/* $Id: ApplianceImplExport.cpp 78428 2019-05-07 11:03:49Z vboxsync $ */ /** @file * IAppliance and IVirtualSystem COM class implementations. */ /* * Copyright (C) 2008-2019 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. */ #define LOG_GROUP LOG_GROUP_MAIN_APPLIANCE #include #include #include #include #include #include #include #include #include "ApplianceImpl.h" #include "VirtualBoxImpl.h" #include "ProgressImpl.h" #include "MachineImpl.h" #include "MediumImpl.h" #include "LoggingNew.h" #include "Global.h" #include "MediumFormatImpl.h" #include "SystemPropertiesImpl.h" #include "AutoCaller.h" #include "ApplianceImplPrivate.h" using namespace std; //////////////////////////////////////////////////////////////////////////////// // // IMachine public methods // //////////////////////////////////////////////////////////////////////////////// // This code is here so we won't have to include the appliance headers in the // IMachine implementation, and we also need to access private appliance data. /** * Public method implementation. * @param aAppliance Appliance object. * @param aLocation Where to store the appliance. * @param aDescription Appliance description. * @return */ HRESULT Machine::exportTo(const ComPtr &aAppliance, const com::Utf8Str &aLocation, ComPtr &aDescription) { HRESULT rc = S_OK; if (!aAppliance) return E_POINTER; ComObjPtr pNewDesc; try { IAppliance *iAppliance = aAppliance; Appliance *pAppliance = static_cast(iAppliance); LocationInfo locInfo; i_parseURI(aLocation, locInfo); Utf8Str strBasename(locInfo.strPath); strBasename.stripPath().stripSuffix(); if (locInfo.strPath.endsWith(".tar.gz", Utf8Str::CaseSensitive)) strBasename.stripSuffix(); // create a new virtual system to store in the appliance rc = pNewDesc.createObject(); if (FAILED(rc)) throw rc; rc = pNewDesc->init(); if (FAILED(rc)) throw rc; // store the machine object so we can dump the XML in Appliance::Write() pNewDesc->m->pMachine = this; // first, call the COM methods, as they request locks BOOL fUSBEnabled = FALSE; com::SafeIfaceArray usbControllers; rc = COMGETTER(USBControllers)(ComSafeArrayAsOutParam(usbControllers)); if (SUCCEEDED(rc)) { for (unsigned i = 0; i < usbControllers.size(); ++i) { USBControllerType_T enmType; rc = usbControllers[i]->COMGETTER(Type)(&enmType); if (FAILED(rc)) throw rc; if (enmType == USBControllerType_OHCI) fUSBEnabled = TRUE; } } // request the machine lock while accessing internal members AutoReadLock alock1(this COMMA_LOCKVAL_SRC_POS); ComPtr pAudioAdapter = mAudioAdapter; BOOL fAudioEnabled; rc = pAudioAdapter->COMGETTER(Enabled)(&fAudioEnabled); if (FAILED(rc)) throw rc; AudioControllerType_T audioController; rc = pAudioAdapter->COMGETTER(AudioController)(&audioController); if (FAILED(rc)) throw rc; // get name Utf8Str strVMName = mUserData->s.strName; // get description Utf8Str strDescription = mUserData->s.strDescription; // get guest OS Utf8Str strOsTypeVBox = mUserData->s.strOsType; // CPU count uint32_t cCPUs = mHWData->mCPUCount; // memory size in MB uint32_t ulMemSizeMB = mHWData->mMemorySize; // VRAM size? // BIOS settings? // 3D acceleration enabled? // hardware virtualization enabled? // nested paging enabled? // HWVirtExVPIDEnabled? // PAEEnabled? // Long mode enabled? BOOL fLongMode; rc = GetCPUProperty(CPUPropertyType_LongMode, &fLongMode); if (FAILED(rc)) throw rc; // snapshotFolder? // VRDPServer? /* Guest OS type */ ovf::CIMOSType_T cim = convertVBoxOSType2CIMOSType(strOsTypeVBox.c_str(), fLongMode); pNewDesc->i_addEntry(VirtualSystemDescriptionType_OS, "", Utf8StrFmt("%RI32", cim), strOsTypeVBox); /* VM name */ pNewDesc->i_addEntry(VirtualSystemDescriptionType_Name, "", strVMName, strVMName); // description pNewDesc->i_addEntry(VirtualSystemDescriptionType_Description, "", strDescription, strDescription); /* CPU count*/ Utf8Str strCpuCount = Utf8StrFmt("%RI32", cCPUs); pNewDesc->i_addEntry(VirtualSystemDescriptionType_CPU, "", strCpuCount, strCpuCount); /* Memory */ Utf8Str strMemory = Utf8StrFmt("%RI64", (uint64_t)ulMemSizeMB * _1M); pNewDesc->i_addEntry(VirtualSystemDescriptionType_Memory, "", strMemory, strMemory); // the one VirtualBox IDE controller has two channels with two ports each, which is // considered two IDE controllers with two ports each by OVF, so export it as two int32_t lIDEControllerPrimaryIndex = 0; int32_t lIDEControllerSecondaryIndex = 0; int32_t lSATAControllerIndex = 0; int32_t lSCSIControllerIndex = 0; /* Fetch all available storage controllers */ com::SafeIfaceArray nwControllers; rc = COMGETTER(StorageControllers)(ComSafeArrayAsOutParam(nwControllers)); if (FAILED(rc)) throw rc; ComPtr pIDEController; ComPtr pSATAController; ComPtr pSCSIController; ComPtr pSASController; for (size_t j = 0; j < nwControllers.size(); ++j) { StorageBus_T eType; rc = nwControllers[j]->COMGETTER(Bus)(&eType); if (FAILED(rc)) throw rc; if ( eType == StorageBus_IDE && pIDEController.isNull()) pIDEController = nwControllers[j]; else if ( eType == StorageBus_SATA && pSATAController.isNull()) pSATAController = nwControllers[j]; else if ( eType == StorageBus_SCSI && pSATAController.isNull()) pSCSIController = nwControllers[j]; else if ( eType == StorageBus_SAS && pSASController.isNull()) pSASController = nwControllers[j]; } // if (!pIDEController.isNull()) { StorageControllerType_T ctlr; rc = pIDEController->COMGETTER(ControllerType)(&ctlr); if (FAILED(rc)) throw rc; Utf8Str strVBox; switch (ctlr) { case StorageControllerType_PIIX3: strVBox = "PIIX3"; break; case StorageControllerType_PIIX4: strVBox = "PIIX4"; break; case StorageControllerType_ICH6: strVBox = "ICH6"; break; default: break; /* Shut up MSC. */ } if (strVBox.length()) { lIDEControllerPrimaryIndex = (int32_t)pNewDesc->m->maDescriptions.size(); pNewDesc->i_addEntry(VirtualSystemDescriptionType_HardDiskControllerIDE, Utf8StrFmt("%d", lIDEControllerPrimaryIndex), // strRef strVBox, // aOvfValue strVBox); // aVBoxValue lIDEControllerSecondaryIndex = lIDEControllerPrimaryIndex + 1; pNewDesc->i_addEntry(VirtualSystemDescriptionType_HardDiskControllerIDE, Utf8StrFmt("%d", lIDEControllerSecondaryIndex), strVBox, strVBox); } } // if (!pSATAController.isNull()) { Utf8Str strVBox = "AHCI"; lSATAControllerIndex = (int32_t)pNewDesc->m->maDescriptions.size(); pNewDesc->i_addEntry(VirtualSystemDescriptionType_HardDiskControllerSATA, Utf8StrFmt("%d", lSATAControllerIndex), strVBox, strVBox); } // if (!pSCSIController.isNull()) { StorageControllerType_T ctlr; rc = pSCSIController->COMGETTER(ControllerType)(&ctlr); if (SUCCEEDED(rc)) { Utf8Str strVBox = "LsiLogic"; // the default in VBox switch (ctlr) { case StorageControllerType_LsiLogic: strVBox = "LsiLogic"; break; case StorageControllerType_BusLogic: strVBox = "BusLogic"; break; default: break; /* Shut up MSC. */ } lSCSIControllerIndex = (int32_t)pNewDesc->m->maDescriptions.size(); pNewDesc->i_addEntry(VirtualSystemDescriptionType_HardDiskControllerSCSI, Utf8StrFmt("%d", lSCSIControllerIndex), strVBox, strVBox); } else throw rc; } if (!pSASController.isNull()) { // VirtualBox considers the SAS controller a class of its own but in OVF // it should be a SCSI controller Utf8Str strVBox = "LsiLogicSas"; lSCSIControllerIndex = (int32_t)pNewDesc->m->maDescriptions.size(); pNewDesc->i_addEntry(VirtualSystemDescriptionType_HardDiskControllerSAS, Utf8StrFmt("%d", lSCSIControllerIndex), strVBox, strVBox); } // // // for (MediumAttachmentList::const_iterator it = mMediumAttachments->begin(); it != mMediumAttachments->end(); ++it) { ComObjPtr pHDA = *it; // the attachment's data ComPtr pMedium; ComPtr ctl; Bstr controllerName; rc = pHDA->COMGETTER(Controller)(controllerName.asOutParam()); if (FAILED(rc)) throw rc; rc = GetStorageControllerByName(controllerName.raw(), ctl.asOutParam()); if (FAILED(rc)) throw rc; StorageBus_T storageBus; DeviceType_T deviceType; LONG lChannel; LONG lDevice; rc = ctl->COMGETTER(Bus)(&storageBus); if (FAILED(rc)) throw rc; rc = pHDA->COMGETTER(Type)(&deviceType); if (FAILED(rc)) throw rc; rc = pHDA->COMGETTER(Medium)(pMedium.asOutParam()); if (FAILED(rc)) throw rc; rc = pHDA->COMGETTER(Port)(&lChannel); if (FAILED(rc)) throw rc; rc = pHDA->COMGETTER(Device)(&lDevice); if (FAILED(rc)) throw rc; Utf8Str strTargetImageName; Utf8Str strLocation; LONG64 llSize = 0; if ( deviceType == DeviceType_HardDisk && pMedium) { Bstr bstrLocation; rc = pMedium->COMGETTER(Location)(bstrLocation.asOutParam()); if (FAILED(rc)) throw rc; strLocation = bstrLocation; // find the source's base medium for two things: // 1) we'll use its name to determine the name of the target disk, which is readable, // as opposed to the UUID filename of a differencing image, if pMedium is one // 2) we need the size of the base image so we can give it to addEntry(), and later // on export, the progress will be based on that (and not the diff image) ComPtr pBaseMedium; rc = pMedium->COMGETTER(Base)(pBaseMedium.asOutParam()); // returns pMedium if there are no diff images if (FAILED(rc)) throw rc; strTargetImageName = Utf8StrFmt("%s-disk%.3d.vmdk", strBasename.c_str(), ++pAppliance->m->cDisks); if (strTargetImageName.length() > RTTAR_NAME_MAX) throw setError(VBOX_E_NOT_SUPPORTED, tr("Cannot attach disk '%s' -- file name too long"), strTargetImageName.c_str()); // force reading state, or else size will be returned as 0 MediumState_T ms; rc = pBaseMedium->RefreshState(&ms); if (FAILED(rc)) throw rc; rc = pBaseMedium->COMGETTER(Size)(&llSize); if (FAILED(rc)) throw rc; /* If the medium is encrypted add the key identifier to the list. */ IMedium *iBaseMedium = pBaseMedium; Medium *pBase = static_cast(iBaseMedium); const com::Utf8Str strKeyId = pBase->i_getKeyId(); if (!strKeyId.isEmpty()) { IMedium *iMedium = pMedium; Medium *pMed = static_cast(iMedium); com::Guid mediumUuid = pMed->i_getId(); bool fKnown = false; /* Check whether the ID is already in our sequence, add it otherwise. */ for (unsigned i = 0; i < pAppliance->m->m_vecPasswordIdentifiers.size(); i++) { if (strKeyId.equals(pAppliance->m->m_vecPasswordIdentifiers[i])) { fKnown = true; break; } } if (!fKnown) { GUIDVEC