medium's format string. Must have caller + locking! * @return */ const Utf8Str& Medium::i_getFormat() const { return m->strFormat; } /** * Internal method to return the medium's format object. Must have caller + locking! * @return */ const ComObjPtr& Medium::i_getMediumFormat() const { return m->formatObj; } /** * Internal method that returns true if the medium is represented by a file on the host disk * (and not iSCSI or something). * @return */ bool Medium::i_isMediumFormatFile() const { if ( m->formatObj && (m->formatObj->i_getCapabilities() & MediumFormatCapabilities_File) ) return true; return false; } /** * Internal method to return the medium's size. Must have caller + locking! * @return */ uint64_t Medium::i_getSize() const { return m->size; } /** * Returns the medium device type. Must have caller + locking! * @return */ DeviceType_T Medium::i_getDeviceType() const { return m->devType; } /** * Returns the medium type. Must have caller + locking! * @return */ MediumType_T Medium::i_getType() const { return m->type; } /** * Returns a short version of the location attribute. * * @note Must be called from under this object's read or write lock. */ Utf8Str Medium::i_getName() { Utf8Str name = RTPathFilename(m->strLocationFull.c_str()); return name; } /** * This adds the given UUID to the list of media registries in which this * medium should be registered. The UUID can either be a machine UUID, * to add a machine registry, or the global registry UUID as returned by * VirtualBox::getGlobalRegistryId(). * * Note that for hard disks, this method does nothing if the medium is * already in another registry to avoid having hard disks in more than * one registry, which causes trouble with keeping diff images in sync. * See getFirstRegistryMachineId() for details. * * If fRecurse == true, then the media tree lock must be held for reading. * * @param id * @param fRecurse If true, recurses into child media to make sure the whole tree has registries in sync. * @return true if the registry was added; false if the given id was already on the list. */ bool Medium::i_addRegistry(const Guid& id, bool fRecurse) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return false; AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); bool fAdd = true; // hard disks cannot be in more than one registry if ( m->devType == DeviceType_HardDisk && m->llRegistryIDs.size() > 0) fAdd = false; // no need to add the UUID twice if (fAdd) { for (GuidList::const_iterator it = m->llRegistryIDs.begin(); it != m->llRegistryIDs.end(); ++it) { if ((*it) == id) { fAdd = false; break; } } } if (fAdd) m->llRegistryIDs.push_back(id); if (fRecurse) { // Get private list of children and release medium lock straight away. MediaList llChildren(m->llChildren); alock.release(); for (MediaList::iterator it = llChildren.begin(); it != llChildren.end(); ++it) { Medium *pChild = *it; fAdd |= pChild->i_addRegistry(id, true); } } return fAdd; } /** * Removes the given UUID from the list of media registry UUIDs. Returns true * if found or false if not. * * If fRecurse == true, then the media tree lock must be held for reading. * * @param id * @param fRecurse If true, recurses into child media to make sure the whole tree has registries in sync. * @return */ bool Medium::i_removeRegistry(const Guid& id, bool fRecurse) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return false; AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); bool fRemove = false; for (GuidList::iterator it = m->llRegistryIDs.begin(); it != m->llRegistryIDs.end(); ++it) { if ((*it) == id) { m->llRegistryIDs.erase(it); fRemove = true; break; } } if (fRecurse) { // Get private list of children and release medium lock straight away. MediaList llChildren(m->llChildren); alock.release(); for (MediaList::iterator it = llChildren.begin(); it != llChildren.end(); ++it) { Medium *pChild = *it; fRemove |= pChild->i_removeRegistry(id, true); } } return fRemove; } /** * Returns true if id is in the list of media registries for this medium. * * Must have caller + read locking! * * @param id * @return */ bool Medium::i_isInRegistry(const Guid& id) { for (GuidList::const_iterator it = m->llRegistryIDs.begin(); it != m->llRegistryIDs.end(); ++it) { if (*it == id) return true; } return false; } /** * Internal method to return the medium's first registry machine (i.e. the machine in whose * machine XML this medium is listed). * * Every attached medium must now (4.0) reside in at least one media registry, which is identified * by a UUID. This is either a machine UUID if the machine is from 4.0 or newer, in which case * machines have their own media registries, or it is the pseudo-UUID of the VirtualBox * object if the machine is old and still needs the global registry in VirtualBox.xml. * * By definition, hard disks may only be in one media registry, in which all its children * will be stored as well. Otherwise we run into problems with having keep multiple registries * in sync. (This is the "cloned VM" case in which VM1 may link to the disks of VM2; in this * case, only VM2's registry is used for the disk in question.) * * If there is no medium registry, particularly if the medium has not been attached yet, this * does not modify uuid and returns false. * * ISOs and RAWs, by contrast, can be in more than one repository to make things easier for * the user. * * Must have caller + locking! * * @param uuid Receives first registry machine UUID, if available. * @return true if uuid was set. */ bool Medium::i_getFirstRegistryMachineId(Guid &uuid) const { if (m->llRegistryIDs.size()) { uuid = m->llRegistryIDs.front(); return true; } return false; } /** * Marks all the registries in which this medium is registered as modified. */ void Medium::i_markRegistriesModified() { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return; // Get local copy, as keeping the lock over VirtualBox::markRegistryModified // causes trouble with the lock order GuidList llRegistryIDs; { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); llRegistryIDs = m->llRegistryIDs; } autoCaller.release(); /* Save the error information now, the implicit restore when this goes * out of scope will throw away spurious additional errors created below. */ ErrorInfoKeeper eik; for (GuidList::const_iterator it = llRegistryIDs.begin(); it != llRegistryIDs.end(); ++it) { m->pVirtualBox->i_markRegistryModified(*it); } } /** * Adds the given machine and optionally the snapshot to the list of the objects * this medium is attached to. * * @param aMachineId Machine ID. * @param aSnapshotId Snapshot ID; when non-empty, adds a snapshot attachment. */ HRESULT Medium::i_addBackReference(const Guid &aMachineId, const Guid &aSnapshotId /*= Guid::Empty*/) { AssertReturn(aMachineId.isValid(), E_FAIL); LogFlowThisFunc(("ENTER, aMachineId: {%RTuuid}, aSnapshotId: {%RTuuid}\n", aMachineId.raw(), aSnapshotId.raw())); AutoCaller autoCaller(this); AssertComRCReturnRC(autoCaller.rc()); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); switch (m->state) { case MediumState_Created: case MediumState_Inaccessible: case MediumState_LockedRead: case MediumState_LockedWrite: break; default: return i_setStateError(); } if (m->numCreateDiffTasks > 0) return setError(VBOX_E_OBJECT_IN_USE, tr("Cannot attach medium '%s' {%RTuuid}: %u differencing child media are being created"), m->strLocationFull.c_str(), m->id.raw(), m->numCreateDiffTasks); BackRefList::iterator it = std::find_if(m->backRefs.begin(), m->backRefs.end(), BackRef::EqualsTo(aMachineId)); if (it == m->backRefs.end()) { BackRef ref(aMachineId, aSnapshotId); m->backRefs.push_back(ref); return S_OK; } // if the caller has not supplied a snapshot ID, then we're attaching // to a machine a medium which represents the machine's current state, // so set the flag if (aSnapshotId.isZero()) { /* sanity: no duplicate attachments */ if (it->fInCurState) return setError(VBOX_E_OBJECT_IN_USE, tr("Cannot attach medium '%s' {%RTuuid}: medium is already associated with the current state of machine uuid {%RTuuid}!"), m->strLocationFull.c_str(), m->id.raw(), aMachineId.raw()); it->fInCurState = true; return S_OK; } // otherwise: a snapshot medium is being attached /* sanity: no duplicate attachments */ for (GuidList::const_iterator jt = it->llSnapshotIds.begin(); jt != it->llSnapshotIds.end(); ++jt) { const Guid &idOldSnapshot = *jt; if (idOldSnapshot == aSnapshotId) { #ifdef DEBUG i_dumpBackRefs(); #endif return setError(VBOX_E_OBJECT_IN_USE, tr("Cannot attach medium '%s' {%RTuuid} from snapshot '%RTuuid': medium is already in use by this snapshot!"), m->strLocationFull.c_str(), m->id.raw(), aSnapshotId.raw()); } } it->llSnapshotIds.push_back(aSnapshotId); // Do not touch fInCurState, as the image may be attached to the current // state *and* a snapshot, otherwise we lose the current state association! LogFlowThisFuncLeave(); return S_OK; } /** * Removes the given machine and optionally the snapshot from the list of the * objects this medium is attached to. * * @param aMachineId Machine ID. * @param aSnapshotId Snapshot ID; when non-empty, removes the snapshot * attachment. */ HRESULT Medium::i_removeBackReference(const Guid &aMachineId, const Guid &aSnapshotId /*= Guid::Empty*/) { AssertReturn(aMachineId.isValid(), E_FAIL); AutoCaller autoCaller(this); AssertComRCReturnRC(autoCaller.rc()); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); BackRefList::iterator it = std::find_if(m->backRefs.begin(), m->backRefs.end(), BackRef::EqualsTo(aMachineId)); AssertReturn(it != m->backRefs.end(), E_FAIL); if (aSnapshotId.isZero()) { /* remove the current state attachment */ it->fInCurState = false; } else { /* remove the snapshot attachment */ GuidList::iterator jt = std::find(it->llSnapshotIds.begin(), it->llSnapshotIds.end(), aSnapshotId); AssertReturn(jt != it->llSnapshotIds.end(), E_FAIL); it->llSnapshotIds.erase(jt); } /* if the backref becomes empty, remove it */ if (it->fInCurState == false && it->llSnapshotIds.size() == 0) m->backRefs.erase(it); return S_OK; } /** * Internal method to return the medium's list of backrefs. Must have caller + locking! * @return */ const Guid* Medium::i_getFirstMachineBackrefId() const { if (!m->backRefs.size()) return NULL; return &m->backRefs.front().machineId; } /** * Internal method which returns a machine that either this medium or one of its children * is attached to. This is used for finding a replacement media registry when an existing * media registry is about to be deleted in VirtualBox::unregisterMachine(). * * Must have caller + locking, *and* caller must hold the media tree lock! * @return */ const Guid* Medium::i_getAnyMachineBackref() const { if (m->backRefs.size()) return &m->backRefs.front().machineId; for (MediaList::iterator it = m->llChildren.begin(); it != m->llChildren.end(); ++it) { Medium *pChild = *it; // recurse for this child const Guid* puuid; if ((puuid = pChild->i_getAnyMachineBackref())) return puuid; } return NULL; } const Guid* Medium::i_getFirstMachineBackrefSnapshotId() const { if (!m->backRefs.size()) return NULL; const BackRef &ref = m->backRefs.front(); if (!ref.llSnapshotIds.size()) return NULL; return &ref.llSnapshotIds.front(); } size_t Medium::i_getMachineBackRefCount() const { return m->backRefs.size(); } #ifdef DEBUG /** * Debugging helper that gets called after VirtualBox initialization that writes all * machine backreferences to the debug log. */ void Medium::i_dumpBackRefs() { AutoCaller autoCaller(this); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); LogFlowThisFunc(("Dumping backrefs for medium '%s':\n", m->strLocationFull.c_str())); for (BackRefList::iterator it2 = m->backRefs.begin(); it2 != m->backRefs.end(); ++it2) { const BackRef &ref = *it2; LogFlowThisFunc((" Backref from machine {%RTuuid} (fInCurState: %d)\n", ref.machineId.raw(), ref.fInCurState)); for (GuidList::const_iterator jt2 = it2->llSnapshotIds.begin(); jt2 != it2->llSnapshotIds.end(); ++jt2) { const Guid &id = *jt2; LogFlowThisFunc((" Backref from snapshot {%RTuuid}\n", id.raw())); } } } #endif /** * Checks if the given change of \a aOldPath to \a aNewPath affects the location * of this media and updates it if necessary to reflect the new location. * * @param aOldPath Old path (full). * @param aNewPath New path (full). * * @note Locks this object for writing. */ HRESULT Medium::i_updatePath(const Utf8Str &strOldPath, const Utf8Str &strNewPath) { AssertReturn(!strOldPath.isEmpty(), E_FAIL); AssertReturn(!strNewPath.isEmpty(), E_FAIL); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); LogFlowThisFunc(("locationFull.before='%s'\n", m->strLocationFull.c_str())); const char *pcszMediumPath = m->strLocationFull.c_str(); if (RTPathStartsWith(pcszMediumPath, strOldPath.c_str())) { Utf8Str newPath(strNewPath); newPath.append(pcszMediumPath + strOldPath.length()); unconst(m->strLocationFull) = newPath; LogFlowThisFunc(("locationFull.after='%s'\n", m->strLocationFull.c_str())); // we changed something return S_OK; } // no change was necessary, signal error which the caller needs to interpret return VBOX_E_FILE_ERROR; } /** * Returns the base medium of the media chain this medium is part of. * * The base medium is found by walking up the parent-child relationship axis. * If the medium doesn't have a parent (i.e. it's a base medium), it * returns itself in response to this method. * * @param aLevel Where to store the number of ancestors of this medium * (zero for the base), may be @c NULL. * * @note Locks medium tree for reading. */ ComObjPtr Medium::i_getBase(uint32_t *aLevel /*= NULL*/) { ComObjPtr pBase; /* it is possible that some previous/concurrent uninit has already cleared * the pVirtualBox reference, and in this case we don't need to continue */ ComObjPtr pVirtualBox(m->pVirtualBox); if (!pVirtualBox) return pBase; /* we access mParent */ AutoReadLock treeLock(pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); AutoCaller autoCaller(this); AssertReturn(autoCaller.isOk(), pBase); pBase = this; uint32_t level = 0; if (m->pParent) { for (;;) { AutoCaller baseCaller(pBase); AssertReturn(baseCaller.isOk(), pBase); if (pBase->m->pParent.isNull()) break; pBase = pBase->m->pParent; ++level; } } if (aLevel != NULL) *aLevel = level; return pBase; } /** * Returns @c true if this medium cannot be modified because it has * dependents (children) or is part of the snapshot. Related to the medium * type and posterity, not to the current media state. * * @note Locks this object and medium tree for reading. */ bool Medium::i_isReadOnly() { AutoCaller autoCaller(this); AssertComRCReturn(autoCaller.rc(), false); /* we access children */ AutoReadLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); switch (m->type) { case MediumType_Normal: { if (i_getChildren().size() != 0) return true; for (BackRefList::const_iterator it = m->backRefs.begin(); it != m->backRefs.end(); ++it) if (it->llSnapshotIds.size() != 0) return true; if (m->variant & MediumVariant_VmdkStreamOptimized) return true; return false; } case MediumType_Immutable: case MediumType_MultiAttach: return true; case MediumType_Writethrough: case MediumType_Shareable: case MediumType_Readonly: /* explicit readonly media has no diffs */ return false; default: break; } AssertFailedReturn(false); } /** * Internal method to return the medium's size. Must have caller + locking! * @return */ void Medium::i_updateId(const Guid &id) { unconst(m->id) = id; } /** * Saves medium data by appending a new child node to the given * parent XML settings node. * * @param data Settings struct to be updated. * @param strHardDiskFolder Folder for which paths should be relative. * * @note Locks this object, medium tree and children for reading. */ HRESULT Medium::i_saveSettings(settings::Medium &data, const Utf8Str &strHardDiskFolder) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); /* we access mParent */ AutoReadLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); data.uuid = m->id; // make path relative if needed if ( !strHardDiskFolder.isEmpty() && RTPathStartsWith(m->strLocationFull.c_str(), strHardDiskFolder.c_str()) ) data.strLocation = m->strLocationFull.substr(strHardDiskFolder.length() + 1); else data.strLocation = m->strLocationFull; data.strFormat = m->strFormat; /* optional, only for diffs, default is false */ if (m->pParent) data.fAutoReset = m->autoReset; else data.fAutoReset = false; /* optional */ data.strDescription = m->strDescription; /* optional properties */ data.properties.clear(); /* handle iSCSI initiator secrets transparently */ bool fHaveInitiatorSecretEncrypted = false; Utf8Str strCiphertext; settings::StringsMap::const_iterator itPln = m->mapProperties.find("InitiatorSecret"); if ( itPln != m->mapProperties.end() && !itPln->second.isEmpty()) { /* Encrypt the plain secret. If that does not work (i.e. no or wrong settings key * specified), just use the encrypted secret (if there is any). */ int rc = m->pVirtualBox->i_encryptSetting(itPln->second, &strCiphertext); if (RT_SUCCESS(rc)) fHaveInitiatorSecretEncrypted = true; } for (settings::StringsMap::const_iterator it = m->mapProperties.begin(); it != m->mapProperties.end(); ++it) { /* only save properties that have non-default values */ if (!it->second.isEmpty()) { const Utf8Str &name = it->first; const Utf8Str &value = it->second; /* do NOT store the plain InitiatorSecret */ if ( !fHaveInitiatorSecretEncrypted || !name.equals("InitiatorSecret")) data.properties[name] = value; } } if (fHaveInitiatorSecretEncrypted) data.properties["InitiatorSecretEncrypted"] = strCiphertext; /* only for base media */ if (m->pParent.isNull()) data.hdType = m->type; /* save all children */ for (MediaList::const_iterator