xenadmin/XenOvfApi/Conversions.cs

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/* Copyright (c) Citrix Systems, Inc.
* All rights reserved.
*
* Redistribution and use in source and binary forms,
* with or without modification, are permitted provided
* that the following conditions are met:
*
* * Redistributions of source code must retain the above
* copyright notice, this list of conditions and the
* following disclaimer.
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the
* following disclaimer in the documentation and/or other
* materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
* CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES,
* INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
using System;
using System.Collections.Generic;
using System.IO;
using System.Management;
using System.Reflection;
using System.Text;
using XenOvf.Definitions;
using XenOvf.Definitions.VMC;
using XenOvf.Utilities;
using XenCenterLib.Compression;
using XenCenterLib.Archive;
namespace XenOvf
{
public partial class OVF
{
private ManagementObject Win32_ComputerSystem = null;
private List<ManagementObject> Win32_Processor = new List<ManagementObject>();
private List<ManagementObject> Win32_CDROMDrive = new List<ManagementObject>();
private List<ManagementObject> Win32_DiskDrive = new List<ManagementObject>();
private List<ManagementObject> Win32_NetworkAdapter = new List<ManagementObject>();
private List<ManagementObject> Win32_IDEController = new List<ManagementObject>();
private List<ManagementObject> Win32_SCSIController = new List<ManagementObject>();
private List<ManagementObject> Win32_IDEControllerDevice = new List<ManagementObject>();
private List<ManagementObject> Win32_SCSIControllerDevice = new List<ManagementObject>();
private List<ManagementObject> Win32_DiskPartition = new List<ManagementObject>();
private List<ManagementObject> Win32_DiskDriveToDiskPartition = new List<ManagementObject>();
private Dictionary<string, string> mappings = new Dictionary<string, string>();
#region CONVERSIONS
public static void ConvertOVFtoOVA(string pathToOvf, string ovfFileName, bool compress, bool cleanup = true)
{
// throws exception if any of the parameters is null (which we want)
string fullOvfPath = Path.Combine(pathToOvf, ovfFileName);
if (!File.Exists(fullOvfPath))
throw new FileNotFoundException(string.Format(Messages.FILE_MISSING, fullOvfPath));
// File Order is:
// 1. OVF File
// 2. Manifest (if exists)
// 3. Signature File (if exists)
// 4. All files listed in References.File.
string origDir = "";
try
{
origDir = Directory.GetCurrentDirectory();
Directory.SetCurrentDirectory(pathToOvf);
EnvelopeType ovfenv = Load(ovfFileName);
File_Type[] files = ovfenv.References.File;
string ovafilename = string.Format("{0}.ova", Path.GetFileNameWithoutExtension(ovfFileName));
string manifestfile = string.Format("{0}.mf", Path.GetFileNameWithoutExtension(ovfFileName));
string signaturefile = string.Format("{0}.cert", Path.GetFileNameWithoutExtension(ovfFileName));
#region COMPRESSION STREAM
Stream ovaStream;
if (compress)
{
if (Properties.Settings.Default.useGZip)
{
log.Info("OVF.ConvertOVFtoOVA GZIP compression stream inserted");
FileStream fsStream = new FileStream(ovafilename + ".gz", FileMode.CreateNew, FileAccess.Write, FileShare.None);
ovaStream = CompressionFactory.Writer(CompressionFactory.Type.Gz, fsStream);
}
else
{
log.Info("OVF.ConvertOVFtoOVA BZIP2 compression stream inserted");
FileStream fsStream = new FileStream(ovafilename + ".bz2", FileMode.CreateNew, FileAccess.Write, FileShare.None);
ovaStream = CompressionFactory.Writer(CompressionFactory.Type.Bz2, fsStream);
}
}
else
{
ovaStream = new FileStream(ovafilename, FileMode.CreateNew, FileAccess.Write, FileShare.None);
}
#endregion
#region TAR
using (var tar = ArchiveFactory.Writer(ArchiveFactory.Type.Tar, ovaStream))
{
AddFileToArchiveWriter(tar, ovfFileName, cleanup);
if (File.Exists(manifestfile))
{
AddFileToArchiveWriter(tar, manifestfile, cleanup);
// Cannot exist without manifest file.
if (File.Exists(signaturefile))
AddFileToArchiveWriter(tar, signaturefile, cleanup);
}
if (files != null)
{
foreach (File_Type file in files)
AddFileToArchiveWriter(tar, file.href, cleanup);
}
}
#endregion
}
catch (Exception ex)
{
log.ErrorFormat("{0} {1}", Messages.CONVERSION_FAILED, ex.Message);
throw new Exception(Messages.CONVERSION_FAILED, ex);
}
finally
{
Directory.SetCurrentDirectory(origDir);
}
log.Debug("OVF.ConvertOVFtoOVA completed");
}
private static void AddFileToArchiveWriter(ArchiveWriter tar, string fileName, bool cleanup)
{
using (FileStream fs = File.OpenRead(fileName))
tar.Add(fs, fileName);
log.InfoFormat("Added file {0} to OVA archive", fileName);
if (cleanup)
{
try
{
File.Delete(fileName);
}
catch
{
}
}
}
public EnvelopeType ConvertPhysicaltoOVF(DiskInfo[] vhdExports, string pathToOvf, string ovfName)
{
return ConvertPhysicaltoOVF(vhdExports, pathToOvf, ovfName, Properties.Settings.Default.Language);
}
public EnvelopeType ConvertPhysicaltoOVF(DiskInfo[] vhdExports, string pathToOvf, string ovfName, string lang)
{
CollectInformation();
var env = CreateEnvelope(ovfName, lang);
string vmUuid = AddVirtualSystem(env, lang, ovfName);
string vhsId = AddVirtualHardwareSection(env, vmUuid, lang);
AddVssd(env, vmUuid, vhsId);
AddCPUs(env, vmUuid);
AddMemory(env, vmUuid);
AddNetworks(env, vmUuid, lang);
CreateConnectedDevices(env, vmUuid, vhdExports);
#region CREATE PVP ENTRIES
foreach (DiskInfo di in vhdExports)
{
string pvpFilename = string.Format(@"{0}.pvp", Path.GetFileNameWithoutExtension(di.VhdFileName));
string pvpPathWithFilename = Path.Combine(pathToOvf, pvpFilename);
if (File.Exists(pvpPathWithFilename))
{
AddExternalFile(env, pvpFilename, null);
}
}
#endregion
FinalizeEnvelope(env);
log.DebugFormat("OVF.Create completed, {0}", ovfName);
return env;
}
/// <summary>
/// Converts an ova.xml (version 2) file from an XenServer Export *.xva into and OVF xml string.
/// </summary>
/// <param name="vhdExports">DiskInfo[] an array of disk names / identifiers</param>
/// <param name="ovaxml">ova.xml data in a string</param>
/// <param name="ovfFilePath">OVF file Path</param>
/// <param name="ovfName">Name of the OVF</param>
/// <returns>OVF XML String</returns>
public string ConvertXVAtoOVF(DiskInfo[] vhdExports, string ovaxml, string ovfFilePath, string ovfName)
{
return ConvertXVAtoOVF(vhdExports, ovaxml, ovfFilePath, ovfName, Properties.Settings.Default.Language);
}
/// <summary>
/// Converts an ova.xml (version 2) file from an XenServer Export *.xva into and OVF xml string.
/// </summary>
/// <param name="vhdExports">DiskInfo[] an array of disk names / identifiers</param>
/// <param name="ovaxml">ova.xml data in a string</param>
/// <param name="ovfFilePath">OVF file Path</param>
/// <param name="ovfName">Name of the OVF</param>
/// <param name="lang">Language to use</param>
/// <returns>OVF XML String</returns>
public string ConvertXVAtoOVF(DiskInfo[] vhdExports, string ovaxml, string ovfFilePath, string ovfName, string lang)
{
XenXva xenobj = Tools.DeserializeOvaXml(ovaxml);
EnvelopeType env = ConvertFromXenOVA(xenobj, vhdExports, ovfFilePath, ovfName, lang);
string xmlstring = Tools.Serialize(env, typeof(EnvelopeType), Tools.LoadNamespaces());
log.Debug("OVF.ConvertXVAtoOVF completed");
return xmlstring;
}
/// <summary>
/// Convert Virtual PC configuration file to an OVF Xml string.
/// </summary>
/// <param name="vpcFileName">filename</param>
/// <param name="ovfName">ovf name</param>
/// <returns>xml ovf string</returns>
public string ConvertVPCtoOVF(string vpcFileName, string ovfName)
{
return ConvertVPCtoOVF(vpcFileName, ovfName, Properties.Settings.Default.Language);
}
/// <summary>
/// Convert Virtual PC configuration file to an OVF Xml string.