vecMediumIds; vecMediumIds.push_back(mediumUuid); pAppliance->m->m_vecPasswordIdentifiers.push_back(strKeyId); pAppliance->m->m_mapPwIdToMediumIds.insert(std::pair(strKeyId, vecMediumIds)); } else { std::map::iterator itMap = pAppliance->m->m_mapPwIdToMediumIds.find(strKeyId); if (itMap == pAppliance->m->m_mapPwIdToMediumIds.end()) throw setError(E_FAIL, tr("Internal error adding a medium UUID to the map")); itMap->second.push_back(mediumUuid); } } } else if ( deviceType == DeviceType_DVD && pMedium) { /* * check the minimal rules to grant access to export an image * 1. no host drive CD/DVD image * 2. the image must be accessible and readable * 3. only ISO image is exported */ //1. no host drive CD/DVD image BOOL fHostDrive = false; rc = pMedium->COMGETTER(HostDrive)(&fHostDrive); if (FAILED(rc)) throw rc; if(fHostDrive) continue; //2. the image must be accessible and readable MediumState_T ms; rc = pMedium->RefreshState(&ms); if (FAILED(rc)) throw rc; if (ms != MediumState_Created) continue; //3. only ISO image is exported Bstr bstrLocation; rc = pMedium->COMGETTER(Location)(bstrLocation.asOutParam()); if (FAILED(rc)) throw rc; strLocation = bstrLocation; Utf8Str ext = strLocation; ext.assignEx(RTPathSuffix(ext.c_str()));//returns extension with dot (".iso") int eq = ext.compare(".iso", Utf8Str::CaseInsensitive); if (eq != 0) continue; strTargetImageName = Utf8StrFmt("%s-disk%.3d.iso", strBasename.c_str(), ++pAppliance->m->cDisks); if (strTargetImageName.length() > RTTAR_NAME_MAX) throw setError(VBOX_E_NOT_SUPPORTED, tr("Cannot attach image '%s' -- file name too long"), strTargetImageName.c_str()); rc = pMedium->COMGETTER(Size)(&llSize); if (FAILED(rc)) throw rc; } // and how this translates to the virtual system int32_t lControllerVsys = 0; LONG lChannelVsys; switch (storageBus) { case StorageBus_IDE: // this is the exact reverse to what we're doing in Appliance::taskThreadImportMachines, // and it must be updated when that is changed! // Before 3.2 we exported one IDE controller with channel 0-3, but we now maintain // compatibility with what VMware does and export two IDE controllers with two channels each if (lChannel == 0 && lDevice == 0) // primary master { lControllerVsys = lIDEControllerPrimaryIndex; lChannelVsys = 0; } else if (lChannel == 0 && lDevice == 1) // primary slave { lControllerVsys = lIDEControllerPrimaryIndex; lChannelVsys = 1; } else if (lChannel == 1 && lDevice == 0) // secondary master; by default this is the CD-ROM but // as of VirtualBox 3.1 that can change { lControllerVsys = lIDEControllerSecondaryIndex; lChannelVsys = 0; } else if (lChannel == 1 && lDevice == 1) // secondary slave { lControllerVsys = lIDEControllerSecondaryIndex; lChannelVsys = 1; } else throw setError(VBOX_E_NOT_SUPPORTED, tr("Cannot handle medium attachment: channel is %d, device is %d"), lChannel, lDevice); break; case StorageBus_SATA: lChannelVsys = lChannel; // should be between 0 and 29 lControllerVsys = lSATAControllerIndex; break; case StorageBus_SCSI: case StorageBus_SAS: lChannelVsys = lChannel; // should be between 0 and 15 lControllerVsys = lSCSIControllerIndex; break; case StorageBus_Floppy: lChannelVsys = 0; lControllerVsys = 0; break; default: throw setError(VBOX_E_NOT_SUPPORTED, tr("Cannot handle medium attachment: storageBus is %d, channel is %d, device is %d"), storageBus, lChannel, lDevice); } Utf8StrFmt strExtra("controller=%RI32;channel=%RI32", lControllerVsys, lChannelVsys); Utf8Str strEmpty; switch (deviceType) { case DeviceType_HardDisk: Log(("Adding VirtualSystemDescriptionType_HardDiskImage, disk size: %RI64\n", llSize)); pNewDesc->i_addEntry(VirtualSystemDescriptionType_HardDiskImage, strTargetImageName, // disk ID: let's use the name strTargetImageName, // OVF value: strLocation, // vbox value: media path (uint32_t)(llSize / _1M), strExtra); break; case DeviceType_DVD: Log(("Adding VirtualSystemDescriptionType_CDROM, disk size: %RI64\n", llSize)); pNewDesc->i_addEntry(VirtualSystemDescriptionType_CDROM, strTargetImageName, // disk ID strTargetImageName, // OVF value strLocation, // vbox value (uint32_t)(llSize / _1M),// ulSize strExtra); break; case DeviceType_Floppy: pNewDesc->i_addEntry(VirtualSystemDescriptionType_Floppy, strEmpty, // disk ID strEmpty, // OVF value strEmpty, // vbox value 1, // ulSize strExtra); break; default: break; /* Shut up MSC. */ } } // uint32_t maxNetworkAdapters = Global::getMaxNetworkAdapters(i_getChipsetType()); size_t a; for (a = 0; a < maxNetworkAdapters; ++a) { ComPtr pNetworkAdapter; BOOL fEnabled; NetworkAdapterType_T adapterType; NetworkAttachmentType_T attachmentType; rc = GetNetworkAdapter((ULONG)a, pNetworkAdapter.asOutParam()); if (FAILED(rc)) throw rc; /* Enable the network card & set the adapter type */ rc = pNetworkAdapter->COMGETTER(Enabled)(&fEnabled); if (FAILED(rc)) throw rc; if (fEnabled) { rc = pNetworkAdapter->COMGETTER(AdapterType)(&adapterType); if (FAILED(rc)) throw rc; rc = pNetworkAdapter->COMGETTER(AttachmentType)(&attachmentType); if (FAILED(rc)) throw rc; Utf8Str strAttachmentType = convertNetworkAttachmentTypeToString(attachmentType); pNewDesc->i_addEntry(VirtualSystemDescriptionType_NetworkAdapter, "", // ref strAttachmentType, // orig Utf8StrFmt("%RI32", (uint32_t)adapterType), // conf 0, Utf8StrFmt("type=%s", strAttachmentType.c_str())); // extra conf } } // #ifdef VBOX_WITH_USB if (fUSBEnabled) pNewDesc->i_addEntry(VirtualSystemDescriptionType_USBController, "", "", ""); #endif /* VBOX_WITH_USB */ // if (fAudioEnabled) pNewDesc->i_addEntry(VirtualSystemDescriptionType_SoundCard, "", "ensoniq1371", // this is what OVFTool writes and VMware supports Utf8StrFmt("%RI32", audioController)); /* We return the new description to the caller */ ComPtr copy(pNewDesc); copy.queryInterfaceTo(aDescription.asOutParam()); AutoWriteLock alock(pAppliance COMMA_LOCKVAL_SRC_POS); // finally, add the virtual system to the appliance pAppliance->m->virtualSystemDescriptions.push_back(pNewDesc); } catch(HRESULT arc) { rc = arc; } return rc; } //////////////////////////////////////////////////////////////////////////////// // // IAppliance public methods // //////////////////////////////////////////////////////////////////////////////// /** * Public method implementation. * @param aFormat Appliance format. * @param aOptions Export options. * @param aPath Path to write the appliance to. * @param aProgress Progress object. * @return */ HRESULT Appliance::write(const com::Utf8Str &aFormat, const std::vector &aOptions, const com::Utf8Str &aPath, ComPtr &aProgress) { AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); m->optListExport.clear(); if (aOptions.size()) { for (size_t i = 0; i < aOptions.size(); ++i) { m->optListExport.insert(i, aOptions[i]); } } HRESULT rc = S_OK; // AssertReturn(!(m->optListExport.contains(ExportOptions_CreateManifest) // && m->optListExport.contains(ExportOptions_ExportDVDImages)), E_INVALIDARG); /* Parse all necessary info out of the URI */ i_parseURI(aPath, m->locInfo); if (m->locInfo.storageType == VFSType_Cloud) { rc = S_OK; ComObjPtr progress; try { rc = i_writeCloudImpl(m->locInfo, progress); } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) /* Return progress to the caller */ progress.queryInterfaceTo(aProgress.asOutParam()); } else { m->fExportISOImages = m->optListExport.contains(ExportOptions_ExportDVDImages); if (!m->fExportISOImages)/* remove all ISO images from VirtualSystemDescription */ { for (list >::const_iterator it = m->virtualSystemDescriptions.begin(); it != m->virtualSystemDescriptions.end(); ++it) { ComObjPtr vsdescThis = *it; std::list skipped = vsdescThis->i_findByType(VirtualSystemDescriptionType_CDROM); std::list::const_iterator itSkipped = skipped.begin(); while (itSkipped != skipped.end()) { (*itSkipped)->skipIt = true; ++itSkipped; } } } // do not allow entering this method if the appliance is busy reading or writing if (!i_isApplianceIdle()) return E_ACCESSDENIED; // figure the export format. We exploit the unknown version value for oracle public cloud. ovf::OVFVersion_T ovfF; if (aFormat == "ovf-0.9") ovfF = ovf::OVFVersion_0_9; else if (aFormat == "ovf-1.0") ovfF = ovf::OVFVersion_1_0; else if (aFormat == "ovf-2.0") ovfF = ovf::OVFVersion_2_0; else if (aFormat == "opc-1.0") ovfF = ovf::OVFVersion_unknown; else return setError(VBOX_E_FILE_ERROR, tr("Invalid format \"%s\" specified"), aFormat.c_str()); // Check the extension. if (ovfF == ovf::OVFVersion_unknown) { if (!aPath.endsWith(".tar.gz", Utf8Str::CaseInsensitive)) return setError(VBOX_E_FILE_ERROR, tr("OPC appliance file must have .tar.gz extension")); } else if ( !aPath.endsWith(".ovf", Utf8Str::CaseInsensitive) && !aPath.endsWith(".ova", Utf8Str::CaseInsensitive)) return setError(VBOX_E_FILE_ERROR, tr("Appliance file must have .ovf or .ova extension")); /* As of OVF 2.0 we have to use SHA-256 in the manifest. */ m->fManifest = m->optListExport.contains(ExportOptions_CreateManifest); if (m->fManifest) m->fDigestTypes = ovfF >= ovf::OVFVersion_2_0 ? RTMANIFEST_ATTR_SHA256 : RTMANIFEST_ATTR_SHA1; Assert(m->hOurManifest == NIL_RTMANIFEST); /* Check whether all passwords are supplied or error out. */ if (m->m_cPwProvided < m->m_vecPasswordIdentifiers.size()) return setError(VBOX_E_INVALID_OBJECT_STATE, tr("Appliance export failed because not all passwords were provided for all encrypted media")); ComObjPtr progress; rc = S_OK; try { /* Parse all necessary info out of the URI */ i_parseURI(aPath, m->locInfo); switch (ovfF) { case ovf::OVFVersion_unknown: rc = i_writeOPCImpl(ovfF, m->locInfo, progress); break; default: rc = i_writeImpl(ovfF, m->locInfo, progress); break; } } catch (HRESULT aRC) { rc = aRC; } if (SUCCEEDED(rc)) /* Return progress to the caller */ progress.queryInterfaceTo(aProgress.asOutParam()); } return rc; } //////////////////////////////////////////////////////////////////////////////// // // Appliance private methods // //////////////////////////////////////////////////////////////////////////////// /******************************************************************************* * Export stuff ******************************************************************************/ /** * Implementation for writing out the OVF to disk. This starts a new thread which will call * Appliance::taskThreadWriteOVF(). * * This is in a separate private method because it is used from two locations: * * 1) from the public Appliance::Write(). * * 2) in a second worker thread; in that case, Appliance::Write() called Appliance::i_writeImpl(), which * called Appliance::i_writeFSOVA(), which called Appliance::i_writeImpl(), which then called this again. * * @param aFormat * @param aLocInfo * @param aProgress * @return */ HRESULT Appliance::i_writeImpl(ovf::OVFVersion_T aFormat, const LocationInfo &aLocInfo, ComObjPtr &aProgress) { HRESULT rc; rc = i_setUpProgress(aProgress, BstrFmt(tr("Export appliance '%s'"), aLocInfo.strPath.c_str()), (aLocInfo.storageType == VFSType_File) ? WriteFile : WriteS3); if (FAILED(rc)) return rc; /* Initialize our worker task */ TaskOVF* task = NULL; try { task = new TaskOVF(this, TaskOVF::Write, aLocInfo, aProgress); } catch(...) { return setError(VBOX_E_OBJECT_NOT_FOUND, tr("Could not create TaskOVF object for for writing out the OVF to disk")); } /* The OVF version to write */ task->enFormat = aFormat; rc = task->createThread(); return rc; } HRESULT Appliance::i_writeCloudImpl(const LocationInfo &aLocInfo, ComObjPtr &aProgress) { HRESULT rc; for (list >::const_iterator it = m->virtualSystemDescriptions.begin(); it != m->virtualSystemDescriptions.end(); ++it) { ComObjPtr vsdescThis = *it; std::list skipped = vsdescThis->i_findByType(VirtualSystemDescriptionType_CDROM); std::list::const_iterator itSkipped = skipped.begin(); while (itSkipped != skipped.end()) { (*itSkipped)->skipIt = true; ++itSkipped; } //remove all disks from the VirtualSystemDescription exept one skipped = vsdescThis->i_findByType(VirtualSystemDescriptionType_HardDiskImage); itSkipped = skipped.begin(); Utf8Str strBootLocation; while (itSkipped != skipped.end()) { if (strBootLocation.isEmpty()) strBootLocation = (*itSkipped)->strVBoxCurrent; else (*itSkipped)->skipIt = true; ++itSkipped; } //just in case if (vsdescThis->i_findByType(VirtualSystemDescriptionType_HardDiskImage).empty()) { return setError(VBOX_E_OBJECT_NOT_FOUND, tr("There are no images to export to Cloud after preparation steps")); } /* * Fills out the OCI settings */ std::list profileName = vsdescThis->i_findByType(VirtualSystemDescriptionType_CloudProfileName); if (profileName.size() > 1) return setError(VBOX_E_OBJECT_NOT_FOUND, tr("Cloud: More than one profile name was found.")); else if (profileName.empty()) return setError(VBOX_E_OBJECT_NOT_FOUND, tr("Cloud: Profile name wasn't specified.")); if (profileName.front()->strVBoxCurrent.isEmpty()) return setError(VBOX_E_OBJECT_NOT_FOUND, tr("Cloud: Cloud user profile name is empty")); LogRel(("profile name: %s\n", profileName.front()->strVBoxCurrent.c_str())); } // we need to do that as otherwise Task won't be created successfully aProgress.createObject(); if (aLocInfo.strProvider.equals("OCI")) { aProgress->init(mVirtualBox, static_cast(this), Bstr("Exporting VM to Cloud...").raw(), TRUE /* aCancelable */, 5, // ULONG cOperations, 1000, // ULONG ulTotalOperationsWeight, Bstr("Exporting VM to Cloud...").raw(), // aFirstOperationDescription 10); // ULONG ulFirstOperationWeight } else return setErrorVrc(VBOX_E_NOT_SUPPORTED, tr("Only \"OCI\" cloud provider is supported for now. \"%s\" isn't supported."), aLocInfo.strProvider.c_str()); // Initialize our worker task TaskCloud* task = NULL; try { task = new Appliance::TaskCloud(this, TaskCloud::Export, aLocInfo, aProgress); } catch(...) { return setError(VBOX_E_OBJECT_NOT_FOUND, tr("Could not create TaskCloud object for exporting to Cloud")); } rc = task->createThread(); return rc; } HRESULT Appliance::i_writeOPCImpl(ovf::OVFVersion_T aFormat, const LocationInfo &aLocInfo, ComObjPtr &aProgress) { HRESULT rc; RT_NOREF(aFormat); rc = i_setUpProgress(aProgress, BstrFmt(tr("Export appliance '%s'"), aLocInfo.strPath.c_str()), (aLocInfo.storageType == VFSType_File) ? WriteFile : WriteS3); if (FAILED(rc)) return rc; /* Initialize our worker task */ TaskOPC* task = NULL; try { task = new Appliance::TaskOPC(this, TaskOPC::Export, aLocInfo, aProgress); } catch(...) { return setError(VBOX_E_OBJECT_NOT_FOUND, tr("Could not create TaskOPC object for for writing out the OPC to disk")); } rc = task->createThread(); return rc; } /** * Called from Appliance::i_writeFS() for creating a XML document for this * Appliance. * * @param writeLock The current write lock. * @param doc The xml document to fill. * @param stack Structure for temporary private * data shared with caller. * @param strPath Path to the target OVF. * instance for which to write XML. * @param enFormat OVF format (0.9 or 1.0). */ void Appliance::i_buildXML(AutoWriteLockBase& writeLock, xml::Document &doc, XMLStack &stack, const Utf8Str &strPath, ovf::OVFVersion_T enFormat) { xml::ElementNode *pelmRoot = doc.createRootElement("Envelope"); pelmRoot->setAttribute("ovf:version", enFormat == ovf::OVFVersion_2_0 ? "2.0" : enFormat == ovf::OVFVersion_1_0 ? "1.0" : "0.9"); pelmRoot->setAttribute("xml:lang", "en-US"); Utf8Str strNamespace; if (enFormat == ovf::OVFVersion_0_9) { strNamespace = ovf::OVF09_URI_string; } else if (enFormat == ovf::OVFVersion_1_0) { strNamespace = ovf::OVF10_URI_string; } else { strNamespace = ovf::OVF20_URI_string; } pelmRoot->setAttribute("xmlns", strNamespace); pelmRoot->setAttribute("xmlns:ovf", strNamespace); // pelmRoot->setAttribute("xmlns:ovfstr", "http://schema.dmtf.org/ovf/strings/1"); pelmRoot->setAttribute("xmlns:rasd", "http://schemas.dmtf.org/wbem/wscim/1/cim-schema/2/CIM_ResourceAllocationSettingData"); pelmRoot->setAttribute("xmlns:vssd", "http://schemas.dmtf.org/wbem/wscim/1/cim-schema/2/CIM_VirtualSystemSettingData"); pelmRoot->setAttribute("xmlns:xsi", "http://www.w3.org/2001/XMLSchema-instance"); pelmRoot->setAttribute("xmlns:vbox", "http://www.virtualbox.org/ovf/machine"); // pelmRoot->setAttribute("xsi:schemaLocation", "http://schemas.dmtf.org/ovf/envelope/1 ../ovf-envelope.xsd"); if (enFormat == ovf::OVFVersion_2_0) { pelmRoot->setAttribute("xmlns:epasd", "http://schemas.dmtf.org/wbem/wscim/1/cim-schema/2/CIM_EthernetPortAllocationSettingData.xsd"); pelmRoot->setAttribute("xmlns:sasd", "http://schemas.dmtf.org/wbem/wscim/1/cim-schema/2/CIM_StorageAllocationSettingData.xsd"); } // / xml::ElementNode *pelmReferences = pelmRoot->createChild("References"); // 0.9 and 1.0 /* /: List of the virtual disks used in the package */ xml::ElementNode *pelmDiskSection; if (enFormat == ovf::OVFVersion_0_9) { //
pelmDiskSection = pelmRoot->createChild("Section"); pelmDiskSection->setAttribute("xsi:type", "ovf:DiskSection_Type"); } else pelmDiskSection = pelmRoot->createChild("DiskSection"); xml::ElementNode *pelmDiskSectionInfo = pelmDiskSection->createChild("Info"); pelmDiskSectionInfo->addContent("List of the virtual disks used in the package"); /* /: Logical networks used in the package The network that the LAMP Service will be available on */ xml::ElementNode *pelmNetworkSection; if (enFormat == ovf::OVFVersion_0_9) { //
pelmNetworkSection = pelmRoot->createChild("Section"); pelmNetworkSection->setAttribute("xsi:type", "ovf:NetworkSection_Type"); } else pelmNetworkSection = pelmRoot->createChild("NetworkSection"); xml::ElementNode *pelmNetworkSectionInfo = pelmNetworkSection->createChild("Info"); pelmNetworkSectionInfo->addContent("Logical networks used in the package"); // and here come the virtual systems: // write a collection if we have more than one virtual system _and_ we're // writing OVF 1.0; otherwise fail since ovftool can't import more than // one machine, it seems xml::ElementNode *pelmToAddVirtualSystemsTo; if (m->virtualSystemDescriptions.size() > 1) { if (enFormat == ovf::OVFVersion_0_9) throw setError(VBOX_E_FILE_ERROR, tr("Cannot export more than one virtual system with OVF 0.9, use OVF 1.0")); pelmToAddVirtualSystemsTo = pelmRoot->createChild("VirtualSystemCollection"); pelmToAddVirtualSystemsTo->setAttribute("ovf:name", "ExportedVirtualBoxMachines"); // whatever } else pelmToAddVirtualSystemsTo = pelmRoot; // add virtual system directly under root element // this list receives pointers to the XML elements in the machine XML which // might have UUIDs that need fixing after we know the UUIDs of the exported images std::list llElementsWithUuidAttributes; uint32_t ulFile = 1; /* Iterate through all virtual systems of that appliance */ for (list >::const_iterator itV = m->virtualSystemDescriptions.begin(); itV != m->virtualSystemDescriptions.end(); ++itV) { ComObjPtr vsdescThis = *itV; i_buildXMLForOneVirtualSystem(writeLock, *pelmToAddVirtualSystemsTo, &llElementsWithUuidAttributes, vsdescThis, enFormat, stack); // disks and networks stack list diskList; for (list::const_iterator itDisk = stack.mapDiskSequenceForOneVM.begin(); itDisk != stack.mapDiskSequenceForOneVM.end(); ++itDisk) { const Utf8Str &strDiskID = *itDisk; const VirtualSystemDescriptionEntry *pDiskEntry = stack.mapDisks[strDiskID]; // source path: where the VBox image is const Utf8Str &strSrcFilePath = pDiskEntry->strVBoxCurrent; Bstr bstrSrcFilePath(strSrcFilePath); //skip empty Medium. There are no information to add into section or if (strSrcFilePath.isEmpty() || pDiskEntry->skipIt == true) continue; // Do NOT check here whether the file exists. FindMedium will figure // that out, and filesystem-based tests are simply wrong in the // general case (think of iSCSI). // We need some info from the source disks ComPtr pSourceDisk; //DeviceType_T deviceType = DeviceType_HardDisk;// by default Log(("Finding source disk \"%ls\"\n", bstrSrcFilePath.raw())); HRESULT rc; if (pDiskEntry->type == VirtualSystemDescriptionType_HardDiskImage) { rc = mVirtualBox->OpenMedium(bstrSrcFilePath.raw(), DeviceType_HardDisk, AccessMode_ReadWrite, FALSE /* fForceNewUuid */, pSourceDisk.asOutParam()); if (FAILED(rc)) throw rc; } else if (pDiskEntry->type == VirtualSystemDescriptionType_CDROM)//may be, this is CD/DVD { rc = mVirtualBox->OpenMedium(bstrSrcFilePath.raw(), DeviceType_DVD, AccessMode_ReadOnly, FALSE, pSourceDisk.asOutParam()); if (FAILED(rc)) throw rc; } Bstr uuidSource; rc = pSourceDisk->COMGETTER(Id)(uuidSource.asOutParam()); if (FAILED(rc)) throw rc; Guid guidSource(uuidSource); // output filename const Utf8Str &strTargetFileNameOnly = pDiskEntry->strOvf; // target path needs to be composed from where the output OVF is Utf8Str strTargetFilePath(strPath); strTargetFilePath.stripFilename(); strTargetFilePath.append("/"); strTargetFilePath.append(strTargetFileNameOnly); // We are always exporting to VMDK stream optimized for now //Bstr bstrSrcFormat = L"VMDK";//not used diskList.push_back(strTargetFilePath); LONG64 cbCapacity = 0; // size reported to guest rc = pSourceDisk->COMGETTER(LogicalSize)(&cbCapacity); if (FAILED(rc)) throw rc; /// @todo r=poetzsch: wrong it is reported in bytes ... // capacity is reported in megabytes, so... //cbCapacity *= _1M; Guid guidTarget; /* Creates a new uniq number for the target disk. */ guidTarget.create(); // now handle the XML for the disk: Utf8StrFmt strFileRef("file%RI32", ulFile++); // xml::ElementNode *pelmFile = pelmReferences->createChild("File"); pelmFile->setAttribute("ovf:id", strFileRef); pelmFile->setAttribute("ovf:href", strTargetFileNameOnly); /// @todo the actual size is not available at this point of time, // cause the disk will be compressed. The 1.0 standard says this is // optional! 