/* $Id: VBoxManageInfo.cpp 52037 2014-07-15 13:07:29Z vboxsync $ */ /** @file * VBoxManage - The 'showvminfo' command and helper routines. */ /* * Copyright (C) 2006-2014 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ #ifndef VBOX_ONLY_DOCS /******************************************************************************* * Header Files * *******************************************************************************/ #include #include #include #include #include #include #include #ifdef VBOX_WITH_PCI_PASSTHROUGH #include #endif #include #include #include #include #include #include #include "VBoxManage.h" using namespace com; // funcs /////////////////////////////////////////////////////////////////////////////// HRESULT showSnapshots(ComPtr &rootSnapshot, ComPtr ¤tSnapshot, VMINFO_DETAILS details, const Utf8Str &prefix /* = ""*/, int level /*= 0*/) { /* start with the root */ Bstr name; Bstr uuid; Bstr description; CHECK_ERROR2_RET(rootSnapshot, COMGETTER(Name)(name.asOutParam()), hrcCheck); CHECK_ERROR2_RET(rootSnapshot, COMGETTER(Id)(uuid.asOutParam()), hrcCheck); CHECK_ERROR2_RET(rootSnapshot, COMGETTER(Description)(description.asOutParam()), hrcCheck); bool fCurrent = (rootSnapshot == currentSnapshot); if (details == VMINFO_MACHINEREADABLE) { /* print with hierarchical numbering */ RTPrintf("SnapshotName%s=\"%ls\"\n", prefix.c_str(), name.raw()); RTPrintf("SnapshotUUID%s=\"%s\"\n", prefix.c_str(), Utf8Str(uuid).c_str()); if (!description.isEmpty()) RTPrintf("SnapshotDescription%s=\"%ls\"\n", prefix.c_str(), description.raw()); if (fCurrent) { RTPrintf("CurrentSnapshotName=\"%ls\"\n", name.raw()); RTPrintf("CurrentSnapshotUUID=\"%s\"\n", Utf8Str(uuid).c_str()); RTPrintf("CurrentSnapshotNode=\"SnapshotName%s\"\n", prefix.c_str()); } } else { /* print with indentation */ RTPrintf(" %sName: %ls (UUID: %s)%s\n", prefix.c_str(), name.raw(), Utf8Str(uuid).c_str(), (fCurrent) ? " *" : ""); if (!description.isEmpty()) RTPrintf(" %sDescription:\n%ls\n", prefix.c_str(), description.raw()); } /* get the children */ HRESULT hrc = S_OK; SafeIfaceArray coll; CHECK_ERROR2_RET(rootSnapshot,COMGETTER(Children)(ComSafeArrayAsOutParam(coll)), hrcCheck); if (!coll.isNull()) { for (size_t index = 0; index < coll.size(); ++index) { ComPtr snapshot = coll[index]; if (snapshot) { Utf8Str newPrefix; if (details == VMINFO_MACHINEREADABLE) newPrefix = Utf8StrFmt("%s-%d", prefix.c_str(), index + 1); else { newPrefix = Utf8StrFmt("%s ", prefix.c_str()); } /* recursive call */ HRESULT hrc2 = showSnapshots(snapshot, currentSnapshot, details, newPrefix, level + 1); if (FAILED(hrc2)) hrc = hrc2; } } } return hrc; } static void makeTimeStr(char *s, int cb, int64_t millies) { RTTIME t; RTTIMESPEC ts; RTTimeSpecSetMilli(&ts, millies); RTTimeExplode(&t, &ts); RTStrPrintf(s, cb, "%04d/%02d/%02d %02d:%02d:%02d UTC", t.i32Year, t.u8Month, t.u8MonthDay, t.u8Hour, t.u8Minute, t.u8Second); } const char *machineStateToName(MachineState_T machineState, bool fShort) { switch (machineState) { case MachineState_PoweredOff: return fShort ? "poweroff" : "powered off"; case MachineState_Saved: return "saved"; case MachineState_Aborted: return "aborted"; case MachineState_Teleported: return "teleported"; case MachineState_Running: return "running"; case MachineState_Paused: return "paused"; case MachineState_Stuck: return fShort ? "gurumeditation" : "guru meditation"; case MachineState_LiveSnapshotting: return fShort ? "livesnapshotting" : "live snapshotting"; case MachineState_Teleporting: return "teleporting"; case MachineState_Starting: return "starting"; case MachineState_Stopping: return "stopping"; case MachineState_Saving: return "saving"; case MachineState_Restoring: return "restoring"; case MachineState_TeleportingPausedVM: return fShort ? "teleportingpausedvm" : "teleporting paused vm"; case MachineState_TeleportingIn: return fShort ? "teleportingin" : "teleporting (incoming)"; case MachineState_RestoringSnapshot: return fShort ? "restoringsnapshot" : "restoring snapshot"; case MachineState_DeletingSnapshot: return fShort ? "deletingsnapshot" : "deleting snapshot"; case MachineState_DeletingSnapshotOnline: return fShort ? "deletingsnapshotlive" : "deleting snapshot live"; case MachineState_DeletingSnapshotPaused: return fShort ? "deletingsnapshotlivepaused" : "deleting snapshot live paused"; case MachineState_SettingUp: return fShort ? "settingup" : "setting up"; default: break; } return "unknown"; } const char *facilityStateToName(AdditionsFacilityStatus_T faStatus, bool fShort) { switch (faStatus) { case AdditionsFacilityStatus_Inactive: return fShort ? "inactive" : "not active"; case AdditionsFacilityStatus_Paused: return "paused"; case AdditionsFacilityStatus_PreInit: return fShort ? "preinit" : "pre-initializing"; case AdditionsFacilityStatus_Init: return fShort ? "init" : "initializing"; case AdditionsFacilityStatus_Active: return fShort ? "active" : "active/running"; case AdditionsFacilityStatus_Terminating: return "terminating"; case AdditionsFacilityStatus_Terminated: return "terminated"; case AdditionsFacilityStatus_Failed: return "failed"; case AdditionsFacilityStatus_Unknown: default: break; } return "unknown"; } /** * This takes care of escaping double quotes and slashes that the string might * contain. * * @param pszName The variable name. * @param pbstrValue The value. */ static void outputMachineReadableString(const char *pszName, Bstr const *pbstrValue) { Assert(strpbrk(pszName, "\"\\") == NULL); com::Utf8Str strValue(*pbstrValue); if ( strValue.isEmpty() || ( !strValue.count('"') && !strValue.count('\\'))) RTPrintf("%s=\"%s\"\n", pszName, strValue.c_str()); else { /* The value needs escaping. */ RTPrintf("%s=\"", pszName); const char *psz = strValue.c_str(); for (;;) { const char *pszNext = strpbrk(psz, "\"\\"); if (!pszNext) { RTPrintf("%s", psz); break; } RTPrintf("%.*s\\%c", pszNext - psz, psz, *pszNext); psz = pszNext + 1; } RTPrintf("\"\n"); } } /** * Converts bandwidth group type to a string. * @returns String representation. * @param enmType Bandwidth control group type. */ inline const char * bwGroupTypeToString(BandwidthGroupType_T enmType) { switch (enmType) { case BandwidthGroupType_Disk: return "Disk"; case BandwidthGroupType_Network: return "Network"; } return "unknown"; } HRESULT showBandwidthGroups(ComPtr &bwCtrl, VMINFO_DETAILS details) { int rc = S_OK; SafeIfaceArray bwGroups; CHECK_ERROR_RET(bwCtrl, GetAllBandwidthGroups(ComSafeArrayAsOutParam(bwGroups)), rc); if (bwGroups.size() && details != VMINFO_MACHINEREADABLE) RTPrintf("\n\n"); for (size_t i = 0; i < bwGroups.size(); i++) { Bstr strName; LONG64 cMaxBytesPerSec; BandwidthGroupType_T enmType; CHECK_ERROR_RET(bwGroups[i], COMGETTER(Name)(strName.asOutParam()), rc); CHECK_ERROR_RET(bwGroups[i], COMGETTER(Type)(&enmType), rc); CHECK_ERROR_RET(bwGroups[i], COMGETTER(MaxBytesPerSec)(&cMaxBytesPerSec), rc); const char *pszType = bwGroupTypeToString(enmType); if (details == VMINFO_MACHINEREADABLE) RTPrintf("BandwidthGroup%zu=%ls,%s,%lld\n", i, strName.raw(), pszType, cMaxBytesPerSec); else { const char *pszUnits = ""; LONG64 cBytes = cMaxBytesPerSec; if (cBytes == 0) { RTPrintf("Name: '%ls', Type: %s, Limit: none (disabled)\n", strName.raw(), pszType); continue; } else if (!(cBytes % _1G)) { pszUnits = "G"; cBytes /= _1G; } else if (!(cBytes % _1M)) { pszUnits = "M"; cBytes /= _1M; } else if (!(cBytes % _1K)) { pszUnits = "K"; cBytes /= _1K; } const char *pszNetUnits = NULL; if (enmType == BandwidthGroupType_Network) { /* * We want to report network rate limit in bits/s, not bytes. * Only if it cannot be express it in kilobits we will fall * back to reporting it in bytes. */ LONG64 cBits = cMaxBytesPerSec; if (!(cBits % 125)) { cBits /= 125; pszNetUnits = "k"; if (!(cBits % 1000000)) { cBits /= 1000000; pszNetUnits = "g"; } else if (!