it = i_getChildren().begin(); it != i_getChildren().end(); ++it) { settings::Medium med; HRESULT rc = (*it)->i_saveSettings(med, strHardDiskFolder); AssertComRCReturnRC(rc); data.llChildren.push_back(med); } return S_OK; } /** * Constructs a medium lock list for this medium. The lock is not taken. * * @note Caller MUST NOT hold the media tree or medium lock. * * @param fFailIfInaccessible If true, this fails with an error if a medium is inaccessible. If false, * inaccessible media are silently skipped and not locked (i.e. their state remains "Inaccessible"); * this is necessary for a VM's removable media VM startup for which we do not want to fail. * @param fMediumLockWrite Whether to associate a write lock with this medium. * @param pToBeParent Medium which will become the parent of this medium. * @param mediumLockList Where to store the resulting list. */ HRESULT Medium::i_createMediumLockList(bool fFailIfInaccessible, bool fMediumLockWrite, Medium *pToBeParent, MediumLockList &mediumLockList) { Assert(!m->pVirtualBox->i_getMediaTreeLockHandle().isWriteLockOnCurrentThread()); Assert(!isWriteLockOnCurrentThread()); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); HRESULT rc = S_OK; /* paranoid sanity checking if the medium has a to-be parent medium */ if (pToBeParent) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); ComAssertRet(i_getParent().isNull(), E_FAIL); ComAssertRet(i_getChildren().size() == 0, E_FAIL); } ErrorInfoKeeper eik; MultiResult mrc(S_OK); ComObjPtr pMedium = this; while (!pMedium.isNull()) { AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); /* Accessibility check must be first, otherwise locking interferes * with getting the medium state. Lock lists are not created for * fun, and thus getting the medium status is no luxury. */ MediumState_T mediumState = pMedium->i_getState(); if (mediumState == MediumState_Inaccessible) { alock.release(); rc = pMedium->i_queryInfo(false /* fSetImageId */, false /* fSetParentId */, autoCaller); alock.acquire(); if (FAILED(rc)) return rc; mediumState = pMedium->i_getState(); if (mediumState == MediumState_Inaccessible) { // ignore inaccessible ISO media and silently return S_OK, // otherwise VM startup (esp. restore) may fail without good reason if (!fFailIfInaccessible) return S_OK; // otherwise report an error Bstr error; rc = pMedium->COMGETTER(LastAccessError)(error.asOutParam()); if (FAILED(rc)) return rc; /* collect multiple errors */ eik.restore(); Assert(!error.isEmpty()); mrc = setError(E_FAIL, "%ls", error.raw()); // error message will be something like // "Could not open the medium ... VD: error VERR_FILE_NOT_FOUND opening image file ... (VERR_FILE_NOT_FOUND). eik.fetch(); } } if (pMedium == this) mediumLockList.Prepend(pMedium, fMediumLockWrite); else mediumLockList.Prepend(pMedium, false); pMedium = pMedium->i_getParent(); if (pMedium.isNull() && pToBeParent) { pMedium = pToBeParent; pToBeParent = NULL; } } return mrc; } /** * Creates a new differencing storage unit using the format of the given target * medium and the location. Note that @c aTarget must be NotCreated. * * The @a aMediumLockList parameter contains the associated medium lock list, * which must be in locked state. If @a aWait is @c true then the caller is * responsible for unlocking. * * If @a aProgress is not NULL but the object it points to is @c null then a * new progress object will be created and assigned to @a *aProgress on * success, otherwise the existing progress object is used. If @a aProgress is * NULL, then no progress object is created/used at all. * * When @a aWait is @c false, this method will create a thread to perform the * create operation asynchronously and will return immediately. Otherwise, it * will perform the operation on the calling thread and will not return to the * caller until the operation is completed. Note that @a aProgress cannot be * NULL when @a aWait is @c false (this method will assert in this case). * * @param aTarget Target medium. * @param aVariant Precise medium variant to create. * @param aMediumLockList List of media which should be locked. * @param aProgress Where to find/store a Progress object to track * operation completion. * @param aWait @c true if this method should block instead of * creating an asynchronous thread. * * @note Locks this object and @a aTarget for writing. */ HRESULT Medium::i_createDiffStorage(ComObjPtr &aTarget, MediumVariant_T aVariant, MediumLockList *aMediumLockList, ComObjPtr *aProgress, bool aWait) { AssertReturn(!aTarget.isNull(), E_FAIL); AssertReturn(aMediumLockList, E_FAIL); AssertReturn(aProgress != NULL || aWait == true, E_FAIL); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoCaller targetCaller(aTarget); if (FAILED(targetCaller.rc())) return targetCaller.rc(); HRESULT rc = S_OK; ComObjPtr pProgress; Medium::Task *pTask = NULL; try { AutoMultiWriteLock2 alock(this, aTarget COMMA_LOCKVAL_SRC_POS); ComAssertThrow( m->type != MediumType_Writethrough && m->type != MediumType_Shareable && m->type != MediumType_Readonly, E_FAIL); ComAssertThrow(m->state == MediumState_LockedRead, E_FAIL); if (aTarget->m->state != MediumState_NotCreated) throw aTarget->i_setStateError(); /* Check that the medium is not attached to the current state of * any VM referring to it. */ for (BackRefList::const_iterator it = m->backRefs.begin(); it != m->backRefs.end(); ++it) { if (it->fInCurState) { /* Note: when a VM snapshot is being taken, all normal media * attached to the VM in the current state will be, as an * exception, also associated with the snapshot which is about * to create (see SnapshotMachine::init()) before deassociating * them from the current state (which takes place only on * success in Machine::fixupHardDisks()), so that the size of * snapshotIds will be 1 in this case. The extra condition is * used to filter out this legal situation. */ if (it->llSnapshotIds.size() == 0) throw setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is attached to a virtual machine with UUID {%RTuuid}. No differencing media based on it may be created until it is detached"), m->strLocationFull.c_str(), it->machineId.raw()); Assert(it->llSnapshotIds.size() == 1); } } if (aProgress != NULL) { /* use the existing progress object... */ pProgress = *aProgress; /* ...but create a new one if it is null */ if (pProgress.isNull()) { pProgress.createObject(); rc = pProgress->init(m->pVirtualBox, static_cast(this), BstrFmt(tr("Creating differencing medium storage unit '%s'"), aTarget->m->strLocationFull.c_str()).raw(), TRUE /* aCancelable */); if (FAILED(rc)) throw rc; } } /* setup task object to carry out the operation sync/async */ pTask = new Medium::CreateDiffTask(this, pProgress, aTarget, aVariant, aMediumLockList, aWait /* fKeepMediumLockList */); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; /* register a task (it will deregister itself when done) */ ++m->numCreateDiffTasks; Assert(m->numCreateDiffTasks != 0); /* overflow? */ aTarget->m->state = MediumState_Creating; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { if (aWait) rc = i_runNow(pTask); else rc = i_startThread(pTask); if (SUCCEEDED(rc) && aProgress != NULL) *aProgress = pProgress; } else if (pTask != NULL) delete pTask; return rc; } /** * Returns a preferred format for differencing media. */ Utf8Str Medium::i_getPreferredDiffFormat() { AutoCaller autoCaller(this); AssertComRCReturn(autoCaller.rc(), Utf8Str::Empty); /* check that our own format supports diffs */ if (!(m->formatObj->i_getCapabilities() & MediumFormatCapabilities_Differencing)) { /* use the default format if not */ Utf8Str tmp; m->pVirtualBox->i_getDefaultHardDiskFormat(tmp); return tmp; } /* m->strFormat is const, no need to lock */ return m->strFormat; } /** * Implementation for the public Medium::Close() with the exception of calling * VirtualBox::saveRegistries(), in case someone wants to call this for several * media. * * After this returns with success, uninit() has been called on the medium, and * the object is no longer usable ("not ready" state). * * @param autoCaller AutoCaller instance which must have been created on the caller's * stack for this medium. This gets released hereupon * which the Medium instance gets uninitialized. * @return */ HRESULT Medium::i_close(AutoCaller &autoCaller) { // must temporarily drop the caller, need the tree lock first autoCaller.release(); // we're accessing parent/child and backrefs, so lock the tree first, then ourselves AutoMultiWriteLock2 multilock(&m->pVirtualBox->i_getMediaTreeLockHandle(), this->lockHandle() COMMA_LOCKVAL_SRC_POS); autoCaller.add(); if (FAILED(autoCaller.rc())) return autoCaller.rc(); LogFlowFunc(("ENTER for %s\n", i_getLocationFull().c_str())); bool wasCreated = true; switch (m->state) { case MediumState_NotCreated: wasCreated = false; break; case MediumState_Created: case MediumState_Inaccessible: break; default: return i_setStateError(); } if (m->backRefs.size() != 0) return setError(VBOX_E_OBJECT_IN_USE, tr("Medium '%s' cannot be closed because it is still attached to %d virtual machines"), m->strLocationFull.c_str(), m->backRefs.size()); // perform extra media-dependent close checks HRESULT rc = i_canClose(); if (FAILED(rc)) return rc; if (wasCreated) { // remove from the list of known media before performing actual // uninitialization (to keep the media registry consistent on // failure to do so) rc = i_unregisterWithVirtualBox(); if (FAILED(rc)) return rc; multilock.release(); // Release the AutoCaller now, as otherwise uninit() will simply hang. // Needs to be done before mark the registries as modified and saving // the registry, as otherwise there may be a deadlock with someone else // closing this object while we're in i_saveModifiedRegistries(), which // needs the media tree lock, which the other thread holds until after // uninit() below. autoCaller.release(); i_markRegistriesModified(); m->pVirtualBox->i_saveModifiedRegistries(); } else { multilock.release(); // release the AutoCaller, as otherwise uninit() will simply hang autoCaller.release(); } // Keep the locks held until after uninit, as otherwise the consistency // of the medium tree cannot be guaranteed. uninit(); LogFlowFuncLeave(); return rc; } /** * Deletes the medium storage unit. * * If @a aProgress is not NULL but the object it points to is @c null then a new * progress object will be created and assigned to @a *aProgress on success, * otherwise the existing progress object is used. If Progress is NULL, then no * progress object is created/used at all. * * When @a aWait is @c false, this method will create a thread to perform the * delete operation asynchronously and will return immediately. Otherwise, it * will perform the operation on the calling thread and will not return to the * caller until the operation is completed. Note that @a aProgress cannot be * NULL when @a aWait is @c false (this method will assert in this case). * * @param aProgress Where to find/store a Progress object to track operation * completion. * @param aWait @c true if this method should block instead of creating * an asynchronous thread. * * @note Locks mVirtualBox and this object for writing. Locks medium tree for * writing. */ HRESULT Medium::i_deleteStorage(ComObjPtr *aProgress, bool aWait) { AssertReturn(aProgress != NULL || aWait == true, E_FAIL); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); HRESULT rc = S_OK; ComObjPtr pProgress; Medium::Task *pTask = NULL; try { /* we're accessing the media tree, and canClose() needs it too */ AutoMultiWriteLock2 multilock(&m->pVirtualBox->i_getMediaTreeLockHandle(), this->lockHandle() COMMA_LOCKVAL_SRC_POS); LogFlowThisFunc(("aWait=%RTbool locationFull=%s\n", aWait, i_getLocationFull().c_str() )); if ( !(m->formatObj->i_getCapabilities() & ( MediumFormatCapabilities_CreateDynamic | MediumFormatCapabilities_CreateFixed))) throw setError(VBOX_E_NOT_SUPPORTED, tr("Medium format '%s' does not support storage deletion"), m->strFormat.c_str()); /* Note that we are fine with Inaccessible state too: a) for symmetry * with create calls and b) because it doesn't really harm to try, if * it is really inaccessible, the delete operation will fail anyway. * Accepting Inaccessible state is especially important because all * registered media are initially Inaccessible upon VBoxSVC startup * until COMGETTER(RefreshState) is called. Accept Deleting state * because some callers need to put the medium in this state early * to prevent races. */ switch (m->state) { case MediumState_Created: case MediumState_Deleting: case MediumState_Inaccessible: break; default: throw i_setStateError(); } if (m->backRefs.size() != 0) { Utf8Str strMachines; for (BackRefList::const_iterator it = m->backRefs.begin(); it != m->backRefs.end(); ++it) { const BackRef &b = *it; if (strMachines.length()) strMachines.append(", "); strMachines.append(b.machineId.toString().c_str()); } #ifdef DEBUG i_dumpBackRefs(); #endif throw setError(VBOX_E_OBJECT_IN_USE, tr("Cannot delete storage: medium '%s' is still attached to the following %d virtual machine(s): %s"), m->strLocationFull.c_str(), m->backRefs.size(), strMachines.c_str()); } rc = i_canClose(); if (FAILED(rc)) throw rc; /* go to Deleting state, so that the medium is not actually locked */ if (m->state != MediumState_Deleting) { rc = i_markForDeletion(); if (FAILED(rc)) throw rc; } /* Build the medium lock list. */ MediumLockList *pMediumLockList(new MediumLockList()); multilock.release(); rc = i_createMediumLockList(true /* fFailIfInaccessible */, true /* fMediumLockWrite */, NULL, *pMediumLockList); multilock.acquire(); if (FAILED(rc)) { delete pMediumLockList; throw rc; } multilock.release(); rc = pMediumLockList->Lock(); multilock.acquire(); if (FAILED(rc)) { delete pMediumLockList; throw setError(rc, tr("Failed to lock media when deleting '%s'"), i_getLocationFull().c_str()); } /* try to remove from the list of known media before performing * actual deletion (we favor the consistency of the media registry * which would have been broken if unregisterWithVirtualBox() failed * after we successfully deleted the storage) */ rc = i_unregisterWithVirtualBox(); if (FAILED(rc)) throw rc; // no longer need lock multilock.release(); i_markRegistriesModified(); if (aProgress != NULL) { /* use the existing progress object... */ pProgress = *aProgress; /* ...but create a new one if it is null */ if (pProgress.isNull()) { pProgress.createObject(); rc = pProgress->init(m->pVirtualBox, static_cast(this), BstrFmt(tr("Deleting medium storage unit '%s'"), m->strLocationFull.c_str()).raw(), FALSE /* aCancelable */); if (FAILED(rc)) throw rc; } } /* setup task object to carry out the operation sync/async */ pTask = new Medium::DeleteTask(this, pProgress, pMediumLockList); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { if (aWait) rc = i_runNow(pTask); else rc = i_startThread(pTask); if (SUCCEEDED(rc) && aProgress != NULL) *aProgress = pProgress; } else { if (pTask) delete pTask; /* Undo deleting state if necessary. */ AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); /* Make sure that any error signalled by unmarkForDeletion() is not * ending up in the error list (if the caller uses MultiResult). It * usually is spurious, as in most cases the medium hasn't been marked * for deletion when the error was thrown above. */ ErrorInfoKeeper eik; i_unmarkForDeletion(); } return rc; } /** * Mark a medium for deletion. * * @note Caller must hold the write lock on this medium! */ HRESULT Medium::i_markForDeletion() { ComAssertRet(isWriteLockOnCurrentThread(), E_FAIL); switch (m->state) { case MediumState_Created: case MediumState_Inaccessible: m->preLockState = m->state; m->state = MediumState_Deleting; return S_OK; default: return i_setStateError(); } } /** * Removes the "mark for deletion". * * @note Caller must hold the write lock on this medium! */ HRESULT Medium::i_unmarkForDeletion() { ComAssertRet(isWriteLockOnCurrentThread(), E_FAIL); switch (m->state) { case MediumState_Deleting: m->state = m->preLockState; return S_OK; default: return i_setStateError(); } } /** * Mark a medium for deletion which is in locked state. * * @note Caller must hold the write lock on this medium! */ HRESULT Medium::i_markLockedForDeletion() { ComAssertRet(isWriteLockOnCurrentThread(), E_FAIL); if ( ( m->state == MediumState_LockedRead || m->state == MediumState_LockedWrite) && m->preLockState == MediumState_Created) { m->preLockState = MediumState_Deleting; return S_OK; } else return i_setStateError(); } /** * Removes the "mark for deletion" for a medium in locked state. * * @note Caller must hold the write lock on this medium! */ HRESULT Medium::i_unmarkLockedForDeletion() { ComAssertRet(isWriteLockOnCurrentThread(), E_FAIL); if ( ( m->state == MediumState_LockedRead || m->state == MediumState_LockedWrite) && m->preLockState == MediumState_Deleting) { m->preLockState = MediumState_Created; return S_OK; } else return i_setStateError(); } /** * Queries the preferred merge direction from this to the other medium, i.e. * the one which requires the least amount of I/O and therefore time and * disk consumption. * * @returns Status code. * @retval E_FAIL in case determining the merge direction fails for some reason, * for example if getting the size of the media fails. There is no * error set though and the caller is free to continue to find out * what was going wrong later. Leaves fMergeForward unset. * @retval VBOX_E_INVALID_OBJECT_STATE if both media are not related to each other * An error is set. * @param pOther The other medium to merge with. * @param fMergeForward Resulting preferred merge direction (out). */ HRESULT Medium::i_queryPreferredMergeDirection(const