1.1 isn't fully clear if the "gzip" format is used. // Need to be checked. */ // pelmFile->setAttribute("ovf:size", Utf8StrFmt("%RI64", cbFile).c_str()); // add disk to XML Disks section // xml::ElementNode *pelmDisk = pelmDiskSection->createChild("Disk"); pelmDisk->setAttribute("ovf:capacity", Utf8StrFmt("%RI64", cbCapacity).c_str()); pelmDisk->setAttribute("ovf:diskId", strDiskID); pelmDisk->setAttribute("ovf:fileRef", strFileRef); if (pDiskEntry->type == VirtualSystemDescriptionType_HardDiskImage)//deviceType == DeviceType_HardDisk { pelmDisk->setAttribute("ovf:format", (enFormat == ovf::OVFVersion_0_9) ? "http://www.vmware.com/specifications/vmdk.html#sparse" // must be sparse or ovftoo : "http://www.vmware.com/interfaces/specifications/vmdk.html#streamOptimized" // correct string as communicated to us by VMware (public bug #6612) ); } else //pDiskEntry->type == VirtualSystemDescriptionType_CDROM, deviceType == DeviceType_DVD { pelmDisk->setAttribute("ovf:format", "http://www.ecma-international.org/publications/standards/Ecma-119.htm" ); } // add the UUID of the newly target image to the OVF disk element, but in the // vbox: namespace since it's not part of the standard pelmDisk->setAttribute("vbox:uuid", Utf8StrFmt("%RTuuid", guidTarget.raw()).c_str()); // now, we might have other XML elements from vbox:Machine pointing to this image, // but those would refer to the UUID of the _source_ image (which we created the // export image from); those UUIDs need to be fixed to the export image Utf8Str strGuidSourceCurly = guidSource.toStringCurly(); for (std::list::const_iterator it = llElementsWithUuidAttributes.begin(); it != llElementsWithUuidAttributes.end(); ++it) { xml::ElementNode *pelmImage = *it; Utf8Str strUUID; pelmImage->getAttributeValue("uuid", strUUID); if (strUUID == strGuidSourceCurly) // overwrite existing uuid attribute pelmImage->setAttribute("uuid", guidTarget.toStringCurly()); } } llElementsWithUuidAttributes.clear(); stack.mapDiskSequenceForOneVM.clear(); } // now, fill in the network section we set up empty above according // to the networks we found with the hardware items for (map::const_iterator it = stack.mapNetworks.begin(); it != stack.mapNetworks.end(); ++it) { const Utf8Str &strNetwork = it->first; xml::ElementNode *pelmNetwork = pelmNetworkSection->createChild("Network"); pelmNetwork->setAttribute("ovf:name", strNetwork.c_str()); pelmNetwork->createChild("Description")->addContent("Logical network used by this appliance."); } } /** * Called from Appliance::i_buildXML() for each virtual system (machine) that * needs XML written out. * * @param writeLock The current write lock. * @param elmToAddVirtualSystemsTo XML element to append elements to. * @param pllElementsWithUuidAttributes out: list of XML elements produced here * with UUID attributes for quick * fixing by caller later * @param vsdescThis The IVirtualSystemDescription * instance for which to write XML. * @param enFormat OVF format (0.9 or 1.0). * @param stack Structure for temporary private * data shared with caller. */ void Appliance::i_buildXMLForOneVirtualSystem(AutoWriteLockBase& writeLock, xml::ElementNode &elmToAddVirtualSystemsTo, std::list *pllElementsWithUuidAttributes, ComObjPtr &vsdescThis, ovf::OVFVersion_T enFormat, XMLStack &stack) { LogFlowFunc(("ENTER appliance %p\n", this)); xml::ElementNode *pelmVirtualSystem; if (enFormat == ovf::OVFVersion_0_9) { //
pelmVirtualSystem = elmToAddVirtualSystemsTo.createChild("Content"); pelmVirtualSystem->setAttribute("xsi:type", "ovf:VirtualSystem_Type"); } else pelmVirtualSystem = elmToAddVirtualSystemsTo.createChild("VirtualSystem"); /*xml::ElementNode *pelmVirtualSystemInfo =*/ pelmVirtualSystem->createChild("Info")->addContent("A virtual machine"); std::list llName = vsdescThis->i_findByType(VirtualSystemDescriptionType_Name); if (llName.empty()) throw setError(VBOX_E_NOT_SUPPORTED, tr("Missing VM name")); Utf8Str &strVMName = llName.back()->strVBoxCurrent; pelmVirtualSystem->setAttribute("ovf:id", strVMName); // product info std::list llProduct = vsdescThis->i_findByType(VirtualSystemDescriptionType_Product); std::list llProductUrl = vsdescThis->i_findByType(VirtualSystemDescriptionType_ProductUrl); std::list llVendor = vsdescThis->i_findByType(VirtualSystemDescriptionType_Vendor); std::list llVendorUrl = vsdescThis->i_findByType(VirtualSystemDescriptionType_VendorUrl); std::list llVersion = vsdescThis->i_findByType(VirtualSystemDescriptionType_Version); bool fProduct = llProduct.size() && !llProduct.back()->strVBoxCurrent.isEmpty(); bool fProductUrl = llProductUrl.size() && !llProductUrl.back()->strVBoxCurrent.isEmpty(); bool fVendor = llVendor.size() && !llVendor.back()->strVBoxCurrent.isEmpty(); bool fVendorUrl = llVendorUrl.size() && !llVendorUrl.back()->strVBoxCurrent.isEmpty(); bool fVersion = llVersion.size() && !llVersion.back()->strVBoxCurrent.isEmpty(); if (fProduct || fProductUrl || fVendor || fVendorUrl || fVersion) { /*
Meta-information about the installed software VAtest SUN Microsystems 10.0 http://blogs.sun.com/VirtualGuru http://www.sun.com
*/ xml::ElementNode *pelmAnnotationSection; if (enFormat == ovf::OVFVersion_0_9) { //
pelmAnnotationSection = pelmVirtualSystem->createChild("Section"); pelmAnnotationSection->setAttribute("xsi:type", "ovf:ProductSection_Type"); } else pelmAnnotationSection = pelmVirtualSystem->createChild("ProductSection"); pelmAnnotationSection->createChild("Info")->addContent("Meta-information about the installed software"); if (fProduct) pelmAnnotationSection->createChild("Product")->addContent(llProduct.back()->strVBoxCurrent); if (fVendor) pelmAnnotationSection->createChild("Vendor")->addContent(llVendor.back()->strVBoxCurrent); if (fVersion) pelmAnnotationSection->createChild("Version")->addContent(llVersion.back()->strVBoxCurrent); if (fProductUrl) pelmAnnotationSection->createChild("ProductUrl")->addContent(llProductUrl.back()->strVBoxCurrent); if (fVendorUrl) pelmAnnotationSection->createChild("VendorUrl")->addContent(llVendorUrl.back()->strVBoxCurrent); } // description std::list llDescription = vsdescThis->i_findByType(VirtualSystemDescriptionType_Description); if (llDescription.size() && !llDescription.back()->strVBoxCurrent.isEmpty()) { /*
A human-readable annotation Plan 9
*/ xml::ElementNode *pelmAnnotationSection; if (enFormat == ovf::OVFVersion_0_9) { //
pelmAnnotationSection = pelmVirtualSystem->createChild("Section"); pelmAnnotationSection->setAttribute("xsi:type", "ovf:AnnotationSection_Type"); } else pelmAnnotationSection = pelmVirtualSystem->createChild("AnnotationSection"); pelmAnnotationSection->createChild("Info")->addContent("A human-readable annotation"); pelmAnnotationSection->createChild("Annotation")->addContent(llDescription.back()->strVBoxCurrent); } // license std::list llLicense = vsdescThis->i_findByType(VirtualSystemDescriptionType_License); if (llLicense.size() && !llLicense.back()->strVBoxCurrent.isEmpty()) { /* License agreement for the Virtual System. License terms can go in here. */ xml::ElementNode *pelmEulaSection; if (enFormat == ovf::OVFVersion_0_9) { pelmEulaSection = pelmVirtualSystem->createChild("Section"); pelmEulaSection->setAttribute("xsi:type", "ovf:EulaSection_Type"); } else pelmEulaSection = pelmVirtualSystem->createChild("EulaSection"); pelmEulaSection->createChild("Info")->addContent("License agreement for the virtual system"); pelmEulaSection->createChild("License")->addContent(llLicense.back()->strVBoxCurrent); } // operating system std::list llOS = vsdescThis->i_findByType(VirtualSystemDescriptionType_OS); if (llOS.empty()) throw setError(VBOX_E_NOT_SUPPORTED, tr("Missing OS type")); /* Guest Operating System Linux 2.6.x */ VirtualSystemDescriptionEntry *pvsdeOS = llOS.back(); xml::ElementNode *pelmOperatingSystemSection; if (enFormat == ovf::OVFVersion_0_9) { pelmOperatingSystemSection = pelmVirtualSystem->createChild("Section"); pelmOperatingSystemSection->setAttribute("xsi:type", "ovf:OperatingSystemSection_Type"); } else pelmOperatingSystemSection = pelmVirtualSystem->createChild("OperatingSystemSection"); pelmOperatingSystemSection->setAttribute("ovf:id", pvsdeOS->strOvf); pelmOperatingSystemSection->createChild("Info")->addContent("The kind of installed guest operating system"); Utf8Str strOSDesc; convertCIMOSType2VBoxOSType(strOSDesc, (ovf::CIMOSType_T)pvsdeOS->strOvf.toInt32(), ""); pelmOperatingSystemSection->createChild("Description")->addContent(strOSDesc); // add the VirtualBox ostype in a custom tag in a different namespace xml::ElementNode *pelmVBoxOSType = pelmOperatingSystemSection->createChild("vbox:OSType"); pelmVBoxOSType->setAttribute("ovf:required", "false"); pelmVBoxOSType->addContent(pvsdeOS->strVBoxCurrent); // xml::ElementNode *pelmVirtualHardwareSection; if (enFormat == ovf::OVFVersion_0_9) { //