/// </summary>
/// <param name="vpcFileName">filename</param>
/// <param name="ovfName">ovf name</param>
/// <param name="lang">language string</param>
/// <returns>xml ovf string</returns>
public string ConvertVPCtoOVF(string vpcFileName, string ovfName, string lang)
{
string vpcstring = Tools.LoadFile(vpcFileName);
vpcstring = vpcstring.Replace("utf-16", "utf-8").Replace("UTF-16", "UTF-8"); // fails if we don't do this. (not nice need to figure real answer)
Ms_Vmc_Type xca = Tools.Deserialize<Ms_Vmc_Type>(vpcstring);
EnvelopeType env = ConvertFromVPCXml(xca, Path.GetFileNameWithoutExtension(vpcFileName), ovfName, lang);
return Tools.Serialize(env, typeof(EnvelopeType), Tools.LoadNamespaces());
}
/// <summary>
/// Convert Vmware meta data to OVF xml string
/// </summary>
/// <param name="vmxFileName">filename</param>
/// <param name="ovfName">ovf name.</param>
/// <returns>ovf xml string</returns>
public string ConvertVMXtoOVF(string vmxFileName, string ovfName)
{
return ConvertVMXtoOVF(vmxFileName, ovfName, Properties.Settings.Default.Language);
}
/// <summary>
/// Convert Vmware meta data to OVF xml string
/// </summary>
/// <param name="vmxFileName">filename</param>
/// <param name="ovfName">ovf name.</param>
/// <param name="lang">language</param>
/// <returns>ovf xml string</returns>
public string ConvertVMXtoOVF(string vmxFileName, string ovfName, string lang)
{
string vmxstring = Tools.LoadFile(vmxFileName);
StringReader sr = new StringReader(vmxstring);
string line = sr.ReadLine();
while (true)
{
if (!string.IsNullOrEmpty(line) && line.Contains("="))
{
string[] vmxpair = line.Split(new char[] {'='});
mappings.Add(vmxpair[0].Trim(), vmxpair[1].Replace("\"", "").Trim());
}
try
{
line = sr.ReadLine();
if (line == null) break;
}
catch
{
break;
}
}
sr.Dispose();
EnvelopeType env = ConvertFromVMXcfg(mappings, ovfName, lang);
return Tools.Serialize(env, typeof(EnvelopeType), Tools.LoadNamespaces());
}
/// <summary>
/// Convert Hyper-V Export CIM XML vm meta data to OVF xml
/// </summary>
/// <param name="hvxmlFileName">filename</param>
/// <param name="ovfName">ovfname</param>
/// <returns>ovf xml string</returns>
public string ConvertHyperVtoOVF(string hvxmlFileName, string ovfName)
{
return ConvertHyperVtoOVF(hvxmlFileName, ovfName, Properties.Settings.Default.Language);
}
/// <summary>
/// Convert Hyper-V Export CIM XML vm meta data to OVF xml
/// </summary>
/// <param name="hvxmlFileName">filename</param>
/// <param name="ovfName">ovfname</param>
/// <param name="lang">language</param>
/// <returns>ovf xml string</returns>
public string ConvertHyperVtoOVF(string hvxmlFileName, string ovfName, string lang)
{
string hvxml = Tools.LoadFile(hvxmlFileName);
hvxml = hvxml.Replace("utf-16", "utf-8"); // fails if we don't do this.
string xmlstring = null;
Ms_Declarations_Type hvobj = Tools.Deserialize<Ms_Declarations_Type>(hvxml);
if (hvobj != null &&
hvobj.declgroups != null &&
hvobj.declgroups.Count > 0 &&
hvobj.declgroups[0].values != null &&
hvobj.declgroups[0].values.Count > 0)
{
EnvelopeType env = ConvertFromHyperVXml(hvobj, ovfName, lang);
xmlstring = Tools.Serialize(env, typeof(EnvelopeType), Tools.LoadNamespaces());
log.Debug("XenOvf::ConvertHyperVtoOVF completed");
}
else
{
throw new InvalidDataException(Messages.CONVERSION_NO_DATA);
}
return xmlstring;
}
#endregion
#region PRIVATE
private EnvelopeType ConvertFromXenOVA(XenXva xenxva, DiskInfo[] vhdExports, string ovfFilePath, string ovfname, string lang)
{
mappings.Clear();
EnvelopeType env = CreateEnvelope(ovfname, lang);
string vsId = AddVirtualSystem(env, lang, ovfname);
string vhsId = AddVirtualHardwareSection(env, vsId, lang);
// Do this because it isn't defined yet this will allow for
// it to update in any order.
UpdateVirtualSystemSettingData(env, vsId, "VirtualSystemType", "hvm");
foreach (XenMember xm in xenxva.xenstruct.xenmember)
{
if (xm.xenname.ToLower().Equals("objects"))
{
foreach (object obj in ((XenArray)xm.xenvalue).xendata.xenvalue)
{
if (obj is XenStruct)
{
bool AtVM = false;
bool AtVBD = false;
bool AtVIF = false;
bool AtNetwork = false;
bool AtVDI = false;
bool AtSR = false;
bool IsReferenced = false;
string reference = null;
foreach (XenMember xmm in ((XenStruct)obj).xenmember)
{
#region SET AREA
if (xmm.xenname.ToLower().Equals("class") &&
xmm.xenvalue != null &&
xmm.xenvalue is string &&
((string)xmm.xenvalue).Length > 0 &&
((string)xmm.xenvalue).ToLower().Equals("vm"))
{
AtVM = true;
}
else if (xmm.xenname.ToLower().Equals("class") &&
xmm.xenvalue != null &&
xmm.xenvalue is string &&
((string)xmm.xenvalue).Length > 0 &&
((string)xmm.xenvalue).ToLower().Equals("vbd"))
{
AtVBD = true;
}
else if (xmm.xenname.ToLower().Equals("class") &&
xmm.xenvalue != null &&
xmm.xenvalue is string &&
((string)xmm.xenvalue).Length > 0 &&
((string)xmm.xenvalue).ToLower().Equals("vif"))
{
AtVIF = true;
}
else if (xmm.xenname.ToLower().Equals("class") &&
xmm.xenvalue != null &&
xmm.xenvalue is string &&
((string)xmm.xenvalue).Length > 0 &&
((string)xmm.xenvalue).ToLower().Equals("network"))
{
AtNetwork = true;
}
else if (xmm.xenname.ToLower().Equals("class") &&
xmm.xenvalue != null &&
xmm.xenvalue is string &&
((string)xmm.xenvalue).Length > 0 &&
((string)xmm.xenvalue).ToLower().Equals("vdi"))
{
AtVDI = true;
}
else if (xmm.xenname.ToLower().Equals("class") &&
xmm.xenvalue != null &&
xmm.xenvalue is string &&
((string)xmm.xenvalue).Length > 0 &&
((string)xmm.xenvalue).ToLower().Equals("sr"))
{
AtSR = true;
}
#endregion
#region CHECK REFERENCE
if (xmm.xenname.ToLower().Equals("id") &&
xmm.xenvalue != null &&
xmm.xenvalue is string)
{
string curid = (string)(xmm.xenvalue);
if (mappings.ContainsKey(curid))
{
IsReferenced = true;
reference = curid;
}
else
{
IsReferenced = false;
}
}
#endregion
#region GET DATA
if (xmm.xenname.ToLower().Equals("snapshot") &&
xmm.xenvalue != null &&
xmm.xenvalue is XenStruct)
{
if (AtVM)
{
TransformXvaOvf_VM(env, vsId, lang, (XenStruct)xmm.xenvalue);
AtVM = false;
}
else if (AtVBD)
{
TransformXvaOvf_VBD(env, vsId, lang, (XenStruct)xmm.xenvalue);
AtVBD = false;
}
else if (AtVIF)
{
TransformXvaOvf_VIF(env, vsId, lang, (XenStruct)xmm.xenvalue);
AtVIF = false;
}
else if (AtNetwork && IsReferenced)
{
TransformXvaOvf_Network(env, vsId, lang, reference, (XenStruct)xmm.xenvalue);
AtNetwork = false;
}
else if (AtVDI && IsReferenced)
{
DiskInfo diskDetails = null;
foreach (DiskInfo di in vhdExports)
{
if (di.DriveId.ToLower().Equals(reference.ToLower()))
{
diskDetails = di;
break;
}
}
if (diskDetails != null)
{
TransformXvaOvf_VDI(env, vsId, lang, reference, diskDetails, (XenStruct)xmm.xenvalue);
string pvpFilename = string.Format(@"{0}.pvp", Path.GetFileNameWithoutExtension(diskDetails.VhdFileName));
string pvpFileWithPath = Path.Combine(ovfFilePath, pvpFilename);
if (File.Exists(pvpFileWithPath))
{
AddExternalFile(env, pvpFilename, null);
}
}
else
{
log.ErrorFormat("Could not find the details for disk, {0}", reference);
}
AtVDI = false;
}
else if (AtSR && IsReferenced)
{
TransformXvaOvf_SR(env, vsId, lang, (XenStruct)xmm.xenvalue);
AtSR = false;
}
IsReferenced = false;
}
#endregion
}
}
}
}
}
FinalizeEnvelope(env);
log.DebugFormat("OVF.ConvertFromXenOVA completed {0}", ovfname);
mappings.Clear();
return env;
}
private EnvelopeType ConvertFromXenOVAv1(XcAppliance xenxva, DiskInfo[] vhdExports, string ovfname, string lang)
{
mappings.Clear();
if (ovfname == null ||
xenxva == null ||
xenxva.vm == null ||
xenxva.vm.config == null ||
xenxva.vm.hacks == null ||
xenxva.vm.vbd == null ||
xenxva.vm.label == null ||
xenxva.vm.label.Length <= 0 ||
vhdExports == null ||
vhdExports.Length <= 0)
throw new NullReferenceException("Invalid/Null argument");
EnvelopeType env = CreateEnvelope(ovfname, lang);
string vsId = AddVirtualSystem(env, lang, ovfname);
string vhsId = AddVirtualHardwareSection(env, vsId, lang);
ulong mem = 0;
if (xenxva.vm.config.memset != 0)
{
mem = xenxva.vm.config.memset/MB;
SetMemory(env, vsId, mem, "MB");