(cBits % 1000)) { cBits /= 1000; pszNetUnits = "m"; } RTPrintf("Name: '%ls', Type: %s, Limit: %lld %sbits/sec (%lld %sbytes/sec)\n", strName.raw(), pszType, cBits, pszNetUnits, cBytes, pszUnits); } } if (!pszNetUnits) RTPrintf("Name: '%ls', Type: %s, Limit: %lld %sbytes/sec\n", strName.raw(), pszType, cBytes, pszUnits); } } if (details != VMINFO_MACHINEREADABLE) RTPrintf(bwGroups.size() != 0 ? "\n" : "\n\n"); return rc; } /* Disable global optimizations for MSC 8.0/64 to make it compile in reasonable time. MSC 7.1/32 doesn't have quite as much trouble with it, but still sufficient to qualify for this hack as well since this code isn't performance critical and probably won't gain much from the extra optimizing in real life. */ #if defined(_MSC_VER) # pragma optimize("g", off) #endif HRESULT showVMInfo(ComPtr virtualBox, ComPtr machine, VMINFO_DETAILS details /*= VMINFO_NONE*/, ComPtr console /*= ComPtr ()*/) { HRESULT rc; #define SHOW_BOOLEAN_PROP(a_pObj, a_Prop, a_szMachine, a_szHuman) \ SHOW_BOOLEAN_PROP_EX(a_pObj, a_Prop, a_szMachine, a_szHuman, "on", "off") #define SHOW_BOOLEAN_PROP_EX(a_pObj, a_Prop, a_szMachine, a_szHuman, a_szTrue, a_szFalse) \ do \ { \ BOOL f; \ CHECK_ERROR2_RET(a_pObj, COMGETTER(a_Prop)(&f), hrcCheck); \ if (details == VMINFO_MACHINEREADABLE) \ RTPrintf( a_szMachine "=\"%s\"\n", f ? "on" : "off"); \ else \ RTPrintf("%-16s %s\n", a_szHuman ":", f ? a_szTrue : a_szFalse); \ } while (0) #define SHOW_BOOLEAN_METHOD(a_pObj, a_Invocation, a_szMachine, a_szHuman) \ do \ { \ BOOL f; \ CHECK_ERROR2_RET(a_pObj, a_Invocation, hrcCheck); \ if (details == VMINFO_MACHINEREADABLE) \ RTPrintf( a_szMachine "=\"%s\"\n", f ? "on" : "off"); \ else \ RTPrintf("%-16s %s\n", a_szHuman ":", f ? "on" : "off"); \ } while (0) #define SHOW_STRING_PROP(a_pObj, a_Prop, a_szMachine, a_szHuman) \ do \ { \ Bstr bstr; \ CHECK_ERROR2_RET(a_pObj, COMGETTER(a_Prop)(bstr.asOutParam()), hrcCheck); \ if (details == VMINFO_MACHINEREADABLE) \ outputMachineReadableString(a_szMachine, &bstr); \ else \ RTPrintf("%-16s %ls\n", a_szHuman ":", bstr.raw()); \ } while (0) #define SHOW_STRINGARRAY_PROP(a_pObj, a_Prop, a_szMachine, a_szHuman) \ do \ { \ SafeArray array; \ CHECK_ERROR2_RET(a_pObj, COMGETTER(a_Prop)(ComSafeArrayAsOutParam(array)), hrcCheck); \ Utf8Str str; \ for (size_t i = 0; i < array.size(); i++) \ { \ if (i != 0) \ str.append(","); \ str.append(Utf8Str(array[i]).c_str()); \ } \ Bstr bstr(str); \ if (details == VMINFO_MACHINEREADABLE) \ outputMachineReadableString(a_szMachine, &bstr); \ else \ RTPrintf("%-16s %ls\n", a_szHuman ":", bstr.raw()); \ } while (0) #define SHOW_UUID_PROP(a_pObj, a_Prop, a_szMachine, a_szHuman) \ SHOW_STRING_PROP(a_pObj, a_Prop, a_szMachine, a_szHuman) #define SHOW_ULONG_PROP(a_pObj, a_Prop, a_szMachine, a_szHuman, a_szUnit) \ do \ { \ ULONG u32; \ CHECK_ERROR2_RET(a_pObj, COMGETTER(a_Prop)(&u32), hrcCheck); \ if (details == VMINFO_MACHINEREADABLE) \ RTPrintf(a_szMachine "=%u\n", u32); \ else \ RTPrintf("%-16s %u" a_szUnit "\n", a_szHuman ":", u32); \ } while (0) #define SHOW_LONG64_PROP(a_pObj, a_Prop, a_szMachine, a_szHuman, a_szUnit) \ do \ { \ LONG64 i64; \ CHECK_ERROR2_RET(a_pObj, COMGETTER(a_Prop)(&i64), hrcCheck); \ if (details == VMINFO_MACHINEREADABLE) \ RTPrintf(a_szMachine "=%lld\n", i64); \ else \ RTPrintf("%-16s %'lld" a_szUnit "\n", a_szHuman ":", i64); \ } while (0) /* * The rules for output in -argdump format: * 1) the key part (the [0-9a-zA-Z_\-]+ string before the '=' delimiter) * is all lowercase for "VBoxManage modifyvm" parameters. Any * other values printed are in CamelCase. * 2) strings (anything non-decimal) are printed surrounded by * double quotes '"'. If the strings themselves contain double * quotes, these characters are escaped by '\'. Any '\' character * in the original string is also escaped by '\'. * 3) numbers (containing just [0-9\-]) are written out unchanged. */ BOOL fAccessible; CHECK_ERROR2_RET(machine, COMGETTER(Accessible)(&fAccessible), hrcCheck); if (!fAccessible) { Bstr uuid; machine->COMGETTER(Id)(uuid.asOutParam()); if (details == VMINFO_COMPACT) RTPrintf("\"\" {%s}\n", Utf8Str(uuid).c_str()); else { if (details == VMINFO_MACHINEREADABLE) RTPrintf("name=\"\"\n"); else RTPrintf("Name: \n"); if (details == VMINFO_MACHINEREADABLE) RTPrintf("UUID=\"%s\"\n", Utf8Str(uuid).c_str()); else RTPrintf("UUID: %s\n", Utf8Str(uuid).c_str()); if (details != VMINFO_MACHINEREADABLE) { Bstr settingsFilePath; rc = machine->COMGETTER(SettingsFilePath)(settingsFilePath.asOutParam()); RTPrintf("Config file: %ls\n", settingsFilePath.raw()); ComPtr accessError; rc = machine->COMGETTER(AccessError)(accessError.asOutParam()); RTPrintf("Access error details:\n"); ErrorInfo ei(accessError); GluePrintErrorInfo(ei); RTPrintf("\n"); } } return S_OK; } if (details == VMINFO_COMPACT) { Bstr machineName; machine->COMGETTER(Name)(machineName.asOutParam()); Bstr uuid; machine->COMGETTER(Id)(uuid.asOutParam()); RTPrintf("\"%ls\" {%s}\n", machineName.raw(), Utf8Str(uuid).c_str()); return S_OK; } SHOW_STRING_PROP( machine, Name, "name", "Name"); Bstr osTypeId; CHECK_ERROR2_RET(machine, COMGETTER(OSTypeId)(osTypeId.asOutParam()), hrcCheck); ComPtr osType; CHECK_ERROR2_RET(virtualBox, GetGuestOSType(osTypeId.raw(), osType.asOutParam()), hrcCheck); SHOW_STRINGARRAY_PROP( machine, Groups, "groups", "Groups"); SHOW_STRING_PROP( osType, Description, "ostype", "Guest OS"); SHOW_UUID_PROP( machine, Id, "UUID", "UUID"); SHOW_STRING_PROP( machine, SettingsFilePath, "CfgFile", "Config file"); SHOW_STRING_PROP( machine, SnapshotFolder, "SnapFldr", "Snapshot folder"); SHOW_STRING_PROP( machine, LogFolder, "LogFldr", "Log folder"); SHOW_UUID_PROP( machine, HardwareUUID, "hardwareuuid", "Hardware UUID"); SHOW_ULONG_PROP( machine, MemorySize, "memory", "Memory size", "MB"); SHOW_BOOLEAN_PROP( machine, PageFusionEnabled, "pagefusion", "Page Fusion"); SHOW_ULONG_PROP( machine, VRAMSize, "vram", "VRAM size", "MB"); SHOW_ULONG_PROP( machine, CPUExecutionCap, "cpuexecutioncap", "CPU exec cap", "%%"); SHOW_BOOLEAN_PROP( machine, HPETEnabled, "hpet", "HPET"); ChipsetType_T chipsetType; CHECK_ERROR2_RET(machine, COMGETTER(ChipsetType)(&chipsetType), hrcCheck); const char *pszChipsetType; switch (chipsetType) { case ChipsetType_Null: pszChipsetType = "invalid"; break; case ChipsetType_PIIX3: pszChipsetType = "piix3"; break; case ChipsetType_ICH9: pszChipsetType = "ich9"; break; default: AssertFailed(); pszChipsetType = "unknown"; break; } if (details == VMINFO_MACHINEREADABLE) RTPrintf("chipset=\"%s\"\n", pszChipsetType); else RTPrintf("Chipset: %s\n", pszChipsetType); FirmwareType_T firmwareType; CHECK_ERROR2_RET(machine, COMGETTER(FirmwareType)(&firmwareType), hrcCheck); const char *pszFirmwareType; switch (firmwareType) { case FirmwareType_BIOS: pszFirmwareType = "BIOS"; break; case FirmwareType_EFI: pszFirmwareType = "EFI"; break; case FirmwareType_EFI32: pszFirmwareType = "EFI32"; break; case FirmwareType_EFI64: pszFirmwareType = "EFI64"; break; case FirmwareType_EFIDUAL: pszFirmwareType = "EFIDUAL"; break; default: AssertFailed(); pszFirmwareType = "unknown"; break; } if (details == VMINFO_MACHINEREADABLE) RTPrintf("firmware=\"%s\"\n", pszFirmwareType); else RTPrintf("Firmware: %s\n", pszFirmwareType); SHOW_ULONG_PROP( machine, CPUCount, "cpus", "Number of CPUs", ""); SHOW_BOOLEAN_METHOD( machine, GetCPUProperty(CPUPropertyType_PAE, &f), "pae", "PAE"); SHOW_BOOLEAN_METHOD( machine, GetCPUProperty(CPUPropertyType_LongMode, &f), "longmode", "Long Mode"); SHOW_BOOLEAN_METHOD( machine, GetCPUProperty(CPUPropertyType_Synthetic, &f), "synthcpu", "Synthetic CPU"); if (details != VMINFO_MACHINEREADABLE) RTPrintf("CPUID overrides: "); ULONG cFound = 0; static uint32_t const s_auCpuIdRanges[] = { UINT32_C(0x00000000), UINT32_C(0x0000000a), UINT32_C(0x80000000), UINT32_C(0x8000000a) }; for (unsigned i = 0; i < RT_ELEMENTS(s_auCpuIdRanges); i += 2) for (uint32_t uLeaf = s_auCpuIdRanges[i]; uLeaf < s_auCpuIdRanges[i + 1]; uLeaf++) { ULONG uEAX, uEBX, uECX, uEDX; rc = machine->GetCPUIDLeaf(uLeaf, &uEAX, &uEBX, &uECX, &uEDX); if (SUCCEEDED(rc)) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("cpuid=%08x,%08x,%08x,%08x,%08x", uLeaf, uEAX, uEBX, uECX, uEDX); else { if (!cFound) RTPrintf("Leaf no. EAX EBX ECX EDX\n"); RTPrintf(" %08x %08x %08x %08x %08x\n", uLeaf, uEAX, uEBX, uECX, uEDX); } cFound++; } } if (!cFound && details != VMINFO_MACHINEREADABLE) RTPrintf("None\n"); ComPtr biosSettings; CHECK_ERROR2_RET(machine, COMGETTER(BIOSSettings)(biosSettings.asOutParam()), hrcCheck); BIOSBootMenuMode_T bootMenuMode; CHECK_ERROR2_RET(biosSettings, COMGETTER(BootMenuMode)(&bootMenuMode), hrcCheck); const char *pszBootMenu; switch (bootMenuMode) { case BIOSBootMenuMode_Disabled: pszBootMenu = "disabled"; break; case BIOSBootMenuMode_MenuOnly: if (details == VMINFO_MACHINEREADABLE) pszBootMenu = "menuonly"; else pszBootMenu = "menu only"; break; default: if (details == VMINFO_MACHINEREADABLE) pszBootMenu = "messageandmenu"; else pszBootMenu = "message and menu"; } if (details == VMINFO_MACHINEREADABLE) RTPrintf("bootmenu=\"%s\"\n", pszBootMenu); else RTPrintf("Boot menu mode: %s\n", pszBootMenu); ComPtr systemProperties; CHECK_ERROR2_RET(virtualBox, COMGETTER(SystemProperties)(systemProperties.asOutParam()), hrcCheck); ULONG maxBootPosition = 0; CHECK_ERROR2_RET(systemProperties, COMGETTER(MaxBootPosition)(&maxBootPosition), hrcCheck); for (ULONG i = 1; i <= maxBootPosition; i++) { DeviceType_T bootOrder; CHECK_ERROR2_RET(machine, GetBootOrder(i, &bootOrder), hrcCheck); if (bootOrder == DeviceType_Floppy) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("boot%d=\"floppy\"\n", i); else RTPrintf("Boot Device (%d): Floppy\n", i); } else if (bootOrder == DeviceType_DVD) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("boot%d=\"dvd\"\n", i); else RTPrintf("Boot Device (%d): DVD\n", i); } else if (bootOrder == DeviceType_HardDisk) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("boot%d=\"disk\"\n", i); else RTPrintf("Boot Device (%d): HardDisk\n", i); } else if (bootOrder == DeviceType_Network) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("boot%d=\"net\"\n", i); else RTPrintf("Boot Device (%d): Network\n", i); } else if (bootOrder == DeviceType_USB) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("boot%d=\"usb\"\n", i); else RTPrintf("Boot Device (%d): USB\n", i); } else if (bootOrder == DeviceType_SharedFolder) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("boot%d=\"sharedfolder\"\n", i); else RTPrintf("Boot Device (%d): Shared Folder\n", i); } else { if (details == VMINFO_MACHINEREADABLE) RTPrintf("boot%d=\"none\"\n", i); else RTPrintf("Boot Device (%d): Not Assigned\n", i); } } SHOW_BOOLEAN_PROP(biosSettings, ACPIEnabled, "acpi", "ACPI"); SHOW_BOOLEAN_PROP(biosSettings, IOAPICEnabled, "ioapic", "IOAPIC"); SHOW_LONG64_PROP(biosSettings, TimeOffset, "biossystemtimeoffset", "Time offset", "ms"); SHOW_BOOLEAN_PROP_EX(machine, RTCUseUTC, "rtcuseutc", "RTC", "UTC", "local time"); SHOW_BOOLEAN_METHOD(machine, GetHWVirtExProperty(HWVirtExPropertyType_Enabled, &f), "hwvirtex", "Hardw. virt.ext"); SHOW_BOOLEAN_METHOD(machine, GetHWVirtExProperty(HWVirtExPropertyType_NestedPaging, &f),"nestedpaging", "Nested Paging"); SHOW_BOOLEAN_METHOD(machine, GetHWVirtExProperty(HWVirtExPropertyType_LargePages, &f), "largepages", "Large Pages"); SHOW_BOOLEAN_METHOD(machine, GetHWVirtExProperty(HWVirtExPropertyType_VPID, &f), "vtxvpid", "VT-x VPID"); SHOW_BOOLEAN_METHOD(machine, GetHWVirtExProperty(HWVirtExPropertyType_UnrestrictedExecution, &f), "vtxux", "VT-x unr. exec."); ParavirtProvider_T paravirtProvider; CHECK_ERROR2_RET(machine, COMGETTER(ParavirtProvider)(¶virtProvider), hrcCheck); const char *pszParavirtProvider; switch (paravirtProvider) { case ParavirtProvider_None: if (details == VMINFO_MACHINEREADABLE) pszParavirtProvider = "none"; else pszParavirtProvider = "None"; break; case ParavirtProvider_Default: if (details == VMINFO_MACHINEREADABLE) pszParavirtProvider = "default"; else pszParavirtProvider = "Default"; break; case ParavirtProvider_Legacy: if (details == VMINFO_MACHINEREADABLE) pszParavirtProvider = "legacy"; else pszParavirtProvider = "Legacy"; break; case ParavirtProvider_Minimal: if (details == VMINFO_MACHINEREADABLE) pszParavirtProvider = "minimal"; else pszParavirtProvider = "Minimal"; break; case ParavirtProvider_HyperV: if (details == VMINFO_MACHINEREADABLE) pszParavirtProvider = "hyperv"; else pszParavirtProvider = "HyperV"; break; default: if (details == VMINFO_MACHINEREADABLE) pszParavirtProvider = "unknown"; else pszParavirtProvider = "Unknown"; } if (details == VMINFO_MACHINEREADABLE) RTPrintf("paravirtprovider=\"%s\"\n", pszParavirtProvider); else RTPrintf("Paravirt. Provider: %s\n", pszParavirtProvider); MachineState_T machineState; CHECK_ERROR2_RET(machine, COMGETTER(State)(&machineState), hrcCheck); const char *pszState = machineStateToName(machineState, details == VMINFO_MACHINEREADABLE /*=fShort*/); LONG64 stateSince; machine->COMGETTER(LastStateChange)(&stateSince); RTTIMESPEC timeSpec; RTTimeSpecSetMilli(&timeSpec, stateSince); char pszTime[30] = {0}; RTTimeSpecToString(&timeSpec, pszTime, sizeof(pszTime)); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("VMState=\"%s\"\n", pszState); RTPrintf("VMStateChangeTime=\"%s\"\n", pszTime); Bstr stateFile; machine->COMGETTER(StateFilePath)(stateFile.asOutParam()); if (!stateFile.isEmpty()) RTPrintf("VMStateFile=\"%ls\"\n", stateFile.raw()); } else RTPrintf("State: %s (since %s)\n", pszState, pszTime); SHOW_ULONG_PROP( machine, MonitorCount, "monitorcount", "Monitor count", ""); SHOW_BOOLEAN_PROP( machine, Accelerate3DEnabled, "accelerate3d", "3D Acceleration"); #ifdef VBOX_WITH_VIDEOHWACCEL SHOW_BOOLEAN_PROP( machine, Accelerate2DVideoEnabled, "accelerate2dvideo", "2D Video Acceleration"); #endif SHOW_BOOLEAN_PROP( machine, TeleporterEnabled, "teleporterenabled", "Teleporter Enabled"); SHOW_ULONG_PROP( machine, TeleporterPort, "teleporterport", "Teleporter Port", ""); SHOW_STRING_PROP( machine, TeleporterAddress, "teleporteraddress", "Teleporter Address"); SHOW_STRING_PROP( machine, TeleporterPassword, "teleporterpassword", "Teleporter Password"); SHOW_BOOLEAN_PROP( machine, TracingEnabled, "tracing-enabled", "Tracing Enabled"); SHOW_BOOLEAN_PROP( machine, AllowTracingToAccessVM, "tracing-allow-vm-access", "Allow Tracing to Access VM"); SHOW_STRING_PROP( machine, TracingConfig, "tracing-config", "Tracing Configuration"); SHOW_BOOLEAN_PROP( machine, AutostartEnabled, "autostart-enabled", "Autostart Enabled"); SHOW_ULONG_PROP( machine, AutostartDelay, "autostart-delay", "Autostart Delay", ""); SHOW_STRING_PROP( machine, DefaultFrontend, "defaultfrontend", "Default Frontend"); /** @todo Convert the remainder of the function to SHOW_XXX macros and add error * checking where missing. */ /* * Storage Controllers and their attached Mediums. */ com::SafeIfaceArray storageCtls; CHECK_ERROR(machine, COMGETTER(StorageControllers)(ComSafeArrayAsOutParam(storageCtls))); for (size_t i = 0; i < storageCtls.size(); ++ i) { ComPtr storageCtl = storageCtls[i]; StorageControllerType_T enmCtlType = StorageControllerType_Null; const char *pszCtl = NULL; ULONG ulValue = 0; BOOL fBootable = FALSE; Bstr storageCtlName; storageCtl->COMGETTER(Name)(storageCtlName.asOutParam()); if (details == VMINFO_MACHINEREADABLE) RTPrintf("storagecontrollername%u=\"%ls\"\n", i, storageCtlName.raw()); else RTPrintf("Storage Controller Name (%u): %ls\n", i, storageCtlName.raw()); storageCtl->COMGETTER(ControllerType)(&enmCtlType); switch (enmCtlType) { case StorageControllerType_LsiLogic: pszCtl = "LsiLogic"; break; case StorageControllerType_LsiLogicSas: pszCtl = "LsiLogicSas"; break; case StorageControllerType_BusLogic: pszCtl = "BusLogic"; break; case StorageControllerType_IntelAhci: pszCtl = "IntelAhci"; break; case StorageControllerType_PIIX3: pszCtl = "PIIX3"; break; case StorageControllerType_PIIX4: pszCtl = "PIIX4"; break; case StorageControllerType_ICH6: pszCtl = "ICH6"; break; case StorageControllerType_I82078: pszCtl = "I82078"; break; case StorageControllerType_USB: pszCtl = "USB"; break; default: pszCtl = "unknown"; } if (details == VMINFO_MACHINEREADABLE) RTPrintf("storagecontrollertype%u=\"%s\"\n", i, pszCtl); else RTPrintf("Storage Controller Type (%u): %s\n", i, pszCtl); storageCtl->COMGETTER(Instance)(&ulValue); if (details == VMINFO_MACHINEREADABLE) RTPrintf("storagecontrollerinstance%u=\"%lu\"\n", i, ulValue); else RTPrintf("Storage Controller Instance Number (%u): %lu\n", i, ulValue); storageCtl->COMGETTER(MaxPortCount)(&ulValue); if (details == VMINFO_MACHINEREADABLE) RTPrintf("storagecontrollermaxportcount%u=\"%lu\"\n", i, ulValue); else RTPrintf("Storage Controller Max Port Count (%u): %lu\n", i, ulValue); storageCtl->COMGETTER(PortCount)(&ulValue); if (details == VMINFO_MACHINEREADABLE) RTPrintf("storagecontrollerportcount%u=\"%lu\"\n", i, ulValue); else RTPrintf("Storage Controller Port Count (%u): %lu\n", i, ulValue); storageCtl->COMGETTER(Bootable)(&fBootable); if (details == VMINFO_MACHINEREADABLE) RTPrintf("storagecontrollerbootable%u=\"%s\"\n", i, fBootable ? "on" : "off"); else RTPrintf("Storage Controller Bootable (%u): %s\n", i, fBootable ? "on" : "off"); } for (size_t j = 0; j < storageCtls.size(); ++ j) { ComPtr storageCtl = storageCtls[j]; ComPtr medium; Bstr storageCtlName; Bstr filePath; ULONG cDevices; ULONG cPorts; storageCtl->COMGETTER(Name)(storageCtlName.asOutParam()); storageCtl->COMGETTER(MaxDevicesPerPortCount)(&cDevices); storageCtl->COMGETTER(PortCount)(&cPorts); for (ULONG i = 0; i < cPorts; ++ i) { for (ULONG k = 0; k < cDevices; ++ k) { ComPtr mediumAttach; machine->GetMediumAttachment(storageCtlName.raw(), i, k, mediumAttach.asOutParam()); BOOL fIsEjected = FALSE; BOOL fTempEject = FALSE; DeviceType_T devType = DeviceType_Null; if (mediumAttach) { mediumAttach->COMGETTER(TemporaryEject)(&fTempEject); mediumAttach->COMGETTER(IsEjected)(&fIsEjected); mediumAttach->COMGETTER(Type)(&devType); } rc = machine->GetMedium(storageCtlName.raw(), i, k, medium.asOutParam()); if (SUCCEEDED(rc) && medium) { BOOL fPassthrough = FALSE; if (mediumAttach) mediumAttach->COMGETTER(Passthrough)(&fPassthrough); medium->COMGETTER(Location)(filePath.asOutParam()); Bstr uuid; medium->COMGETTER(Id)(uuid.asOutParam()); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("\"%ls-%d-%d\"=\"%ls\"\n", storageCtlName.raw(), i, k, filePath.raw()); RTPrintf("\"%ls-ImageUUID-%d-%d\"=\"%s\"\n", storageCtlName.raw(), i, k, Utf8Str(uuid).c_str()); if (fPassthrough) RTPrintf("\"%ls-dvdpassthrough\"=\"%s\"\n", storageCtlName.raw(), fPassthrough ? "on" : "off"); if (devType == DeviceType_DVD) { RTPrintf("\"%ls-tempeject\"=\"%s\"\n", storageCtlName.raw(), fTempEject ? "on" : "off"); RTPrintf("\"%ls-IsEjected\"=\"%s\"\n", storageCtlName.raw(), fIsEjected ? "on" : "off"); } } else { RTPrintf("%ls (%d, %d): %ls (UUID: %s)", storageCtlName.raw(), i, k, filePath.raw(), Utf8Str(uuid).c_str()); if (fPassthrough) RTPrintf(" (passthrough enabled)"); if (fTempEject) RTPrintf(" (temp eject)"); if (fIsEjected) RTPrintf(" (ejected)"); RTPrintf("\n"); } } else if (SUCCEEDED(rc)) { if (details == VMINFO_MACHINEREADABLE) { RTPrintf("\"%ls-%d-%d\"=\"emptydrive\"\n", storageCtlName.raw(), i, k); if (devType == DeviceType_DVD) RTPrintf("\"%ls-IsEjected\"=\"%s\"\n", storageCtlName.raw(), fIsEjected ? "on" : "off"); } else { RTPrintf("%ls (%d, %d): Empty", storageCtlName.raw(), i, k); if (fTempEject) RTPrintf(" (temp eject)"); if (fIsEjected) RTPrintf(" (ejected)"); RTPrintf("\n"); } } else { if (details == VMINFO_MACHINEREADABLE) RTPrintf("\"%ls-%d-%d\"=\"none\"\n", storageCtlName.raw(), i, k); } } } } /* get the maximum amount of NICS */ ULONG maxNICs = getMaxNics(virtualBox, machine); for (ULONG currentNIC = 0; currentNIC < maxNICs; currentNIC++) { ComPtr nic; rc = machine->GetNetworkAdapter(currentNIC, nic.asOutParam()); if (SUCCEEDED(rc) && nic) { BOOL fEnabled; nic->COMGETTER(Enabled)(&fEnabled); if (!fEnabled) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("nic%d=\"none\"\n", currentNIC + 1); else RTPrintf("NIC %d: disabled\n", currentNIC + 1); } else { Bstr strMACAddress; nic->COMGETTER(MACAddress)(strMACAddress.asOutParam()); Utf8Str strAttachment; Utf8Str strNatSettings = ""; Utf8Str strNatForwardings = ""; NetworkAttachmentType_T attachment; nic->COMGETTER(AttachmentType)(&attachment); switch (attachment) { case NetworkAttachmentType_Null: if (details == VMINFO_MACHINEREADABLE) strAttachment = "null"; else strAttachment = "none"; break; case NetworkAttachmentType_NAT: { Bstr strNetwork; ComPtr engine; nic->COMGETTER(NATEngine)(engine.asOutParam()); engine->COMGETTER(Network)(strNetwork.asOutParam()); com::SafeArray forwardings; engine->COMGETTER(Redirects)(ComSafeArrayAsOutParam(forwardings)); strNatForwardings = ""; for (size_t i = 0; i < forwardings.size(); ++i) { bool fSkip = false; uint16_t port = 0; BSTR r = forwardings[i]; Utf8Str utf = Utf8Str(r); Utf8Str strName; Utf8Str strProto; Utf8Str strHostPort; Utf8Str strHostIP; Utf8Str strGuestPort; Utf8Str strGuestIP; size_t pos, ppos; pos = ppos = 0; #define ITERATE_TO_NEXT_TERM(res, str, pos, ppos) \ do { \ pos = str.find(",", ppos); \ if (pos == Utf8Str::npos) \ { \ Log(( #res " extracting from %s is failed\n", str.c_str())); \ fSkip = true; \ } \ res = str.substr(ppos, pos - ppos); \ Log2((#res " %s pos:%d, ppos:%d\n", res.c_str(), pos, ppos)); \ ppos = pos + 1; \ } while (0) ITERATE_TO_NEXT_TERM(strName, utf, pos, ppos); if (fSkip) continue; ITERATE_TO_NEXT_TERM(strProto, utf, pos, ppos); if (fSkip) continue; ITERATE_TO_NEXT_TERM(strHostIP, utf, pos, ppos); if (fSkip) continue; ITERATE_TO_NEXT_TERM(strHostPort, utf, pos, ppos); if (fSkip) continue; ITERATE_TO_NEXT_TERM(strGuestIP, utf, pos, ppos); if (fSkip) continue; strGuestPort = utf.substr(ppos, utf.length() - ppos); #undef ITERATE_TO_NEXT_TERM switch (strProto.toUInt32()) { case NATProtocol_TCP: strProto = "tcp"; break; case NATProtocol_UDP: strProto = "udp"; break; default: strProto = "unk"; break; } if (details == VMINFO_MACHINEREADABLE) { strNatForwardings = Utf8StrFmt("%sForwarding(%d)=\"%s,%s,%s,%s,%s,%s\"\n", strNatForwardings.c_str(), i, strName.c_str(), strProto.c_str(), strHostIP.c_str(), strHostPort.c_str(), strGuestIP.c_str(), strGuestPort.c_str()); } else { strNatForwardings = Utf8StrFmt("%sNIC %d Rule(%d): name = %s, protocol = %s," " host ip = %s, host port = %s, guest ip = %s, guest port = %s\n", strNatForwardings.c_str(), currentNIC + 1, i, strName.c_str(), strProto.c_str(), strHostIP.c_str(), strHostPort.c_str(), strGuestIP.c_str(), strGuestPort.c_str()); } } ULONG mtu = 0; ULONG sockSnd = 0; ULONG sockRcv = 0; ULONG tcpSnd = 0; ULONG tcpRcv = 0; engine->GetNetworkSettings(&mtu, &sockSnd, &sockRcv, &tcpSnd, &tcpRcv); /** @todo r=klaus dnsproxy etc needs to be dumped, too */ if (details == VMINFO_MACHINEREADABLE) { RTPrintf("natnet%d=\"%ls\"\n", currentNIC + 1, strNetwork.length() ? strNetwork.raw(): Bstr("nat").raw()); strAttachment = "nat"; strNatSettings = Utf8StrFmt("mtu=\"%d\"\nsockSnd=\"%d\"\nsockRcv=\"%d\"\ntcpWndSnd=\"%d\"\ntcpWndRcv=\"%d\"\n", mtu, sockSnd ? sockSnd : 64, sockRcv ? sockRcv : 64, tcpSnd ? tcpSnd : 64, tcpRcv ? tcpRcv : 64); } else { strAttachment = "NAT"; strNatSettings = Utf8StrFmt("NIC %d Settings: MTU: %d, Socket (send: %d, receive: %d), TCP Window (send:%d, receive: %d)\n", currentNIC + 1, mtu, sockSnd ? sockSnd : 64, sockRcv ? sockRcv : 64, tcpSnd ? tcpSnd : 64, tcpRcv ? tcpRcv : 64); } break; } case NetworkAttachmentType_Bridged: { Bstr strBridgeAdp; nic->COMGETTER(BridgedInterface)(strBridgeAdp.asOutParam()); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("bridgeadapter%d=\"%ls\"\n", currentNIC + 1, strBridgeAdp.raw()); strAttachment = "bridged"; } else strAttachment = Utf8StrFmt("Bridged Interface '%ls'", strBridgeAdp.raw()); break; } case NetworkAttachmentType_Internal: { Bstr strNetwork; nic->COMGETTER(InternalNetwork)(strNetwork.asOutParam()); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("intnet%d=\"%ls\"\n", currentNIC + 1, strNetwork.raw()); strAttachment = "intnet"; } else strAttachment = Utf8StrFmt("Internal Network '%s'", Utf8Str(strNetwork).c_str()); break; } case NetworkAttachmentType_HostOnly: { Bstr strHostonlyAdp; nic->COMGETTER(HostOnlyInterface)(strHostonlyAdp.asOutParam()); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("hostonlyadapter%d=\"%ls\"\n", currentNIC + 1, strHostonlyAdp.raw()); strAttachment = "hostonly"; } else strAttachment = Utf8StrFmt("Host-only Interface '%ls'", strHostonlyAdp.raw()); break; } case NetworkAttachmentType_Generic: { Bstr strGenericDriver; nic->COMGETTER(GenericDriver)(strGenericDriver.asOutParam()); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("generic%d=\"%ls\"\n", currentNIC + 1, strGenericDriver.raw()); strAttachment = "Generic"; } else { strAttachment = Utf8StrFmt("Generic '%ls'", strGenericDriver.raw()); // show the generic properties com::SafeArray aProperties; com::SafeArray aValues; rc = nic->GetProperties(NULL, ComSafeArrayAsOutParam(aProperties), ComSafeArrayAsOutParam(aValues)); if (SUCCEEDED(rc)) { strAttachment += " { "; for (unsigned i = 0; i < aProperties.size(); ++i) strAttachment += Utf8StrFmt(!i ? "%ls='%ls'" : ", %ls='%ls'", aProperties[i], aValues[i]); strAttachment += " }"; } } break; } case NetworkAttachmentType_NATNetwork: { Bstr strNetwork; nic->COMGETTER(NATNetwork)(strNetwork.asOutParam()); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("nat-network%d=\"%ls\"\n", currentNIC + 1, strNetwork.raw()); strAttachment = "natnetwork"; } else strAttachment = Utf8StrFmt("NAT Network '%s'", Utf8Str(strNetwork).c_str()); break; } default: strAttachment = "unknown"; break; } /* cable connected */ BOOL fConnected; nic->COMGETTER(CableConnected)(&fConnected); /* promisc policy */ NetworkAdapterPromiscModePolicy_T enmPromiscModePolicy; CHECK_ERROR2_RET(nic, COMGETTER(PromiscModePolicy)(&enmPromiscModePolicy), hrcCheck); const char *pszPromiscuousGuestPolicy; switch (enmPromiscModePolicy) { case NetworkAdapterPromiscModePolicy_Deny: pszPromiscuousGuestPolicy = "deny"; break; case NetworkAdapterPromiscModePolicy_AllowNetwork: pszPromiscuousGuestPolicy = "allow-vms"; break; case NetworkAdapterPromiscModePolicy_AllowAll: pszPromiscuousGuestPolicy = "allow-all"; break; default: AssertFailedReturn(E_INVALIDARG); } /* trace stuff */ BOOL fTraceEnabled; nic->COMGETTER(TraceEnabled)(&fTraceEnabled); Bstr traceFile; nic->COMGETTER(TraceFile)(traceFile.asOutParam()); /* NIC type */ NetworkAdapterType_T NICType; nic->COMGETTER(AdapterType)(&NICType); const char *pszNICType; switch (NICType) { case NetworkAdapterType_Am79C970A: pszNICType = "Am79C970A"; break; case NetworkAdapterType_Am79C973: pszNICType = "Am79C973"; break; #ifdef VBOX_WITH_E1000 case NetworkAdapterType_I82540EM: pszNICType = "82540EM"; break; case NetworkAdapterType_I82543GC: pszNICType = "82543GC"; break; case NetworkAdapterType_I82545EM: pszNICType = "82545EM"; break; #endif #ifdef VBOX_WITH_VIRTIO case NetworkAdapterType_Virtio: pszNICType = "virtio"; break; #endif default: AssertFailed(); pszNICType = "unknown"; break; } /* reported line speed */ ULONG ulLineSpeed; nic->COMGETTER(LineSpeed)(&ulLineSpeed); /* boot priority of the adapter */ ULONG ulBootPriority; nic->COMGETTER(BootPriority)(&ulBootPriority); /* bandwidth group */ ComObjPtr pBwGroup; Bstr strBwGroup; nic->COMGETTER(BandwidthGroup)(pBwGroup.asOutParam()); if (!pBwGroup.isNull()) pBwGroup->COMGETTER(Name)(strBwGroup.asOutParam()); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("macaddress%d=\"%ls\"\n", currentNIC + 1, strMACAddress.raw()); RTPrintf("cableconnected%d=\"%s\"\n", currentNIC + 1, fConnected ? "on" : "off"); RTPrintf("nic%d=\"%s\"\n", currentNIC + 1, strAttachment.c_str()); RTPrintf("nictype%d=\"%s\"\n", currentNIC + 1, pszNICType); RTPrintf("nicspeed%d=\"%d\"\n", currentNIC + 1, ulLineSpeed); } else RTPrintf("NIC %u: MAC: %ls, Attachment: %s, Cable connected: %s, Trace: %s (file: %ls), Type: %s, Reported speed: %d Mbps, Boot priority: %d, Promisc Policy: %s, Bandwidth group: %ls\n", currentNIC + 1, strMACAddress.raw(), strAttachment.c_str(), fConnected ? "on" : "off", fTraceEnabled ? "on" : "off", traceFile.isEmpty() ? Bstr("none").raw() : traceFile.raw(), pszNICType, ulLineSpeed / 1000, (int)ulBootPriority, pszPromiscuousGuestPolicy, strBwGroup.isEmpty() ? Bstr("none").raw() : strBwGroup.raw()); if (strNatSettings.length()) RTPrintf(strNatSettings.c_str()); if (strNatForwardings.length()) RTPrintf(strNatForwardings.c_str()); } } } /* Pointing device information */ PointingHIDType_T aPointingHID; const char *pszHID = "Unknown"; const char *pszMrHID = "unknown"; machine->COMGETTER(PointingHIDType)(&aPointingHID); switch (aPointingHID) { case PointingHIDType_None: pszHID = "None"; pszMrHID = "none"; break; case PointingHIDType_PS2Mouse: pszHID = "PS/2 Mouse"; pszMrHID = "ps2mouse"; break; case PointingHIDType_USBMouse: pszHID = "USB Mouse"; pszMrHID = "usbmouse"; break; case PointingHIDType_USBTablet: pszHID = "USB Tablet"; pszMrHID = "usbtablet"; break; case PointingHIDType_ComboMouse: pszHID = "USB Tablet and PS/2 Mouse"; pszMrHID = "combomouse"; break; case PointingHIDType_USBMultiTouch: pszHID = "USB Multi-Touch"; pszMrHID = "usbmultitouch"; break; default: break; } if (details == VMINFO_MACHINEREADABLE) RTPrintf("hidpointing=\"%s\"\n", pszMrHID); else RTPrintf("Pointing Device: %s\n", pszHID); /* Keyboard device information */ KeyboardHIDType_T aKeyboardHID; machine->COMGETTER(KeyboardHIDType)(&aKeyboardHID); pszHID = "Unknown"; pszMrHID = "unknown"; switch (aKeyboardHID) { case KeyboardHIDType_None: pszHID = "None"; pszMrHID = "none"; break; case KeyboardHIDType_PS2Keyboard: pszHID = "PS/2 Keyboard"; pszMrHID = "ps2kbd"; break; case KeyboardHIDType_USBKeyboard: pszHID = "USB Keyboard"; pszMrHID = "usbkbd"; break; case KeyboardHIDType_ComboKeyboard: pszHID = "USB and PS/2 Keyboard"; pszMrHID = "combokbd"; break; default: break; } if (details == VMINFO_MACHINEREADABLE) RTPrintf("hidkeyboard=\"%s\"\n", pszMrHID); else RTPrintf("Keyboard Device: %s\n", pszHID); ComPtr sysProps; virtualBox->COMGETTER(SystemProperties)(sysProps.asOutParam()); /* get the maximum amount of UARTs */ ULONG maxUARTs = 0; sysProps->COMGETTER(SerialPortCount)(&maxUARTs); for (ULONG currentUART = 0; currentUART < maxUARTs; currentUART++) { ComPtr uart; rc = machine->GetSerialPort(currentUART, uart.asOutParam()); if (SUCCEEDED(rc) && uart) { /* show the config of this UART */ BOOL fEnabled; uart->COMGETTER(Enabled)(&fEnabled); if (!fEnabled) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("uart%d=\"off\"\n", currentUART + 1); else RTPrintf("UART %d: disabled\n", currentUART + 1); } else { ULONG ulIRQ, ulIOBase; PortMode_T HostMode; Bstr path; BOOL fServer; uart->COMGETTER(IRQ)(&ulIRQ); uart->COMGETTER(IOBase)(&ulIOBase); uart->COMGETTER(Path)(path.asOutParam()); uart->COMGETTER(Server)(&fServer); uart->COMGETTER(HostMode)(&HostMode); if (details == VMINFO_MACHINEREADABLE) RTPrintf("uart%d=\"%#06x,%d\"\n", currentUART + 1, ulIOBase, ulIRQ); else RTPrintf("UART %d: I/O base: %#06x, IRQ: %d", currentUART + 1, ulIOBase, ulIRQ); switch (HostMode) { default: case PortMode_Disconnected: if (details == VMINFO_MACHINEREADABLE) RTPrintf("uartmode%d=\"disconnected\"\n", currentUART + 1); else RTPrintf(", disconnected\n"); break; case PortMode_RawFile: if (details == VMINFO_MACHINEREADABLE) RTPrintf("uartmode%d=\"%ls\"\n", currentUART + 1, path.raw()); else RTPrintf(", attached to raw file '%ls'\n", path.raw()); break; case PortMode_HostPipe: if (details == VMINFO_MACHINEREADABLE) RTPrintf("uartmode%d=\"%s,%ls\"\n", currentUART + 1, fServer ? "server" : "client", path.raw()); else RTPrintf(", attached to pipe (%s) '%ls'\n", fServer ? "server" : "client", path.raw()); break; case PortMode_HostDevice: if (details == VMINFO_MACHINEREADABLE) RTPrintf("uartmode%d=\"%ls\"\n", currentUART + 1, path.raw()); else RTPrintf(", attached to device '%ls'\n", path.raw()); break; } } } } /* get the maximum amount of LPTs */ ULONG maxLPTs = 0; sysProps->COMGETTER(ParallelPortCount)(&maxLPTs); for (ULONG currentLPT = 0; currentLPT < maxLPTs; currentLPT++) { ComPtr lpt; rc = machine->GetParallelPort(currentLPT, lpt.asOutParam()); if (SUCCEEDED(rc) && lpt) { /* show the config of this LPT */ BOOL fEnabled; lpt->COMGETTER(Enabled)(&fEnabled); if (!fEnabled) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("lpt%d=\"off\"\n", currentLPT + 1); else RTPrintf("LPT %d: disabled\n", currentLPT + 1); } else { ULONG ulIRQ, ulIOBase; Bstr path; lpt->COMGETTER(IRQ)(&ulIRQ); lpt->COMGETTER(IOBase)(&ulIOBase); lpt->COMGETTER(Path)(path.asOutParam()); if (details == VMINFO_MACHINEREADABLE) RTPrintf("lpt%d=\"%#06x,%d\"\n", currentLPT + 1, ulIOBase, ulIRQ); else RTPrintf("LPT %d: I/O base: %#06x, IRQ: %d", currentLPT + 1, ulIOBase, ulIRQ); if (details == VMINFO_MACHINEREADABLE) RTPrintf("lptmode%d=\"%ls\"\n", currentLPT + 1, path.raw()); else RTPrintf(", attached to device '%ls'\n", path.raw()); } } } ComPtr AudioAdapter; rc = machine->COMGETTER(AudioAdapter)(AudioAdapter.asOutParam()); if (SUCCEEDED(rc)) { const char *pszDrv = "Unknown"; const char *pszCtrl = "Unknown"; BOOL fEnabled; rc = AudioAdapter->COMGETTER(Enabled)(&fEnabled); if (SUCCEEDED(rc) && fEnabled) { AudioDriverType_T enmDrvType; rc = AudioAdapter->COMGETTER(AudioDriver)(&enmDrvType); switch (enmDrvType) { case AudioDriverType_Null: if (details == VMINFO_MACHINEREADABLE) pszDrv = "null"; else pszDrv = "Null"; break; case AudioDriverType_WinMM: if (details == VMINFO_MACHINEREADABLE) pszDrv = "winmm"; else pszDrv = "WINMM"; break; case AudioDriverType_DirectSound: if (details == VMINFO_MACHINEREADABLE) pszDrv = "dsound"; else pszDrv = "DSOUND"; break; case AudioDriverType_OSS: if (details == VMINFO_MACHINEREADABLE) pszDrv = "oss"; else pszDrv = "OSS"; break; case AudioDriverType_ALSA: if (details == VMINFO_MACHINEREADABLE) pszDrv = "alsa"; else pszDrv = "ALSA"; break; case AudioDriverType_Pulse: if (details == VMINFO_MACHINEREADABLE) pszDrv = "pulse"; else pszDrv = "PulseAudio"; break; case AudioDriverType_CoreAudio: if (details == VMINFO_MACHINEREADABLE) pszDrv = "coreaudio"; else pszDrv = "CoreAudio"; break; case AudioDriverType_SolAudio: if (details == VMINFO_MACHINEREADABLE) pszDrv = "solaudio"; else pszDrv = "SolAudio"; break; default: if (details == VMINFO_MACHINEREADABLE) pszDrv = "unknown"; break; } AudioControllerType_T enmCtrlType; rc = AudioAdapter->COMGETTER(AudioController)(&enmCtrlType); switch (enmCtrlType) { case AudioControllerType_AC97: if (details == VMINFO_MACHINEREADABLE) pszCtrl = "ac97"; else pszCtrl = "AC97"; break; case AudioControllerType_SB16: if (details == VMINFO_MACHINEREADABLE) pszCtrl = "sb16"; else pszCtrl = "SB16"; break; case AudioControllerType_HDA: if (details == VMINFO_MACHINEREADABLE) pszCtrl = "hda"; else pszCtrl = "HDA"; break; } } else fEnabled = FALSE; if (details == VMINFO_MACHINEREADABLE) { if (fEnabled) RTPrintf("audio=\"%s\"\n", pszDrv); else RTPrintf("audio=\"none\"\n"); } else { RTPrintf("Audio: %s", fEnabled ? "enabled" : "disabled"); if (fEnabled) RTPrintf(" (Driver: %s, Controller: %s)", pszDrv, pszCtrl); RTPrintf("\n"); } } /* Shared