pelmVirtualHardwareSection = pelmVirtualSystem->createChild("Section"); pelmVirtualHardwareSection->setAttribute("xsi:type", "ovf:VirtualHardwareSection_Type"); } else pelmVirtualHardwareSection = pelmVirtualSystem->createChild("VirtualHardwareSection"); pelmVirtualHardwareSection->createChild("Info")->addContent("Virtual hardware requirements for a virtual machine"); /* Description of the virtual hardware section. vmware 1 MyLampService vmx-4 */ xml::ElementNode *pelmSystem = pelmVirtualHardwareSection->createChild("System"); pelmSystem->createChild("vssd:ElementName")->addContent("Virtual Hardware Family"); // required OVF 1.0 // 0 if (enFormat == ovf::OVFVersion_0_9) pelmSystem->createChild("vssd:InstanceId")->addContent("0"); else // capitalization changed... pelmSystem->createChild("vssd:InstanceID")->addContent("0"); // VAtest pelmSystem->createChild("vssd:VirtualSystemIdentifier")->addContent(strVMName); // vmx-4 const char *pcszHardware = "virtualbox-2.2"; if (enFormat == ovf::OVFVersion_0_9) // pretend to be vmware compatible then pcszHardware = "vmx-6"; pelmSystem->createChild("vssd:VirtualSystemType")->addContent(pcszHardware); // loop thru all description entries twice; once to write out all // devices _except_ disk images, and a second time to assign the // disk images; this is because disk images need to reference // IDE controllers, and we can't know their instance IDs without // assigning them first uint32_t idIDEPrimaryController = 0; int32_t lIDEPrimaryControllerIndex = 0; uint32_t idIDESecondaryController = 0; int32_t lIDESecondaryControllerIndex = 0; uint32_t idSATAController = 0; int32_t lSATAControllerIndex = 0; uint32_t idSCSIController = 0; int32_t lSCSIControllerIndex = 0; uint32_t ulInstanceID = 1; uint32_t cDVDs = 0; for (size_t uLoop = 1; uLoop <= 2; ++uLoop) { int32_t lIndexThis = 0; for (vector::const_iterator it = vsdescThis->m->maDescriptions.begin(); it != vsdescThis->m->maDescriptions.end(); ++it, ++lIndexThis) { const VirtualSystemDescriptionEntry &desc = *it; LogFlowFunc(("Loop %u: handling description entry ulIndex=%u, type=%s, strRef=%s, strOvf=%s, strVBox=%s, strExtraConfig=%s\n", uLoop, desc.ulIndex, ( desc.type == VirtualSystemDescriptionType_HardDiskControllerIDE ? "HardDiskControllerIDE" : desc.type == VirtualSystemDescriptionType_HardDiskControllerSATA ? "HardDiskControllerSATA" : desc.type == VirtualSystemDescriptionType_HardDiskControllerSCSI ? "HardDiskControllerSCSI" : desc.type == VirtualSystemDescriptionType_HardDiskControllerSAS ? "HardDiskControllerSAS" : desc.type == VirtualSystemDescriptionType_HardDiskImage ? "HardDiskImage" : Utf8StrFmt("%d", desc.type).c_str()), desc.strRef.c_str(), desc.strOvf.c_str(), desc.strVBoxCurrent.c_str(), desc.strExtraConfigCurrent.c_str())); ovf::ResourceType_T type = (ovf::ResourceType_T)0; // if this becomes != 0 then we do stuff Utf8Str strResourceSubType; Utf8Str strDescription; // results in ... block Utf8Str strCaption; // results in ... block uint32_t ulParent = 0; int32_t lVirtualQuantity = -1; Utf8Str strAllocationUnits; int32_t lAddress = -1; int32_t lBusNumber = -1; int32_t lAddressOnParent = -1; int32_t lAutomaticAllocation = -1; // 0 means "false", 1 means "true" Utf8Str strConnection; // results in ... block Utf8Str strHostResource; uint64_t uTemp; ovf::VirtualHardwareItem vhi; ovf::StorageItem si; ovf::EthernetPortItem epi; switch (desc.type) { case VirtualSystemDescriptionType_CPU: /* 1 virtual CPU Number of virtual CPUs virtual CPU 1 3 1 */ if (uLoop == 1) { strDescription = "Number of virtual CPUs"; type = ovf::ResourceType_Processor; // 3 desc.strVBoxCurrent.toInt(uTemp); lVirtualQuantity = (int32_t)uTemp; strCaption = Utf8StrFmt("%d virtual CPU", lVirtualQuantity); // without this ovftool // won't eat the item } break; case VirtualSystemDescriptionType_Memory: /* MegaBytes 256 MB of memory Memory Size Memory 2 4 256 */ if (uLoop == 1) { strDescription = "Memory Size"; type = ovf::ResourceType_Memory; // 4 desc.strVBoxCurrent.toInt(uTemp); lVirtualQuantity = (int32_t)(uTemp / _1M); strAllocationUnits = "MegaBytes"; strCaption = Utf8StrFmt("%d MB of memory", lVirtualQuantity); // without this ovftool // won't eat the item } break; case VirtualSystemDescriptionType_HardDiskControllerIDE: /* ideController1 IDE Controller 5 5 1 1 */ if (uLoop == 1) { strDescription = "IDE Controller"; type = ovf::ResourceType_IDEController; // 5 strResourceSubType = desc.strVBoxCurrent; if (!lIDEPrimaryControllerIndex) { // first IDE controller: strCaption = "ideController0"; lAddress = 0; lBusNumber = 0; // remember this ID idIDEPrimaryController = ulInstanceID; lIDEPrimaryControllerIndex = lIndexThis; } else { // second IDE controller: strCaption = "ideController1"; lAddress = 1; lBusNumber = 1; // remember this ID idIDESecondaryController = ulInstanceID; lIDESecondaryControllerIndex = lIndexThis; } } break; case VirtualSystemDescriptionType_HardDiskControllerSATA: /* sataController0 SATA Controller 4 20 ahci 0 0 */ if (uLoop == 1) { strDescription = "SATA Controller"; strCaption = "sataController0"; type = ovf::ResourceType_OtherStorageDevice; // 20 // it seems that OVFTool always writes these two, and since we can only // have one SATA controller, we'll use this as well lAddress = 0; lBusNumber = 0; if ( desc.strVBoxCurrent.isEmpty() // AHCI is the default in VirtualBox || (!desc.strVBoxCurrent.compare("ahci", Utf8Str::CaseInsensitive)) ) strResourceSubType = "AHCI"; else throw setError(VBOX_E_NOT_SUPPORTED, tr("Invalid config string \"%s\" in SATA controller"), desc.strVBoxCurrent.c_str()); // remember this ID idSATAController = ulInstanceID; lSATAControllerIndex = lIndexThis; } break; case VirtualSystemDescriptionType_HardDiskControllerSCSI: case VirtualSystemDescriptionType_HardDiskControllerSAS: /* scsiController0 SCSI Controller 4 6 buslogic 0 0 */ if (uLoop == 1) { strDescription = "SCSI Controller"; strCaption = "scsiController0"; type = ovf::ResourceType_ParallelSCSIHBA; // 6 // it seems that OVFTool always writes these two, and since we can only // have one SATA controller, we'll use this as well lAddress = 0; lBusNumber = 0; if ( desc.strVBoxCurrent.isEmpty() // LsiLogic is the default in VirtualBox || (!desc.strVBoxCurrent.compare("lsilogic", Utf8Str::CaseInsensitive)) ) strResourceSubType = "lsilogic"; else if (!desc.strVBoxCurrent.compare("buslogic", Utf8Str::CaseInsensitive)) strResourceSubType = "buslogic"; else if (!desc.strVBoxCurrent.compare("lsilogicsas", Utf8Str::CaseInsensitive)) strResourceSubType = "lsilogicsas"; else throw setError(VBOX_E_NOT_SUPPORTED, tr("Invalid config string \"%s\" in SCSI/SAS controller"), desc.strVBoxCurrent.c_str()); // remember this ID idSCSIController = ulInstanceID; lSCSIControllerIndex = lIndexThis; } break; case VirtualSystemDescriptionType_HardDiskImage: /* disk1 8 17 /disk/vmdisk1 4 0 */ if (uLoop == 2) { uint32_t cDisks = (uint32_t)stack.mapDisks.size(); Utf8Str strDiskID = Utf8StrFmt("vmdisk%RI32", ++cDisks); strDescription = "Disk Image"; strCaption = Utf8StrFmt("disk%RI32", cDisks); // this is not used for anything else type = ovf::ResourceType_HardDisk; // 17 // the following references the "" XML block strHostResource = Utf8StrFmt("/disk/%s", strDiskID.c_str()); // controller=;channel= size_t pos1 = desc.strExtraConfigCurrent.find("controller="); size_t pos2 = desc.strExtraConfigCurrent.find("channel="); int32_t lControllerIndex = -1; if (pos1 != Utf8Str::npos) { RTStrToInt32Ex(desc.strExtraConfigCurrent.c_str() + pos1 + 11, NULL, 0, &lControllerIndex); if (lControllerIndex == lIDEPrimaryControllerIndex) ulParent = idIDEPrimaryController; else if (lControllerIndex == lIDESecondaryControllerIndex) ulParent = idIDESecondaryController; else if (lControllerIndex == lSCSIControllerIndex) ulParent = idSCSIController; else if (lControllerIndex == lSATAControllerIndex) ulParent = idSATAController; } if (pos2 != Utf8Str::npos) RTStrToInt32Ex(desc.strExtraConfigCurrent.c_str() + pos2 + 8, NULL, 0, &lAddressOnParent); LogFlowFunc(("HardDiskImage details: pos1=%d, pos2=%d, lControllerIndex=%d, lIDEPrimaryControllerIndex=%d, lIDESecondaryControllerIndex=%d, ulParent=%d, lAddressOnParent=%d\n", pos1, pos2, lControllerIndex, lIDEPrimaryControllerIndex, lIDESecondaryControllerIndex, ulParent, lAddressOnParent)); if ( !ulParent || lAddressOnParent == -1 ) throw setError(VBOX_E_NOT_SUPPORTED, tr("Missing or bad extra config string in hard disk image: \"%s\""), desc.strExtraConfigCurrent.c_str()); stack.mapDisks[strDiskID] = &desc; //use the list stack.mapDiskSequence where the disks go as the "VirtualSystem" should be placed //in the OVF description file. stack.mapDiskSequence.push_back(strDiskID); stack.mapDiskSequenceForOneVM.push_back(strDiskID); } break; case VirtualSystemDescriptionType_Floppy: if (uLoop == 1) { strDescription = "Floppy Drive"; strCaption = "floppy0"; // this is what OVFTool writes type = ovf::ResourceType_FloppyDrive; // 14 lAutomaticAllocation = 0; lAddressOnParent = 0; // this is what OVFTool writes } break; case VirtualSystemDescriptionType_CDROM: /* cdrom1 8 15 /disk/cdrom1 4 0 */ if (uLoop == 2) { uint32_t cDisks = (uint32_t)stack.mapDisks.size(); Utf8Str strDiskID = Utf8StrFmt("iso%RI32", ++cDisks); ++cDVDs; strDescription = "CD-ROM Drive"; strCaption = Utf8StrFmt("cdrom%RI32", cDVDs); // OVFTool starts with 1 type = ovf::ResourceType_CDDrive; // 15 lAutomaticAllocation = 1; //skip empty Medium. There are no information to add into section or if (desc.strVBoxCurrent.isNotEmpty() && desc.skipIt == false) { // the following references the "" XML block strHostResource = Utf8StrFmt("/disk/%s", strDiskID.c_str()); } // controller=;channel= size_t pos1 = desc.strExtraConfigCurrent.find("controller="); size_t pos2 = desc.strExtraConfigCurrent.find("channel="); int32_t lControllerIndex = -1; if (pos1 != Utf8Str::npos) { RTStrToInt32Ex(desc.strExtraConfigCurrent.c_str() + pos1 + 11, NULL, 