}
if (xenxva.vm.config.vcpus != 0)
{
SetCPUs(env, vsId, xenxva.vm.config.vcpus);
}
if (xenxva.vm.hacks.isHVM)
{
AddVirtualSystemSettingData(env, vsId, vhsId, xenxva.vm.label.Trim(), xenxva.vm.label.Trim(), _ovfrm.GetString("CONVERT_XVA_VSSD_CAPTION"), Guid.NewGuid().ToString(), Properties.Settings.Default.xenDefaultVirtualSystemType);
AddOtherSystemSettingData(env, vsId, lang, "HVM_boot_policy", Properties.Settings.Default.xenBootOptions, _ovfrm.GetString("XENSERVER_SPECIFIC_DESCRIPTION"));
AddOtherSystemSettingData(env, vsId, lang, "HVM_boot_params", Properties.Settings.Default.xenBootParams, _ovfrm.GetString("XENSERVER_SPECIFIC_DESCRIPTION"));
AddOtherSystemSettingData(env, vsId, lang, "platform", Properties.Settings.Default.xenPlatformSetting, _ovfrm.GetString("XENSERVER_PLATFORM_DESCRIPTION"));
}
else
{
AddVirtualSystemSettingData(env, vsId, vhsId, xenxva.vm.label.Trim(), xenxva.vm.label.Trim(), _ovfrm.GetString("CONVERT_XVA_VSSD_CAPTION"), Guid.NewGuid().ToString(), Properties.Settings.Default.xenDefaultPVVirtualSystemType);
AddOtherSystemSettingData(env, vsId, lang, "PV_bootloader", Properties.Settings.Default.xenPVBootloader, _ovfrm.GetString("XENSERVER_SPECIFIC_DESCRIPTION"));
AddOtherSystemSettingData(env, vsId, lang, "PV_kernel", Properties.Settings.Default.xenKernelOptions, _ovfrm.GetString("XENSERVER_SPECIFIC_DESCRIPTION"));
AddOtherSystemSettingData(env, vsId, lang, "platform", Properties.Settings.Default.xenPVPlatformSetting, _ovfrm.GetString("XENSERVER_PLATFORM_DESCRIPTION"));
}
UpdateVirtualSystemName(env, vsId, lang, xenxva.vm.label.Trim());
AddNetwork(env, vsId, lang, _ovfrm.GetString("RASD_10_CAPTION"), _ovfrm.GetString("RASD_10_DESCRIPTION"), null);
string contollerId = Guid.NewGuid().ToString();
AddController(env, vsId, DeviceType.IDE, contollerId, 0);
int i = 0;
foreach (DiskInfo di in vhdExports)
{
if (di.PhysicalSize == null) di.PhysicalSize = "0";
if (di.CapacitySize == null) di.CapacitySize = "0";
AddDisk(env, vsId, di.DriveId, lang, di.VhdFileName, true, _ovfrm.GetString("RASD_19_CAPTION"), _ovfrm.GetString("RASD_19_DESCRIPTION"), Convert.ToUInt64(di.PhysicalSize), Convert.ToUInt64(di.CapacitySize));
AddDeviceToController(env, vsId, di.DriveId, contollerId, Convert.ToString(i++));
}
FinalizeEnvelope(env);
log.DebugFormat("OVF.ConvertFromXenOVAv1 completed {0}", ovfname);
mappings.Clear();
return env;
}
private EnvelopeType ConvertFromHyperVXml(Ms_Declarations_Type hvobj, string ovfname, string lang)
{
EnvelopeType env = CreateEnvelope(ovfname, lang);
string systemId = AddVirtualSystem(env, lang, ovfname);
string vhsid = AddVirtualHardwareSection(env, systemId, lang);
foreach (Ms_WrapperInstance_Type wrap in hvobj.declgroups[0].values)
{
RASD_Type rasd = new RASD_Type();
switch (wrap.instance.className)
{
#region CASE: Msvm_VirtualSystemSettingData
case "Msvm_VirtualSystemSettingData":
{
string ElementName = null;
string InstanceId = null;
string SystemName = null;
string VirtualSystemType = null;
foreach (Ms_Property_Base_Type prop in wrap.instance.Properties)
{
switch (prop.Name)
{
case "ElementName":
{
ElementName = ((Ms_ParameterValue_Type)prop).Value;
break;
}
case "InstanceID":
{
InstanceId = ((Ms_ParameterValue_Type)prop).Value;
break;
}
case "SystemName":
{
SystemName = ((Ms_ParameterValue_Type)prop).Value;
break;
}
case "VirtualSystemType":
{
VirtualSystemType = ((Ms_ParameterValue_Type)prop).Value;
break;
}
}
}
AddVirtualSystemSettingData(env, systemId, vhsid, ElementName, ElementName, ElementName, InstanceId, VirtualSystemType);
UpdateVirtualSystemName(env, systemId, lang, ElementName);
break;
}
#endregion
#region CASE: ResourceAllocationSettingData
case "Msvm_ProcessorSettingData":
case "Msvm_MemorySettingData":
case "Msvm_SyntheticEthernetPortSettingData":
case "Msvm_ResourceAllocationSettingData":
{
foreach (Ms_Property_Base_Type prop in wrap.instance.Properties)
{
if (prop is Ms_ParameterValue_Type)
{
if (((Ms_ParameterValue_Type)prop).Value == null ||
((Ms_ParameterValue_Type)prop).Value.Length <= 0)
{
continue;
}
}
else if (prop is Ms_ParameterValueArray_Type)
{
if (((Ms_ParameterValueArray_Type)prop).Values == null ||
((Ms_ParameterValueArray_Type)prop).Values.Length <= 0)
{
continue;
}
}
PropertyInfo[] properties = rasd.GetType().GetProperties();
foreach (PropertyInfo pi in properties)
{
if (pi.Name.ToLower().Equals(prop.Name.ToLower()))
{
object newvalue = null;
if (prop is Ms_ParameterValue_Type)
{
switch (prop.Type.ToLower())
{
case "string":
{
newvalue = new cimString((string)((Ms_ParameterValue_Type)prop).Value);
break;
}
case "boolean":
{
newvalue = new cimBoolean();
((cimBoolean)newvalue).Value = Convert.ToBoolean(((Ms_ParameterValue_Type)prop).Value);
break;
}
case "uint16":
{
newvalue = new cimUnsignedShort();
((cimUnsignedShort)newvalue).Value = Convert.ToUInt16(((Ms_ParameterValue_Type)prop).Value);
break;
}
case "uint32":
{
newvalue = new cimUnsignedInt();
((cimUnsignedInt)newvalue).Value = Convert.ToUInt32(((Ms_ParameterValue_Type)prop).Value);
break;
}
case "uint64":
{
newvalue = new cimUnsignedLong();
((cimUnsignedLong)newvalue).Value = Convert.ToUInt64(((Ms_ParameterValue_Type)prop).Value);
break;
}
}
}
else if (prop is Ms_ParameterValueArray_Type)
{
switch (prop.Type.ToLower())
{
case "string":
{
List<cimString> sarray = new List<cimString>();
foreach (Ms_ParameterValue_Type svalue in ((Ms_ParameterValueArray_Type)prop).Values)
{
sarray.Add(new cimString(svalue.Value));
}
newvalue = sarray.ToArray();
break;
}
}
}
object tmpobject = null;
switch (pi.Name.ToLower())
{
case "caption":
{
newvalue = new Caption(((cimString)newvalue).Value);
break;
}
case "changeabletype":
{
tmpobject = newvalue;
newvalue = new ChangeableType();
((ChangeableType)newvalue).Value = ((cimUnsignedShort)tmpobject).Value;
break;
}
case "consumervisibility":
{
tmpobject = newvalue;
newvalue = new ConsumerVisibility();
((ConsumerVisibility)newvalue).Value = ((cimUnsignedShort)tmpobject).Value;
break;
}
case "mappingbehavior":
{
tmpobject = newvalue;
newvalue = new MappingBehavior();
((MappingBehavior)newvalue).Value = ((cimUnsignedShort)tmpobject).Value;
break;
}
case "resourcetype":
{
tmpobject = newvalue;
newvalue = new ResourceType();
((ResourceType)newvalue).Value = ((cimUnsignedShort)tmpobject).Value;
break;
}
case "connection":
case "hostresource":
default:
{
break;
}
}
pi.SetValue(rasd, newvalue, null);
}
}
}
if (rasd != null)
{
if (FillEmptyRequiredFields(rasd))
{
if (rasd.ResourceType.Value == 21 &&
rasd.Caption.Value.ToLower().StartsWith(_ovfrm.GetString("RASD_19_CAPTION").ToLower()))
{
string filename = Path.GetFileName(rasd.Connection[0].Value);
AddFileReference(env, lang, filename, rasd.InstanceID.Value, 0, Properties.Settings.Default.winFileFormatURI);
AddRasd(env, systemId, rasd);
}
else if (rasd.ResourceType.Value == 10)
{
AddNetwork(env, systemId, lang, rasd.InstanceID.Value, rasd.Caption.Value, rasd.Address.Value);
}
else
{
AddRasd(env, systemId, rasd);
}
}
}
break;
}
#endregion
#region CASE: Msvm_VLANEndpointSettingData
case "Msvm_VLANEndpointSettingData":
#endregion
#region CASE: SKIPPED / DEFAULT
case "Msvm_VirtualSystemExportSettingData":
case "Msvm_VirtualSystemGlobalSettingData":
case "Msvm_HeartbeatComponentSettingData":
case "Msvm_KvpExchangeComponentSettingData":
case "Msvm_ShutdownComponentSettingData":
case "Msvm_TimeSyncComponentSettingData":
case "Msvm_VssComponentSettingData":
case "Msvm_SwitchPort":
case "Msvm_VirtualSwitch":
default:
{
break;
}
#endregion
}
}
FinalizeEnvelope(env);
return env;
}
private EnvelopeType ConvertFromVPCXml(Ms_Vmc_Type vmcobj, string vpcName, string ovfname, string lang)
{
EnvelopeType env = CreateEnvelope(ovfname, lang);
string vsId = AddVirtualSystem(env, lang, ovfname);
string vhsId = AddVirtualHardwareSection(env, vsId, lang);
SetMemory(env, vsId, Convert.ToUInt64(vmcobj.hardware.memory.ram_size.value), "MB");
// TODO: See if this is set in the other versions somewhere.