ComObjPtr &pOther, bool &fMergeForward) { AssertReturn(pOther != NULL, E_FAIL); AssertReturn(pOther != this, E_FAIL); AutoCaller autoCaller(this); AssertComRCReturnRC(autoCaller.rc()); AutoCaller otherCaller(pOther); AssertComRCReturnRC(otherCaller.rc()); HRESULT rc = S_OK; bool fThisParent = false; /**<< Flag whether this medium is the parent of pOther. */ try { // locking: we need the tree lock first because we access parent pointers AutoWriteLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); /* more sanity checking and figuring out the current merge direction */ ComObjPtr pMedium = i_getParent(); while (!pMedium.isNull() && pMedium != pOther) pMedium = pMedium->i_getParent(); if (pMedium == pOther) fThisParent = false; else { pMedium = pOther->i_getParent(); while (!pMedium.isNull() && pMedium != this) pMedium = pMedium->i_getParent(); if (pMedium == this) fThisParent = true; else { Utf8Str tgtLoc; { AutoReadLock alock(pOther COMMA_LOCKVAL_SRC_POS); tgtLoc = pOther->i_getLocationFull(); } AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); throw setError(VBOX_E_INVALID_OBJECT_STATE, tr("Media '%s' and '%s' are unrelated"), m->strLocationFull.c_str(), tgtLoc.c_str()); } } /* * Figure out the preferred merge direction. The current way is to * get the current sizes of file based images and select the merge * direction depending on the size. * * Can't use the VD API to get current size here as the media might * be write locked by a running VM. Resort to RTFileQuerySize(). */ int vrc = VINF_SUCCESS; uint64_t cbMediumThis = 0; uint64_t cbMediumOther = 0; if (i_isMediumFormatFile() && pOther->i_isMediumFormatFile()) { vrc = RTFileQuerySize(this->i_getLocationFull().c_str(), &cbMediumThis); if (RT_SUCCESS(vrc)) { vrc = RTFileQuerySize(pOther->i_getLocationFull().c_str(), &cbMediumOther); } if (RT_FAILURE(vrc)) rc = E_FAIL; else { /* * Check which merge direction might be more optimal. * This method is not bullet proof of course as there might * be overlapping blocks in the images so the file size is * not the best indicator but it is good enough for our purpose * and everything else is too complicated, especially when the * media are used by a running VM. */ bool fMergeIntoThis = cbMediumThis > cbMediumOther; fMergeForward = fMergeIntoThis ^ fThisParent; } } } catch (HRESULT aRC) { rc = aRC; } return rc; } /** * Prepares this (source) medium, target medium and all intermediate media * for the merge operation. * * This method is to be called prior to calling the #mergeTo() to perform * necessary consistency checks and place involved media to appropriate * states. If #mergeTo() is not called or fails, the state modifications * performed by this method must be undone by #cancelMergeTo(). * * See #mergeTo() for more information about merging. * * @param pTarget Target medium. * @param aMachineId Allowed machine attachment. NULL means do not check. * @param aSnapshotId Allowed snapshot attachment. NULL or empty UUID means * do not check. * @param fLockMedia Flag whether to lock the medium lock list or not. * If set to false and the medium lock list locking fails * later you must call #cancelMergeTo(). * @param fMergeForward Resulting merge direction (out). * @param pParentForTarget New parent for target medium after merge (out). * @param aChildrenToReparent Medium lock list containing all children of the * source which will have to be reparented to the target * after merge (out). * @param aMediumLockList Medium locking information (out). * * @note Locks medium tree for reading. Locks this object, aTarget and all * intermediate media for writing. */ HRESULT Medium::i_prepareMergeTo(const ComObjPtr &pTarget, const Guid *aMachineId, const Guid *aSnapshotId, bool fLockMedia, bool &fMergeForward, ComObjPtr &pParentForTarget, MediumLockList * &aChildrenToReparent, MediumLockList * &aMediumLockList) { AssertReturn(pTarget != NULL, E_FAIL); AssertReturn(pTarget != this, E_FAIL); AutoCaller autoCaller(this); AssertComRCReturnRC(autoCaller.rc()); AutoCaller targetCaller(pTarget); AssertComRCReturnRC(targetCaller.rc()); HRESULT rc = S_OK; fMergeForward = false; pParentForTarget.setNull(); Assert(aChildrenToReparent == NULL); aChildrenToReparent = NULL; Assert(aMediumLockList == NULL); aMediumLockList = NULL; try { // locking: we need the tree lock first because we access parent pointers AutoWriteLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); /* more sanity checking and figuring out the merge direction */ ComObjPtr pMedium = i_getParent(); while (!pMedium.isNull() && pMedium != pTarget) pMedium = pMedium->i_getParent(); if (pMedium == pTarget) fMergeForward = false; else { pMedium = pTarget->i_getParent(); while (!pMedium.isNull() && pMedium != this) pMedium = pMedium->i_getParent(); if (pMedium == this) fMergeForward = true; else { Utf8Str tgtLoc; { AutoReadLock alock(pTarget COMMA_LOCKVAL_SRC_POS); tgtLoc = pTarget->i_getLocationFull(); } AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); throw setError(VBOX_E_INVALID_OBJECT_STATE, tr("Media '%s' and '%s' are unrelated"), m->strLocationFull.c_str(), tgtLoc.c_str()); } } /* Build the lock list. */ aMediumLockList = new MediumLockList(); treeLock.release(); if (fMergeForward) rc = pTarget->i_createMediumLockList(true /* fFailIfInaccessible */, true /* fMediumLockWrite */, NULL, *aMediumLockList); else rc = i_createMediumLockList(true /* fFailIfInaccessible */, false /* fMediumLockWrite */, NULL, *aMediumLockList); treeLock.acquire(); if (FAILED(rc)) throw rc; /* Sanity checking, must be after lock list creation as it depends on * valid medium states. The medium objects must be accessible. Only * do this if immediate locking is requested, otherwise it fails when * we construct a medium lock list for an already running VM. Snapshot * deletion uses this to simplify its life. */ if (fLockMedia) { { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); if (m->state != MediumState_Created) throw i_setStateError(); } { AutoReadLock alock(pTarget COMMA_LOCKVAL_SRC_POS); if (pTarget->m->state != MediumState_Created) throw pTarget->i_setStateError(); } } /* check medium attachment and other sanity conditions */ if (fMergeForward) { AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); if (i_getChildren().size() > 1) { throw setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' involved in the merge operation has more than one child medium (%d)"), m->strLocationFull.c_str(), i_getChildren().size()); } /* One backreference is only allowed if the machine ID is not empty * and it matches the machine the medium is attached to (including * the snapshot ID if not empty). */ if ( m->backRefs.size() != 0 && ( !aMachineId || m->backRefs.size() != 1 || aMachineId->isZero() || *i_getFirstMachineBackrefId() != *aMachineId || ( (!aSnapshotId || !aSnapshotId->isZero()) && *i_getFirstMachineBackrefSnapshotId() != *aSnapshotId))) throw setError(VBOX_E_OBJECT_IN_USE, tr("Medium '%s' is attached to %d virtual machines"), m->strLocationFull.c_str(), m->backRefs.size()); if (m->type == MediumType_Immutable) throw setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is immutable"), m->strLocationFull.c_str()); if (m->type == MediumType_MultiAttach) throw setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is multi-attach"), m->strLocationFull.c_str()); } else { AutoReadLock alock(pTarget COMMA_LOCKVAL_SRC_POS); if (pTarget->i_getChildren().size() > 1) { throw setError(VBOX_E_OBJECT_IN_USE, tr("Medium '%s' involved in the merge operation has more than one child medium (%d)"), pTarget->m->strLocationFull.c_str(), pTarget->i_getChildren().size()); } if (pTarget->m->type == MediumType_Immutable) throw setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is immutable"), pTarget->m->strLocationFull.c_str()); if (pTarget->m->type == MediumType_MultiAttach) throw setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is multi-attach"), pTarget->m->strLocationFull.c_str()); } ComObjPtr pLast(fMergeForward ? (Medium *)pTarget : this); ComObjPtr pLastIntermediate = pLast->i_getParent(); for (pLast = pLastIntermediate; !pLast.isNull() && pLast != pTarget && pLast != this; pLast = pLast->i_getParent()) { AutoReadLock alock(pLast COMMA_LOCKVAL_SRC_POS); if (pLast->i_getChildren().size() > 1) { throw setError(VBOX_E_OBJECT_IN_USE, tr("Medium '%s' involved in the merge operation has more than one child medium (%d)"), pLast->m->strLocationFull.c_str(), pLast->i_getChildren().size()); } if (pLast->m->backRefs.size() != 0) throw setError(VBOX_E_OBJECT_IN_USE, tr("Medium '%s' is attached to %d virtual machines"), pLast->m->strLocationFull.c_str(), pLast->m->backRefs.size()); } /* Update medium states appropriately */ { AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); if (m->state == MediumState_Created) { rc = i_markForDeletion(); if (FAILED(rc)) throw rc; } else { if (fLockMedia) throw i_setStateError(); else if ( m->state == MediumState_LockedWrite || m->state == MediumState_LockedRead) { /* Either mark it for deletion in locked state or allow * others to have done so. */ if (m->preLockState == MediumState_Created) i_markLockedForDeletion(); else if (m->preLockState != MediumState_Deleting) throw i_setStateError(); } else throw i_setStateError(); } } if (fMergeForward) { /* we will need parent to reparent target */ pParentForTarget = i_getParent(); } else { /* we will need to reparent children of the source */ aChildrenToReparent = new MediumLockList(); for (MediaList::const_iterator it = i_getChildren().begin(); it != i_getChildren().end(); ++it) { pMedium = *it; aChildrenToReparent->Append(pMedium, true /* fLockWrite */); } if (fLockMedia && aChildrenToReparent) { treeLock.release(); rc = aChildrenToReparent->Lock(); treeLock.acquire(); if (FAILED(rc)) throw rc; } } for (pLast = pLastIntermediate; !pLast.isNull() && pLast != pTarget && pLast != this; pLast = pLast->i_getParent()) { AutoWriteLock alock(pLast COMMA_LOCKVAL_SRC_POS); if (pLast->m->state == MediumState_Created) { rc = pLast->i_markForDeletion(); if (FAILED(rc)) throw rc; } else throw pLast->i_setStateError(); } /* Tweak the lock list in the backward merge case, as the target * isn't marked to be locked for writing yet. */ if (!fMergeForward) { MediumLockList::Base::iterator lockListBegin = aMediumLockList->GetBegin(); MediumLockList::Base::iterator lockListEnd = aMediumLockList->GetEnd(); lockListEnd--; for (MediumLockList::Base::iterator it = lockListBegin; it != lockListEnd; ++it) { MediumLock &mediumLock = *it; if (mediumLock.GetMedium() == pTarget) { HRESULT rc2 = mediumLock.UpdateLock(true); AssertComRC(rc2); break; } } } if (fLockMedia) { treeLock.release(); rc = aMediumLockList->Lock(); treeLock.acquire(); if (FAILED(rc)) { AutoReadLock alock(pTarget COMMA_LOCKVAL_SRC_POS); throw setError(rc, tr("Failed to lock media when merging to '%s'"), pTarget->i_getLocationFull().c_str()); } } } catch (HRESULT aRC) { rc = aRC; } if (FAILED(rc)) { if (aMediumLockList) { delete aMediumLockList; aMediumLockList = NULL; } if (aChildrenToReparent) { delete aChildrenToReparent; aChildrenToReparent = NULL; } } return rc; } /** * Merges this medium to the specified medium which must be either its * direct ancestor or descendant. * * Given this medium is SOURCE and the specified medium is TARGET, we will * get two variants of the merge operation: * * forward merge * -------------------------> * [Extra] <- SOURCE <- Intermediate <- TARGET * Any Del Del LockWr * * * backward merge * <------------------------- * TARGET <- Intermediate <- SOURCE <- [Extra] * LockWr Del Del LockWr * * Each diagram shows the involved media on the media chain where * SOURCE and TARGET belong. Under each medium there is a state value which * the medium must have at a time of the mergeTo() call. * * The media in the square braces may be absent (e.g. when the forward * operation takes place and SOURCE is the base medium, or when the backward * merge operation takes place and TARGET is the last child in the chain) but if * they present they are involved too as shown. * * Neither the source medium nor intermediate media may be attached to * any VM directly or in the snapshot, otherwise this method will assert. * * The #prepareMergeTo() method must be called prior to this method to place all * involved to necessary states and perform other consistency checks. * * If @a aWait is @c true then this method will perform the operation on the * calling thread and will not return to the caller until the operation is * completed. When this method succeeds, all intermediate medium objects in * the chain will be uninitialized, the state of the target medium (and all * involved extra media) will be restored. @a aMediumLockList will not be * deleted, whether the operation is successful or not. The caller has to do * this if appropriate. Note that this (source) medium is not uninitialized * because of possible AutoCaller instances held by the caller of this method * on the current thread. It's therefore the responsibility of the caller to * call Medium::uninit() after releasing all callers. * * If @a aWait is @c false then this method will create a thread to perform the * operation asynchronously and will return immediately. If the operation * succeeds, the thread will uninitialize the source medium object and all * intermediate medium objects in the chain, reset the state of the target * medium (and all involved extra media) and delete @a aMediumLockList. * If the operation fails, the thread will only reset the states of all * involved media and delete @a aMediumLockList. * * When this method fails (regardless of the @a aWait mode), it is a caller's * responsibility to undo state changes and delete @a aMediumLockList using * #cancelMergeTo(). * * If @a aProgress is not NULL but the object it points to is @c null then a new * progress object will be created and assigned to @a *aProgress on success, * otherwise the existing progress object is used. If Progress is NULL, then no * progress object is created/used at all. Note that @a aProgress cannot be * NULL when @a aWait is @c false (this method will assert in this case). * * @param pTarget Target medium. * @param fMergeForward Merge direction. * @param pParentForTarget New parent for target medium after merge. * @param aChildrenToReparent List of children of the source which will have * to be reparented to the target after merge. * @param aMediumLockList Medium locking information. * @param aProgress Where to find/store a Progress object to track operation * completion. * @param aWait @c true if this method should block instead of creating * an asynchronous thread. * * @note Locks the tree lock for writing. Locks the media from the chain * for writing. */ HRESULT Medium::i_mergeTo(const ComObjPtr &pTarget, bool fMergeForward, const ComObjPtr &pParentForTarget, MediumLockList *aChildrenToReparent, MediumLockList *aMediumLockList, ComObjPtr *aProgress, bool aWait) { AssertReturn(pTarget != NULL, E_FAIL); AssertReturn(pTarget != this, E_FAIL); AssertReturn(aMediumLockList != NULL, E_FAIL); AssertReturn(aProgress != NULL || aWait == true, E_FAIL); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoCaller targetCaller(pTarget); AssertComRCReturnRC(targetCaller.rc()); HRESULT rc = S_OK; ComObjPtr pProgress; Medium::Task *pTask = NULL; try { if (aProgress != NULL) { /* use the existing progress object... */ pProgress = *aProgress; /* ...but create a new one if it is null */ if (pProgress.isNull()) { Utf8Str tgtName; { AutoReadLock alock(pTarget COMMA_LOCKVAL_SRC_POS); tgtName = pTarget->i_getName(); } AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); pProgress.createObject(); rc = pProgress->init(m->pVirtualBox, static_cast(this), BstrFmt(tr("Merging medium '%s' to '%s'"), i_getName().c_str(), tgtName.c_str()).raw(), TRUE /* aCancelable */); if (FAILED(rc)) throw rc; } } /* setup task object to carry out the operation sync/async */ pTask = new Medium::MergeTask(this, pTarget, fMergeForward, pParentForTarget, aChildrenToReparent, pProgress, aMediumLockList, aWait /* fKeepMediumLockList */); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { if (aWait) rc = i_runNow(pTask); else rc = i_startThread(pTask); if (SUCCEEDED(rc) && aProgress != NULL) *aProgress = pProgress; } else if (pTask != NULL) delete pTask; return rc; } /** * Undoes what #prepareMergeTo() did. Must be called if #mergeTo() is not * called or fails. Frees memory occupied by @a aMediumLockList and unlocks * the medium objects in @a aChildrenToReparent. * * @param aChildrenToReparent List of children of the source which will have * to be reparented to the target after merge. * @param aMediumLockList Medium locking information. * * @note Locks the media from the chain for writing. */ void Medium::i_cancelMergeTo(MediumLockList *aChildrenToReparent, MediumLockList *aMediumLockList) { AutoCaller autoCaller(this); AssertComRCReturnVoid(autoCaller.rc()); AssertReturnVoid(aMediumLockList != NULL); /* Revert media marked for deletion to previous state. */ HRESULT rc; MediumLockList::Base::const_iterator mediumListBegin = aMediumLockList->GetBegin(); MediumLockList::Base::const_iterator mediumListEnd = aMediumLockList->GetEnd(); for (MediumLockList::Base::const_iterator it = mediumListBegin; it != mediumListEnd; ++it) { const MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); AutoWriteLock alock(pMedium COMMA_LOCKVAL_SRC_POS); if (pMedium->m->state == MediumState_Deleting) { rc = pMedium->i_unmarkForDeletion(); AssertComRC(rc); } } /* the destructor will do the work */ delete aMediumLockList; /* unlock the children which had to be reparented, the destructor will do * the work */ if (aChildrenToReparent) delete aChildrenToReparent; } /** * Fix the parent UUID of all children to point to this medium as their * parent. */ HRESULT Medium::i_fixParentUuidOfChildren(MediumLockList *pChildrenToReparent) { Assert(!isWriteLockOnCurrentThread()); Assert(!m->pVirtualBox->i_getMediaTreeLockHandle().isWriteLockOnCurrentThread()); MediumLockList mediumLockList; HRESULT rc = i_createMediumLockList(true /* fFailIfInaccessible */, false /* fMediumLockWrite */, this, mediumLockList); AssertComRCReturnRC(rc); try { PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); try { MediumLockList::Base::iterator lockListBegin = mediumLockList.GetBegin(); MediumLockList::Base::iterator lockListEnd = mediumLockList.GetEnd(); for (MediumLockList::Base::iterator it = lockListBegin; it != lockListEnd; ++it) { MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); // open the medium vrc = VDOpen(hdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), VD_OPEN_FLAGS_READONLY | m->uOpenFlagsDef, pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw vrc; } MediumLockList::Base::iterator childrenBegin = pChildrenToReparent->GetBegin(); MediumLockList::Base::iterator childrenEnd = pChildrenToReparent->GetEnd(); for (MediumLockList::Base::iterator it = childrenBegin; it != childrenEnd; ++it) { Medium *pMedium = it->GetMedium(); /* VD_OPEN_FLAGS_INFO since UUID is wrong yet */ vrc = VDOpen(hdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), VD_OPEN_FLAGS_INFO | m->uOpenFlagsDef, pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw vrc; vrc = VDSetParentUuid(hdd, VD_LAST_IMAGE, m->id.raw()); if (RT_FAILURE(vrc)) throw vrc; vrc = VDClose(hdd, false /* fDelete */); if (RT_FAILURE(vrc)) throw vrc; } } catch (HRESULT aRC) { rc = aRC; } catch (int aVRC) { rc = setError(E_FAIL, tr("Could not update medium UUID references to parent '%s' (%s)"), m->strLocationFull.c_str(), i_vdError(aVRC).c_str()); } VDDestroy(hdd); } catch (HRESULT aRC) { rc = aRC; } return rc; } /** * Used by IAppliance to export disk images. * * @param aFilename Filename to create (UTF8). * @param aFormat Medium format for creating @a aFilename. * @param aVariant Which exact image format variant to use * for the destination image. * @param aVDImageIOCallbacks Pointer to the callback table for a * VDINTERFACEIO interface. May be NULL. * @param aVDImageIOUser Opaque data for the callbacks. * @param aProgress Progress object to use. * @return * @note The source format is defined by the Medium instance. */ HRESULT Medium::i_exportFile(const char *aFilename, const ComObjPtr &aFormat, MediumVariant_T aVariant, PVDINTERFACEIO aVDImageIOIf, void *aVDImageIOUser, const ComObjPtr &aProgress) { AssertPtrReturn(aFilename, E_INVALIDARG); AssertReturn(!aFormat.isNull(), E_INVALIDARG); AssertReturn(!aProgress.isNull(), E_INVALIDARG); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); HRESULT rc = S_OK; Medium::Task *pTask = NULL; try { // This needs no extra locks besides what is done in the called methods. /* Build the source lock list. */ MediumLockList *pSourceMediumLockList(new MediumLockList()); rc = i_createMediumLockList(true /* fFailIfInaccessible */, false /* fMediumLockWrite */, NULL, *pSourceMediumLockList); if (FAILED(rc)) { delete pSourceMediumLockList; throw rc; } rc = pSourceMediumLockList->Lock(); if (FAILED(rc)) { delete pSourceMediumLockList; throw setError(rc, tr("Failed to lock source media '%s'"), i_getLocationFull().c_str()); } /* setup task object to carry out the operation asynchronously */ pTask = new Medium::ExportTask(this, aProgress, aFilename, aFormat, aVariant, aVDImageIOIf, aVDImageIOUser, pSourceMediumLockList); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) rc = i_startThread(pTask); else if (pTask != NULL) delete pTask; return rc; } /** * Used by IAppliance to import disk images. * * @param aFilename Filename to read (UTF8). * @param aFormat Medium format for reading @a aFilename. * @param aVariant Which exact image format variant to use * for the destination image. * @param aVDImageIOCallbacks Pointer to the callback table for a * VDINTERFACEIO interface. May be NULL. * @param aVDImageIOUser Opaque data for the callbacks. * @param aParent Parent medium. May be NULL. * @param aProgress Progress object to use. * @return * @note The destination format is defined by the Medium instance. */ HRESULT Medium::i_importFile(const char *aFilename, const ComObjPtr &aFormat, MediumVariant_T aVariant, PVDINTERFACEIO aVDImageIOIf, void *aVDImageIOUser, const ComObjPtr &aParent, const ComObjPtr &aProgress) { AssertPtrReturn(aFilename, E_INVALIDARG); AssertReturn(!aFormat.isNull(), E_INVALIDARG); AssertReturn(!aProgress.isNull(), E_INVALIDARG); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); HRESULT rc = S_OK; Medium::Task *pTask = NULL; try { // locking: we need the tree lock first because we access parent pointers // and we need to write-lock the media involved uint32_t cHandles = 2; LockHandle* pHandles[3] = { &m->pVirtualBox->i_getMediaTreeLockHandle(), this->lockHandle() }; /* Only add parent to the lock if it is not null */ if (!aParent.isNull()) pHandles[cHandles++] = aParent->lockHandle(); AutoWriteLock alock(cHandles, pHandles COMMA_LOCKVAL_SRC_POS); if ( m->state != MediumState_NotCreated && m->state != MediumState_Created) throw i_setStateError(); /* Build the target lock list. */ MediumLockList *pTargetMediumLockList(new MediumLockList()); alock.release(); rc = i_createMediumLockList(true /* fFailIfInaccessible */, true /* fMediumLockWrite */, aParent, *pTargetMediumLockList); alock.acquire(); if (FAILED(rc)) { delete pTargetMediumLockList; throw rc; } alock.release(); rc = pTargetMediumLockList->Lock(); alock.acquire(); if (FAILED(rc)) { delete pTargetMediumLockList; throw setError(rc, tr("Failed to lock target media '%s'"), i_getLocationFull().c_str()); } /* setup task object to carry out the operation asynchronously */ pTask = new Medium::ImportTask(this, aProgress, aFilename, aFormat, aVariant, aVDImageIOIf, aVDImageIOUser, aParent, pTargetMediumLockList); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; if (m->state == MediumState_NotCreated) m->state = MediumState_Creating; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) rc = i_startThread(pTask); else if (pTask != NULL) delete pTask; return rc; } /** * Internal version of the public CloneTo API which allows to enable certain * optimizations to improve speed during VM cloning. * * @param aTarget Target medium * @param aVariant Which exact image format variant to use * for the destination image. * @param aParent Parent medium. May be NULL. * @param aProgress Progress object to use. * @param idxSrcImageSame The last image in the source chain which has the * same content as the given image in the destination * chain. Use UINT32_MAX to disable this optimization. * @param idxDstImageSame The last image in the destination chain which has the * same content as the given image in the source chain. * Use UINT32_MAX to disable this optimization. * @return */ HRESULT Medium::i_cloneToEx(const ComObjPtr &aTarget, ULONG aVariant, const ComObjPtr &aParent, IProgress **aProgress, uint32_t idxSrcImageSame, uint32_t idxDstImageSame) { CheckComArgNotNull(aTarget); CheckComArgOutPointerValid(aProgress); ComAssertRet(aTarget != this, E_INVALIDARG); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); HRESULT rc = S_OK; ComObjPtr pProgress; Medium::Task *pTask = NULL; try { // locking: we need the tree lock first because we access parent pointers // and we need to write-lock the media involved uint32_t cHandles = 3; LockHandle* pHandles[4] = { &m->pVirtualBox->i_getMediaTreeLockHandle(), this->lockHandle(), aTarget->lockHandle() }; /* Only add parent to the lock if it is not null */ if (!aParent.isNull()) pHandles[cHandles++] = aParent->lockHandle(); AutoWriteLock alock(cHandles, pHandles COMMA_LOCKVAL_SRC_POS); if ( aTarget->m->state != MediumState_NotCreated && aTarget->m->state != MediumState_Created) throw aTarget->i_setStateError(); /* Build the source lock list. */ MediumLockList *pSourceMediumLockList(new MediumLockList()); alock.release(); rc = i_createMediumLockList(true /* fFailIfInaccessible */, false /* fMediumLockWrite */, NULL, *pSourceMediumLockList); alock.acquire(); if (FAILED(rc)) { delete pSourceMediumLockList; throw rc; } /* Build the target lock list (including the to-be parent chain). */ MediumLockList *pTargetMediumLockList(new MediumLockList()); alock.release(); rc = aTarget->i_createMediumLockList(true /* fFailIfInaccessible */, true /* fMediumLockWrite */, aParent, *pTargetMediumLockList); alock.acquire(); if (FAILED(rc)) { delete pSourceMediumLockList; delete pTargetMediumLockList; throw rc; } alock.release(); rc = pSourceMediumLockList->Lock(); alock.acquire(); if (FAILED(rc)) { delete pSourceMediumLockList; delete pTargetMediumLockList; throw setError(rc, tr("Failed to lock source media '%s'"), i_getLocationFull().c_str()); } alock.release(); rc = pTargetMediumLockList->Lock(); alock.acquire(); if (FAILED(rc)) { delete pSourceMediumLockList; delete pTargetMediumLockList; throw setError(rc, tr("Failed to lock target media '%s'"), aTarget->i_getLocationFull().c_str()); } pProgress.createObject(); rc = pProgress->init(m->pVirtualBox, static_cast (this), BstrFmt(tr("Creating clone medium '%s'"), aTarget->m->strLocationFull.c_str()).raw(), TRUE /* aCancelable */); if (FAILED(rc)) { delete pSourceMediumLockList; delete pTargetMediumLockList; throw rc; } /* setup task object to carry out the operation asynchronously */ pTask = new Medium::CloneTask(this, pProgress, aTarget, (MediumVariant_T)aVariant, aParent, idxSrcImageSame, idxDstImageSame, pSourceMediumLockList, pTargetMediumLockList); rc = pTask->rc(); AssertComRC(rc); if (FAILED(rc)) throw rc; if (aTarget->m->state == MediumState_NotCreated) aTarget->m->state = MediumState_Creating; } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { rc = i_startThread(pTask); if (SUCCEEDED(rc)) pProgress.queryInterfaceTo(aProgress); } else if (pTask != NULL) delete pTask; return rc; } //////////////////////////////////////////////////////////////////////////////// // // Private methods // //////////////////////////////////////////////////////////////////////////////// /** * Queries information from the medium. * * As a result of this call, the accessibility state and data members such as * size and description will be updated with the current information. * * @note This method may block during a system I/O call that checks storage * accessibility. * * @note Caller MUST NOT hold the media tree or medium lock. * * @note Locks mParent for reading. Locks this object for writing. * * @param fSetImageId Whether to reset the UUID contained in the image file to the UUID in the medium instance data (see SetIDs()) * @param fSetParentId Whether to reset the parent UUID contained in the image file to the parent * UUID in the medium instance data (see SetIDs()) * @return */ HRESULT Medium::i_queryInfo(bool fSetImageId, bool fSetParentId, AutoCaller &autoCaller) { Assert(!isWriteLockOnCurrentThread()); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); if ( m->state != MediumState_Created && m->state != MediumState_Inaccessible && m->state != MediumState_LockedRead) return E_FAIL; HRESULT rc = S_OK; int vrc = VINF_SUCCESS; /* check if a blocking i_queryInfo() call is in progress on some other thread, * and wait for it to finish if so instead of querying data ourselves */ if (m->queryInfoRunning) { Assert( m->state == MediumState_LockedRead || m->state == MediumState_LockedWrite); while (m->queryInfoRunning) { alock.release(); /* must not hold the object lock now */ Assert(!isWriteLockOnCurrentThread()); { AutoReadLock qlock(m->queryInfoSem COMMA_LOCKVAL_SRC_POS); } alock.acquire(); } return S_OK; } bool success = false; Utf8Str lastAccessError; /* are we dealing with a new medium constructed using the existing * location? */ bool isImport = m->id.isZero(); unsigned uOpenFlags = VD_OPEN_FLAGS_INFO; /* Note that we don't use VD_OPEN_FLAGS_READONLY when opening new * media because that would prevent necessary modifications * when opening media of some third-party formats for the first * time in VirtualBox (such as VMDK for which VDOpen() needs to * generate an UUID if it is missing) */ if ( m->hddOpenMode == OpenReadOnly || m->type == MediumType_Readonly || (!isImport && !fSetImageId && !fSetParentId) ) uOpenFlags |= VD_OPEN_FLAGS_READONLY; /* Open shareable medium with the appropriate flags */ if (m->type == MediumType_Shareable) uOpenFlags |= VD_OPEN_FLAGS_SHAREABLE; /* Lock the medium, which makes the behavior much more consistent, must be * done before dropping the object lock and setting queryInfoRunning. */ ComPtr pToken; if (uOpenFlags & (VD_OPEN_FLAGS_READONLY | VD_OPEN_FLAGS_SHAREABLE)) rc = LockRead(pToken.asOutParam()); else rc = LockWrite(pToken.asOutParam()); if (FAILED(rc)) return rc; /* Copies of the input state fields which are not read-only, * as we're dropping the lock. CAUTION: be extremely careful what * you do with the contents of this medium object, as you will * create races if there are concurrent changes. */ Utf8Str format(m->strFormat); Utf8Str location(m->strLocationFull); ComObjPtr formatObj = m->formatObj; /* "Output" values which can't be set because the lock isn't held * at the time the values are determined. */ Guid mediumId = m->id; uint64_t mediumSize = 0; uint64_t mediumLogicalSize = 0; /* Flag whether a base image has a non-zero parent UUID and thus * need repairing after it was closed again. */ bool fRepairImageZeroParentUuid = false; ComObjPtr pVirtualBox = m->pVirtualBox; /* must be set before leaving the object lock the first time */ m->queryInfoRunning = true; /* must leave object lock now, because a lock from a higher lock class * is needed and also a lengthy operation is coming */ alock.release(); autoCaller.release(); /* Note that taking the queryInfoSem after leaving the object lock above * can lead to short spinning of the loops waiting for i_queryInfo() to * complete. This is unavoidable since the other order causes a lock order * violation: here it would be requesting the object lock (at the beginning * of the method), then queryInfoSem, and below the other way round. */ AutoWriteLock qlock(m->queryInfoSem COMMA_LOCKVAL_SRC_POS); /* take the opportunity to have a media tree lock, released initially */ Assert(!isWriteLockOnCurrentThread()); Assert(!pVirtualBox->i_getMediaTreeLockHandle().isWriteLockOnCurrentThread()); AutoWriteLock treeLock(pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); treeLock.release(); /* re-take the caller, but not the object lock, to keep uninit away */ autoCaller.add(); if (FAILED(autoCaller.rc())) { m->queryInfoRunning = false; return autoCaller.rc(); } try { /* skip accessibility checks for host drives */ if (m->hostDrive) { success = true; throw S_OK; } PVBOXHDD hdd; vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); try { /** @todo This kind of opening of media is assuming that diff * media can be opened as base media. Should be documented that * it must work for all medium format backends. */ vrc = VDOpen(hdd, format.c_str(), location.c_str(), uOpenFlags | m->uOpenFlagsDef, m->vdImageIfaces); if (RT_FAILURE(vrc)) { lastAccessError = Utf8StrFmt(tr("Could not open the medium '%s'%s"), location.c_str(), i_vdError(vrc).c_str()); throw S_OK; } if (formatObj->i_getCapabilities() & MediumFormatCapabilities_Uuid) { /* Modify the UUIDs if necessary. The associated fields are * not modified by other code, so no need to copy. */ if (fSetImageId) { alock.acquire(); vrc = VDSetUuid(hdd, 0, m->uuidImage.raw()); alock.release(); if (RT_FAILURE(vrc)) { lastAccessError = Utf8StrFmt(tr("Could not update the UUID of medium '%s'%s"), location.c_str(), i_vdError(vrc).c_str()); throw S_OK; } mediumId = m->uuidImage; } if (fSetParentId) { alock.acquire(); vrc = VDSetParentUuid(hdd, 0, m->uuidParentImage.raw()); alock.release(); if (RT_FAILURE(vrc)) { lastAccessError = Utf8StrFmt(tr("Could not update the parent UUID of medium '%s'%s"), location.c_str(), i_vdError(vrc).c_str()); throw S_OK; } } /* zap the information, these are no long-term members */ alock.acquire(); unconst(m->uuidImage).clear(); unconst(m->uuidParentImage).clear(); alock.release(); /* check the UUID */ RTUUID uuid; vrc = VDGetUuid(hdd, 0, &uuid); ComAssertRCThrow(vrc, E_FAIL); if (isImport) { mediumId = uuid; if (mediumId.isZero() && (m->hddOpenMode == OpenReadOnly)) // only when importing a VDMK that has no UUID, create one in memory mediumId.create(); } else { Assert(!mediumId.isZero()); if (mediumId != uuid) { /** @todo r=klaus this always refers to VirtualBox.xml as the medium registry, even for new VMs */ lastAccessError = Utf8StrFmt( tr("UUID {%RTuuid} of the medium '%s' does not match the value {%RTuuid} stored in the media registry ('%s')"), &uuid, location.c_str(), mediumId.raw(), pVirtualBox->i_settingsFilePath().c_str()); throw S_OK; } } } else { /* the backend does not support storing UUIDs within the * underlying storage so use what we store in XML */ if (fSetImageId) { /* set the UUID if an API client wants to change it */ alock.acquire(); mediumId = m->uuidImage; alock.release(); } else if (isImport) { /* generate an UUID for an imported UUID-less medium */ mediumId.create(); } } /* set the image uuid before the below parent uuid handling code * might place it somewhere in the media tree, so that the medium * UUID is valid at this point */ alock.acquire(); if (isImport || fSetImageId) unconst(m->id) = mediumId; alock.release(); /* get the medium variant */ unsigned uImageFlags; vrc = VDGetImageFlags(hdd, 0, &uImageFlags); ComAssertRCThrow(vrc, E_FAIL); alock.acquire(); m->variant = (MediumVariant_T)uImageFlags; alock.release(); /* check/get the parent uuid and update corresponding state */ if (uImageFlags & VD_IMAGE_FLAGS_DIFF) { RTUUID parentId; vrc = VDGetParentUuid(hdd, 0, &parentId); ComAssertRCThrow(vrc, E_FAIL); /* streamOptimized VMDK images are only accepted as base * images, as this allows automatic repair of OVF appliances. * Since such images don't support random writes they will not * be created for diff images. Only an overly smart user might * manually create this case. Too bad for him. */ if ( (isImport || fSetParentId) && !