0, &lControllerIndex); if (lControllerIndex == lIDEPrimaryControllerIndex) ulParent = idIDEPrimaryController; else if (lControllerIndex == lIDESecondaryControllerIndex) ulParent = idIDESecondaryController; else if (lControllerIndex == lSCSIControllerIndex) ulParent = idSCSIController; else if (lControllerIndex == lSATAControllerIndex) ulParent = idSATAController; } if (pos2 != Utf8Str::npos) RTStrToInt32Ex(desc.strExtraConfigCurrent.c_str() + pos2 + 8, NULL, 0, &lAddressOnParent); LogFlowFunc(("DVD drive details: pos1=%d, pos2=%d, lControllerIndex=%d, lIDEPrimaryControllerIndex=%d, lIDESecondaryControllerIndex=%d, ulParent=%d, lAddressOnParent=%d\n", pos1, pos2, lControllerIndex, lIDEPrimaryControllerIndex, lIDESecondaryControllerIndex, ulParent, lAddressOnParent)); if ( !ulParent || lAddressOnParent == -1 ) throw setError(VBOX_E_NOT_SUPPORTED, tr("Missing or bad extra config string in DVD drive medium: \"%s\""), desc.strExtraConfigCurrent.c_str()); stack.mapDisks[strDiskID] = &desc; //use the list stack.mapDiskSequence where the disks go as the "VirtualSystem" should be placed //in the OVF description file. stack.mapDiskSequence.push_back(strDiskID); stack.mapDiskSequenceForOneVM.push_back(strDiskID); // there is no DVD drive map to update because it is // handled completely with this entry. } break; case VirtualSystemDescriptionType_NetworkAdapter: /* true Ethernet adapter on 'VM Network' VM Network VM network 3 10 */ if (uLoop == 2) { lAutomaticAllocation = 1; strCaption = Utf8StrFmt("Ethernet adapter on '%s'", desc.strOvf.c_str()); type = ovf::ResourceType_EthernetAdapter; // 10 /* Set the hardware type to something useful. * To be compatible with vmware & others we set * PCNet32 for our PCNet types & E1000 for the * E1000 cards. */ switch (desc.strVBoxCurrent.toInt32()) { case NetworkAdapterType_Am79C970A: case NetworkAdapterType_Am79C973: strResourceSubType = "PCNet32"; break; #ifdef VBOX_WITH_E1000 case NetworkAdapterType_I82540EM: case NetworkAdapterType_I82545EM: case NetworkAdapterType_I82543GC: strResourceSubType = "E1000"; break; #endif /* VBOX_WITH_E1000 */ } strConnection = desc.strOvf; stack.mapNetworks[desc.strOvf] = true; } break; case VirtualSystemDescriptionType_USBController: /* usb USB Controller 3 23 0 0 */ if (uLoop == 1) { strDescription = "USB Controller"; strCaption = "usb"; type = ovf::ResourceType_USBController; // 23 lAddress = 0; // this is what OVFTool writes lBusNumber = 0; // this is what OVFTool writes } break; case VirtualSystemDescriptionType_SoundCard: /* sound Sound Card 10 35 ensoniq1371 false 3 */ if (uLoop == 1) { strDescription = "Sound Card"; strCaption = "sound"; type = ovf::ResourceType_SoundCard; // 35 strResourceSubType = desc.strOvf; // e.g. ensoniq1371 lAutomaticAllocation = 0; lAddressOnParent = 3; // what gives? this is what OVFTool writes } break; default: break; /* Shut up MSC. */ } if (type) { xml::ElementNode *pItem; xml::ElementNode *pItemHelper; RTCString itemElement; RTCString itemElementHelper; if (enFormat == ovf::OVFVersion_2_0) { if(uLoop == 2) { if (desc.type == VirtualSystemDescriptionType_NetworkAdapter) { itemElement = "epasd:"; pItem = pelmVirtualHardwareSection->createChild("EthernetPortItem"); } else if (desc.type == VirtualSystemDescriptionType_CDROM || desc.type == VirtualSystemDescriptionType_HardDiskImage) { itemElement = "sasd:"; pItem = pelmVirtualHardwareSection->createChild("StorageItem"); } else pItem = NULL; } else { itemElement = "rasd:"; pItem = pelmVirtualHardwareSection->createChild("Item"); } } else { itemElement = "rasd:"; pItem = pelmVirtualHardwareSection->createChild("Item"); } // NOTE: DO NOT CHANGE THE ORDER of these items! The OVF standards prescribes that // the elements from the rasd: namespace must be sorted by letter, and VMware // actually requires this as well (see public bug #6612) if (lAddress != -1) { //pItem->createChild("rasd:Address")->addContent(Utf8StrFmt("%d", lAddress)); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("Address").c_str()); pItemHelper->addContent(Utf8StrFmt("%d", lAddress)); } if (lAddressOnParent != -1) { //pItem->createChild("rasd:AddressOnParent")->addContent(Utf8StrFmt("%d", lAddressOnParent)); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("AddressOnParent").c_str()); pItemHelper->addContent(Utf8StrFmt("%d", lAddressOnParent)); } if (!strAllocationUnits.isEmpty()) { //pItem->createChild("rasd:AllocationUnits")->addContent(strAllocationUnits); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("AllocationUnits").c_str()); pItemHelper->addContent(strAllocationUnits); } if (lAutomaticAllocation != -1) { //pItem->createChild("rasd:AutomaticAllocation")->addContent( (lAutomaticAllocation) ? "true" : "false" ); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("AutomaticAllocation").c_str()); pItemHelper->addContent((lAutomaticAllocation) ? "true" : "false" ); } if (lBusNumber != -1) { if (enFormat == ovf::OVFVersion_0_9) { // BusNumber is invalid OVF 1.0 so only write it in 0.9 mode for OVFTool //pItem->createChild("rasd:BusNumber")->addContent(Utf8StrFmt("%d", lBusNumber)); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("BusNumber").c_str()); pItemHelper->addContent(Utf8StrFmt("%d", lBusNumber)); } } if (!strCaption.isEmpty()) { //pItem->createChild("rasd:Caption")->addContent(strCaption); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("Caption").c_str()); pItemHelper->addContent(strCaption); } if (!strConnection.isEmpty()) { //pItem->createChild("rasd:Connection")->addContent(strConnection); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("Connection").c_str()); pItemHelper->addContent(strConnection); } if (!strDescription.isEmpty()) { //pItem->createChild("rasd:Description")->addContent(strDescription); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("Description").c_str()); pItemHelper->addContent(strDescription); } if (!strCaption.isEmpty()) { if (enFormat == ovf::OVFVersion_1_0) { //pItem->createChild("rasd:ElementName")->addContent(strCaption); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("ElementName").c_str()); pItemHelper->addContent(strCaption); } } if (!strHostResource.isEmpty()) { //pItem->createChild("rasd:HostResource")->addContent(strHostResource); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("HostResource").c_str()); pItemHelper->addContent(strHostResource); } { // 1 itemElementHelper = itemElement; if (enFormat == ovf::OVFVersion_0_9) //pelmInstanceID = pItem->createChild("rasd:InstanceId"); pItemHelper = pItem->createChild(itemElementHelper.append("InstanceId").c_str()); else //pelmInstanceID = pItem->createChild("rasd:InstanceID"); // capitalization changed... pItemHelper = pItem->createChild(itemElementHelper.append("InstanceID").c_str()); pItemHelper->addContent(Utf8StrFmt("%d", ulInstanceID++)); } if (ulParent) { //pItem->createChild("rasd:Parent")->addContent(Utf8StrFmt("%d", ulParent)); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("Parent").c_str()); pItemHelper->addContent(Utf8StrFmt("%d", ulParent)); } if (!strResourceSubType.isEmpty()) { //pItem->createChild("rasd:ResourceSubType")->addContent(strResourceSubType); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("ResourceSubType").c_str()); pItemHelper->addContent(strResourceSubType); } { // 3 //pItem->createChild("rasd:ResourceType")->addContent(Utf8StrFmt("%d", type)); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("ResourceType").c_str()); pItemHelper->addContent(Utf8StrFmt("%d", type)); } // 1 if (lVirtualQuantity != -1) { //pItem->createChild("rasd:VirtualQuantity")->addContent(Utf8StrFmt("%d", lVirtualQuantity)); itemElementHelper = itemElement; pItemHelper = pItem->createChild(itemElementHelper.append("VirtualQuantity").c_str()); pItemHelper->addContent(Utf8StrFmt("%d", lVirtualQuantity)); } } } } // for (size_t uLoop = 1; uLoop <= 2; ++uLoop) // now that we're done with the official OVF tags under , write out VirtualBox XML // under the vbox: namespace xml::ElementNode *pelmVBoxMachine = pelmVirtualSystem->createChild("vbox:Machine"); // ovf:required="false" tells other OVF parsers that they can ignore this thing pelmVBoxMachine->setAttribute("ovf:required", "false"); // ovf:Info element is required or VMware will bail out on the vbox:Machine element pelmVBoxMachine->createChild("ovf:Info")->addContent("Complete VirtualBox machine configuration in VirtualBox format"); // create an empty machine config // use the same settings version as the current VM settings file settings::MachineConfigFile *pConfig = new settings::MachineConfigFile(&vsdescThis->m->pMachine->i_getSettingsFileFull()); writeLock.release(); try { AutoWriteLock machineLock(vsdescThis->m->pMachine COMMA_LOCKVAL_SRC_POS); // fill the machine config vsdescThis->m->pMachine->i_copyMachineDataToSettings(*pConfig); pConfig->machineUserData.strName = strVMName; // Apply export tweaks to machine settings bool fStripAllMACs = m->optListExport.contains(ExportOptions_StripAllMACs); bool fStripAllNonNATMACs = m->optListExport.contains(ExportOptions_StripAllNonNATMACs); if (fStripAllMACs || fStripAllNonNATMACs) { for (settings::NetworkAdaptersList::iterator it = pConfig->hardwareMachine.llNetworkAdapters.begin(); it != pConfig->hardwareMachine.llNetworkAdapters.end(); ++it) { settings::NetworkAdapter &nic = *it; if (fStripAllMACs || (fStripAllNonNATMACs && nic.mode != NetworkAttachmentType_NAT)) nic.strMACAddress.setNull(); } } // write the machine config to the vbox:Machine element pConfig->buildMachineXML(*pelmVBoxMachine, settings::MachineConfigFile::BuildMachineXML_WriteVBoxVersionAttribute /*| settings::MachineConfigFile::BuildMachineXML_SkipRemovableMedia*/ | settings::MachineConfigFile::BuildMachineXML_SuppressSavedState, // but not BuildMachineXML_IncludeSnapshots nor BuildMachineXML_MediaRegistry pllElementsWithUuidAttributes); delete pConfig; } catch (...) { writeLock.acquire(); delete pConfig; throw; } writeLock.acquire(); } /** * Actual worker code for writing out OVF/OVA to disk. This is called from Appliance::taskThreadWriteOVF() * and therefore runs on the OVF/OVA