SetCPUs(env, vsId, (ulong)1);
AddVirtualSystemSettingData(env, vsId, vhsId, vpcName, vpcName, _ovfrm.GetString("CONVERT_VPC_VSSD_CAPTION"), Guid.NewGuid().ToString(), Properties.Settings.Default.xenDefaultVirtualSystemType);
AddOtherSystemSettingData(env, vsId, lang, "HVM_boot_policy", Properties.Settings.Default.xenBootOptions, _ovfrm.GetString("XENSERVER_SPECIFIC_DESCRIPTION"));
AddOtherSystemSettingData(env, vsId, lang, "HVM_boot_params", Properties.Settings.Default.xenBootParams, _ovfrm.GetString("XENSERVER_SPECIFIC_DESCRIPTION"));
AddOtherSystemSettingData(env, vsId, lang, "platform", Properties.Settings.Default.xenPlatformSetting, _ovfrm.GetString("XENSERVER_PLATFORM_DESCRIPTION"));
UpdateVirtualSystemName(env, vsId, lang, vpcName);
if (vmcobj.hardware.pci_bus.ethernet_adapter != null &&
vmcobj.hardware.pci_bus.ethernet_adapter.ethernet_controller != null &&
vmcobj.hardware.pci_bus.ethernet_adapter.ethernet_controller.Length > 0)
{
foreach (Ms_Ethernet_Controller_Type ec in vmcobj.hardware.pci_bus.ethernet_adapter.ethernet_controller)
{
if (ec.virtual_network.id.value == null ||
ec.virtual_network.name.value == null)
{
continue;
}
AddNetwork(env, vsId, lang, ec.virtual_network.id.value, ec.virtual_network.name.value, ec.ethernet_card_address.value);
}
}
foreach (Ms_Ide_Controller_Type ide in vmcobj.hardware.pci_bus.ide_adapter.ide_controller)
{
string ideId = Guid.NewGuid().ToString();
AddController(env, vsId, DeviceType.IDE, ideId, Convert.ToInt32(ide.id));
foreach (Ms_Location_Type loc in ide.location)
{
string diskId = Guid.NewGuid().ToString();
switch (loc.drive_type.value)
{
case "0":
{
continue;
} // when 0 location appears empty
case "1": // when 1 VHD
{
AddDisk(env, vsId, lang, diskId, Path.GetFileName(loc.pathname.absolute.value), true, _ovfrm.GetString("RASD_19_CAPTION"), _ovfrm.GetString("RASD_19_DESCRIPTION"), 0, 0);
break;
}
case "2": // when 2 ISO
{
AddCDROM(env, vsId, diskId, _ovfrm.GetString("RASD_16_CAPTION"), _ovfrm.GetString("RASD_16_ELEMENTNAME"));
if (loc.pathname != null &&
loc.pathname.absolute != null &&
!string.IsNullOrEmpty(loc.pathname.absolute.value))
{
AddFileReference(env, lang, Path.GetFileName(loc.pathname.absolute.value), diskId, 0, Properties.Settings.Default.isoFileFormatURI);
UpdateResourceAllocationSettingData(env, vsId, diskId, "HostResource", string.Format(Properties.Settings.Default.hostresource, diskId));
}
break;
}
}
AddDeviceToController(env, vsId, diskId, ideId, loc.id);
}
}
FinalizeEnvelope(env);
log.DebugFormat("OVF.ConvertFromVPCXml completed {0}", ovfname);
mappings.Clear();
return env;
}
private EnvelopeType ConvertFromVMXcfg(Dictionary<string, string> vmxcfg, string ovfname, string lang)
{
EnvelopeType env = CreateEnvelope(ovfname, lang);
string vsId = AddVirtualSystem(env, lang, ovfname);
string vhsId = AddVirtualHardwareSection(env, vsId);
int addedNetwork = 0;
int addedIDE = 0;
int addedSCSI = 0;
string vmxName = ovfname.Replace("\"", "");
// just in case these are in vmx file:
if (!vmxcfg.ContainsKey("numvcpus"))
{
SetCPUs(env, vsId, 1);
}
else
{
SetCPUs(env, vsId, Convert.ToUInt64("numvcpus"));
}
if (!vmxcfg.ContainsKey("memsize"))
{
SetMemory(env, vsId, 512, "MB");
}
else
{
SetMemory(env, vsId, Convert.ToUInt64(vmxcfg["memsize"]), "MB");
}
foreach (string key in vmxcfg.Keys)
{
if (key.ToLower().StartsWith("ethernet"))
{
char i = key[8];
int networkIdx = (int)i - 48;
if (networkIdx == addedNetwork)
{
string mac = null;
string cap = "Network";
string datakey = string.Format("ethernet{0}.generatedAddress", networkIdx);
string vdev = string.Format("ethernet{0}.virtualDev", networkIdx);
if (vmxcfg.ContainsKey(datakey))
mac = vmxcfg[datakey];
if (vmxcfg.ContainsKey(vdev))
cap = vmxcfg[vdev];
AddNetwork(env, vsId, lang, Guid.NewGuid().ToString(), cap, mac);
addedNetwork++;
}
}
else if (key.ToLower().StartsWith("displayname"))
{
vmxName = vmxcfg[key];
}
else if (key.ToLower().StartsWith("ide"))
{
char i = key[3];
int ideIdx = (int)i - 48;
if (ideIdx == addedIDE)
{
string[] parts = key.Split(new char[] {':', '.'});
int port = 0;
if (parts.Length == 3)
{
port = Convert.ToInt32(parts[1]);
}
string devId = Guid.NewGuid().ToString();
string diskId = Guid.NewGuid().ToString();
AddController(env, vsId, DeviceType.IDE, devId, ideIdx);
string filekey = string.Format("ide{0}:{1}.fileName", ideIdx, port);
string devicekey = string.Format("ide{0}:{1}.deviceType", ideIdx, port);
bool addDiskImage = false;
if (vmxcfg.ContainsKey(filekey))
addDiskImage = true;
if (vmxcfg.ContainsKey(devicekey))
{
if (vmxcfg[devicekey].ToLower().StartsWith("cdrom"))
{
AddCDROM(env, vsId, diskId, _ovfrm.GetString("RASD_16_CAPTION"), _ovfrm.GetString("RASD_16_ELEMENTNAME"));
if (addDiskImage)
{
AddFileReference(env, lang, Path.GetFileName(vmxcfg[filekey]), diskId, 0, Properties.Settings.Default.isoFileFormatURI);
UpdateResourceAllocationSettingData(env, vsId, diskId, "HostResource", string.Format(Properties.Settings.Default.hostresource, diskId));
}
}
else
{
if (addDiskImage)
{
AddDisk(env, vsId, diskId, lang, Path.GetFileName(vmxcfg[filekey]), true, _ovfrm.GetString("RASD_19_CAPTION"), _ovfrm.GetString("RASD_19_DESCRIPTION"), 0, 0);
}
}
}
else
{
if (addDiskImage)
{
AddDisk(env, vsId, diskId, lang, Path.GetFileName(vmxcfg[filekey]), true, _ovfrm.GetString("RASD_19_CAPTION"), _ovfrm.GetString("RASD_19_DESCRIPTION"), 0, 0);
}
}
AddDeviceToController(env, vsId, diskId, devId, Convert.ToString(port));
addedIDE++;
}
}
else if (key.ToLower().StartsWith("scsi"))
{
char i = key[4];
int scsiIdx = (int)i - 48;
if (scsiIdx == addedSCSI)
{
string[] parts = key.Split(new char[] {':', '.'});
int port = 0;
if (parts.Length == 3)
{
port = Convert.ToInt32(parts[1]);
}
else
{
continue;
}
string devId = Guid.NewGuid().ToString();
string diskId = Guid.NewGuid().ToString();
AddController(env, vsId, DeviceType.SCSI, devId, port);
string filekey = string.Format("scsi{0}:{1}.fileName", scsiIdx, port);
string devicekey = string.Format("scsi{0}:{1}.deviceType", scsiIdx, port);
bool addDiskImage = false;
if (vmxcfg.ContainsKey(filekey))
addDiskImage = true;
if (vmxcfg.ContainsKey(devicekey))
{
if (vmxcfg[devicekey].ToLower().StartsWith("cdrom"))
{
AddCDROM(env, vsId, diskId, _ovfrm.GetString("RASD_16_CAPTION"), _ovfrm.GetString("RASD_16_ELEMENTNAME"));
if (addDiskImage)
{
AddFileReference(env, lang, Path.GetFileName(vmxcfg[filekey]), diskId, 0, Properties.Settings.Default.isoFileFormatURI);
UpdateResourceAllocationSettingData(env, vsId, diskId, "HostResource", string.Format(Properties.Settings.Default.hostresource, diskId));
}
}
else
{
if (addDiskImage)
{
AddDisk(env, vsId, diskId, lang, Path.GetFileName(vmxcfg[filekey]), true, _ovfrm.GetString("RASD_19_CAPTION"), _ovfrm.GetString("RASD_19_DESCRIPTION"), 0, 0);
}
}
}
else
{
if (addDiskImage)
{
AddDisk(env, vsId, diskId, lang, Path.GetFileName(vmxcfg[filekey]), true, _ovfrm.GetString("RASD_19_CAPTION"), _ovfrm.GetString("RASD_19_DESCRIPTION"), 0, 0);
}
}
AddDeviceToController(env, vsId, diskId, devId, Convert.ToString(port));
addedSCSI++;
}
}
}
AddVirtualSystemSettingData(env, vsId, vhsId, vmxName, vmxName, _ovfrm.GetString("CONVERT_VMX_VSSD_CAPTION"), Guid.NewGuid().ToString(), Properties.Settings.Default.xenDefaultVirtualSystemType);
AddOtherSystemSettingData(env, vsId, lang, "HVM_boot_policy", Properties.Settings.Default.xenBootOptions, _ovfrm.GetString("XENSERVER_SPECIFIC_DESCRIPTION"));
AddOtherSystemSettingData(env, vsId, lang, "HVM_boot_params", Properties.Settings.Default.xenBootParams, _ovfrm.GetString("XENSERVER_SPECIFIC_DESCRIPTION"));
AddOtherSystemSettingData(env, vsId, lang, "platform", Properties.Settings.Default.xenPlatformSetting, _ovfrm.GetString("XENSERVER_PLATFORM_DESCRIPTION"));
FinalizeEnvelope(env);
log.DebugFormat("OVF.ConvertFromVMXcfg completed {0}", ovfname);
mappings.Clear();
return env;
}
private void TransformXvaOvf_VM(EnvelopeType env, string vsId, string lang, XenStruct vmstruct)
{
int PVvalue = 0;
foreach (XenMember n in vmstruct.xenmember)
{
//
// Currently these are the only values we care about.