(uImageFlags & VD_VMDK_IMAGE_FLAGS_STREAM_OPTIMIZED)) { /* the parent must be known to us. Note that we freely * call locking methods of mVirtualBox and parent, as all * relevant locks must be already held. There may be no * concurrent access to the just opened medium on other * threads yet (and init() will fail if this method reports * MediumState_Inaccessible) */ ComObjPtr pParent; if (RTUuidIsNull(&parentId)) rc = VBOX_E_OBJECT_NOT_FOUND; else rc = pVirtualBox->i_findHardDiskById(Guid(parentId), false /* aSetError */, &pParent); if (FAILED(rc)) { if (fSetImageId && !fSetParentId) { /* If the image UUID gets changed for an existing * image then the parent UUID can be stale. In such * cases clear the parent information. The parent * information may/will be re-set later if the * API client wants to adjust a complete medium * hierarchy one by one. */ rc = S_OK; alock.acquire(); RTUuidClear(&parentId); vrc = VDSetParentUuid(hdd, 0, &parentId); alock.release(); ComAssertRCThrow(vrc, E_FAIL); } else { lastAccessError = Utf8StrFmt(tr("Parent medium with UUID {%RTuuid} of the medium '%s' is not found in the media registry ('%s')"), &parentId, location.c_str(), pVirtualBox->i_settingsFilePath().c_str()); throw S_OK; } } /* must drop the caller before taking the tree lock */ autoCaller.release(); /* we set mParent & children() */ treeLock.acquire(); autoCaller.add(); if (FAILED(autoCaller.rc())) throw autoCaller.rc(); if (m->pParent) i_deparent(); i_setParent(pParent); treeLock.release(); } else { /* must drop the caller before taking the tree lock */ autoCaller.release(); /* we access mParent */ treeLock.acquire(); autoCaller.add(); if (FAILED(autoCaller.rc())) throw autoCaller.rc(); /* check that parent UUIDs match. Note that there's no need * for the parent's AutoCaller (our lifetime is bound to * it) */ if (m->pParent.isNull()) { /* Due to a bug in VDCopy() in VirtualBox 3.0.0-3.0.14 * and 3.1.0-3.1.8 there are base images out there * which have a non-zero parent UUID. No point in * complaining about them, instead automatically * repair the problem. Later we can bring back the * error message, but we should wait until really * most users have repaired their images, either with * VBoxFixHdd or this way. */ #if 1 fRepairImageZeroParentUuid = true; #else /* 0 */ lastAccessError = Utf8StrFmt( tr("Medium type of '%s' is differencing but it is not associated with any parent medium in the media registry ('%s')"), location.c_str(), pVirtualBox->settingsFilePath().c_str()); treeLock.release(); throw S_OK; #endif /* 0 */ } { autoCaller.release(); AutoReadLock parentLock(m->pParent COMMA_LOCKVAL_SRC_POS); autoCaller.add(); if (FAILED(autoCaller.rc())) throw autoCaller.rc(); if ( !fRepairImageZeroParentUuid && m->pParent->i_getState() != MediumState_Inaccessible && m->pParent->i_getId() != parentId) { /** @todo r=klaus this always refers to VirtualBox.xml as the medium registry, even for new VMs */ lastAccessError = Utf8StrFmt( tr("Parent UUID {%RTuuid} of the medium '%s' does not match UUID {%RTuuid} of its parent medium stored in the media registry ('%s')"), &parentId, location.c_str(), m->pParent->i_getId().raw(), pVirtualBox->i_settingsFilePath().c_str()); parentLock.release(); treeLock.release(); throw S_OK; } } /// @todo NEWMEDIA what to do if the parent is not /// accessible while the diff is? Probably nothing. The /// real code will detect the mismatch anyway. treeLock.release(); } } mediumSize = VDGetFileSize(hdd, 0); mediumLogicalSize = VDGetSize(hdd, 0); success = true; } catch (HRESULT aRC) { rc = aRC; } vrc = VDDestroy(hdd); if (RT_FAILURE(vrc)) { lastAccessError = Utf8StrFmt(tr("Could not update and close the medium '%s'%s"), location.c_str(), i_vdError(vrc).c_str()); success = false; throw S_OK; } } catch (HRESULT aRC) { rc = aRC; } autoCaller.release(); treeLock.acquire(); autoCaller.add(); if (FAILED(autoCaller.rc())) { m->queryInfoRunning = false; return autoCaller.rc(); } alock.acquire(); if (success) { m->size = mediumSize; m->logicalSize = mediumLogicalSize; m->strLastAccessError.setNull(); } else { m->strLastAccessError = lastAccessError; LogWarningFunc(("'%s' is not accessible (error='%s', rc=%Rhrc, vrc=%Rrc)\n", location.c_str(), m->strLastAccessError.c_str(), rc, vrc)); } /* Set the proper state according to the result of the check */ if (success) m->preLockState = MediumState_Created; else m->preLockState = MediumState_Inaccessible; /* unblock anyone waiting for the i_queryInfo results */ qlock.release(); m->queryInfoRunning = false; pToken->Abandon(); pToken.setNull(); if (FAILED(rc)) return rc; /* If this is a base image which incorrectly has a parent UUID set, * repair the image now by zeroing the parent UUID. This is only done * when we have structural information from a config file, on import * this is not possible. If someone would accidentally call openMedium * with a diff image before the base is registered this would destroy * the diff. Not acceptable. */ if (fRepairImageZeroParentUuid) { rc = LockWrite(pToken.asOutParam()); if (FAILED(rc)) return rc; alock.release(); try { PVBOXHDD hdd; vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); try { vrc = VDOpen(hdd, format.c_str(), location.c_str(), (uOpenFlags & ~VD_OPEN_FLAGS_READONLY) | m->uOpenFlagsDef, m->vdImageIfaces); if (RT_FAILURE(vrc)) throw S_OK; RTUUID zeroParentUuid; RTUuidClear(&zeroParentUuid); vrc = VDSetParentUuid(hdd, 0, &zeroParentUuid); ComAssertRCThrow(vrc, E_FAIL); } catch (HRESULT aRC) { rc = aRC; } VDDestroy(hdd); } catch (HRESULT aRC) { rc = aRC; } pToken->Abandon(); pToken.setNull(); if (FAILED(rc)) return rc; } return rc; } /** * Performs extra checks if the medium can be closed and returns S_OK in * this case. Otherwise, returns a respective error message. Called by * Close() under the medium tree lock and the medium lock. * * @note Also reused by Medium::Reset(). * * @note Caller must hold the media tree write lock! */ HRESULT Medium::i_canClose() { Assert(m->pVirtualBox->i_getMediaTreeLockHandle().isWriteLockOnCurrentThread()); if (i_getChildren().size() != 0) return setError(VBOX_E_OBJECT_IN_USE, tr("Cannot close medium '%s' because it has %d child media"), m->strLocationFull.c_str(), i_getChildren().size()); return S_OK; } /** * Unregisters this medium with mVirtualBox. Called by close() under the medium tree lock. * * @note Caller must have locked the media tree lock for writing! */ HRESULT Medium::i_unregisterWithVirtualBox() { /* Note that we need to de-associate ourselves from the parent to let * unregisterMedium() properly save the registry */ /* we modify mParent and access children */ Assert(m->pVirtualBox->i_getMediaTreeLockHandle().isWriteLockOnCurrentThread()); Medium *pParentBackup = m->pParent; AssertReturn(i_getChildren().size() == 0, E_FAIL); if (m->pParent) i_deparent(); HRESULT rc = m->pVirtualBox->i_unregisterMedium(this); if (FAILED(rc)) { if (pParentBackup) { // re-associate with the parent as we are still relatives in the registry m->pParent = pParentBackup; m->pParent->m->llChildren.push_back(this); } } return rc; } /** * Like SetProperty but do not trigger a settings store. Only for internal use! */ HRESULT Medium::i_setPropertyDirect(const Utf8Str &aName, const Utf8Str &aValue) { AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); AutoWriteLock mlock(this COMMA_LOCKVAL_SRC_POS); switch (m->state) { case MediumState_Created: case MediumState_Inaccessible: break; default: return i_setStateError(); } m->mapProperties[aName] = aValue; return S_OK; } /** * Sets the extended error info according to the current media state. * * @note Must be called from under this object's write or read lock. */ HRESULT Medium::i_setStateError() { HRESULT rc = E_FAIL; switch (m->state) { case MediumState_NotCreated: { rc = setError(VBOX_E_INVALID_OBJECT_STATE, tr("Storage for the medium '%s' is not created"), m->strLocationFull.c_str()); break; } case MediumState_Created: { rc = setError(VBOX_E_INVALID_OBJECT_STATE, tr("Storage for the medium '%s' is already created"), m->strLocationFull.c_str()); break; } case MediumState_LockedRead: { rc = setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is locked for reading by another task"), m->strLocationFull.c_str()); break; } case MediumState_LockedWrite: { rc = setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is locked for writing by another task"), m->strLocationFull.c_str()); break; } case MediumState_Inaccessible: { /* be in sync with Console::powerUpThread() */ if (!m->strLastAccessError.isEmpty()) rc = setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is not accessible. %s"), m->strLocationFull.c_str(), m->strLastAccessError.c_str()); else rc = setError(VBOX_E_INVALID_OBJECT_STATE, tr("Medium '%s' is not accessible"), m->strLocationFull.c_str()); break; } case MediumState_Creating: { rc = setError(VBOX_E_INVALID_OBJECT_STATE, tr("Storage for the medium '%s' is being created"), m->strLocationFull.c_str()); break; } case MediumState_Deleting: { rc = setError(VBOX_E_INVALID_OBJECT_STATE, tr("Storage for the medium '%s' is being deleted"), m->strLocationFull.c_str()); break; } default: { AssertFailed(); break; } } return rc; } /** * Sets the value of m->strLocationFull. The given location must be a fully * qualified path; relative paths are not supported here. * * As a special exception, if the specified location is a file path that ends with '/' * then the file name part will be generated by this method automatically in the format * '{}.' where is a fresh UUID that this method will generate * and assign to this medium, and is the default extension for this * medium's storage format. Note that this procedure requires the media state to * be NotCreated and will return a failure otherwise. * * @param aLocation Location of the storage unit. If the location is a FS-path, * then it can be relative to the VirtualBox home directory. * @param aFormat Optional fallback format if it is an import and the format * cannot be determined. * * @note Must be called from under this object's write lock. */ HRESULT Medium::i_setLocation(const Utf8Str &aLocation, const Utf8Str &aFormat /* = Utf8Str::Empty */) { AssertReturn(!aLocation.isEmpty(), E_FAIL); AutoCaller autoCaller(this); AssertComRCReturnRC(autoCaller.rc()); /* formatObj may be null only when initializing from an existing path and * no format is known yet */ AssertReturn( (!m->strFormat.isEmpty() && !m->formatObj.isNull()) || ( getObjectState().getState() == ObjectState::InInit && m->state != MediumState_NotCreated && m->id.isZero() && m->strFormat.isEmpty() && m->formatObj.isNull()), E_FAIL); /* are we dealing with a new medium constructed using the existing * location? */ bool isImport = m->strFormat.isEmpty(); if ( isImport || ( (m->formatObj->i_getCapabilities() & MediumFormatCapabilities_File) && !m->hostDrive)) { Guid id; Utf8Str locationFull(aLocation); if (m->state == MediumState_NotCreated) { /* must be a file (formatObj must be already known) */ Assert(m->formatObj->i_getCapabilities() & MediumFormatCapabilities_File); if (RTPathFilename(aLocation.c_str()) == NULL) { /* no file name is given (either an empty string or ends with a * slash), generate a new UUID + file name if the state allows * this */ ComAssertMsgRet(!m->formatObj->i_getFileExtensions().empty(), ("Must be at least one extension if it is MediumFormatCapabilities_File\n"), E_FAIL); Utf8Str strExt = m->formatObj->i_getFileExtensions().front(); ComAssertMsgRet(!strExt.isEmpty(), ("Default extension must not be empty\n"), E_FAIL); id.create(); locationFull = Utf8StrFmt("%s{%RTuuid}.%s", aLocation.c_str(), id.raw(), strExt.c_str()); } } // we must always have full paths now (if it refers to a file) if ( ( m->formatObj.isNull() || m->formatObj->i_getCapabilities() & MediumFormatCapabilities_File) && !RTPathStartsWithRoot(locationFull.c_str())) return setError(VBOX_E_FILE_ERROR, tr("The given path '%s' is not fully qualified"), locationFull.c_str()); /* detect the backend from the storage unit if importing */ if (isImport) { VDTYPE enmType = VDTYPE_INVALID; char *backendName = NULL; int vrc = VINF_SUCCESS; /* is it a file? */ { RTFILE file; vrc = RTFileOpen(&file, locationFull.c_str(), RTFILE_O_READ | RTFILE_O_OPEN | RTFILE_O_DENY_NONE); if (RT_SUCCESS(vrc)) RTFileClose(file); } if (RT_SUCCESS(vrc)) { vrc = VDGetFormat(NULL /* pVDIfsDisk */, NULL /* pVDIfsImage */, locationFull.c_str(), &backendName, &enmType); } else if ( vrc != VERR_FILE_NOT_FOUND && vrc != VERR_PATH_NOT_FOUND && vrc != VERR_ACCESS_DENIED && locationFull != aLocation) { /* assume it's not a file, restore the original location */ locationFull = aLocation; vrc = VDGetFormat(NULL /* pVDIfsDisk */, NULL /* pVDIfsImage */, locationFull.c_str(), &backendName, &enmType); } if (RT_FAILURE(vrc)) { if (vrc == VERR_ACCESS_DENIED) return setError(VBOX_E_FILE_ERROR, tr("Permission problem accessing the file for the medium '%s' (%Rrc)"), locationFull.c_str(), vrc); else if (vrc == VERR_FILE_NOT_FOUND || vrc == VERR_PATH_NOT_FOUND) return setError(VBOX_E_FILE_ERROR, tr("Could not find file for the medium '%s' (%Rrc)"), locationFull.c_str(), vrc); else if (aFormat.isEmpty()) return setError(VBOX_E_IPRT_ERROR, tr("Could not get the storage format of the medium '%s' (%Rrc)"), locationFull.c_str(), vrc); else { HRESULT rc = i_setFormat(aFormat); /* setFormat() must not fail since we've just used the backend so * the format object must be there */ AssertComRCReturnRC(rc); } } else if ( enmType == VDTYPE_INVALID || m->devType != i_convertToDeviceType(enmType)) { /* * The user tried to use a image as a device which is not supported * by the backend. */ return setError(E_FAIL, tr("The medium '%s' can't be used as the requested device type"), locationFull.c_str()); } else { ComAssertRet(backendName != NULL && *backendName != '\0', E_FAIL); HRESULT rc = i_setFormat(backendName); RTStrFree(backendName); /* setFormat() must not fail since we've just used the backend so * the format object must be there */ AssertComRCReturnRC(rc); } } m->strLocationFull = locationFull; /* is it still a file? */ if ( (m->formatObj->i_getCapabilities() & MediumFormatCapabilities_File) && (m->state == MediumState_NotCreated) ) /* assign a new UUID (this UUID will be used when calling * VDCreateBase/VDCreateDiff as a wanted UUID). Note that we * also do that if we didn't generate it to make sure it is * either generated by us or reset to null */ unconst(m->id) = id; } else m->strLocationFull = aLocation; return S_OK; } /** * Checks that the format ID is valid and sets it on success. * * Note that this method will caller-reference the format object on success! * This reference must be released somewhere to let the MediumFormat object be * uninitialized. * * @note Must be called from under this object's write lock. */ HRESULT Medium::i_setFormat(const Utf8Str &aFormat) { /* get the format object first */ { SystemProperties *pSysProps = m->pVirtualBox->i_getSystemProperties(); AutoReadLock propsLock(pSysProps COMMA_LOCKVAL_SRC_POS); unconst(m->formatObj) = pSysProps->i_mediumFormat(aFormat); if (m->formatObj.isNull()) return setError(E_INVALIDARG, tr("Invalid medium storage format '%s'"), aFormat.c_str()); /* get properties (preinsert them as keys in the map). Note that the * map doesn't grow over the object life time since the set of * properties is meant to be constant. */ Assert(m->mapProperties.empty()); for (MediumFormat::PropertyArray::const_iterator it = m->formatObj->i_getProperties().begin(); it != m->formatObj->i_getProperties().end(); ++it) { m->mapProperties.insert(std::make_pair(it->strName, Utf8Str::Empty)); } } unconst(m->strFormat) = aFormat; return S_OK; } /** * Converts the Medium device type to the VD type. */ VDTYPE Medium::i_convertDeviceType() { VDTYPE enmType; switch (m->devType) { case DeviceType_HardDisk: enmType = VDTYPE_HDD; break; case DeviceType_DVD: enmType = VDTYPE_DVD; break; case DeviceType_Floppy: enmType = VDTYPE_FLOPPY; break; default: ComAssertFailedRet(VDTYPE_INVALID); } return enmType; } /** * Converts from the VD type to the medium type. */ DeviceType_T Medium::i_convertToDeviceType(VDTYPE enmType) { DeviceType_T devType; switch (enmType) { case VDTYPE_HDD: devType = DeviceType_HardDisk; break; case VDTYPE_DVD: devType = DeviceType_DVD; break; case VDTYPE_FLOPPY: devType = DeviceType_Floppy; break; default: ComAssertFailedRet(DeviceType_Null); } return devType; } /** * Internal method which checks whether a property name is for a filter plugin. */ bool Medium::i_isPropertyForFilter(const com::Utf8Str &aName) { /* If the name contains "/" use the part before as a filter name and lookup the filter. */ size_t offSlash; if ((offSlash = aName.find("/", 0)) != aName.npos) { com::Utf8Str strFilter; com::Utf8Str strKey; HRESULT rc = strFilter.assignEx(aName, 0, offSlash); if (FAILED(rc)) return false; rc = strKey.assignEx(aName, offSlash + 1, aName.length() - offSlash - 1); /* Skip slash */ if (FAILED(rc)) return false; VDFILTERINFO FilterInfo; int vrc = VDFilterInfoOne(strFilter.c_str(), &FilterInfo); if (RT_SUCCESS(vrc)) { /* Check that the property exists. */ PCVDCONFIGINFO paConfig = FilterInfo.paConfigInfo; while (paConfig->pszKey) { if (strKey.equals(paConfig->pszKey)) return true; paConfig++; } } } return false; } /** * Returns the last error message collected by the i_vdErrorCall callback and * resets it. * * The error message is returned prepended with a dot and a space, like this: * * ". (%Rrc)" * * to make it easily appendable to a more general error message. The @c %Rrc * format string is given @a aVRC as an argument. * * If there is no last error message collected by i_vdErrorCall or if it is a * null or empty string, then this function returns the following text: * * " (%Rrc)" * * * @note Doesn't do any object locking; it is assumed that the caller makes sure * the callback isn't called by more than one thread at a time. * * @param aVRC VBox error code to use when no error message is provided. */ Utf8Str Medium::i_vdError(int aVRC) { Utf8Str error; if (m->vdError.isEmpty()) error = Utf8StrFmt(" (%Rrc)", aVRC); else error = Utf8StrFmt(".