write worker thread. * * This runs in one context: * * 1) in a first worker thread; in that case, Appliance::Write() called Appliance::i_writeImpl(); * * @param pTask * @return */ HRESULT Appliance::i_writeFS(TaskOVF *pTask) { LogFlowFuncEnter(); LogFlowFunc(("ENTER appliance %p\n", this)); AutoCaller autoCaller(this); if (FAILED(autoCaller.rc())) return autoCaller.rc(); HRESULT rc = S_OK; // Lock the media tree early to make sure nobody else tries to make changes // to the tree. Also lock the IAppliance object for writing. AutoMultiWriteLock2 multiLock(&mVirtualBox->i_getMediaTreeLockHandle(), this->lockHandle() COMMA_LOCKVAL_SRC_POS); // Additional protect the IAppliance object, cause we leave the lock // when starting the disk export and we don't won't block other // callers on this lengthy operations. m->state = Data::ApplianceExporting; if (pTask->locInfo.strPath.endsWith(".ovf", Utf8Str::CaseInsensitive)) rc = i_writeFSOVF(pTask, multiLock); else rc = i_writeFSOVA(pTask, multiLock); // reset the state so others can call methods again m->state = Data::ApplianceIdle; LogFlowFunc(("rc=%Rhrc\n", rc)); LogFlowFuncLeave(); return rc; } HRESULT Appliance::i_writeFSOVF(TaskOVF *pTask, AutoWriteLockBase& writeLock) { LogFlowFuncEnter(); /* * Create write-to-dir file system stream for the target directory. * This unifies the disk access with the TAR based OVA variant. */ HRESULT hrc; int vrc; RTVFSFSSTREAM hVfsFss2Dir = NIL_RTVFSFSSTREAM; try { Utf8Str strTargetDir(pTask->locInfo.strPath); strTargetDir.stripFilename(); vrc = RTVfsFsStrmToNormalDir(strTargetDir.c_str(), 0 /*fFlags*/, &hVfsFss2Dir); if (RT_SUCCESS(vrc)) hrc = S_OK; else hrc = setErrorVrc(vrc, tr("Failed to open directory '%s' (%Rrc)"), strTargetDir.c_str(), vrc); } catch (std::bad_alloc &) { hrc = E_OUTOFMEMORY; } if (SUCCEEDED(hrc)) { /* * Join i_writeFSOVA. On failure, delete (undo) anything we might * have written to the disk before failing. */ hrc = i_writeFSImpl(pTask, writeLock, hVfsFss2Dir); if (FAILED(hrc)) RTVfsFsStrmToDirUndo(hVfsFss2Dir); RTVfsFsStrmRelease(hVfsFss2Dir); } LogFlowFuncLeave(); return hrc; } HRESULT Appliance::i_writeFSOVA(TaskOVF *pTask, AutoWriteLockBase &writeLock) { LogFlowFuncEnter(); /* * Open the output file and attach a TAR creator to it. * The OVF 1.1.0 spec specifies the TAR format to be compatible with USTAR * according to POSIX 1003.1-2008. We use the 1988 spec here as it's the * only variant we currently implement. */ HRESULT hrc; RTVFSIOSTREAM hVfsIosTar; int vrc = RTVfsIoStrmOpenNormal(pTask->locInfo.strPath.c_str(), RTFILE_O_CREATE | RTFILE_O_WRITE | RTFILE_O_DENY_WRITE, &hVfsIosTar); if (RT_SUCCESS(vrc)) { RTVFSFSSTREAM hVfsFssTar; vrc = RTZipTarFsStreamToIoStream(hVfsIosTar, RTZIPTARFORMAT_USTAR, 0 /*fFlags*/, &hVfsFssTar); RTVfsIoStrmRelease(hVfsIosTar); if (RT_SUCCESS(vrc)) { RTZipTarFsStreamSetFileMode(hVfsFssTar, 0660, 0440); RTZipTarFsStreamSetOwner(hVfsFssTar, VBOX_VERSION_MAJOR, pTask->enFormat == ovf::OVFVersion_0_9 ? "vboxovf09" : pTask->enFormat == ovf::OVFVersion_1_0 ? "vboxovf10" : pTask->enFormat == ovf::OVFVersion_2_0 ? "vboxovf20" : "vboxovf"); RTZipTarFsStreamSetGroup(hVfsFssTar, VBOX_VERSION_MINOR, "vbox_v" RT_XSTR(VBOX_VERSION_MAJOR) "." RT_XSTR(VBOX_VERSION_MINOR) "." RT_XSTR(VBOX_VERSION_BUILD) "r" RT_XSTR(VBOX_SVN_REV)); hrc = i_writeFSImpl(pTask, writeLock, hVfsFssTar); RTVfsFsStrmRelease(hVfsFssTar); } else hrc = setErrorVrc(vrc, tr("Failed create TAR creator for '%s' (%Rrc)"), pTask->locInfo.strPath.c_str(), vrc); /* Delete the OVA on failure. */ if (FAILED(hrc)) RTFileDelete(pTask->locInfo.strPath.c_str()); } else hrc = setErrorVrc(vrc, tr("Failed to open '%s' for writing (%Rrc)"), pTask->locInfo.strPath.c_str(), vrc); LogFlowFuncLeave(); return hrc; } /** * Upload the image to the OCI Storage service, next import the * uploaded image into internal OCI image format and launch an * instance with this image in the OCI Compute service. */ HRESULT Appliance::i_exportCloudImpl(TaskCloud *pTask) { LogFlowFuncEnter(); HRESULT hrc = S_OK; ComPtr cpm; hrc = mVirtualBox->COMGETTER(CloudProviderManager)(cpm.asOutParam()); if (FAILED(hrc)) return setErrorVrc(VERR_COM_OBJECT_NOT_FOUND, tr("%: Cloud provider manager object wasn't found", __FUNCTION__)); Utf8Str strProviderName = pTask->locInfo.strProvider; ComPtr cloudProvider; ComPtr cloudProfile; hrc = cpm->GetProviderByShortName(Bstr(strProviderName.c_str()).raw(), cloudProvider.asOutParam()); if (FAILED(hrc)) return setErrorVrc(VERR_COM_OBJECT_NOT_FOUND, tr("%s: Cloud provider object wasn't found", __FUNCTION__)); ComPtr vsd = m->virtualSystemDescriptions.front(); com::SafeArray retTypes; com::SafeArray aRefs; com::SafeArray aOvfValues; com::SafeArray aVBoxValues; com::SafeArray aExtraConfigValues; hrc = vsd->GetDescriptionByType(VirtualSystemDescriptionType_CloudProfileName, ComSafeArrayAsOutParam(retTypes), ComSafeArrayAsOutParam(aRefs), ComSafeArrayAsOutParam(aOvfValues), ComSafeArrayAsOutParam(aVBoxValues), ComSafeArrayAsOutParam(aExtraConfigValues)); if (FAILED(hrc)) return hrc; Utf8Str profileName(aVBoxValues[0]); if (profileName.isEmpty()) return setErrorVrc(VBOX_E_OBJECT_NOT_FOUND, tr("%s: Cloud user profile name wasn't found", __FUNCTION__)); hrc = cloudProvider->GetProfileByName(aVBoxValues[0], cloudProfile.asOutParam()); if (FAILED(hrc)) return setErrorVrc(VERR_COM_OBJECT_NOT_FOUND, tr("%s: Cloud profile object wasn't found", __FUNCTION__)); ComObjPtr cloudClient; hrc = cloudProfile->CreateCloudClient(cloudClient.asOutParam()); if (FAILED(hrc)) return setErrorVrc(VERR_COM_OBJECT_NOT_FOUND, tr("%s: Cloud client object wasn't found", __FUNCTION__)); if (m->virtualSystemDescriptions.size() == 1) { ComPtr VBox(mVirtualBox); hrc = cloudClient->ExportLaunchVM(m->virtualSystemDescriptions.front(), pTask->pProgress, VBox); } else hrc = setErrorVrc(VERR_MISMATCH, tr("Export to Cloud isn't supported for more than one VM instance.")); LogFlowFuncLeave(); return hrc; } /** * Writes the Oracle Public Cloud appliance. * * It expect raw disk images inside a gzipped tarball. We enable sparse files * to save diskspace on the target host system. */ HRESULT Appliance::i_writeFSOPC(TaskOPC *pTask) { LogFlowFuncEnter(); HRESULT hrc = S_OK; // Lock the media tree early to make sure nobody else tries to make changes // to the tree. Also lock the IAppliance object for writing. AutoMultiWriteLock2 multiLock(&mVirtualBox->i_getMediaTreeLockHandle(), this->lockHandle() COMMA_LOCKVAL_SRC_POS); // Additional protect the IAppliance object, cause we leave the lock // when starting the disk export and we don't won't block other // callers on this lengthy operations. m->state = Data::ApplianceExporting; /* * We're duplicating parts of i_writeFSImpl here because that's simpler * and creates less spaghetti code. */ std::list lstTarballs; /* * Use i_buildXML to build a stack of disk images. We don't care about the XML doc here. */ XMLStack stack; { xml::Document doc; i_buildXML(multiLock, doc, stack, pTask->locInfo.strPath, ovf::OVFVersion_2_0); } /* * Process the disk images. */ unsigned cTarballs = 0; for (list::const_iterator it = stack.mapDiskSequence.begin(); it != stack.mapDiskSequence.end(); ++it) { const Utf8Str &strDiskID = *it; const VirtualSystemDescriptionEntry *pDiskEntry = stack.mapDisks[strDiskID]; const Utf8Str &strSrcFilePath = pDiskEntry->strVBoxCurrent; // where the VBox image is /* * Some skipping. */ if (pDiskEntry->skipIt) continue; /* Skip empty media (DVD-ROM, floppy). */ if (strSrcFilePath.isEmpty()) continue; /* Only deal with harddisk and DVD-ROMs, skip any floppies for now. */ if ( pDiskEntry->type != VirtualSystemDescriptionType_HardDiskImage && pDiskEntry->type != VirtualSystemDescriptionType_CDROM) continue; /* * Locate the Medium object for this entry (by location/path). */ Log(("Finding source disk \"%s\"\n", strSrcFilePath.c_str())); ComObjPtr ptrSourceDisk; if (pDiskEntry->type == VirtualSystemDescriptionType_HardDiskImage) hrc = mVirtualBox->i_findHardDiskByLocation(strSrcFilePath, true /*aSetError*/, &ptrSourceDisk); else hrc = mVirtualBox->i_findDVDOrFloppyImage(DeviceType_DVD, NULL /*aId*/, strSrcFilePath, true /*aSetError*/, &ptrSourceDisk); if (FAILED(hrc)) break; if (strSrcFilePath.isEmpty()) continue; /* * Figure out the names. */ /* The name inside the tarball. Replace the suffix of harddisk images with ".img". */ Utf8Str strInsideName = pDiskEntry->strOvf; if (pDiskEntry->type == VirtualSystemDescriptionType_HardDiskImage) strInsideName.stripSuffix().append(".img"); /* The first tarball we create uses the specified name. Subsequent takes the name from the disk entry or something. */ Utf8Str strTarballPath = pTask->locInfo.strPath; if (cTarballs > 0) { strTarballPath.stripFilename().append(RTPATH_SLASH_STR).append(pDiskEntry->strOvf); const char *pszExt = RTPathSuffix(pDiskEntry->strOvf.c_str()); if (pszExt && pszExt[0] == '.' && pszExt[1] != '\0') { strTarballPath.stripSuffix(); if (pDiskEntry->type != VirtualSystemDescriptionType_HardDiskImage) strTarballPath.append("_").append(&pszExt[1]); } strTarballPath.append(".tar.gz"); } cTarballs++; /* * Create the tar output stream. */ RTVFSIOSTREAM hVfsIosFile; int vrc = RTVfsIoStrmOpenNormal(strTarballPath.c_str(), RTFILE_O_CREATE | RTFILE_O_WRITE | RTFILE_O_DENY_WRITE, &hVfsIosFile); if (RT_SUCCESS(vrc)) { RTVFSIOSTREAM hVfsIosGzip = NIL_RTVFSIOSTREAM; vrc = RTZipGzipCompressIoStream(hVfsIosFile, 0 /*fFlags*/, 6 /*uLevel*/, &hVfsIosGzip); RTVfsIoStrmRelease(hVfsIosFile); /** @todo insert I/O thread here between gzip and the tar creator. Needs * implementing. */ RTVFSFSSTREAM hVfsFssTar = NIL_RTVFSFSSTREAM; if (RT_SUCCESS(vrc)) vrc = RTZipTarFsStreamToIoStream(hVfsIosGzip, RTZIPTARFORMAT_GNU, RTZIPTAR_C_SPARSE, &hVfsFssTar); RTVfsIoStrmRelease(hVfsIosGzip); if (RT_SUCCESS(vrc)) { RTZipTarFsStreamSetFileMode(hVfsFssTar, 0660, 0440); RTZipTarFsStreamSetOwner(hVfsFssTar, VBOX_VERSION_MAJOR, "vboxopc10"); RTZipTarFsStreamSetGroup(hVfsFssTar, VBOX_VERSION_MINOR, "vbox_v" RT_XSTR(VBOX_VERSION_MAJOR) "." RT_XSTR(VBOX_VERSION_MINOR) "." RT_XSTR(VBOX_VERSION_BUILD) "r" RT_XSTR(VBOX_SVN_REV)); /* * Let