//
if (n.xenname.ToLower().Equals("uuid"))
{
UpdateVirtualSystemSettingData(env, vsId, "VirtualSystemIdentifier", (string)n.xenvalue);
}
if (n.xenname.ToLower().Equals("name_label"))
{
if (n.xenvalue != null && n.xenvalue is string && ((string)n.xenvalue).Length > 0)
{
UpdateVirtualSystemName(env, vsId, lang, (string)n.xenvalue);
UpdateVirtualSystemSettingData(env, vsId, "ElementName", (string)n.xenvalue);
UpdateVirtualSystemSettingData(env, vsId, "Caption", _ovfrm.GetString("CONVERT_APP_NAME"));
}
}
else if (n.xenname.ToLower().Equals("memory_static_max"))
{
if (n.xenvalue != null && n.xenvalue is string && ((string)n.xenvalue).Length > 0)
{
UInt64 memory = Convert.ToUInt64(n.xenvalue)/MB;
SetMemory(env, vsId, memory, "MB");
}
}
else if (n.xenname.ToLower().Equals("vcpus_max"))
{
if (n.xenvalue != null && n.xenvalue is string && ((string)n.xenvalue).Length > 0)
{
UInt64 cpus = Convert.ToUInt64(n.xenvalue);
SetCPUs(env, vsId, cpus);
}
}
else if (
n.xenname.ToLower().Equals("pv_bootloader") ||
n.xenname.ToLower().Equals("pv_kernel") ||
n.xenname.ToLower().Equals("pv_ramdisk") ||
n.xenname.ToLower().Equals("pv_args") ||
n.xenname.ToLower().Equals("pv_bootloader_args") ||
n.xenname.ToLower().Equals("pv_legacy_args") ||
n.xenname.ToLower().Equals("hvm_boot_policy") ||
n.xenname.ToLower().Equals("hvm_shadow_multiplier")
)
{
if (n.xenvalue != null && n.xenvalue is string && ((string)n.xenvalue).Length > 0)
{
if (n.xenname.ToLower().StartsWith("pv"))
{
PVvalue++;
}
if (n.xenname.ToLower().StartsWith("hvm_boot"))
{
PVvalue--;
}
AddOtherSystemSettingData(env, vsId, lang, n.xenname, (string)n.xenvalue, _ovfrm.GetString("XENSERVER_SPECIFIC_DESCRIPTION"));
}
}
else if (n.xenname.ToLower().Equals("hvm_boot_params"))
{
if (n.xenvalue != null && n.xenvalue is XenStruct && ((XenStruct)n.xenvalue).xenmember != null)
{
string bootorder = "dc";
foreach (XenMember xm in ((XenStruct)n.xenvalue).xenmember)
{
PVvalue--;
if (xm.xenname.ToLower().Equals("order"))
{
if (xm.xenvalue != null && xm.xenvalue is string && ((string)xm.xenvalue).Length > 0)
{
bootorder = (string)xm.xenvalue;
}
}
}
AddOtherSystemSettingData(env, vsId, lang, n.xenname, bootorder, _ovfrm.GetString("XENSERVER_SPECIFIC_DESCRIPTION"));
}
}
else if (n.xenname.ToLower().Equals("platform"))
{
if (n.xenvalue != null && n.xenvalue is XenStruct && ((XenStruct)n.xenvalue).xenmember != null)
{
StringBuilder p = new StringBuilder();
foreach (XenMember xm in ((XenStruct)n.xenvalue).xenmember)
{
if (xm.xenvalue != null && xm.xenvalue is string && ((string)xm.xenvalue).Length > 0)
{
p.AppendFormat("{0}={1}; ", xm.xenname, (string)xm.xenvalue);
}
}
AddOtherSystemSettingData(env, vsId, lang, n.xenname, p.ToString().Trim(), _ovfrm.GetString("XENSERVER_PLATFORM_DESCRIPTION"));
}
}
else if (n.xenname.ToLower().Equals("other_config"))
{
// Ignored, why you say? Because I haven't found one that is 'required' to reproduce the vm, yet.
}
else if (n.xenname.ToLower().Equals("domarch"))
{
// Can't depend on a value here but we need to set it to work correctly.
if (n.xenvalue != null && n.xenvalue is string && ((string)n.xenvalue).Length > 0)
{
string svalue = (string)n.xenvalue;
if (svalue.Equals("hvm"))
{
PVvalue = -10;
}
}
if (PVvalue < 0)
{
UpdateVirtualSystemSettingData(env, vsId, "VirtualSystemType", "hvm-3.0-unknown");
}
else
{
UpdateVirtualSystemSettingData(env, vsId, "VirtualSystemType", "xen-3.0-unknown");
}
}
}
log.DebugFormat("OVF.TransformXvaOvf_VM completed {0}", vsId);
}
private void TransformXvaOvf_VBD(EnvelopeType env, string vsId, string lang, XenStruct vmstruct)
{
string diskId = null;
string vhdfilename = "";
bool bootable = false;
string caption = null;
string description = null;
ulong filesize = 0;
ulong capacity = 0;
string vdiuuid = null;
bool isDisk = false;
StringBuilder connection = new StringBuilder();
foreach (XenMember n in vmstruct.xenmember)
{
//
// Currently these are the only values we care about.
//
if (n.xenname.ToLower().Equals("uuid") &&
n.xenvalue != null &&
n.xenvalue is string &&
((string)n.xenvalue).Length > 0)
{
vdiuuid = (string)n.xenvalue;
if (!vdiuuid.ToLower().Contains("null"))
{
diskId = string.Format(@"Xen:{0}/{1}", vsId, vdiuuid);
}
else
{
vdiuuid = null;
}
}
else if (n.xenname.ToLower().Equals("vdi") &&
n.xenvalue != null &&
n.xenvalue is string &&
((string)n.xenvalue).Length > 0)
{
string vdiref = ((string)n.xenvalue);
if (!vdiref.ToLower().Contains("null"))
{
if (!mappings.ContainsKey(vdiref))
{
mappings.Add(vdiref, vdiuuid);
}
}
}
else if (n.xenname.ToLower().Equals("userdevice") &&
n.xenvalue != null &&
n.xenvalue is string &&
((string)n.xenvalue).Length > 0)
{
connection.AppendFormat("device={0},", ((string)n.xenvalue));
}
else if (n.xenname.ToLower().Equals("bootable") &&
n.xenvalue != null &&
n.xenvalue is string &&
((string)n.xenvalue).Length > 0)
{
connection.AppendFormat("bootable={0},", ((string)n.xenvalue));
bootable = Convert.ToBoolean(((string)n.xenvalue));
}
else if (n.xenname.ToLower().Equals("mode") &&
n.xenvalue != null &&
n.xenvalue is string &&
((string)n.xenvalue).Length > 0)
{
connection.AppendFormat("mode={0},", ((string)n.xenvalue));
}
else if (n.xenname.ToLower().Equals("type") &&
n.xenvalue != null &&
n.xenvalue is string &&
((string)n.xenvalue).Length > 0)
{
switch (((string)n.xenvalue).ToUpper())
{
case "CD":
{
isDisk = false;
caption = _ovfrm.GetString("RASD_16_CAPTION");
description = _ovfrm.GetString("RASD_16_DESCRIPTION");
break;
}
case "DISK":
{
caption = _ovfrm.GetString("RASD_19_CAPTION");
description = _ovfrm.GetString("RASD_19_DESCRIPTION");
isDisk = true;
break;
}
}
}
}
if (vdiuuid != null)
connection.AppendFormat("vdi={0}", vdiuuid);
if (isDisk)
{
AddDisk(env, vsId, diskId, lang, vhdfilename, bootable, caption, description, filesize, capacity);
UpdateResourceAllocationSettingData(env, vsId, diskId, "Connection", connection.ToString());
}
else
{
AddCDROM(env, vsId, diskId, caption, description);
}
log.DebugFormat("OVF.TransformXvaOvf_VBD completed {0}", vsId);
}
private void TransformXvaOvf_VIF(EnvelopeType env, string vsId, string lang, XenStruct vmstruct)
{
string vifuuid = null;
string mac = null;
foreach (XenMember n in vmstruct.xenmember)
{
//
// Currently these are the only values we care about.
//
if (n.xenname.ToLower().Equals("uuid") &&
n.xenvalue != null &&
n.xenvalue is string &&
((string)n.xenvalue).Length > 0)
{
vifuuid = (string)n.xenvalue;
if (vifuuid.ToLower().Contains("null"))
{
vifuuid = null;
}
}
else if (n.xenname.ToLower().Equals("network") &&
n.xenvalue != null &&
n.xenvalue is string &&
((string)n.xenvalue).Length > 0)
{
string netref = ((string)n.xenvalue);
if (!netref.ToLower().Contains("null"))
{
if (!mappings.ContainsKey(netref))
{
mappings.Add(netref, vifuuid);
}
}
}
else if (n.xenname.ToLower().Equals("mac") &&
n.xenvalue != null &&
n.xenvalue is string &&
((string)n.xenvalue).Length > 0)
{
mac = ((string)n.xenvalue);
}
}
AddNetwork(env, vsId, lang, vifuuid, null, mac);
log.DebugFormat("OVF.TransformXvaOvf_VIF completed {0}", vsId);
}
private void TransformXvaOvf_Network(EnvelopeType env, string vsId, string lang, string refId, XenStruct vmstruct)
{
string networkName = null;
foreach (XenMember n in vmstruct.xenmember)
{
//
// Currently these are the only values we care about.
//
if (n.xenname.ToLower().Equals("name_label") &&
n.xenvalue != null &&
n.xenvalue is string &&
((string)n.xenvalue).Length > 0)
{
networkName = ((string)n.xenvalue);
break;
}
}
foreach (Section_Type section in env.Sections)
{
if (section is NetworkSection_Type)
{
NetworkSection_Type ns = (NetworkSection_Type)section;
foreach (NetworkSection_TypeNetwork net in ns.Network)
{
if (net.Description != null &&
net.Description.msgid != null &&
net.Description.msgid.Equals(mappings[refId]))
{
net.Description.Value = networkName;
break;
}
}
break;
}
}
log.DebugFormat("OVF.TransformXvaOvf_Network completed {0}", vsId);
}
private void TransformXvaOvf_VDI(EnvelopeType env, string vsId, string lang, string refId, DiskInfo di, XenStruct vmstruct)
{
string instanceId = null;
if (mappings.ContainsKey(refId))
{
instanceId = string.Format(@"Xen:{0}/{1}", vsId, mappings[refId]);
}
else
{
instanceId = string.Format(@"Xen:{0}/{1}", vsId, Guid.NewGuid().ToString());
}
string description = null;
string vhdfilename = di.VhdFileName;
ulong filesize = 0;
ulong capacity = 0;
ulong freespace = 0;
foreach (XenMember n in vmstruct.xenmember)
{
if (n.xenname.ToLower().Equals("virtual_size"))
{
capacity = Convert.ToUInt64(n.xenvalue);
}
else if (n.xenname.ToLower().Equals("physical_utilisation"))
{
filesize = Convert.ToUInt64(n.xenvalue);
}
}
freespace = capacity - filesize;
UpdateDisk(env, vsId, instanceId, description, vhdfilename, filesize, capacity, freespace);
log.DebugFormat("OVF.TransformXvaOvf_VDI completed {0}", vsId);
}
private void TransformXvaOvf_SR(EnvelopeType env, string vsId, string lang, XenStruct vmstruct)
{
//
// Currently this is data for the Environment not necessarily part of the VM
// even if the VM is in this SR it may not exist in the target server therefore
// it is not required in the OVF.