\n%s", m->vdError.c_str()); m->vdError.setNull(); return error; } /** * Error message callback. * * Puts the reported error message to the m->vdError field. * * @note Doesn't do any object locking; it is assumed that the caller makes sure * the callback isn't called by more than one thread at a time. * * @param pvUser The opaque data passed on container creation. * @param rc The VBox error code. * @param RT_SRC_POS_DECL Use RT_SRC_POS. * @param pszFormat Error message format string. * @param va Error message arguments. */ /*static*/ DECLCALLBACK(void) Medium::i_vdErrorCall(void *pvUser, int rc, RT_SRC_POS_DECL, const char *pszFormat, va_list va) { NOREF(pszFile); NOREF(iLine); NOREF(pszFunction); /* RT_SRC_POS_DECL */ Medium *that = static_cast(pvUser); AssertReturnVoid(that != NULL); if (that->m->vdError.isEmpty()) that->m->vdError = Utf8StrFmt("%s (%Rrc)", Utf8Str(pszFormat, va).c_str(), rc); else that->m->vdError = Utf8StrFmt("%s.\n%s (%Rrc)", that->m->vdError.c_str(), Utf8Str(pszFormat, va).c_str(), rc); } /* static */ DECLCALLBACK(bool) Medium::i_vdConfigAreKeysValid(void *pvUser, const char * /* pszzValid */) { Medium *that = static_cast(pvUser); AssertReturn(that != NULL, false); /* we always return true since the only keys we have are those found in * VDBACKENDINFO */ return true; } /* static */ DECLCALLBACK(int) Medium::i_vdConfigQuerySize(void *pvUser, const char *pszName, size_t *pcbValue) { AssertReturn(VALID_PTR(pcbValue), VERR_INVALID_POINTER); Medium *that = static_cast(pvUser); AssertReturn(that != NULL, VERR_GENERAL_FAILURE); settings::StringsMap::const_iterator it = that->m->mapProperties.find(Utf8Str(pszName)); if (it == that->m->mapProperties.end()) return VERR_CFGM_VALUE_NOT_FOUND; /* we interpret null values as "no value" in Medium */ if (it->second.isEmpty()) return VERR_CFGM_VALUE_NOT_FOUND; *pcbValue = it->second.length() + 1 /* include terminator */; return VINF_SUCCESS; } /* static */ DECLCALLBACK(int) Medium::i_vdConfigQuery(void *pvUser, const char *pszName, char *pszValue, size_t cchValue) { AssertReturn(VALID_PTR(pszValue), VERR_INVALID_POINTER); Medium *that = static_cast(pvUser); AssertReturn(that != NULL, VERR_GENERAL_FAILURE); settings::StringsMap::const_iterator it = that->m->mapProperties.find(Utf8Str(pszName)); if (it == that->m->mapProperties.end()) return VERR_CFGM_VALUE_NOT_FOUND; /* we interpret null values as "no value" in Medium */ if (it->second.isEmpty()) return VERR_CFGM_VALUE_NOT_FOUND; const Utf8Str &value = it->second; if (value.length() >= cchValue) return VERR_CFGM_NOT_ENOUGH_SPACE; memcpy(pszValue, value.c_str(), value.length() + 1); return VINF_SUCCESS; } DECLCALLBACK(int) Medium::i_vdTcpSocketCreate(uint32_t fFlags, PVDSOCKET pSock) { PVDSOCKETINT pSocketInt = NULL; if ((fFlags & VD_INTERFACETCPNET_CONNECT_EXTENDED_SELECT) != 0) return VERR_NOT_SUPPORTED; pSocketInt = (PVDSOCKETINT)RTMemAllocZ(sizeof(VDSOCKETINT)); if (!pSocketInt) return VERR_NO_MEMORY; pSocketInt->hSocket = NIL_RTSOCKET; *pSock = pSocketInt; return VINF_SUCCESS; } DECLCALLBACK(int) Medium::i_vdTcpSocketDestroy(VDSOCKET Sock) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; if (pSocketInt->hSocket != NIL_RTSOCKET) RTTcpClientCloseEx(pSocketInt->hSocket, false /*fGracefulShutdown*/); RTMemFree(pSocketInt); return VINF_SUCCESS; } DECLCALLBACK(int) Medium::i_vdTcpClientConnect(VDSOCKET Sock, const char *pszAddress, uint32_t uPort) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; return RTTcpClientConnect(pszAddress, uPort, &pSocketInt->hSocket); } DECLCALLBACK(int) Medium::i_vdTcpClientClose(VDSOCKET Sock) { int rc = VINF_SUCCESS; PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; rc = RTTcpClientCloseEx(pSocketInt->hSocket, false /*fGracefulShutdown*/); pSocketInt->hSocket = NIL_RTSOCKET; return rc; } DECLCALLBACK(bool) Medium::i_vdTcpIsClientConnected(VDSOCKET Sock) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; return pSocketInt->hSocket != NIL_RTSOCKET; } DECLCALLBACK(int) Medium::i_vdTcpSelectOne(VDSOCKET Sock, RTMSINTERVAL cMillies) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; return RTTcpSelectOne(pSocketInt->hSocket, cMillies); } DECLCALLBACK(int) Medium::i_vdTcpRead(VDSOCKET Sock, void *pvBuffer, size_t cbBuffer, size_t *pcbRead) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; return RTTcpRead(pSocketInt->hSocket, pvBuffer, cbBuffer, pcbRead); } DECLCALLBACK(int) Medium::i_vdTcpWrite(VDSOCKET Sock, const void *pvBuffer, size_t cbBuffer) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; return RTTcpWrite(pSocketInt->hSocket, pvBuffer, cbBuffer); } DECLCALLBACK(int) Medium::i_vdTcpSgWrite(VDSOCKET Sock, PCRTSGBUF pSgBuf) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; return RTTcpSgWrite(pSocketInt->hSocket, pSgBuf); } DECLCALLBACK(int) Medium::i_vdTcpFlush(VDSOCKET Sock) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; return RTTcpFlush(pSocketInt->hSocket); } DECLCALLBACK(int) Medium::i_vdTcpSetSendCoalescing(VDSOCKET Sock, bool fEnable) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; return RTTcpSetSendCoalescing(pSocketInt->hSocket, fEnable); } DECLCALLBACK(int) Medium::i_vdTcpGetLocalAddress(VDSOCKET Sock, PRTNETADDR pAddr) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; return RTTcpGetLocalAddress(pSocketInt->hSocket, pAddr); } DECLCALLBACK(int) Medium::i_vdTcpGetPeerAddress(VDSOCKET Sock, PRTNETADDR pAddr) { PVDSOCKETINT pSocketInt = (PVDSOCKETINT)Sock; return RTTcpGetPeerAddress(pSocketInt->hSocket, pAddr); } /** * Starts a new thread driven by the appropriate Medium::Task::handler() method. * * @note When the task is executed by this method, IProgress::notifyComplete() * is automatically called for the progress object associated with this * task when the task is finished to signal the operation completion for * other threads asynchronously waiting for it. */ HRESULT Medium::i_startThread(Medium::Task *pTask) { #ifdef VBOX_WITH_MAIN_LOCK_VALIDATION /* Extreme paranoia: The calling thread should not hold the medium * tree lock or any medium lock. Since there is no separate lock class * for medium objects be even more strict: no other object locks. */ Assert(!AutoLockHoldsLocksInClass(LOCKCLASS_LISTOFMEDIA)); Assert(!AutoLockHoldsLocksInClass(getLockingClass())); #endif /// @todo use a more descriptive task name int vrc = RTThreadCreate(NULL, Medium::Task::fntMediumTask, pTask, 0, RTTHREADTYPE_MAIN_HEAVY_WORKER, 0, "Medium::Task"); if (RT_FAILURE(vrc)) { delete pTask; return setError(E_FAIL, "Could not create Medium::Task thread (%Rrc)\n", vrc); } return S_OK; } /** * Runs Medium::Task::handler() on the current thread instead of creating * a new one. * * This call implies that it is made on another temporary thread created for * some asynchronous task. Avoid calling it from a normal thread since the task * operations are potentially lengthy and will block the calling thread in this * case. * * @note When the task is executed by this method, IProgress::notifyComplete() * is not called for the progress object associated with this task when * the task is finished. Instead, the result of the operation is returned * by this method directly and it's the caller's responsibility to * complete the progress object in this case. */ HRESULT Medium::i_runNow(Medium::Task *pTask) { #ifdef VBOX_WITH_MAIN_LOCK_VALIDATION /* Extreme paranoia: The calling thread should not hold the medium * tree lock or any medium lock. Since there is no separate lock class * for medium objects be even more strict: no other object locks. */ Assert(!AutoLockHoldsLocksInClass(LOCKCLASS_LISTOFMEDIA)); Assert(!AutoLockHoldsLocksInClass(getLockingClass())); #endif /* NIL_RTTHREAD indicates synchronous call. */ return (HRESULT)Medium::Task::fntMediumTask(NIL_RTTHREAD, pTask); } /** * Implementation code for the "create base" task. * * This only gets started from Medium::CreateBaseStorage() and always runs * asynchronously. As a result, we always save the VirtualBox.xml file when * we're done here. * * @param task * @return */ HRESULT Medium::i_taskCreateBaseHandler(Medium::CreateBaseTask &task) { HRESULT rc = S_OK; /* these parameters we need after creation */ uint64_t size = 0, logicalSize = 0; MediumVariant_T variant = MediumVariant_Standard; bool fGenerateUuid = false; try { AutoWriteLock thisLock(this COMMA_LOCKVAL_SRC_POS); /* The object may request a specific UUID (through a special form of * the setLocation() argument). Otherwise we have to generate it */ Guid id = m->id; fGenerateUuid = id.isZero(); if (fGenerateUuid) { id.create(); /* VirtualBox::registerMedium() will need UUID */ unconst(m->id) = id; } Utf8Str format(m->strFormat); Utf8Str location(m->strLocationFull); uint64_t capabilities = m->formatObj->i_getCapabilities(); ComAssertThrow(capabilities & ( MediumFormatCapabilities_CreateFixed | MediumFormatCapabilities_CreateDynamic), E_FAIL); Assert(m->state == MediumState_Creating); PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); /* unlock before the potentially lengthy operation */ thisLock.release(); try { /* ensure the directory exists */ if (capabilities & MediumFormatCapabilities_File) { rc = VirtualBox::i_ensureFilePathExists(location, !(task.mVariant & MediumVariant_NoCreateDir) /* fCreate */); if (FAILED(rc)) throw rc; } VDGEOMETRY geo = { 0, 0, 0 }; /* auto-detect */ vrc = VDCreateBase(hdd, format.c_str(), location.c_str(), task.mSize, task.mVariant & ~MediumVariant_NoCreateDir, NULL, &geo, &geo, id.raw(), VD_OPEN_FLAGS_NORMAL | m->uOpenFlagsDef, m->vdImageIfaces, task.mVDOperationIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not create the medium storage unit '%s'%s"), location.c_str(), i_vdError(vrc).c_str()); size = VDGetFileSize(hdd, 0); logicalSize = VDGetSize(hdd, 0); unsigned uImageFlags; vrc = VDGetImageFlags(hdd, 0, &uImageFlags); if (RT_SUCCESS(vrc)) variant = (MediumVariant_T)uImageFlags; } catch (HRESULT aRC) { rc = aRC; } VDDestroy(hdd); } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { /* register with mVirtualBox as the last step and move to * Created state only on success (leaving an orphan file is * better than breaking media registry consistency) */ AutoWriteLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); ComObjPtr pMedium; rc = m->pVirtualBox->i_registerMedium(this, &pMedium, DeviceType_HardDisk, treeLock); Assert(this == pMedium); } // re-acquire the lock before changing state AutoWriteLock thisLock(this COMMA_LOCKVAL_SRC_POS); if (SUCCEEDED(rc)) { m->state = MediumState_Created; m->size = size; m->logicalSize = logicalSize; m->variant = variant; thisLock.release(); i_markRegistriesModified(); if (task.isAsync()) { // in asynchronous mode, save settings now m->pVirtualBox->i_saveModifiedRegistries(); } } else { /* back to NotCreated on failure */ m->state = MediumState_NotCreated; /* reset UUID to prevent it from being reused next time */ if (fGenerateUuid) unconst(m->id).clear(); } return rc; } /** * Implementation code for the "create diff" task. * * This task always gets started from Medium::createDiffStorage() and can run * synchronously or asynchronously depending on the "wait" parameter passed to * that function. If we run synchronously, the caller expects the medium * registry modification to be set before returning; otherwise (in asynchronous * mode), we save the settings ourselves. * * @param task * @return */ HRESULT Medium::i_taskCreateDiffHandler(Medium::CreateDiffTask &task) { HRESULT rcTmp = S_OK; const ComObjPtr &pTarget = task.mTarget; uint64_t size = 0, logicalSize = 0; MediumVariant_T variant = MediumVariant_Standard; bool fGenerateUuid = false; try { /* Lock both in {parent,child} order. */ AutoMultiWriteLock2 mediaLock(this, pTarget COMMA_LOCKVAL_SRC_POS); /* The object may request a specific UUID (through a special form of * the setLocation() argument). Otherwise we have to generate it */ Guid targetId = pTarget->m->id; fGenerateUuid = targetId.isZero(); if (fGenerateUuid) { targetId.create(); /* VirtualBox::registerMedium() will need UUID */ unconst(pTarget->m->id) = targetId; } Guid id = m->id; Utf8Str targetFormat(pTarget->m->strFormat); Utf8Str targetLocation(pTarget->m->strLocationFull); uint64_t capabilities = pTarget->m->formatObj->i_getCapabilities(); ComAssertThrow(capabilities & MediumFormatCapabilities_CreateDynamic, E_FAIL); Assert(pTarget->m->state == MediumState_Creating); Assert(m->state == MediumState_LockedRead); PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); /* the two media are now protected by their non-default states; * unlock the media before the potentially lengthy operation */ mediaLock.release(); try { /* Open all media in the target chain but the last. */ MediumLockList::Base::const_iterator targetListBegin = task.mpMediumLockList->GetBegin(); MediumLockList::Base::const_iterator targetListEnd = task.mpMediumLockList->GetEnd(); for (MediumLockList::Base::const_iterator it = targetListBegin; it != targetListEnd; ++it) { const MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); /* Skip over the target diff medium */ if (pMedium->m->state == MediumState_Creating) continue; /* sanity check */ Assert(pMedium->m->state == MediumState_LockedRead); /* Open all media in appropriate mode. */ vrc = VDOpen(hdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), VD_OPEN_FLAGS_READONLY | VD_OPEN_FLAGS_INFO | m->uOpenFlagsDef, pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not open the medium storage unit '%s'%s"), pMedium->m->strLocationFull.c_str(), i_vdError(vrc).c_str()); } /* ensure the target directory exists */ if (capabilities & MediumFormatCapabilities_File) { HRESULT rc = VirtualBox::i_ensureFilePathExists(targetLocation, !(task.mVariant & MediumVariant_NoCreateDir) /* fCreate */); if (FAILED(rc)) throw rc; } vrc = VDCreateDiff(hdd, targetFormat.c_str(), targetLocation.c_str(), (task.mVariant & ~MediumVariant_NoCreateDir) | VD_IMAGE_FLAGS_DIFF, NULL, targetId.raw(), id.raw(), VD_OPEN_FLAGS_NORMAL | m->uOpenFlagsDef, pTarget->m->vdImageIfaces, task.mVDOperationIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not create the differencing medium storage unit '%s'%s"), targetLocation.c_str(), i_vdError(vrc).c_str()); size = VDGetFileSize(hdd, VD_LAST_IMAGE); logicalSize = VDGetSize(hdd, VD_LAST_IMAGE); unsigned uImageFlags; vrc = VDGetImageFlags(hdd, 0, &uImageFlags); if (RT_SUCCESS(vrc)) variant = (MediumVariant_T)uImageFlags; } catch (HRESULT aRC) { rcTmp = aRC; } VDDestroy(hdd); } catch (HRESULT aRC) { rcTmp = aRC; } MultiResult mrc(rcTmp); if (SUCCEEDED(mrc)) { AutoWriteLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); Assert(pTarget->m->pParent.isNull()); /* associate the child with the parent */ pTarget->m->pParent = this; m->llChildren.push_back(pTarget); /** @todo r=klaus neither target nor base() are locked, * potential race! */ /* diffs for immutable media are auto-reset by default */ pTarget->m->autoReset = (i_getBase()->m->type == MediumType_Immutable); /* register with mVirtualBox as the last step and move to * Created state only on success (leaving an orphan file is * better than breaking media registry consistency) */ ComObjPtr pMedium; mrc = m->pVirtualBox->i_registerMedium(pTarget, &pMedium, DeviceType_HardDisk, treeLock); Assert(pTarget == pMedium); if (FAILED(mrc)) /* break the parent association on failure to register */ i_deparent(); } AutoMultiWriteLock2 mediaLock(this, pTarget COMMA_LOCKVAL_SRC_POS); if (SUCCEEDED(mrc)) { pTarget->m->state = MediumState_Created; pTarget->m->size = size; pTarget->m->logicalSize = logicalSize; pTarget->m->variant = variant; } else { /* back to NotCreated on failure */ pTarget->m->state = MediumState_NotCreated; pTarget->m->autoReset = false; /* reset UUID to prevent it from being reused next time */ if (fGenerateUuid) unconst(pTarget->m->id).clear(); } // deregister the task registered in createDiffStorage() Assert(m->numCreateDiffTasks != 0); --m->numCreateDiffTasks; mediaLock.release(); i_markRegistriesModified(); if (task.isAsync()) { // in asynchronous mode, save settings now m->pVirtualBox->i_saveModifiedRegistries(); } /* Note that in sync mode, it's the caller's responsibility to * unlock the medium. */ return mrc; } /** * Implementation code for the "merge" task. * * This task always gets started from Medium::mergeTo() and can run * synchronously or asynchronously depending on the "wait" parameter passed to * that function. If we run synchronously, the caller expects the medium * registry modification to be set before returning; otherwise (in asynchronous * mode), we save the settings ourselves. * * @param task * @return */ HRESULT Medium::i_taskMergeHandler(Medium::MergeTask &task) { HRESULT rcTmp = S_OK; const ComObjPtr &pTarget = task.mTarget; try { PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); try { // Similar code appears in SessionMachine::onlineMergeMedium, so // if you make any changes below check whether they are applicable // in that context as well. unsigned uTargetIdx = VD_LAST_IMAGE; unsigned uSourceIdx = VD_LAST_IMAGE; /* Open all media in the chain. */ MediumLockList::Base::iterator lockListBegin = task.mpMediumLockList->GetBegin(); MediumLockList::Base::iterator lockListEnd = task.mpMediumLockList->GetEnd(); unsigned i = 0; for (MediumLockList::Base::iterator it = lockListBegin; it != lockListEnd; ++it) { MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); if (pMedium == this) uSourceIdx = i; else if (pMedium == pTarget) uTargetIdx = i; AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); /* * complex sanity (sane complexity) * * The current medium must be in the Deleting (medium is merged) * or LockedRead (parent medium) state if it is not the target. * If it is the target it must be in the LockedWrite state. */ Assert( ( pMedium != pTarget && ( pMedium->m->state == MediumState_Deleting || pMedium->m->state == MediumState_LockedRead)) || ( pMedium == pTarget && pMedium->m->state == MediumState_LockedWrite)); /* * Medium must be the target, in the LockedRead state * or Deleting state where it is not allowed to be attached * to a virtual machine. */ Assert( pMedium == pTarget || pMedium->m->state == MediumState_LockedRead || ( pMedium->m->backRefs.size() == 0 && pMedium->m->state == MediumState_Deleting)); /* The source medium must be in Deleting state. */ Assert( pMedium != this || pMedium->m->state == MediumState_Deleting); unsigned uOpenFlags = VD_OPEN_FLAGS_NORMAL; if ( pMedium->m->state == MediumState_LockedRead || pMedium->m->state == MediumState_Deleting) uOpenFlags = VD_OPEN_FLAGS_READONLY; if (pMedium->m->type == MediumType_Shareable) uOpenFlags |= VD_OPEN_FLAGS_SHAREABLE; /* Open the medium */ vrc = VDOpen(hdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), uOpenFlags | m->uOpenFlagsDef, pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw vrc; i++; } ComAssertThrow( uSourceIdx != VD_LAST_IMAGE && uTargetIdx != VD_LAST_IMAGE, E_FAIL); vrc = VDMerge(hdd, uSourceIdx, uTargetIdx, task.mVDOperationIfaces); if (RT_FAILURE(vrc)) throw vrc; /* update parent UUIDs */ if (!task.mfMergeForward) { /* we need to update UUIDs of all source's children * which cannot be part of the container at once so * add each one in there individually */ if (task.mpChildrenToReparent) { MediumLockList::Base::iterator childrenBegin = task.mpChildrenToReparent->GetBegin(); MediumLockList::Base::iterator childrenEnd = task.mpChildrenToReparent->GetEnd(); for (MediumLockList::Base::iterator it = childrenBegin; it != childrenEnd; ++it) { Medium *pMedium = it->GetMedium(); /* VD_OPEN_FLAGS_INFO since UUID is wrong yet */ vrc = VDOpen(hdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), VD_OPEN_FLAGS_INFO | m->uOpenFlagsDef, pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw vrc; vrc = VDSetParentUuid(hdd, VD_LAST_IMAGE, pTarget->m->id.raw()); if (RT_FAILURE(vrc)) throw vrc; vrc = VDClose(hdd, false /* fDelete */); if (RT_FAILURE(vrc)) throw vrc; } } } } catch (HRESULT aRC) { rcTmp = aRC; } catch (int aVRC) { rcTmp = setError(VBOX_E_FILE_ERROR, tr("Could not merge the medium '%s' to '%s'%s"), m->strLocationFull.c_str(), pTarget->m->strLocationFull.c_str(), i_vdError(aVRC).c_str()); } VDDestroy(hdd); } catch (HRESULT aRC) { rcTmp = aRC; } ErrorInfoKeeper eik; MultiResult mrc(rcTmp); HRESULT rc2; if (SUCCEEDED(mrc)) { /* all media but the target were successfully deleted by * VDMerge; reparent the last one and uninitialize deleted media. */ AutoWriteLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); if (task.mfMergeForward) { /* first, unregister the target since it may become a base * medium which needs re-registration */ rc2 = m->pVirtualBox->i_unregisterMedium(pTarget); AssertComRC(rc2); /* then, reparent it and disconnect the deleted branch at * both ends (chain->parent() is source's parent) */ pTarget->i_deparent(); pTarget->m->pParent = task.mParentForTarget; if (pTarget->m->pParent) { pTarget->m->pParent->m->llChildren.push_back(pTarget); i_deparent(); } /* then, register again */ ComObjPtr pMedium; rc2 = m->pVirtualBox->i_registerMedium(pTarget, &pMedium, DeviceType_HardDisk, treeLock); AssertComRC(rc2); } else { Assert(pTarget->i_getChildren().size() == 1); Medium *targetChild = pTarget->i_getChildren().front(); /* disconnect the deleted branch at the elder end */ targetChild->i_deparent(); /* reparent source's children and disconnect the deleted * branch at the younger end */ if (task.mpChildrenToReparent) { /* obey {parent,child} lock order */ AutoWriteLock sourceLock(this COMMA_LOCKVAL_SRC_POS); MediumLockList::Base::iterator childrenBegin = task.mpChildrenToReparent->GetBegin(); MediumLockList::Base::iterator childrenEnd = task.mpChildrenToReparent->GetEnd(); for (MediumLockList::Base::iterator it = childrenBegin; it != childrenEnd; ++it) { Medium *pMedium = it->GetMedium(); AutoWriteLock childLock(pMedium COMMA_LOCKVAL_SRC_POS); pMedium->i_deparent(); // removes pMedium from source pMedium->i_setParent(pTarget); } } } /* unregister and uninitialize all media removed by the merge */ MediumLockList::Base::iterator lockListBegin = task.mpMediumLockList->GetBegin(); MediumLockList::Base::iterator lockListEnd = task.mpMediumLockList->GetEnd(); for (MediumLockList::Base::iterator it = lockListBegin; it != lockListEnd; ) { MediumLock &mediumLock = *it; /* Create a real copy of the medium pointer, as the medium * lock deletion below would invalidate the referenced object. */ const ComObjPtr pMedium = mediumLock.GetMedium(); /* The target and all media not merged (readonly) are skipped */ if ( pMedium == pTarget || pMedium->m->state == MediumState_LockedRead) { ++it; continue; } rc2 = pMedium->m->pVirtualBox->i_unregisterMedium(pMedium); AssertComRC(rc2); /* now, uninitialize the deleted medium (note that * due to the Deleting state, uninit() will not touch * the parent-child relationship so we need to * uninitialize each disk individually) */ /* note that the operation initiator medium (which is * normally also the source medium) is a special case * -- there is one more caller added by Task to it which * we must release. Also, if we are in sync mode, the * caller may still hold an AutoCaller instance for it * and therefore we cannot uninit() it (it's therefore * the caller's responsibility) */ if (pMedium == this) { Assert(i_getChildren().size() == 0); Assert(m->backRefs.size() == 0); task.mMediumCaller.release(); } /* Delete the medium lock list entry, which also releases the * caller added by MergeChain before uninit() and updates the * iterator to point to the right place. */ rc2 = task.mpMediumLockList->RemoveByIterator(it); AssertComRC(rc2); if (task.isAsync() || pMedium != this) { treeLock.release(); pMedium->uninit(); treeLock.acquire(); } } } i_markRegistriesModified(); if (task.isAsync()) { // in asynchronous mode, save settings now eik.restore(); m->pVirtualBox->i_saveModifiedRegistries(); eik.fetch(); } if (FAILED(mrc)) { /* Here we come if either VDMerge() failed (in which case we * assume that it tried to do everything to make a further * retry possible -- e.g. not deleted intermediate media * and so on) or VirtualBox::saveRegistries() failed (where we * should have the original tree but with intermediate storage * units deleted by VDMerge()). We have to only restore states * (through the MergeChain dtor) unless we are run synchronously * in which case it's the responsibility of the caller as stated * in the mergeTo() docs. The latter also implies that we * don't own the merge chain, so release it in this case. */ if (task.isAsync()) i_cancelMergeTo(task.mpChildrenToReparent, task.mpMediumLockList); } return mrc; } /** * Implementation code for the "clone" task. * * This only gets started from Medium::CloneTo() and always runs asynchronously. * As a result, we always save the VirtualBox.xml file when we're done here. * * @param task * @return */ HRESULT Medium::i_taskCloneHandler(Medium::CloneTask &task) { HRESULT rcTmp = S_OK; const ComObjPtr &pTarget = task.mTarget; const ComObjPtr &pParent = task.mParent; bool fCreatingTarget = false; uint64_t size = 0, logicalSize = 0; MediumVariant_T variant = MediumVariant_Standard; bool fGenerateUuid = false; try { /* Lock all in {parent,child} order. The lock is also used as a * signal from the task initiator (which releases it only after * RTThreadCreate()) that we can start the job. */ AutoMultiWriteLock3 thisLock(this, pTarget, pParent COMMA_LOCKVAL_SRC_POS); fCreatingTarget = pTarget->m->state == MediumState_Creating; /* The object may request a specific UUID (through a special form of * the setLocation() argument). Otherwise we have to generate it */ Guid targetId = pTarget->m->id; fGenerateUuid = targetId.isZero(); if (fGenerateUuid) { targetId.create(); /* VirtualBox::registerMedium() will need UUID */ unconst(pTarget->m->id) = targetId; } PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); try { /* Open all media in the source chain. */ MediumLockList::Base::const_iterator sourceListBegin = task.mpSourceMediumLockList->GetBegin(); MediumLockList::Base::const_iterator sourceListEnd = task.mpSourceMediumLockList->GetEnd(); for (MediumLockList::Base::const_iterator it = sourceListBegin; it != sourceListEnd; ++it) { const MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); /* sanity check */ Assert(pMedium->m->state == MediumState_LockedRead); /** Open all media in read-only mode. */ vrc = VDOpen(hdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), VD_OPEN_FLAGS_READONLY | m->uOpenFlagsDef, pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not open the medium storage unit '%s'%s"), pMedium->m->strLocationFull.c_str(), i_vdError(vrc).c_str()); } Utf8Str targetFormat(pTarget->m->strFormat); Utf8Str targetLocation(pTarget->m->strLocationFull); uint64_t capabilities = pTarget->m->formatObj->i_getCapabilities(); Assert( pTarget->m->state == MediumState_Creating || pTarget->m->state == MediumState_LockedWrite); Assert(m->state == MediumState_LockedRead); Assert( pParent.isNull() || pParent->m->state == MediumState_LockedRead); /* unlock before the potentially lengthy operation */ thisLock.release(); /* ensure the target directory exists */ if (capabilities & MediumFormatCapabilities_File) { HRESULT rc = VirtualBox::i_ensureFilePathExists(targetLocation, !(task.mVariant & MediumVariant_NoCreateDir) /* fCreate */); if (FAILED(rc)) throw rc; } PVBOXHDD targetHdd; vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &targetHdd); ComAssertRCThrow(vrc, E_FAIL); try { /* Open all media in the target chain. */ MediumLockList::Base::const_iterator targetListBegin = task.mpTargetMediumLockList->GetBegin(); MediumLockList::Base::const_iterator targetListEnd = task.mpTargetMediumLockList->GetEnd(); for (MediumLockList::Base::const_iterator it = targetListBegin; it != targetListEnd; ++it) { const MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); /* If the target medium is not created yet there's no * reason to open it. */ if (pMedium == pTarget && fCreatingTarget) continue; AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); /* sanity check */ Assert( pMedium->m->state == MediumState_LockedRead || pMedium->m->state == MediumState_LockedWrite); unsigned uOpenFlags = VD_OPEN_FLAGS_NORMAL; if (pMedium->m->state != MediumState_LockedWrite) uOpenFlags = VD_OPEN_FLAGS_READONLY; if (pMedium->m->type == MediumType_Shareable) uOpenFlags |= VD_OPEN_FLAGS_SHAREABLE; /* Open all media in appropriate mode. */ vrc = VDOpen(targetHdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), uOpenFlags | m->uOpenFlagsDef, pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not open the medium storage unit '%s'%s"), pMedium->m->strLocationFull.c_str(), i_vdError(vrc).c_str()); } /** @todo r=klaus target isn't locked, race getting the state */ if (task.midxSrcImageSame == UINT32_MAX) { vrc = VDCopy(hdd, VD_LAST_IMAGE, targetHdd, targetFormat.c_str(), (fCreatingTarget) ? targetLocation.c_str() : (char *)NULL, false /* fMoveByRename */, 0 /* cbSize */, task.mVariant & ~MediumVariant_NoCreateDir, targetId.raw(), VD_OPEN_FLAGS_NORMAL | m->uOpenFlagsDef, NULL /* pVDIfsOperation */, pTarget->m->vdImageIfaces, task.mVDOperationIfaces); } else { vrc = VDCopyEx(hdd, VD_LAST_IMAGE, targetHdd, targetFormat.c_str(), (fCreatingTarget) ? targetLocation.c_str() : (char *)NULL, false /* fMoveByRename */, 0 /* cbSize */, task.midxSrcImageSame, task.midxDstImageSame, task.mVariant & ~MediumVariant_NoCreateDir, targetId.raw(), VD_OPEN_FLAGS_NORMAL | m->uOpenFlagsDef, NULL /* pVDIfsOperation */, pTarget->m->vdImageIfaces, task.mVDOperationIfaces); } if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not create the clone medium '%s'%s"), targetLocation.c_str(), i_vdError(vrc).c_str()); size = VDGetFileSize(targetHdd, VD_LAST_IMAGE); logicalSize = VDGetSize(targetHdd, VD_LAST_IMAGE); unsigned uImageFlags; vrc = VDGetImageFlags(targetHdd, 0, &uImageFlags); if (RT_SUCCESS(vrc)) variant = (MediumVariant_T)uImageFlags; } catch (HRESULT aRC) { rcTmp = aRC; } VDDestroy(targetHdd); } catch (HRESULT aRC) { rcTmp = aRC; } VDDestroy(hdd); } catch (HRESULT aRC) { rcTmp = aRC; } ErrorInfoKeeper eik; MultiResult mrc(rcTmp); /* Only do the parent changes for newly created media. */ if (SUCCEEDED(mrc) && fCreatingTarget) { /* we set mParent & children() */ AutoWriteLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); Assert(pTarget->m->pParent.isNull()); if (pParent) { /* associate the clone with the parent and deassociate * from VirtualBox */ pTarget->m->pParent = pParent; pParent->m->llChildren.push_back(pTarget); /* register with mVirtualBox as the last step and move to * Created state only on success (leaving an orphan file is * better than breaking media registry consistency) */ eik.restore(); ComObjPtr pMedium; mrc = pParent->m->pVirtualBox->i_registerMedium(pTarget, &pMedium, DeviceType_HardDisk, treeLock); Assert( FAILED(mrc) || pTarget == pMedium); eik.fetch(); if (FAILED(mrc)) /* break parent association on failure to register */ pTarget->i_deparent(); // removes target from parent } else { /* just register */ eik.restore(); ComObjPtr pMedium; mrc = m->pVirtualBox->i_registerMedium(pTarget, &pMedium, DeviceType_HardDisk, treeLock); Assert( FAILED(mrc) || pTarget == pMedium); eik.fetch(); } } if (fCreatingTarget) { AutoWriteLock mLock(pTarget COMMA_LOCKVAL_SRC_POS); if (SUCCEEDED(mrc)) { pTarget->m->state = MediumState_Created; pTarget->m->size = size; pTarget->m->logicalSize = logicalSize; pTarget->m->variant = variant; } else { /* back to NotCreated on failure */ pTarget->m->state = MediumState_NotCreated; /* reset UUID to prevent it from being reused next time */ if (fGenerateUuid) unconst(pTarget->m->id).clear(); } } // now, at the end of this task (always asynchronous), save the settings if (SUCCEEDED(mrc)) { // save the settings i_markRegistriesModified(); /* collect multiple errors */ eik.restore(); m->pVirtualBox->i_saveModifiedRegistries(); eik.fetch(); } /* Everything is explicitly unlocked when the task exits, * as the task destruction also destroys the source chain. */ /* Make sure the source chain is released early. It could happen * that we get a deadlock in Appliance::Import when Medium::Close * is called & the source chain is released at the same time. */ task.mpSourceMediumLockList->Clear(); return mrc; } /** * Implementation code for the "delete" task. * * This task always gets started from Medium::deleteStorage() and can run * synchronously or asynchronously depending on the "wait" parameter passed to * that function. * * @param task * @return */ HRESULT Medium::i_taskDeleteHandler(Medium::DeleteTask &task) { NOREF(task); HRESULT rc = S_OK; try { /* The lock is also used as a signal from the task initiator (which * releases it only after RTThreadCreate()) that we can start the job */ AutoWriteLock thisLock(this COMMA_LOCKVAL_SRC_POS); PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); Utf8Str format(m->strFormat); Utf8Str location(m->strLocationFull); /* unlock before the potentially lengthy operation */ Assert(m->state == MediumState_Deleting); thisLock.release(); try { vrc = VDOpen(hdd, format.c_str(), location.c_str(), VD_OPEN_FLAGS_READONLY | VD_OPEN_FLAGS_INFO | m->uOpenFlagsDef, m->vdImageIfaces); if (RT_SUCCESS(vrc)) vrc = VDClose(hdd, true /* fDelete */); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not delete the medium storage unit '%s'%s"), location.c_str(), i_vdError(vrc).c_str()); } catch (HRESULT aRC) { rc = aRC; } VDDestroy(hdd); } catch (HRESULT aRC) { rc = aRC; } AutoWriteLock thisLock(this COMMA_LOCKVAL_SRC_POS); /* go to the NotCreated state even on failure since the storage * may have been already partially deleted and cannot be used any * more. One will be able to manually re-open the storage if really * needed to re-register it. */ m->state = MediumState_NotCreated; /* Reset UUID to prevent Create* from reusing it again */ unconst(m->id).clear(); return rc; } /** * Implementation code for the "reset" task. * * This always gets started asynchronously from Medium::Reset(). * * @param task * @return */ HRESULT Medium::i_taskResetHandler(Medium::ResetTask &task) { HRESULT rc = S_OK; uint64_t size = 0, logicalSize = 0; MediumVariant_T variant = MediumVariant_Standard; try { /* The lock is also used as a signal from the task initiator (which * releases it only after RTThreadCreate()) that we can start the job */ AutoWriteLock thisLock(this COMMA_LOCKVAL_SRC_POS); /// @todo Below we use a pair of delete/create operations to reset /// the diff contents but the most efficient way will of course be /// to add a VDResetDiff() API call PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); Guid id = m->id; Utf8Str format(m->strFormat); Utf8Str location(m->strLocationFull); Medium *pParent = m->pParent; Guid parentId = pParent->m->id; Utf8Str parentFormat(pParent->m->strFormat); Utf8Str parentLocation(pParent->m->strLocationFull); Assert(m->state == MediumState_LockedWrite); /* unlock before the potentially lengthy operation */ thisLock.release(); try { /* Open all media in the target chain but the last. */ MediumLockList::Base::const_iterator targetListBegin = task.mpMediumLockList->GetBegin(); MediumLockList::Base::const_iterator targetListEnd = task.mpMediumLockList->GetEnd(); for (MediumLockList::Base::const_iterator it = targetListBegin; it != targetListEnd; ++it) { const MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); /* sanity check, "this" is checked above */ Assert( pMedium == this || pMedium->m->state == MediumState_LockedRead); /* Open all media in appropriate mode. */ vrc = VDOpen(hdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), VD_OPEN_FLAGS_READONLY | m->uOpenFlagsDef, pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not open the medium storage unit '%s'%s"), pMedium->m->strLocationFull.c_str(), i_vdError(vrc).c_str()); /* Done when we hit the media which should be reset */ if (pMedium == this) break; } /* first, delete the storage unit */ vrc = VDClose(hdd, true /* fDelete */); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not delete the medium storage unit '%s'%s"), location.c_str(), i_vdError(vrc).c_str()); /* next, create it again */ vrc = VDOpen(hdd, parentFormat.c_str(), parentLocation.c_str(), VD_OPEN_FLAGS_READONLY | VD_OPEN_FLAGS_INFO | m->uOpenFlagsDef, m->vdImageIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not open the medium storage unit '%s'%s"), parentLocation.c_str(), i_vdError(vrc).c_str()); vrc = VDCreateDiff(hdd, format.c_str(), location.c_str(), /// @todo use the same medium variant as before VD_IMAGE_FLAGS_NONE, NULL, id.raw(), parentId.raw(), VD_OPEN_FLAGS_NORMAL, m->vdImageIfaces, task.mVDOperationIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not create the differencing medium storage unit '%s'%s"), location.c_str(), i_vdError(vrc).c_str()); size = VDGetFileSize(hdd, VD_LAST_IMAGE); logicalSize = VDGetSize(hdd, VD_LAST_IMAGE); unsigned uImageFlags; vrc = VDGetImageFlags(hdd, 0, &uImageFlags); if (RT_SUCCESS(vrc)) variant = (MediumVariant_T)uImageFlags; } catch (HRESULT aRC) { rc = aRC; } VDDestroy(hdd); } catch (HRESULT aRC) { rc = aRC; } AutoWriteLock thisLock(this COMMA_LOCKVAL_SRC_POS); m->size = size; m->logicalSize = logicalSize; m->variant = variant; /* Everything is explicitly unlocked when the task exits, * as the task destruction also destroys the media chain. */ return rc; } /** * Implementation code for the "compact" task. * * @param task * @return */ HRESULT Medium::i_taskCompactHandler(Medium::CompactTask &task) { HRESULT rc = S_OK; /* Lock all in {parent,child} order. The lock is also used as a * signal from the task initiator (which releases it only after * RTThreadCreate()) that we can start the job. */ AutoWriteLock thisLock(this COMMA_LOCKVAL_SRC_POS); try { PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); try { /* Open all media in the chain. */ MediumLockList::Base::const_iterator mediumListBegin = task.mpMediumLockList->GetBegin(); MediumLockList::Base::const_iterator mediumListEnd = task.mpMediumLockList->GetEnd(); MediumLockList::Base::const_iterator mediumListLast = mediumListEnd; mediumListLast--; for (MediumLockList::Base::const_iterator it = mediumListBegin; it != mediumListEnd; ++it) { const MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); /* sanity check */ if (it == mediumListLast) Assert(pMedium->m->state == MediumState_LockedWrite); else Assert(pMedium->m->state == MediumState_LockedRead); /* Open all media but last in read-only mode. Do not handle * shareable media, as compaction and sharing are mutually * exclusive. */ vrc = VDOpen(hdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), m->uOpenFlagsDef | (it == mediumListLast ? VD_OPEN_FLAGS_NORMAL : VD_OPEN_FLAGS_READONLY), pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not open the medium storage unit '%s'%s"), pMedium->m->strLocationFull.c_str(), i_vdError(vrc).c_str()); } Assert(m->state == MediumState_LockedWrite); Utf8Str location(m->strLocationFull); /* unlock before the potentially lengthy operation */ thisLock.release(); vrc = VDCompact(hdd, VD_LAST_IMAGE, task.mVDOperationIfaces); if (RT_FAILURE(vrc)) { if (vrc == VERR_NOT_SUPPORTED) throw setError(VBOX_E_NOT_SUPPORTED, tr("Compacting is not yet supported for medium '%s'"), location.c_str()); else if (vrc == VERR_NOT_IMPLEMENTED) throw setError(E_NOTIMPL, tr("Compacting is not implemented, medium '%s'"), location.c_str()); else throw setError(VBOX_E_FILE_ERROR, tr("Could not compact medium '%s'%s"), location.c_str(), i_vdError(vrc).c_str()); } } catch (HRESULT aRC) { rc = aRC; } VDDestroy(hdd); } catch (HRESULT aRC) { rc = aRC; } /* Everything is explicitly unlocked when the task exits, * as the task destruction also destroys the media chain. */ return rc; } /** * Implementation code for the "resize" task. * * @param task * @return */ HRESULT Medium::i_taskResizeHandler(Medium::ResizeTask &task) { HRESULT rc = S_OK; uint64_t size = 0, logicalSize = 0; try { /* The lock is also used as a signal from the task initiator (which * releases it only after RTThreadCreate()) that we can start the job */ AutoWriteLock thisLock(this COMMA_LOCKVAL_SRC_POS); PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); try { /* Open all media in the chain. */ MediumLockList::Base::const_iterator mediumListBegin = task.mpMediumLockList->GetBegin(); MediumLockList::Base::const_iterator mediumListEnd = task.mpMediumLockList->GetEnd(); MediumLockList::Base::const_iterator mediumListLast = mediumListEnd; mediumListLast--; for (MediumLockList::Base::const_iterator it = mediumListBegin; it != mediumListEnd; ++it) { const MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); /* sanity check */ if (it == mediumListLast) Assert(pMedium->m->state == MediumState_LockedWrite); else Assert(pMedium->m->state == MediumState_LockedRead); /* Open all media but last in read-only mode. Do not handle * shareable media, as compaction and sharing are mutually * exclusive. */ vrc = VDOpen(hdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), m->uOpenFlagsDef | (it == mediumListLast ? VD_OPEN_FLAGS_NORMAL : VD_OPEN_FLAGS_READONLY), pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not open the medium storage unit '%s'%s"), pMedium->m->strLocationFull.c_str(), i_vdError(vrc).c_str()); } Assert(m->state == MediumState_LockedWrite); Utf8Str location(m->strLocationFull); /* unlock before the potentially lengthy operation */ thisLock.release(); VDGEOMETRY geo = {0, 0, 0}; /* auto */ vrc = VDResize(hdd, task.mSize, &geo, &geo, task.mVDOperationIfaces); if (RT_FAILURE(vrc)) { if (vrc == VERR_NOT_SUPPORTED) throw setError(VBOX_E_NOT_SUPPORTED, tr("Resizing to new size %llu is not yet supported for medium '%s'"), task.mSize, location.c_str()); else if (vrc == VERR_NOT_IMPLEMENTED) throw setError(E_NOTIMPL, tr("Resiting is not implemented, medium '%s'"), location.c_str()); else throw setError(VBOX_E_FILE_ERROR, tr("Could not resize medium '%s'%s"), location.c_str(), i_vdError(vrc).c_str()); } size = VDGetFileSize(hdd, VD_LAST_IMAGE); logicalSize = VDGetSize(hdd, VD_LAST_IMAGE); } catch (HRESULT aRC) { rc = aRC; } VDDestroy(hdd); } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) { AutoWriteLock thisLock(this COMMA_LOCKVAL_SRC_POS); m->size = size; m->logicalSize = logicalSize; } /* Everything is explicitly unlocked when the task exits, * as the task destruction also destroys the media chain. */ return rc; } /** * Implementation code for the "export" task. * * This only gets started from Medium::exportFile() and always runs * asynchronously. It doesn't touch anything configuration related, so * we never save the VirtualBox.xml file here. * * @param task * @return */ HRESULT Medium::i_taskExportHandler(Medium::ExportTask &task) { HRESULT rc = S_OK; try { /* Lock all in {parent,child} order. The lock is also used as a * signal from the task initiator (which releases it only after * RTThreadCreate()) that we can start the job. */ AutoWriteLock thisLock(this COMMA_LOCKVAL_SRC_POS); PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); try { /* Open all media in the source chain. */ MediumLockList::Base::const_iterator sourceListBegin = task.mpSourceMediumLockList->GetBegin(); MediumLockList::Base::const_iterator sourceListEnd = task.mpSourceMediumLockList->GetEnd(); for (MediumLockList::Base::const_iterator it = sourceListBegin; it != sourceListEnd; ++it) { const MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); /* sanity check */ Assert(pMedium->m->state == MediumState_LockedRead); /* Open all media in read-only mode. */ vrc = VDOpen(hdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), VD_OPEN_FLAGS_READONLY | m->uOpenFlagsDef, pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not open the medium storage unit '%s'%s"), pMedium->m->strLocationFull.c_str(), i_vdError(vrc).c_str()); } Utf8Str targetFormat(task.mFormat->i_getId()); Utf8Str targetLocation(task.mFilename); uint64_t capabilities = task.mFormat->i_getCapabilities(); Assert(m->state == MediumState_LockedRead); /* unlock before the potentially lengthy operation */ thisLock.release(); /* ensure the target directory exists */ if (capabilities & MediumFormatCapabilities_File) { rc = VirtualBox::i_ensureFilePathExists(targetLocation, !(task.mVariant & MediumVariant_NoCreateDir) /* fCreate */); if (FAILED(rc)) throw rc; } PVBOXHDD targetHdd; vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &targetHdd); ComAssertRCThrow(vrc, E_FAIL); try { vrc = VDCopy(hdd, VD_LAST_IMAGE, targetHdd, targetFormat.c_str(), targetLocation.c_str(), false /* fMoveByRename */, 0 /* cbSize */, task.mVariant & ~MediumVariant_NoCreateDir, NULL /* pDstUuid */, VD_OPEN_FLAGS_NORMAL | VD_OPEN_FLAGS_SEQUENTIAL, NULL /* pVDIfsOperation */, task.mVDImageIfaces, task.mVDOperationIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not create the exported medium '%s'%s"), targetLocation.c_str(), i_vdError(vrc).c_str()); } catch (HRESULT aRC) { rc = aRC; } VDDestroy(targetHdd); } catch (HRESULT aRC) { rc = aRC; } VDDestroy(hdd); } catch (HRESULT aRC) { rc = aRC; } /* Everything is explicitly unlocked when the task exits, * as the task destruction also destroys the source chain. */ /* Make sure the source chain is released early, otherwise it can * lead to deadlocks with concurrent IAppliance activities. */ task.mpSourceMediumLockList->Clear(); return rc; } /** * Implementation code for the "import" task. * * This only gets started from Medium::importFile() and always runs * asynchronously. It potentially touches the media registry, so we * always save the VirtualBox.xml file when we're done here. * * @param task * @return */ HRESULT Medium::i_taskImportHandler(Medium::ImportTask &task) { HRESULT rcTmp = S_OK; const ComObjPtr &pParent = task.mParent; bool fCreatingTarget = false; uint64_t size = 0, logicalSize = 0; MediumVariant_T variant = MediumVariant_Standard; bool fGenerateUuid = false; try { /* Lock all in {parent,child} order. The lock is also used as a * signal from the task initiator (which releases it only after * RTThreadCreate()) that we can start the job. */ AutoMultiWriteLock2 thisLock(this, pParent COMMA_LOCKVAL_SRC_POS); fCreatingTarget = m->state == MediumState_Creating; /* The object may request a specific UUID (through a special form of * the setLocation() argument). Otherwise we have to generate it */ Guid targetId = m->id; fGenerateUuid = targetId.isZero(); if (fGenerateUuid) { targetId.create(); /* VirtualBox::i_registerMedium() will need UUID */ unconst(m->id) = targetId; } PVBOXHDD hdd; int vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &hdd); ComAssertRCThrow(vrc, E_FAIL); try { /* Open source medium. */ vrc = VDOpen(hdd, task.mFormat->i_getId().c_str(), task.mFilename.c_str(), VD_OPEN_FLAGS_READONLY | VD_OPEN_FLAGS_SEQUENTIAL | m->uOpenFlagsDef, task.mVDImageIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not open the medium storage unit '%s'%s"), task.mFilename.c_str(), i_vdError(vrc).c_str()); Utf8Str targetFormat(m->strFormat); Utf8Str targetLocation(m->strLocationFull); uint64_t capabilities = task.mFormat->i_getCapabilities(); Assert( m->state == MediumState_Creating || m->state == MediumState_LockedWrite); Assert( pParent.isNull() || pParent->m->state == MediumState_LockedRead); /* unlock before the potentially lengthy operation */ thisLock.release(); /* ensure the target directory exists */ if (capabilities & MediumFormatCapabilities_File) { HRESULT rc = VirtualBox::i_ensureFilePathExists(targetLocation, !(task.mVariant & MediumVariant_NoCreateDir) /* fCreate */); if (FAILED(rc)) throw rc; } PVBOXHDD targetHdd; vrc = VDCreate(m->vdDiskIfaces, i_convertDeviceType(), &targetHdd); ComAssertRCThrow(vrc, E_FAIL); try { /* Open all media in the target chain. */ MediumLockList::Base::const_iterator targetListBegin = task.mpTargetMediumLockList->GetBegin(); MediumLockList::Base::const_iterator targetListEnd = task.mpTargetMediumLockList->GetEnd(); for (MediumLockList::Base::const_iterator it = targetListBegin; it != targetListEnd; ++it) { const MediumLock &mediumLock = *it; const ComObjPtr &pMedium = mediumLock.GetMedium(); /* If the target medium is not created yet there's no * reason to open it. */ if (pMedium == this && fCreatingTarget) continue; AutoReadLock alock(pMedium COMMA_LOCKVAL_SRC_POS); /* sanity check */ Assert( pMedium->m->state == MediumState_LockedRead || pMedium->m->state == MediumState_LockedWrite); unsigned uOpenFlags = VD_OPEN_FLAGS_NORMAL; if (pMedium->m->state != MediumState_LockedWrite) uOpenFlags = VD_OPEN_FLAGS_READONLY; if (pMedium->m->type == MediumType_Shareable) uOpenFlags |= VD_OPEN_FLAGS_SHAREABLE; /* Open all media in appropriate mode. */ vrc = VDOpen(targetHdd, pMedium->m->strFormat.c_str(), pMedium->m->strLocationFull.c_str(), uOpenFlags | m->uOpenFlagsDef, pMedium->m->vdImageIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not open the medium storage unit '%s'%s"), pMedium->m->strLocationFull.c_str(), i_vdError(vrc).c_str()); } /** @todo r=klaus target isn't locked, race getting the state */ vrc = VDCopy(hdd, VD_LAST_IMAGE, targetHdd, targetFormat.c_str(), (fCreatingTarget) ? targetLocation.c_str() : (char *)NULL, false /* fMoveByRename */, 0 /* cbSize */, task.mVariant & ~MediumVariant_NoCreateDir, targetId.raw(), VD_OPEN_FLAGS_NORMAL, NULL /* pVDIfsOperation */, m->vdImageIfaces, task.mVDOperationIfaces); if (RT_FAILURE(vrc)) throw setError(VBOX_E_FILE_ERROR, tr("Could not create the imported medium '%s'%s"), targetLocation.c_str(), i_vdError(vrc).c_str()); size = VDGetFileSize(targetHdd, VD_LAST_IMAGE); logicalSize = VDGetSize(targetHdd, VD_LAST_IMAGE); unsigned uImageFlags; vrc = VDGetImageFlags(targetHdd, 0, &uImageFlags); if (RT_SUCCESS(vrc)) variant = (MediumVariant_T)uImageFlags; } catch (HRESULT aRC) { rcTmp = aRC; } VDDestroy(targetHdd); } catch (HRESULT aRC) { rcTmp = aRC; } VDDestroy(hdd); } catch (HRESULT aRC) { rcTmp = aRC; } ErrorInfoKeeper eik; MultiResult mrc(rcTmp); /* Only do the parent changes for newly created media. */ if (SUCCEEDED(mrc) && fCreatingTarget) { /* we set mParent & children() */ AutoWriteLock treeLock(m->pVirtualBox->i_getMediaTreeLockHandle() COMMA_LOCKVAL_SRC_POS); Assert(m->pParent.isNull()); if (pParent) { /* associate the imported medium with the parent and deassociate * from VirtualBox */ m->pParent = pParent; pParent->m->llChildren.push_back(this); /* register with mVirtualBox as the last step and move to * Created state only on success (leaving an orphan file is * better than breaking media registry consistency) */ eik.restore(); ComObjPtr pMedium; mrc = pParent->m->pVirtualBox->i_registerMedium(this, &pMedium, DeviceType_HardDisk, treeLock); Assert(this == pMedium); eik.fetch(); if (FAILED(mrc)) /* break parent association on failure to register */ this->i_deparent(); // removes target from parent } else { /* just register */ eik.restore(); ComObjPtr pMedium; mrc = m->pVirtualBox->i_registerMedium(this, &pMedium, DeviceType_HardDisk, treeLock); Assert(this == pMedium); eik.fetch(); } } if (fCreatingTarget) { AutoWriteLock mLock(this COMMA_LOCKVAL_SRC_POS); if (SUCCEEDED(mrc)) { m->state = MediumState_Created; m->size = size; m->logicalSize = logicalSize; m->variant = variant; } else { /* back to NotCreated on failure */ m->state = MediumState_NotCreated; /* reset UUID to prevent it from being reused next time */ if (fGenerateUuid) unconst(m->id).clear(); } } // now, at the end of this task (always asynchronous), save the settings { // save the settings i_markRegistriesModified(); /* collect multiple errors */ eik.restore(); m->pVirtualBox->i_saveModifiedRegistries(); eik.fetch(); } /* Everything is explicitly unlocked when the task exits, * as the task destruction also destroys the target chain. */ /* Make sure the target chain is released early, otherwise it can * lead to deadlocks with concurrent IAppliance activities. */ task.mpTargetMediumLockList->Clear(); return mrc; } /* vi: set tabstop=4 shiftwidth=4 expandtab: */