the Medium code do the heavy work. * * The exporting requests a lock on the media tree. So temporarily * leave the appliance lock. */ multiLock.release(); pTask->pProgress->SetNextOperation(BstrFmt(tr("Exporting to disk image '%Rbn'"), strTarballPath.c_str()).raw(), pDiskEntry->ulSizeMB); // operation's weight, as set up // with the IProgress originally hrc = ptrSourceDisk->i_addRawToFss(strInsideName.c_str(), m->m_pSecretKeyStore, hVfsFssTar, pTask->pProgress, true /*fSparse*/); multiLock.acquire(); if (SUCCEEDED(hrc)) { /* * Complete and close the tarball. */ vrc = RTVfsFsStrmEnd(hVfsFssTar); RTVfsFsStrmRelease(hVfsFssTar); hVfsFssTar = NIL_RTVFSFSSTREAM; if (RT_SUCCESS(vrc)) { /* Remember the tarball name for cleanup. */ try { lstTarballs.push_back(strTarballPath.c_str()); strTarballPath.setNull(); } catch (std::bad_alloc &) { hrc = E_OUTOFMEMORY; } } else hrc = setErrorBoth(VBOX_E_FILE_ERROR, vrc, tr("Error completing TAR file '%s' (%Rrc)"), strTarballPath.c_str(), vrc); } } else hrc = setErrorVrc(vrc, tr("Failed to TAR creator instance for '%s' (%Rrc)"), strTarballPath.c_str(), vrc); if (FAILED(hrc) && strTarballPath.isNotEmpty()) RTFileDelete(strTarballPath.c_str()); } else hrc = setErrorVrc(vrc, tr("Failed to create '%s' (%Rrc)"), strTarballPath.c_str(), vrc); if (FAILED(hrc)) break; } /* * Delete output files on failure. */ if (FAILED(hrc)) for (list::const_iterator it = lstTarballs.begin(); it != lstTarballs.end(); ++it) RTFileDelete(it->c_str()); // reset the state so others can call methods again m->state = Data::ApplianceIdle; LogFlowFuncLeave(); return hrc; } HRESULT Appliance::i_writeFSImpl(TaskOVF *pTask, AutoWriteLockBase &writeLock, RTVFSFSSTREAM hVfsFssDst) { LogFlowFuncEnter(); HRESULT rc = S_OK; int vrc; try { // the XML stack contains two maps for disks and networks, which allows us to // a) have a list of unique disk names (to make sure the same disk name is only added once) // and b) keep a list of all networks XMLStack stack; // Scope this to free the memory as soon as this is finished { /* Construct the OVF name. */ Utf8Str strOvfFile(pTask->locInfo.strPath); strOvfFile.stripPath().stripSuffix().append(".ovf"); /* Render a valid ovf document into a memory buffer. The unknown version upgrade relates to the OPC hack up in Appliance::write(). */ xml::Document doc; i_buildXML(writeLock, doc, stack, pTask->locInfo.strPath, pTask->enFormat != ovf::OVFVersion_unknown ? pTask->enFormat : ovf::OVFVersion_2_0); void *pvBuf = NULL; size_t cbSize = 0; xml::XmlMemWriter writer; writer.write(doc, &pvBuf, &cbSize); if (RT_UNLIKELY(!pvBuf)) throw setError(VBOX_E_FILE_ERROR, tr("Could not create OVF file '%s'"), strOvfFile.c_str()); /* Write the ovf file to "disk". */ rc = i_writeBufferToFile(hVfsFssDst, strOvfFile.c_str(), pvBuf, cbSize); if (FAILED(rc)) throw rc; } // We need a proper format description ComObjPtr formatTemp; ComObjPtr format; // Scope for the AutoReadLock { SystemProperties *pSysProps = mVirtualBox->i_getSystemProperties(); AutoReadLock propsLock(pSysProps COMMA_LOCKVAL_SRC_POS); // We are always exporting to VMDK stream optimized for now formatTemp = pSysProps->i_mediumFormatFromExtension("iso"); format = pSysProps->i_mediumFormat("VMDK"); if (format.isNull()) throw setError(VBOX_E_NOT_SUPPORTED, tr("Invalid medium storage format")); } // Finally, write out the disks! //use the list stack.mapDiskSequence where the disks were put as the "VirtualSystem"s had been placed //in the OVF description file. I.e. we have one "VirtualSystem" in the OVF file, we extract all disks //attached to it. And these disks are stored in the stack.mapDiskSequence. Next we shift to the next //"VirtualSystem" and repeat the operation. //And here we go through the list and extract all disks in the same sequence for (list::const_iterator it = stack.mapDiskSequence.begin(); it != stack.mapDiskSequence.end(); ++it) { const Utf8Str &strDiskID = *it; const VirtualSystemDescriptionEntry *pDiskEntry = stack.mapDisks[strDiskID]; // source path: where the VBox image is const Utf8Str &strSrcFilePath = pDiskEntry->strVBoxCurrent; //skip empty Medium. In common, It's may be empty CD/DVD if (strSrcFilePath.isEmpty() || pDiskEntry->skipIt == true) continue; // Do NOT check here whether the file exists. findHardDisk will // figure that out, and filesystem-based tests are simply wrong // in the general case (think of iSCSI). // clone the disk: ComObjPtr pSourceDisk; Log(("Finding source disk \"%s\"\n", strSrcFilePath.c_str())); if (pDiskEntry->type == VirtualSystemDescriptionType_HardDiskImage) { rc = mVirtualBox->i_findHardDiskByLocation(strSrcFilePath, true, &pSourceDisk); if (FAILED(rc)) throw rc; } else//may be CD or DVD { rc = mVirtualBox->i_findDVDOrFloppyImage(DeviceType_DVD, NULL, strSrcFilePath, true, &pSourceDisk); if (FAILED(rc)) throw rc; } Bstr uuidSource; rc = pSourceDisk->COMGETTER(Id)(uuidSource.asOutParam()); if (FAILED(rc)) throw rc; Guid guidSource(uuidSource); // output filename const Utf8Str &strTargetFileNameOnly = pDiskEntry->strOvf; // target path needs to be composed from where the output OVF is const Utf8Str &strTargetFilePath = strTargetFileNameOnly; // The exporting requests a lock on the media tree. So leave our lock temporary. writeLock.release(); try { // advance to the next operation pTask->pProgress->SetNextOperation(BstrFmt(tr("Exporting to disk image '%s'"), RTPathFilename(strTargetFilePath.c_str())).raw(), pDiskEntry->ulSizeMB); // operation's weight, as set up // with the IProgress originally // create a flat copy of the source disk image if (pDiskEntry->type == VirtualSystemDescriptionType_HardDiskImage) { /* * Export a disk image. */ /* For compressed VMDK fun, we let i_exportFile produce the image bytes. */ RTVFSIOSTREAM hVfsIosDst; vrc = RTVfsFsStrmPushFile(hVfsFssDst, strTargetFilePath.c_str(), UINT64_MAX, NULL /*paObjInfo*/, 0 /*cObjInfo*/, RTVFSFSSTRM_PUSH_F_STREAM, &hVfsIosDst); if (RT_FAILURE(vrc)) throw setErrorVrc(vrc, tr("RTVfsFsStrmPushFile failed for '%s' (%Rrc)"), strTargetFilePath.c_str(), vrc); hVfsIosDst = i_manifestSetupDigestCalculationForGivenIoStream(hVfsIosDst, strTargetFilePath.c_str(), false /*fRead*/); if (hVfsIosDst == NIL_RTVFSIOSTREAM) throw setError(E_FAIL, "i_manifestSetupDigestCalculationForGivenIoStream(%s)", strTargetFilePath.c_str()); rc = pSourceDisk->i_exportFile(strTargetFilePath.c_str(), format, MediumVariant_VmdkStreamOptimized, m->m_pSecretKeyStore, hVfsIosDst, pTask->pProgress); RTVfsIoStrmRelease(hVfsIosDst); } else { /* * Copy CD/DVD/floppy image. */ Assert(pDiskEntry->type == VirtualSystemDescriptionType_CDROM); rc = pSourceDisk->i_addRawToFss(strTargetFilePath.c_str(), m->m_pSecretKeyStore, hVfsFssDst, pTask->pProgress, false /*fSparse*/); } if (FAILED(rc)) throw rc; } catch (HRESULT rc3) { writeLock.acquire(); /// @todo file deletion on error? If not, we can remove that whole try/catch block. throw rc3; } // Finished, lock again (so nobody mess around with the medium tree // in the meantime) writeLock.acquire(); } if (m->fManifest) { // Create & write the manifest file Utf8Str strMfFilePath = Utf8Str(pTask->locInfo.strPath).stripSuffix().append(".mf"); Utf8Str strMfFileName = Utf8Str(strMfFilePath).stripPath(); pTask->pProgress->SetNextOperation(BstrFmt(tr("Creating manifest file '%s'"), strMfFileName.c_str()).raw(), m->ulWeightForManifestOperation); // operation's weight, as set up // with the IProgress originally); /* Create a memory I/O stream and write the manifest to it. */ RTVFSIOSTREAM hVfsIosManifest; vrc = RTVfsMemIoStrmCreate(NIL_RTVFSIOSTREAM, _1K, &hVfsIosManifest); if (RT_FAILURE(vrc)) throw setErrorVrc(vrc, tr("RTVfsMemIoStrmCreate failed (%Rrc)"), vrc); if (m->hOurManifest != NIL_RTMANIFEST) /* In case it's empty. */ vrc = RTManifestWriteStandard(m->hOurManifest, hVfsIosManifest); if (RT_SUCCESS(vrc)) { /* Rewind the stream and add it to the output. */ size_t cbIgnored; vrc = RTVfsIoStrmReadAt(hVfsIosManifest, 0 /*offset*/, &cbIgnored, 0, true /*fBlocking*/, &cbIgnored); if (RT_SUCCESS(vrc)) { RTVFSOBJ hVfsObjManifest = RTVfsObjFromIoStream(hVfsIosManifest); vrc = RTVfsFsStrmAdd(hVfsFssDst, strMfFileName.c_str(), hVfsObjManifest, 0 /*fFlags*/); if (RT_SUCCESS(vrc)) rc = S_OK; else rc = setErrorVrc(vrc, tr("RTVfsFsStrmAdd failed for the manifest (%Rrc)"), vrc); } else rc = setErrorVrc(vrc, tr("RTManifestWriteStandard failed (%Rrc)"), vrc); } else rc = setErrorVrc(vrc, tr("RTManifestWriteStandard failed (%Rrc)"), vrc); RTVfsIoStrmRelease(hVfsIosManifest); if (FAILED(rc)) throw rc; } } catch (RTCError &x) // includes all XML exceptions { rc = setError(VBOX_E_FILE_ERROR, x.what()); } catch (HRESULT aRC) { rc = aRC; } LogFlowFunc(("rc=%Rhrc\n", rc)); LogFlowFuncLeave(); return rc; } /** * Writes a memory buffer to a file in the output file system stream. * * @returns COM status code. * @param hVfsFssDst The file system stream to add the file to. * @param pszFilename The file name (w/ path if desired). * @param pvContent Pointer to buffer containing the file content. * @param cbContent Size of the content. */ HRESULT Appliance::i_writeBufferToFile(RTVFSFSSTREAM hVfsFssDst, const char *pszFilename, const void *pvContent, size_t cbContent) { /* * Create a VFS file around the memory, converting it to a base VFS object handle. */ HRESULT hrc; RTVFSIOSTREAM hVfsIosSrc; int vrc = RTVfsIoStrmFromBuffer(RTFILE_O_READ, pvContent, cbContent, &hVfsIosSrc); if (RT_SUCCESS(vrc)) { hVfsIosSrc = i_manifestSetupDigestCalculationForGivenIoStream(hVfsIosSrc, pszFilename); AssertReturn(hVfsIosSrc != NIL_RTVFSIOSTREAM, setErrorVrc(vrc, "i_manifestSetupDigestCalculationForGivenIoStream")); RTVFSOBJ hVfsObj = RTVfsObjFromIoStream(hVfsIosSrc); RTVfsIoStrmRelease(hVfsIosSrc); AssertReturn(hVfsObj != NIL_RTVFSOBJ, E_FAIL); /* * Add it to the stream. */ vrc = RTVfsFsStrmAdd(hVfsFssDst, pszFilename, hVfsObj, 0); RTVfsObjRelease(hVfsObj); if (RT_SUCCESS(vrc)) hrc = S_OK; else hrc = setErrorVrc(vrc, tr("RTVfsFsStrmAdd failed for '%s' (%Rrc)"), pszFilename, vrc); } else hrc = setErrorVrc(vrc, "RTVfsIoStrmFromBuffer"); return hrc; }