//
log.DebugFormat("OVF.TransformXvaOvf_SR completed {0}", vsId);
}
private void CollectInformation()
{
Win32_ComputerSystem = null;
Win32_Processor.Clear();
Win32_CDROMDrive.Clear();
Win32_DiskDrive.Clear();
Win32_NetworkAdapter.Clear();
Win32_IDEController.Clear();
Win32_SCSIController.Clear();
Win32_SCSIControllerDevice.Clear();
Win32_IDEControllerDevice.Clear();
Win32_DiskPartition.Clear();
ManagementObjectSearcher searcher = null;
#region Win32_ComputerSystem
try
{
searcher = new ManagementObjectSearcher(@"select * from Win32_ComputerSystem");
foreach (ManagementObject mgtobj in searcher.Get())
{
Win32_ComputerSystem = mgtobj; // only want one.
break;
}
log.Debug("OVF.CollectionInformation Win32_ComputerSystem.1");
}
catch (Exception ex)
{
log.WarnFormat("OVF.CollectionInformation: call to Win32_ComputerSystem failed. Exception: {0}", ex.Message);
}
finally
{
if (searcher != null)
searcher.Dispose();
searcher = null;
}
#endregion
#region Win32_Processor
try
{
searcher = new ManagementObjectSearcher(@"select * from Win32_Processor");
foreach (ManagementObject mgtobj in searcher.Get())
{
Win32_Processor.Add(mgtobj); // only want one.
break;
}
log.DebugFormat("OVF.CollectionInformation Win32_Processor.{0}", Win32_Processor.Count);
}
catch (Exception ex)
{
log.WarnFormat("OVF.CollectionInformation: call to Win32_Processor failed. Exception: {0}", ex.Message);
}
finally
{
if (searcher != null)
searcher.Dispose();
searcher = null;
}
#endregion
#region Win32_CDROMDrive
try
{
searcher = new ManagementObjectSearcher(@"select * from Win32_CDROMDrive");
foreach (ManagementObject mgtobj in searcher.Get())
{
Win32_CDROMDrive.Add(mgtobj);
}
log.DebugFormat("OVF.CollectionInformation Win32_CDROMDrive.{0}", Win32_CDROMDrive.Count);
}
catch (Exception ex)
{
log.WarnFormat("OVF.CollectionInformation: call to Win32_CDROMDrive failed. Exception: {0}", ex.Message);
}
finally
{
if (searcher != null)
searcher.Dispose();
searcher = null;
}
#endregion
#region Win32_DiskDrive
try
{
searcher = new ManagementObjectSearcher(@"select * from Win32_DiskDrive");
foreach (ManagementObject mgtobj in searcher.Get())
{
Win32_DiskDrive.Add(mgtobj);
}
log.DebugFormat("OVF.CollectionInformation Win32_DiskDrive.{0}", Win32_DiskDrive.Count);
}
catch (Exception ex)
{
log.WarnFormat("OVF.CollectionInformation: call to Win32_CDROMDrive failed. Exception: {0}", ex.Message);
}
finally
{
if (searcher != null)
searcher.Dispose();
searcher = null;
}
#endregion
#region Win32_NetworkAdapter
try
{
searcher = new ManagementObjectSearcher(@"select * from Win32_NetworkAdapter");
foreach (ManagementObject mgtobj in searcher.Get())
{
Win32_NetworkAdapter.Add(mgtobj);
}
log.DebugFormat("OVF.CollectionInformation Win32_NetworkAdapter.{0}", Win32_NetworkAdapter.Count);
}
catch (Exception ex)
{
log.WarnFormat("OVF.CollectionInformation: call to Win32_NetworkAdapter failed. Exception: {0}", ex.Message);
}
finally
{
if (searcher != null)
searcher.Dispose();
searcher = null;
}
#endregion
#region Win32_IDEController
try
{
searcher = new ManagementObjectSearcher(@"select * from Win32_IDEController");
foreach (ManagementObject mgtobj in searcher.Get())
{
Win32_IDEController.Add(mgtobj);
}
log.DebugFormat("OVF.CollectionInformation Win32_IDEController.{0}", Win32_IDEController.Count);
}
catch (Exception ex)
{
log.WarnFormat("OVF.CollectionInformation: call for Win32_IDEController failed. Exception: {0}", ex.Message);
}
finally
{
if (searcher != null)
searcher.Dispose();
searcher = null;
}
#endregion
#region Win32_SCSIController
try
{
searcher = new ManagementObjectSearcher(@"select * from Win32_SCSIController");
foreach (ManagementObject mgtobj in searcher.Get())
{
Win32_SCSIController.Add(mgtobj);
}
log.DebugFormat("OVF.CollectionInformation Win32_SCSIController.{0}", Win32_SCSIController.Count);
}
catch (Exception ex)
{
log.WarnFormat("OVF.CollectionInformation: call for Win32_SCSIController failed. Exception: {0}", ex.Message);
}
finally
{
if (searcher != null)
searcher.Dispose();
searcher = null;
}
#endregion
#region Win32_DiskPartition
try
{
searcher = new ManagementObjectSearcher(@"select * from Win32_DiskPartition");
foreach (ManagementObject mgtobj in searcher.Get())
{
Win32_DiskPartition.Add(mgtobj);
}
log.DebugFormat("OVF.CollectionInformation Win32_DiskPartition.{0}", Win32_DiskPartition.Count);
}
catch (Exception ex)
{
log.WarnFormat("OVF.CollectionInformation: call for Win32_DiskPartition failed. Exception: {0}", ex.Message);
}
finally
{
if (searcher != null)
searcher.Dispose();
searcher = null;
}
#endregion
#region Win32_DiskDriveToDiskPartition
try
{
searcher = new ManagementObjectSearcher(@"select * from Win32_DiskDriveToDiskPartition");
foreach (ManagementObject mgtobj in searcher.Get())
{
Win32_DiskDriveToDiskPartition.Add(mgtobj);
}
log.DebugFormat("OVF.CollectionInformation Win32_DiskDriveToDiskPartition.{0}", Win32_DiskDriveToDiskPartition.Count);
}
catch (Exception ex)
{
log.WarnFormat("OVF.CollectionInformation: call for Win32_DiskDriveToDiskPartition failed, Exception: {0}", ex.Message);
}
finally
{
if (searcher != null)
searcher.Dispose();
searcher = null;
}
#endregion
}
private void AddVssd(EnvelopeType ovfEnv, string vsId, string vhsId)
{
AddVssd(ovfEnv, vsId, vhsId, Properties.Settings.Default.Language);
}
private void AddVssd(EnvelopeType ovfEnv, string vsId, string vhsId, string lang)
{
if (Win32_ComputerSystem != null)
{
#region FIND BY PROPERTIES NOT EXPLICID
string name = "Generic Computer";
string caption = "Generic Caption";
string description = "Autogenerated OVF/OVA Package";
foreach (PropertyData pd in Win32_ComputerSystem.Properties)
{
if (pd.Name.ToLower().Equals("name") && pd.Value != null)
{
name = (string)pd.Value;
}
else if (pd.Name.ToLower().Equals("caption") && pd.Value != null)
{
caption = (string)pd.Value;
}
else if (pd.Name.ToLower().Equals("description") && pd.Value != null)
{
description = (string)pd.Value;
}
}
#endregion
UpdateVirtualSystemName(ovfEnv, vsId, lang, name);
AddVirtualSystemSettingData(ovfEnv,
vsId,
vhsId,
name,
caption,
description,
Guid.NewGuid().ToString(),
"301"); // 301 == Microsoft (source), hvm-3.0-unknown == (xen source) Microsoft && Linux NOT PV'd, xen-3.0-unknown == PV'd
}
else
{
Random rand = new Random();
string name = string.Format(Messages.AUTOGENERATED, rand.Next());
string caption = string.Format(Messages.UNKNOWN);
string description = string.Format(Messages.UNKNOWN);
UpdateVirtualSystem(ovfEnv, vsId, lang, name);
AddVirtualSystemSettingData(ovfEnv,
vsId,
vhsId,
name,
caption,
description,
Guid.NewGuid().ToString(),
"301");
log.Warn("System definition not available, created defaults");
}
log.Debug("OVF.AddVssd completed");
}
private void AddNetworks(EnvelopeType ovfEnv, string vsId)
{
AddNetworks(ovfEnv, vsId, Properties.Settings.Default.Language);
}
private void AddNetworks(EnvelopeType ovfEnv, string vsId, string lang)
{
if (Win32_NetworkAdapter != null)
{
foreach (ManagementObject mo in Win32_NetworkAdapter)
{
// Only get the physical adapters, not logical (which there are numerous)
//if ((bool)mo["PhysicalAdapter"])
bool addThisNetwork = false;
string macaddress = null;
string description = null;
//
// setPriority is used to determine the description
// 0 = unset
// 1 highest priority
// 2 next
// 3 next
// ...
//
int setPriority = 0;
foreach (PropertyData pd in mo.Properties)
{
if (pd.Name != null && pd.Name.Length > 0)
{
if (pd.Name.ToLower().Equals("macaddress") && pd.Value != null && ((string)pd.Value).Length > 0)
{
macaddress = (string)pd.Value;
}
else if (pd.Name.ToLower().Equals("netconnectionid") && pd.Value != null && ((string)pd.Value).Length > 0)
{
description = (string)pd.Value;
setPriority = 1;
}
else if (pd.Name.ToLower().Equals("name") && pd.Value != null && ((string)pd.Value).Length > 0)
{
if (setPriority == 0 || setPriority > 2)
{
description = (string)pd.Value;
setPriority = 2;
}
}
else if (pd.Name.ToLower().Equals("description") && pd.Value != null && ((string)pd.Value).Length > 0)
{
if (setPriority == 0 || setPriority > 3)
{
description = (string)pd.Value;
setPriority = 3;
}
}
// Below is trying to figure out if this is a Network Connection that
// is to be exported/defined.
// The issue is WMI has different value sets for different types of hardware
// such as hardware as we know it... pci ethernet
// or blade style, which WMI gives a different result.
// WAN/RAS connections.. etc.
// ANY one of the values can set this to true:
// netconnectionstatus
// pnpdeviceid
// physicaladapter
//
else if (pd.Name.ToLower().Equals("netconnectionstatus") && pd.Value != null)
{
if ((UInt16)pd.Value == 0x2)
{
addThisNetwork = true;
}
}
else if (pd.Name.ToLower().Equals("pnpdeviceid") && pd.Value != null && ((string)pd.Value).Length > 0)
{
if ((((string)pd.Value).ToLower().StartsWith("pci") || ((string)pd.Value).ToLower().StartsWith("scsi")))
{
addThisNetwork = true;
}
}
else if (pd.Name.ToLower().Equals("physicaladapter") && pd.Value != null)
{
addThisNetwork = (bool)pd.Value;
}
}
}
if (addThisNetwork)
{
AddNetwork(ovfEnv, vsId, lang, Guid.NewGuid().ToString(), description, macaddress);
}
}
}
else
{
log.Warn("No networks defined, If a network interface is required, the administrator will need to add it after import of OVF/OVA Package.");
}
log.DebugFormat("OVF.AddNetworks completed {0}", vsId);
}
private void AddCPUs(EnvelopeType ovfEnv, string vsId)
{
AddCPUs(ovfEnv, vsId, Properties.Settings.Default.Language);
}
private void AddCPUs(EnvelopeType ovfEnv, string vsId, string lang)
{
UInt64 cpucount = 0;
if (Win32_Processor != null && Win32_Processor.Count > 0)
{
foreach (ManagementObject mo in Win32_Processor)
{
#region FIND BY PROPERTIES NOT EXPLICID
uint numberofcores = 1;
foreach (PropertyData pd in mo.Properties)
{
if (pd.Name.ToLower().Equals("numberofcores") && pd.Value != null)
{
numberofcores = (uint)pd.Value;
}
}
#endregion
cpucount += Convert.ToUInt64(numberofcores);
}
SetCPUs(ovfEnv, vsId, cpucount);
}
else
{
SetCPUs(ovfEnv, vsId, 1);
log.Warn("OVF.AddCPUs, set using default (1) CPU");
}
log.DebugFormat("OVF.AddCPUs completed {0} cpus {1}", vsId, cpucount);
}
private void AddMemory(EnvelopeType ovfEnv, string vsId)
{
AddMemory(ovfEnv, vsId, Properties.Settings.Default.Language);
}
private void AddMemory(EnvelopeType ovfEnv, string vsId, string lang)
{
ulong divisor = 1024*1024;
ulong totalphysicalmemory = divisor*512; // 512MB Default Memory
ulong memory = 0;
if (Win32_ComputerSystem != null)
{
#region FIND BY PROPERTIES NOT EXPLICID
foreach (PropertyData pd in Win32_ComputerSystem.Properties)
{
if (pd.Name.ToLower().Equals("totalphysicalmemory") && pd.Value != null)
{
totalphysicalmemory = (ulong)pd.Value;
break;
}
}
#endregion
memory = totalphysicalmemory/divisor;
}
else
{
log.Warn("OVF.AddMemory: could not determine system memory, defaulting to 512MB");
memory = 512L;
}
SetMemory(ovfEnv, vsId, memory, "byte * 2^20");
log.DebugFormat("OVF.AddMemory completed {0} memory {1} (byte * 2 ^ 20)", vsId, memory);
}
private void CreateConnectedDevices(EnvelopeType ovfEnv, string vsId, DiskInfo[] vhdExports)
{
CreateConnectedDevices(ovfEnv, vsId, Properties.Settings.Default.Language, vhdExports);
}
private void CreateConnectedDevices(EnvelopeType ovfEnv, string vsId, string lang, DiskInfo[] vhdExports)
{
//VirtualHardwareSection_Type vhs = FindVirtualHardwareSection(ovfEnv, vsId);
bool guessPosition = true;
int i = 0;
#region IDE
if (Win32_IDEController != null && Win32_IDEController.Count > 0)
{
foreach (ManagementObject mo in Win32_IDEController)
{
#region FIND BY PROPERTIES NOT EXPLICID
string deviceid = null;
foreach (PropertyData pd in mo.Properties)
{
if (pd.Name.ToLower().Equals("deviceid") && pd.Value != null)
{
deviceid = (string)pd.Value;
}
}
#endregion
if (deviceid == null)
{
log.Debug("No device id defined, continuing");
continue;
}
List<ManagementObject> ControllerAssociations = FindDeviceReferences("Win32_IDEControllerDevice", deviceid);
string controllerInstanceId = Guid.NewGuid().ToString();
AddController(ovfEnv, vsId, DeviceType.IDE, controllerInstanceId, i++);
foreach (ManagementObject ca in ControllerAssociations)
{
#region FIND BY PROPERTIES NOT EXPLICID
string _dependent = null;
foreach (PropertyData pd in ca.Properties)
{
if (pd.Name.ToLower().Equals("dependent") && pd.Value != null)
{
_dependent = (string)pd.Value;
}
}
if (_dependent == null)
{
log.Debug("PCI Association not available, continuing.");
continue;
}
#endregion
string[] dependent = _dependent.Split(new char[] {'='});
string dependentId = dependent[dependent.Length - 1].Replace("\"", "");
dependentId = dependentId.Replace(@"\", "");
string startswith = dependentId; //.Replace(@"\", "");
if (startswith.ToUpper().StartsWith(@"IDEDISK"))
{
log.Debug("OVF.CreateConnectedDevices Checking IDEDISK");
foreach (ManagementObject md in Win32_DiskDrive)
{
#region FIND BY PROPERTIES NOT EXPLICID
string _deviceid = null;
string _pnpdeviceid = null;
UInt64 _size = 0;
foreach (PropertyData pd in md.Properties)
{
if (pd.Name.ToLower().Equals("deviceid") && pd.Value != null)
{
_deviceid = (string)pd.Value;
}
else if (pd.Name.ToLower().Equals("pnpdeviceid") && pd.Value != null)
{
_pnpdeviceid = (string)pd.Value;
}
else if (pd.Name.ToLower().Equals("size") && pd.Value != null)
{
_size = (UInt64)pd.Value;
}
}
#endregion
_pnpdeviceid = _pnpdeviceid.Replace(@"\", "");
if (_pnpdeviceid.Equals(dependentId))
{
foreach (DiskInfo di in vhdExports)
{
if (_deviceid.Contains(di.DriveId))
{
try
{
log.DebugFormat("OVF.CreateConnectedDevices: Dependent: {0} Device: {1}", dependentId, _deviceid);
string diskInstanceId = Guid.NewGuid().ToString();
int lastAmp = dependentId.LastIndexOf('&');
if (lastAmp < 0) lastAmp = 0;
string[] tmp = dependentId.Substring(lastAmp + 1).Split(new char[] {'.'});
string address = null;
if (tmp.Length >= 2)
{
address = tmp[1];
}
else
{
address = (guessPosition) ? "0" : "1";
guessPosition = !guessPosition;
}
address = address.Replace("&", "_");
bool bootable = IsBootDisk(di.DriveId);
AddDisk(ovfEnv, vsId, diskInstanceId, lang, di.VhdFileName, bootable,
_ovfrm.GetString("RASD_19_CAPTION"),
_ovfrm.GetString("RASD_19_DESCRIPTION"),
Convert.ToUInt64(di.PhysicalSize), Convert.ToUInt64(di.CapacitySize));
AddDeviceToController(ovfEnv, vsId, diskInstanceId, controllerInstanceId, address);
di.Added = true;
log.DebugFormat("OVF.CreateConnectedDevices: {0} ({1}) added to {2}", di.DriveId, di.VhdFileName, dependentId);
}
catch (Exception ex)
{
string msg = string.Format("{0} [{1}] controller connection could not be identified.", "IDEDISK", _pnpdeviceid);
log.ErrorFormat("OVF.CreateConnectedDevices: {0}", msg);
throw new Exception(msg, ex);
}
}
}
}
}
}
else if (startswith.ToUpper().StartsWith(@"IDECDROM"))
{
log.Debug("OVF.CreateConnectedDevices Checking IDECDROM");
foreach (ManagementObject md in Win32_CDROMDrive)
{
#region FIND BY PROPERTIES NOT EXPLICID
string _pnpdeviceid = null;
foreach (PropertyData pd in md.Properties)
{
if (pd.Name.ToLower().Equals("pnpdeviceid") && pd.Value != null)
{
_pnpdeviceid = (string)pd.Value;
}
}
if (_pnpdeviceid == null)
{
log.Debug("PNPDeviceID not available, continuing.");
continue;
}
#endregion
_pnpdeviceid = _pnpdeviceid.Replace(@"\", "");
if (_pnpdeviceid.Equals(dependentId))
{
log.DebugFormat("OVF.CreateConnectedDevices: Dependent: {0} Device: {1}", dependentId, _pnpdeviceid);
try
{
string diskInstanceId = Guid.NewGuid().ToString();
int lastAmp = dependentId.LastIndexOf('&');
if (lastAmp < 0) lastAmp = 0;
string[] tmp = dependentId.Substring(lastAmp + 1).Split(new char[] {'.'});
//string[] tmp = dependentId.Split(new char[] { '.' });
string address = tmp[1];
int idetest = Convert.ToInt32(address);
if (idetest != 0 && idetest != 1)
{
address = "0";
}
AddCDROM(ovfEnv, vsId, diskInstanceId, _ovfrm.GetString("RASD_16_CAPTION"), _ovfrm.GetString("RASD_16_ELEMENTNAME"));
AddDeviceToController(ovfEnv, vsId, diskInstanceId, controllerInstanceId, address);
log.DebugFormat("OVF.CreateConnectedDevices: CDROM added to {0}", dependentId);
}
catch
{
log.WarnFormat("OVF.CreateConnectedDevices: CDROM [{0}] controller connection could not be identified, skipped.", _pnpdeviceid);
}
}
}
}
}
}
}
else
{
log.Info("OVF.CreateConnectedDevices NO IDE controllers detected.");
}
log.Debug("OVF.CreateConnectedDevices IDE Controllers completed.");
#endregion
#region SCSI
if (Win32_SCSIController != null && Win32_SCSIController.Count > 0)
{
foreach (ManagementObject device in Win32_SCSIController)
{
#region FIND BY PROPERTIES NOT EXPLICID
string _deviceid = null;
foreach (PropertyData pd in device.Properties)
{
if (pd.Name.ToLower().Equals("deviceid") && pd.Value != null)
{
_deviceid = (string)pd.Value;
}
}
if (_deviceid == null)
{
log.Debug("SCSI DeviceID not available, continuing.");
continue;
}
#endregion
List<ManagementObject> ControllerAssociations = FindDeviceReferences("Win32_SCSIControllerDevice", _deviceid);
string controllerInstanceId = Guid.NewGuid().ToString();
if (ControllerAssociations == null || ControllerAssociations.Count <= 0)
{
log.DebugFormat("No Controller associations for {0}", _deviceid);
continue;
}
AddController(ovfEnv, vsId, DeviceType.SCSI, controllerInstanceId, i++);
foreach (ManagementObject ca in ControllerAssociations)
{
#region FIND BY PROPERTIES NOT EXPLICID
string _dependent = null;
foreach (PropertyData pd in ca.Properties)
{
if (pd.Name.ToLower().Equals("dependent") && pd.Value != null)
{
_dependent = (string)pd.Value;
}
}
if (_dependent == null)
{
log.Debug("SCSI Association not available, continuing.");
continue;
}
#endregion
string[] dependent = _dependent.Split(new char[] {'='});
string dependentId = dependent[dependent.Length - 1].Replace("\"", "");
dependentId = dependentId.Replace(@"\", "");
string startswith = dependentId; //.Replace(@"\", "");
if (startswith.ToUpper().StartsWith(@"SCSIDISK"))
{
foreach (ManagementObject md in Win32_DiskDrive)
{
#region FIND BY PROPERTIES NOT EXPLICID
string __deviceid = null;
string __pnpdeviceid = null;
UInt32 __scsibus = 0;
UInt16 __scsilogicalunit = 0;
UInt16 __scsiport = 0;
UInt16 __scsitargetid = 0;
UInt64 __size = 0;
foreach (PropertyData pd in md.Properties)
{
if (pd.Name.ToLower().Equals("deviceid") && pd.Value != null)
{
__deviceid = (string)pd.Value;
}
if (pd.Name.ToLower().Equals("pnpdeviceid") && pd.Value != null)
{
__pnpdeviceid = (string)pd.Value;
}
if (pd.Name.ToLower().Equals("scsibus") && pd.Value != null)
{
__scsibus = (UInt32)pd.Value;
}
if (pd.Name.ToLower().Equals("scsilogicalunit") && pd.Value != null)
{
__scsilogicalunit = (UInt16)pd.Value;
}
if (pd.Name.ToLower().Equals("scsiport") && pd.Value != null)
{
__scsiport = (UInt16)pd.Value;
}
if (pd.Name.ToLower().Equals("scsitargetid") && pd.Value != null)
{
__scsitargetid = (UInt16)pd.Value;
}
if (pd.Name.ToLower().Equals("size") && pd.Value != null)
{
__size = (UInt64)pd.Value;
}
}
if (__deviceid == null)
{
log.Debug("SCSI DeviceID not available, continuing.");
continue;
}
#endregion
__pnpdeviceid = __pnpdeviceid.Replace(@"\", "");
if (__pnpdeviceid.Equals(dependentId))
{
foreach (DiskInfo di in vhdExports)
{
if (__deviceid.Contains(di.DriveId))
{
string diskInstanceId = Guid.NewGuid().ToString();
string _description = string.Format(_ovfrm.GetString("RASD_CONTROLLER_SCSI_DESCRIPTION"), __scsibus, __scsilogicalunit, __scsiport, __scsitargetid);
bool bootable = IsBootDisk(di.DriveId);
AddDisk(ovfEnv, vsId, diskInstanceId, lang, di.VhdFileName, bootable, _ovfrm.GetString("RASD_19_CAPTION"), _description, Convert.ToUInt64(di.PhysicalSize), Convert.ToUInt64(di.CapacitySize));
AddDeviceToController(ovfEnv, vsId, diskInstanceId, controllerInstanceId, Convert.ToString(__scsiport));
di.Added = true;
log.DebugFormat("CreateConnectedDevices: {0} ({1}) added to {2}", di.DriveId, di.VhdFileName, dependentId);
}
}
}
}
}
else if (startswith.ToUpper().StartsWith(@"SCSICDROM"))
{
foreach (ManagementObject md in Win32_CDROMDrive)
{
#region FIND BY PROPERTIES NOT EXPLICID
string __deviceid = null;
string __pnpdeviceid = null;
UInt32 __scsibus = 0;
UInt16 __scsilogicalunit = 0;
UInt16 __scsiport = 0;
UInt16 __scsitargetid = 0;
foreach (PropertyData pd in md.Properties)
{
if (pd.Name.ToLower().Equals("deviceid") && pd.Value != null)
{
__deviceid = (string)pd.Value;
}
if (pd.Name.ToLower().Equals("pnpdeviceid") && pd.Value != null)
{
__pnpdeviceid = (string)pd.Value;
}
if (pd.Name.ToLower().Equals("scsibus") && pd.Value != null)
{
__scsibus = (UInt32)pd.Value;
}
if (pd.Name.ToLower().Equals("scsilogicalunit") && pd.Value != null)
{
__scsilogicalunit = (UInt16)pd.Value;
}
if (pd.Name.ToLower().Equals("scsiport") && pd.Value != null)
{
__scsiport = (UInt16)pd.Value;
}
if (pd.Name.ToLower().Equals("scsitargetid") && pd.Value != null)
{
__scsitargetid = (UInt16)pd.Value;
}
}
if (__deviceid == null)
{
log.Debug("SCSI DeviceID not available, continuing.");
continue;
}
#endregion
__pnpdeviceid = __pnpdeviceid.Replace(@"\", "");
if (__pnpdeviceid.Equals(dependentId))
{
string diskInstanceId = Guid.NewGuid().ToString();
string caption = string.Format(_ovfrm.GetString("RASD_CONTROLLER_SCSI_DESCRIPTION"), __scsibus, __scsilogicalunit, __scsiport, __scsitargetid);
AddCDROM(ovfEnv, vsId, diskInstanceId, caption, _ovfrm.GetString("RASD_16_DESCRIPTION"));
AddDeviceToController(ovfEnv, vsId, diskInstanceId, controllerInstanceId, Convert.ToString(__scsiport));
log.DebugFormat("CreateConnectedDevices: CDROM added to {0}", dependentId);
}
}
}
}
}
}
else
{
log.Info("OVF.CreateConnectedDevices no SCSI Controllers detected.");
}
log.DebugFormat("OVF.CreateConnectedDevices SCSI Controllers completed {0} ", vsId);
#endregion
#region OTHER CONTROLLER DISKS
// These are disks that were not found on an IDE or SCSI, but exist and want to be exported.
// these could be USB, 1394 etc.
foreach (DiskInfo di in vhdExports)
{
if (!di.Added)
{
UInt64 _size = 0;
string diskInstanceId = Guid.NewGuid().ToString();
string _deviceid = null;
string _mediatype = null;
foreach (ManagementObject md in Win32_DiskDrive)
{
#region FIND BY PROPERTIES NOT EXPLICID
foreach (PropertyData pd in md.Properties)
{
if (pd.Name.ToLower().Equals("deviceid") && pd.Value != null)
{
_deviceid = (string)pd.Value;
}
else if (pd.Name.ToLower().Equals("mediatype") && pd.Value != null)
{
_mediatype = (string)pd.Value;
}
else if (pd.Name.ToLower().Equals("size") && pd.Value != null)
{
_size = (UInt64)pd.Value;
}
}
#endregion
}
bool bootable = IsBootDisk(di.DriveId);
AddDisk(ovfEnv, vsId, diskInstanceId, lang, di.VhdFileName, bootable, _ovfrm.GetString("RASD_19_CAPTION"), _mediatype, Convert.ToUInt64(di.PhysicalSize), Convert.ToUInt64(di.CapacitySize));
di.Added = true;
log.DebugFormat("CreateConnectedDevices: {0} ({1}) added to {2}", di.DriveId, di.VhdFileName, _mediatype);
}
}
log.DebugFormat("OVF.CreateConnectedDevices OTHER Controllers completed {0} ", vsId);
#endregion
#region CHECK ALL DISKS WERE DEFINED
foreach (DiskInfo di in vhdExports)
{
if (!di.Added)
{
AddDisk(ovfEnv, vsId, Guid.NewGuid().ToString(), lang, di.VhdFileName, false, _ovfrm.GetString("RASD_19_CAPTION"), _ovfrm.GetString("RASD_19_DESCRIPTION"), Convert.ToUInt64(di.PhysicalSize), Convert.ToUInt64(di.CapacitySize));
di.Added = true;
log.Warn("CreateConnectedDevices: MANUAL Update of OVF REQUIRED TO DEFINE: Disk Size and Capacity");
log.WarnFormat("CreateConnectedDevices: {0} ({1}) NOT FOUND, added as Unknown with 0 Size", di.DriveId, di.VhdFileName);
}
}
#endregion
log.DebugFormat("OVF.CreateConnectedDevices completed {0} ", vsId);
}
#endregion
}
}