clipboard */ { const char *psz = "Unknown"; ClipboardMode_T enmMode; rc = machine->COMGETTER(ClipboardMode)(&enmMode); switch (enmMode) { case ClipboardMode_Disabled: if (details == VMINFO_MACHINEREADABLE) psz = "disabled"; else psz = "disabled"; break; case ClipboardMode_HostToGuest: if (details == VMINFO_MACHINEREADABLE) psz = "hosttoguest"; else psz = "HostToGuest"; break; case ClipboardMode_GuestToHost: if (details == VMINFO_MACHINEREADABLE) psz = "guesttohost"; else psz = "GuestToHost"; break; case ClipboardMode_Bidirectional: if (details == VMINFO_MACHINEREADABLE) psz = "bidirectional"; else psz = "Bidirectional"; break; default: if (details == VMINFO_MACHINEREADABLE) psz = "unknown"; break; } if (details == VMINFO_MACHINEREADABLE) RTPrintf("clipboard=\"%s\"\n", psz); else RTPrintf("Clipboard Mode: %s\n", psz); } /* Drag'n'drop */ { const char *psz = "Unknown"; DnDMode_T enmMode; rc = machine->COMGETTER(DnDMode)(&enmMode); switch (enmMode) { case DnDMode_Disabled: if (details == VMINFO_MACHINEREADABLE) psz = "disabled"; else psz = "disabled"; break; case DnDMode_HostToGuest: if (details == VMINFO_MACHINEREADABLE) psz = "hosttoguest"; else psz = "HostToGuest"; break; case DnDMode_GuestToHost: if (details == VMINFO_MACHINEREADABLE) psz = "guesttohost"; else psz = "GuestToHost"; break; case DnDMode_Bidirectional: if (details == VMINFO_MACHINEREADABLE) psz = "bidirectional"; else psz = "Bidirectional"; break; default: if (details == VMINFO_MACHINEREADABLE) psz = "unknown"; break; } if (details == VMINFO_MACHINEREADABLE) RTPrintf("draganddrop=\"%s\"\n", psz); else RTPrintf("Drag'n'drop Mode: %s\n", psz); } { SessionState_T sessState; rc = machine->COMGETTER(SessionState)(&sessState); if (SUCCEEDED(rc) && sessState != SessionState_Unlocked) { Bstr sessType; rc = machine->COMGETTER(SessionType)(sessType.asOutParam()); if (SUCCEEDED(rc) && !sessType.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("SessionType=\"%ls\"\n", sessType.raw()); else RTPrintf("Session type: %ls\n", sessType.raw()); } } } if (console) { do { ComPtr display; rc = console->COMGETTER(Display)(display.asOutParam()); if (rc == E_ACCESSDENIED || display.isNull()) break; /* VM not powered up */ if (FAILED(rc)) { com::GlueHandleComError(console, "COMGETTER(Display)(display.asOutParam())", rc, __FILE__, __LINE__); return rc; } ULONG xRes, yRes, bpp; LONG xOrigin, yOrigin; rc = display->GetScreenResolution(0, &xRes, &yRes, &bpp, &xOrigin, &yOrigin); if (rc == E_ACCESSDENIED) break; /* VM not powered up */ if (FAILED(rc)) { com::ErrorInfo info(display, COM_IIDOF(IDisplay)); GluePrintErrorInfo(info); return rc; } if (details == VMINFO_MACHINEREADABLE) RTPrintf("VideoMode=\"%d,%d,%d\"@%d,%d\n", xRes, yRes, bpp, xOrigin, yOrigin); else RTPrintf("Video mode: %dx%dx%d at %d,%d\n", xRes, yRes, bpp, xOrigin, yOrigin); } while (0); } /* * Remote Desktop */ ComPtr vrdeServer; rc = machine->COMGETTER(VRDEServer)(vrdeServer.asOutParam()); if (SUCCEEDED(rc) && vrdeServer) { BOOL fEnabled = false; vrdeServer->COMGETTER(Enabled)(&fEnabled); if (fEnabled) { LONG currentPort = -1; Bstr ports; vrdeServer->GetVRDEProperty(Bstr("TCP/Ports").raw(), ports.asOutParam()); Bstr address; vrdeServer->GetVRDEProperty(Bstr("TCP/Address").raw(), address.asOutParam()); BOOL fMultiCon; vrdeServer->COMGETTER(AllowMultiConnection)(&fMultiCon); BOOL fReuseCon; vrdeServer->COMGETTER(ReuseSingleConnection)(&fReuseCon); Bstr videoChannel; vrdeServer->GetVRDEProperty(Bstr("VideoChannel/Enabled").raw(), videoChannel.asOutParam()); BOOL fVideoChannel = (videoChannel.compare(Bstr("true"), Bstr::CaseInsensitive)== 0) || (videoChannel == "1"); Bstr videoChannelQuality; vrdeServer->GetVRDEProperty(Bstr("VideoChannel/Quality").raw(), videoChannelQuality.asOutParam()); AuthType_T authType; const char *strAuthType; vrdeServer->COMGETTER(AuthType)(&authType); switch (authType) { case AuthType_Null: strAuthType = "null"; break; case AuthType_External: strAuthType = "external"; break; case AuthType_Guest: strAuthType = "guest"; break; default: strAuthType = "unknown"; break; } if (console) { ComPtr vrdeServerInfo; CHECK_ERROR_RET(console, COMGETTER(VRDEServerInfo)(vrdeServerInfo.asOutParam()), rc); if (!vrdeServerInfo.isNull()) { rc = vrdeServerInfo->COMGETTER(Port)(¤tPort); if (rc == E_ACCESSDENIED) { currentPort = -1; /* VM not powered up */ } else if (FAILED(rc)) { com::ErrorInfo info(vrdeServerInfo, COM_IIDOF(IVRDEServerInfo)); GluePrintErrorInfo(info); return rc; } } } if (details == VMINFO_MACHINEREADABLE) { RTPrintf("vrde=\"on\"\n"); RTPrintf("vrdeport=%d\n", currentPort); RTPrintf("vrdeports=\"%ls\"\n", ports.raw()); RTPrintf("vrdeaddress=\"%ls\"\n", address.raw()); RTPrintf("vrdeauthtype=\"%s\"\n", strAuthType); RTPrintf("vrdemulticon=\"%s\"\n", fMultiCon ? "on" : "off"); RTPrintf("vrdereusecon=\"%s\"\n", fReuseCon ? "on" : "off"); RTPrintf("vrdevideochannel=\"%s\"\n", fVideoChannel ? "on" : "off"); if (fVideoChannel) RTPrintf("vrdevideochannelquality=\"%ls\"\n", videoChannelQuality.raw()); } else { if (address.isEmpty()) address = "0.0.0.0"; RTPrintf("VRDE: enabled (Address %ls, Ports %ls, MultiConn: %s, ReuseSingleConn: %s, Authentication type: %s)\n", address.raw(), ports.raw(), fMultiCon ? "on" : "off", fReuseCon ? "on" : "off", strAuthType); if (console && currentPort != -1 && currentPort != 0) RTPrintf("VRDE port: %d\n", currentPort); if (fVideoChannel) RTPrintf("Video redirection: enabled (Quality %ls)\n", videoChannelQuality.raw()); else RTPrintf("Video redirection: disabled\n"); } com::SafeArray aProperties; if (SUCCEEDED(vrdeServer->COMGETTER(VRDEProperties)(ComSafeArrayAsOutParam(aProperties)))) { unsigned i; for (i = 0; i < aProperties.size(); ++i) { Bstr value; vrdeServer->GetVRDEProperty(aProperties[i], value.asOutParam()); if (details == VMINFO_MACHINEREADABLE) { if (value.isEmpty()) RTPrintf("vrdeproperty[%ls]=\n", aProperties[i]); else RTPrintf("vrdeproperty[%ls]=\"%ls\"\n", aProperties[i], value.raw()); } else { if (value.isEmpty()) RTPrintf("VRDE property: %-10lS = \n", aProperties[i]); else RTPrintf("VRDE property: %-10lS = \"%ls\"\n", aProperties[i], value.raw()); } } } } else { if (details == VMINFO_MACHINEREADABLE) RTPrintf("vrde=\"off\"\n"); else RTPrintf("VRDE: disabled\n"); } } /* * USB. */ SafeIfaceArray USBCtlColl; rc = machine->COMGETTER(USBControllers)(ComSafeArrayAsOutParam(USBCtlColl)); if (SUCCEEDED(rc)) { bool fOhciEnabled = false; bool fEhciEnabled = false; bool fXhciEnabled = false; for (unsigned i = 0; i < USBCtlColl.size(); i++) { USBControllerType_T enmType; rc = USBCtlColl[i]->COMGETTER(Type)(&enmType); if (SUCCEEDED(rc)) { switch (enmType) { case USBControllerType_OHCI: fOhciEnabled = true; break; case USBControllerType_EHCI: fEhciEnabled = true; break; case USBControllerType_XHCI: fXhciEnabled = true; break; default: break; } } } if (details == VMINFO_MACHINEREADABLE) RTPrintf("usb=\"%s\"\n", fOhciEnabled ? "on" : "off"); else RTPrintf("USB: %s\n", fOhciEnabled ? "enabled" : "disabled"); if (details == VMINFO_MACHINEREADABLE) RTPrintf("ehci=\"%s\"\n", fEhciEnabled ? "on" : "off"); else RTPrintf("EHCI: %s\n", fEhciEnabled ? "enabled" : "disabled"); if (details == VMINFO_MACHINEREADABLE) RTPrintf("xhci=\"%s\"\n", fXhciEnabled ? "on" : "off"); else RTPrintf("XHCI: %s\n", fXhciEnabled ? "enabled" : "disabled"); } ComPtr USBFlts; rc = machine->COMGETTER(USBDeviceFilters)(USBFlts.asOutParam()); if (SUCCEEDED(rc)) { SafeIfaceArray Coll; rc = USBFlts->COMGETTER(DeviceFilters)(ComSafeArrayAsOutParam(Coll)); if (SUCCEEDED(rc)) { if (details != VMINFO_MACHINEREADABLE) RTPrintf("\nUSB Device Filters:\n\n"); if (Coll.size() == 0) { if (details != VMINFO_MACHINEREADABLE) RTPrintf("\n\n"); } else { for (size_t index = 0; index < Coll.size(); ++index) { ComPtr DevPtr = Coll[index]; /* Query info. */ if (details != VMINFO_MACHINEREADABLE) RTPrintf("Index: %zu\n", index); BOOL bActive = FALSE; CHECK_ERROR_RET(DevPtr, COMGETTER(Active)(&bActive), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBFilterActive%zu=\"%s\"\n", index + 1, bActive ? "on" : "off"); else RTPrintf("Active: %s\n", bActive ? "yes" : "no"); Bstr bstr; CHECK_ERROR_RET(DevPtr, COMGETTER(Name)(bstr.asOutParam()), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBFilterName%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Name: %ls\n", bstr.raw()); CHECK_ERROR_RET(DevPtr, COMGETTER(VendorId)(bstr.asOutParam()), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBFilterVendorId%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("VendorId: %ls\n", bstr.raw()); CHECK_ERROR_RET(DevPtr, COMGETTER(ProductId)(bstr.asOutParam()), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBFilterProductId%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("ProductId: %ls\n", bstr.raw()); CHECK_ERROR_RET(DevPtr, COMGETTER(Revision)(bstr.asOutParam()), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBFilterRevision%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Revision: %ls\n", bstr.raw()); CHECK_ERROR_RET(DevPtr, COMGETTER(Manufacturer)(bstr.asOutParam()), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBFilterManufacturer%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Manufacturer: %ls\n", bstr.raw()); CHECK_ERROR_RET(DevPtr, COMGETTER(Product)(bstr.asOutParam()), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBFilterProduct%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Product: %ls\n", bstr.raw()); CHECK_ERROR_RET(DevPtr, COMGETTER(Remote)(bstr.asOutParam()), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBFilterRemote%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Remote: %ls\n", bstr.raw()); CHECK_ERROR_RET(DevPtr, COMGETTER(SerialNumber)(bstr.asOutParam()), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBFilterSerialNumber%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Serial Number: %ls\n", bstr.raw()); if (details != VMINFO_MACHINEREADABLE) { ULONG fMaskedIfs; CHECK_ERROR_RET(DevPtr, COMGETTER(MaskedInterfaces)(&fMaskedIfs), rc); if (fMaskedIfs) RTPrintf("Masked Interfaces: %#010x\n", fMaskedIfs); RTPrintf("\n"); } } } } if (console) { /* scope */ { if (details != VMINFO_MACHINEREADABLE) RTPrintf("Available remote USB devices:\n\n"); SafeIfaceArray coll; CHECK_ERROR_RET(console, COMGETTER(RemoteUSBDevices)(ComSafeArrayAsOutParam(coll)), rc); if (coll.size() == 0) { if (details != VMINFO_MACHINEREADABLE) RTPrintf("\n\n"); } else { for (size_t index = 0; index < coll.size(); ++index) { ComPtr dev = coll[index]; /* Query info. */ Bstr id; CHECK_ERROR_RET(dev, COMGETTER(Id)(id.asOutParam()), rc); USHORT usVendorId; CHECK_ERROR_RET(dev, COMGETTER(VendorId)(&usVendorId), rc); USHORT usProductId; CHECK_ERROR_RET(dev, COMGETTER(ProductId)(&usProductId), rc); USHORT bcdRevision; CHECK_ERROR_RET(dev, COMGETTER(Revision)(&bcdRevision), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBRemoteUUID%zu=\"%s\"\n" "USBRemoteVendorId%zu=\"%#06x\"\n" "USBRemoteProductId%zu=\"%#06x\"\n" "USBRemoteRevision%zu=\"%#04x%02x\"\n", index + 1, Utf8Str(id).c_str(), index + 1, usVendorId, index + 1, usProductId, index + 1, bcdRevision >> 8, bcdRevision & 0xff); else RTPrintf("UUID: %s\n" "VendorId: %#06x (%04X)\n" "ProductId: %#06x (%04X)\n" "Revision: %u.%u (%02u%02u)\n", Utf8Str(id).c_str(), usVendorId, usVendorId, usProductId, usProductId, bcdRevision >> 8, bcdRevision & 0xff, bcdRevision >> 8, bcdRevision & 0xff); /* optional stuff. */ Bstr bstr; CHECK_ERROR_RET(dev, COMGETTER(Manufacturer)(bstr.asOutParam()), rc); if (!bstr.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBRemoteManufacturer%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Manufacturer: %ls\n", bstr.raw()); } CHECK_ERROR_RET(dev, COMGETTER(Product)(bstr.asOutParam()), rc); if (!bstr.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBRemoteProduct%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Product: %ls\n", bstr.raw()); } CHECK_ERROR_RET(dev, COMGETTER(SerialNumber)(bstr.asOutParam()), rc); if (!bstr.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBRemoteSerialNumber%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("SerialNumber: %ls\n", bstr.raw()); } CHECK_ERROR_RET(dev, COMGETTER(Address)(bstr.asOutParam()), rc); if (!bstr.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBRemoteAddress%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Address: %ls\n", bstr.raw()); } if (details != VMINFO_MACHINEREADABLE) RTPrintf("\n"); } } } /* scope */ { if (details != VMINFO_MACHINEREADABLE) RTPrintf("Currently Attached USB Devices:\n\n"); SafeIfaceArray coll; CHECK_ERROR_RET(console, COMGETTER(USBDevices)(ComSafeArrayAsOutParam(coll)), rc); if (coll.size() == 0) { if (details != VMINFO_MACHINEREADABLE) RTPrintf("\n\n"); } else { for (size_t index = 0; index < coll.size(); ++index) { ComPtr dev = coll[index]; /* Query info. */ Bstr id; CHECK_ERROR_RET(dev, COMGETTER(Id)(id.asOutParam()), rc); USHORT usVendorId; CHECK_ERROR_RET(dev, COMGETTER(VendorId)(&usVendorId), rc); USHORT usProductId; CHECK_ERROR_RET(dev, COMGETTER(ProductId)(&usProductId), rc); USHORT bcdRevision; CHECK_ERROR_RET(dev, COMGETTER(Revision)(&bcdRevision), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBAttachedUUID%zu=\"%s\"\n" "USBAttachedVendorId%zu=\"%#06x\"\n" "USBAttachedProductId%zu=\"%#06x\"\n" "USBAttachedRevision%zu=\"%#04x%02x\"\n", index + 1, Utf8Str(id).c_str(), index + 1, usVendorId, index + 1, usProductId, index + 1, bcdRevision >> 8, bcdRevision & 0xff); else RTPrintf("UUID: %s\n" "VendorId: %#06x (%04X)\n" "ProductId: %#06x (%04X)\n" "Revision: %u.%u (%02u%02u)\n", Utf8Str(id).c_str(), usVendorId, usVendorId, usProductId, usProductId, bcdRevision >> 8, bcdRevision & 0xff, bcdRevision >> 8, bcdRevision & 0xff); /* optional stuff. */ Bstr bstr; CHECK_ERROR_RET(dev, COMGETTER(Manufacturer)(bstr.asOutParam()), rc); if (!bstr.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBAttachedManufacturer%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Manufacturer: %ls\n", bstr.raw()); } CHECK_ERROR_RET(dev, COMGETTER(Product)(bstr.asOutParam()), rc); if (!bstr.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBAttachedProduct%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Product: %ls\n", bstr.raw()); } CHECK_ERROR_RET(dev, COMGETTER(SerialNumber)(bstr.asOutParam()), rc); if (!bstr.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBAttachedSerialNumber%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("SerialNumber: %ls\n", bstr.raw()); } CHECK_ERROR_RET(dev, COMGETTER(Address)(bstr.asOutParam()), rc); if (!bstr.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("USBAttachedAddress%zu=\"%ls\"\n", index + 1, bstr.raw()); else RTPrintf("Address: %ls\n", bstr.raw()); } if (details != VMINFO_MACHINEREADABLE) RTPrintf("\n"); } } } } } /* USB */ #ifdef VBOX_WITH_PCI_PASSTHROUGH /* Host PCI passthrough devices */ { SafeIfaceArray assignments; rc = machine->COMGETTER(PCIDeviceAssignments)(ComSafeArrayAsOutParam(assignments)); if (SUCCEEDED(rc)) { if (assignments.size() > 0 && (details != VMINFO_MACHINEREADABLE)) { RTPrintf("\nAttached physical PCI devices:\n\n"); } for (size_t index = 0; index < assignments.size(); ++index) { ComPtr Assignment = assignments[index]; char szHostPCIAddress[32], szGuestPCIAddress[32]; LONG iHostPCIAddress = -1, iGuestPCIAddress = -1; Bstr DevName; Assignment->COMGETTER(Name)(DevName.asOutParam()); Assignment->COMGETTER(HostAddress)(&iHostPCIAddress); Assignment->COMGETTER(GuestAddress)(&iGuestPCIAddress); PCIBusAddress().fromLong(iHostPCIAddress).format(szHostPCIAddress, sizeof(szHostPCIAddress)); PCIBusAddress().fromLong(iGuestPCIAddress).format(szGuestPCIAddress, sizeof(szGuestPCIAddress)); if (details == VMINFO_MACHINEREADABLE) RTPrintf("AttachedHostPCI=%s,%s\n", szHostPCIAddress, szGuestPCIAddress); else RTPrintf(" Host device %ls at %s attached as %s\n", DevName.raw(), szHostPCIAddress, szGuestPCIAddress); } if (assignments.size() > 0 && (details != VMINFO_MACHINEREADABLE)) { RTPrintf("\n"); } } } /* Host PCI passthrough devices */ #endif /* * Bandwidth groups */ if (details != VMINFO_MACHINEREADABLE) RTPrintf("Bandwidth groups: "); { ComPtr bwCtrl; CHECK_ERROR_RET(machine, COMGETTER(BandwidthControl)(bwCtrl.asOutParam()), rc); rc = showBandwidthGroups(bwCtrl, details); } /* * Shared folders */ if (details != VMINFO_MACHINEREADABLE) RTPrintf("Shared folders: "); uint32_t numSharedFolders = 0; #if 0 // not yet implemented /* globally shared folders first */ { SafeIfaceArray sfColl; CHECK_ERROR_RET(virtualBox, COMGETTER(SharedFolders)(ComSafeArrayAsOutParam(sfColl)), rc); for (size_t i = 0; i < sfColl.size(); ++i) { ComPtr sf = sfColl[i]; Bstr name, hostPath; sf->COMGETTER(Name)(name.asOutParam()); sf->COMGETTER(HostPath)(hostPath.asOutParam()); RTPrintf("Name: '%ls', Host path: '%ls' (global mapping)\n", name.raw(), hostPath.raw()); ++numSharedFolders; } } #endif /* now VM mappings */ { com::SafeIfaceArray folders; CHECK_ERROR_RET(machine, COMGETTER(SharedFolders)(ComSafeArrayAsOutParam(folders)), rc); for (size_t i = 0; i < folders.size(); ++i) { ComPtr sf = folders[i]; Bstr name, hostPath; BOOL writable; sf->COMGETTER(Name)(name.asOutParam()); sf->COMGETTER(HostPath)(hostPath.asOutParam()); sf->COMGETTER(Writable)(&writable); if (!numSharedFolders && details != VMINFO_MACHINEREADABLE) RTPrintf("\n\n"); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("SharedFolderNameMachineMapping%zu=\"%ls\"\n", i + 1, name.raw()); RTPrintf("SharedFolderPathMachineMapping%zu=\"%ls\"\n", i + 1, hostPath.raw()); } else RTPrintf("Name: '%ls', Host path: '%ls' (machine mapping), %s\n", name.raw(), hostPath.raw(), writable ? "writable" : "readonly"); ++numSharedFolders; } } /* transient mappings */ if (console) { com::SafeIfaceArray folders; CHECK_ERROR_RET(console, COMGETTER(SharedFolders)(ComSafeArrayAsOutParam(folders)), rc); for (size_t i = 0; i < folders.size(); ++i) { ComPtr sf = folders[i]; Bstr name, hostPath; sf->COMGETTER(Name)(name.asOutParam()); sf->COMGETTER(HostPath)(hostPath.asOutParam()); if (!numSharedFolders && details != VMINFO_MACHINEREADABLE) RTPrintf("\n\n"); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("SharedFolderNameTransientMapping%zu=\"%ls\"\n", i + 1, name.raw()); RTPrintf("SharedFolderPathTransientMapping%zu=\"%ls\"\n", i + 1, hostPath.raw()); } else RTPrintf("Name: '%ls', Host path: '%ls' (transient mapping)\n", name.raw(), hostPath.raw()); ++numSharedFolders; } } if (!numSharedFolders && details != VMINFO_MACHINEREADABLE) RTPrintf("\n"); if (details != VMINFO_MACHINEREADABLE) RTPrintf("\n"); if (console) { /* * Live VRDE info. */ ComPtr vrdeServerInfo; CHECK_ERROR_RET(console, COMGETTER(VRDEServerInfo)(vrdeServerInfo.asOutParam()), rc); BOOL Active = FALSE; ULONG NumberOfClients = 0; LONG64 BeginTime = 0; LONG64 EndTime = 0; LONG64 BytesSent = 0; LONG64 BytesSentTotal = 0; LONG64 BytesReceived = 0; LONG64 BytesReceivedTotal = 0; Bstr User; Bstr Domain; Bstr ClientName; Bstr ClientIP; ULONG ClientVersion = 0; ULONG EncryptionStyle = 0; if (!vrdeServerInfo.isNull()) { CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(Active)(&Active), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(NumberOfClients)(&NumberOfClients), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(BeginTime)(&BeginTime), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(EndTime)(&EndTime), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(BytesSent)(&BytesSent), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(BytesSentTotal)(&BytesSentTotal), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(BytesReceived)(&BytesReceived), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(BytesReceivedTotal)(&BytesReceivedTotal), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(User)(User.asOutParam()), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(Domain)(Domain.asOutParam()), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(ClientName)(ClientName.asOutParam()), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(ClientIP)(ClientIP.asOutParam()), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(ClientVersion)(&ClientVersion), rc); CHECK_ERROR_RET(vrdeServerInfo, COMGETTER(EncryptionStyle)(&EncryptionStyle), rc); } if (details == VMINFO_MACHINEREADABLE) RTPrintf("VRDEActiveConnection=\"%s\"\n", Active ? "on": "off"); else RTPrintf("VRDE Connection: %s\n", Active? "active": "not active"); if (details == VMINFO_MACHINEREADABLE) RTPrintf("VRDEClients=%d\n", NumberOfClients); else RTPrintf("Clients so far: %d\n", NumberOfClients); if (NumberOfClients > 0) { char timestr[128]; if (Active) { makeTimeStr(timestr, sizeof(timestr), BeginTime); if (details == VMINFO_MACHINEREADABLE) RTPrintf("VRDEStartTime=\"%s\"\n", timestr); else RTPrintf("Start time: %s\n", timestr); } else { makeTimeStr(timestr, sizeof(timestr), BeginTime); if (details == VMINFO_MACHINEREADABLE) RTPrintf("VRDELastStartTime=\"%s\"\n", timestr); else RTPrintf("Last started: %s\n", timestr); makeTimeStr(timestr, sizeof(timestr), EndTime); if (details == VMINFO_MACHINEREADABLE) RTPrintf("VRDELastEndTime=\"%s\"\n", timestr); else RTPrintf("Last ended: %s\n", timestr); } int64_t ThroughputSend = 0; int64_t ThroughputReceive = 0; if (EndTime != BeginTime) { ThroughputSend = (BytesSent * 1000) / (EndTime - BeginTime); ThroughputReceive = (BytesReceived * 1000) / (EndTime - BeginTime); } if (details == VMINFO_MACHINEREADABLE) { RTPrintf("VRDEBytesSent=%lld\n", BytesSent); RTPrintf("VRDEThroughputSend=%lld\n", ThroughputSend); RTPrintf("VRDEBytesSentTotal=%lld\n", BytesSentTotal); RTPrintf("VRDEBytesReceived=%lld\n", BytesReceived); RTPrintf("VRDEThroughputReceive=%lld\n", ThroughputReceive); RTPrintf("VRDEBytesReceivedTotal=%lld\n", BytesReceivedTotal); } else { RTPrintf("Sent: %lld Bytes\n", BytesSent); RTPrintf("Average speed: %lld B/s\n", ThroughputSend); RTPrintf("Sent total: %lld Bytes\n", BytesSentTotal); RTPrintf("Received: %lld Bytes\n", BytesReceived); RTPrintf("Speed: %lld B/s\n", ThroughputReceive); RTPrintf("Received total: %lld Bytes\n", BytesReceivedTotal); } if (Active) { if (details == VMINFO_MACHINEREADABLE) { RTPrintf("VRDEUserName=\"%ls\"\n", User.raw()); RTPrintf("VRDEDomain=\"%ls\"\n", Domain.raw()); RTPrintf("VRDEClientName=\"%ls\"\n", ClientName.raw()); RTPrintf("VRDEClientIP=\"%ls\"\n", ClientIP.raw()); RTPrintf("VRDEClientVersion=%d\n", ClientVersion); RTPrintf("VRDEEncryption=\"%s\"\n", EncryptionStyle == 0? "RDP4": "RDP5 (X.509)"); } else { RTPrintf("User name: %ls\n", User.raw()); RTPrintf("Domain: %ls\n", Domain.raw()); RTPrintf("Client name: %ls\n", ClientName.raw()); RTPrintf("Client IP: %ls\n", ClientIP.raw()); RTPrintf("Client version: %d\n", ClientVersion); RTPrintf("Encryption: %s\n", EncryptionStyle == 0? "RDP4": "RDP5 (X.509)"); } } } if (details != VMINFO_MACHINEREADABLE) RTPrintf("\n"); } { /* Video capture */ BOOL bActive = FALSE; CHECK_ERROR_RET(machine, COMGETTER(VideoCaptureEnabled)(&bActive), rc); com::SafeArray screens; CHECK_ERROR_RET(machine, COMGETTER(VideoCaptureScreens)(ComSafeArrayAsOutParam(screens)), rc); ULONG Width; CHECK_ERROR_RET(machine, COMGETTER(VideoCaptureWidth)(&Width), rc); ULONG Height; CHECK_ERROR_RET(machine, COMGETTER(VideoCaptureHeight)(&Height), rc); ULONG Rate; CHECK_ERROR_RET(machine, COMGETTER(VideoCaptureRate)(&Rate), rc); ULONG Fps; CHECK_ERROR_RET(machine, COMGETTER(VideoCaptureFPS)(&Fps), rc); Bstr File; CHECK_ERROR_RET(machine, COMGETTER(VideoCaptureFile)(File.asOutParam()), rc); if (details == VMINFO_MACHINEREADABLE) { RTPrintf("vcpenabled=\"%s\"\n", bActive ? "on" : "off"); RTPrintf("vcpscreens="); bool fComma = false; for (unsigned i = 0; i < screens.size(); i++) if (screens[i]) { RTPrintf("%s%u", fComma ? "," : "", i); fComma = true; } RTPrintf("\n"); RTPrintf("vcpfile=\"%ls\"\n", File.raw()); RTPrintf("vcpwidth=%u\n", (unsigned)Width); RTPrintf("vcpheight=%u\n", (unsigned)Height); RTPrintf("vcprate=%u\n", (unsigned)Rate); RTPrintf("vcpfps=%u\n", (unsigned)Fps); } else { RTPrintf("Video capturing: %s\n", bActive ? "active" : "not active"); RTPrintf("Capture screens: "); bool fComma = false; for (unsigned i = 0; i < screens.size(); i++) if (screens[i]) { RTPrintf("%s%u", fComma ? "," : "", i); fComma = true; } RTPrintf("\n"); RTPrintf("Capture file: %ls\n", File.raw()); RTPrintf("Capture dimensions: %ux%u\n", Width, Height); RTPrintf("Capture rate: %u kbps\n", Rate); RTPrintf("Capture FPS: %u\n", Fps); RTPrintf("\n"); } } if ( details == VMINFO_STANDARD || details == VMINFO_FULL || details == VMINFO_MACHINEREADABLE) { Bstr description; machine->COMGETTER(Description)(description.asOutParam()); if (!description.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("description=\"%ls\"\n", description.raw()); else RTPrintf("Description:\n%ls\n", description.raw()); } } if (details != VMINFO_MACHINEREADABLE) RTPrintf("Guest:\n\n"); ULONG guestVal; rc = machine->COMGETTER(MemoryBalloonSize)(&guestVal); if (SUCCEEDED(rc)) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("GuestMemoryBalloon=%d\n", guestVal); else RTPrintf("Configured memory balloon size: %d MB\n", guestVal); } if (console) { ComPtr guest; rc = console->COMGETTER(Guest)(guest.asOutParam()); if (SUCCEEDED(rc) && !guest.isNull()) { Bstr guestString; rc = guest->COMGETTER(OSTypeId)(guestString.asOutParam()); if ( SUCCEEDED(rc) && !guestString.isEmpty()) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("GuestOSType=\"%ls\"\n", guestString.raw()); else RTPrintf("OS type: %ls\n", guestString.raw()); } AdditionsRunLevelType_T guestRunLevel; /** @todo Add a runlevel-to-string (e.g. 0 = "None") method? */ rc = guest->COMGETTER(AdditionsRunLevel)(&guestRunLevel); if (SUCCEEDED(rc)) { if (details == VMINFO_MACHINEREADABLE) RTPrintf("GuestAdditionsRunLevel=%u\n", guestRunLevel); else RTPrintf("Additions run level: %u\n", guestRunLevel); } rc = guest->COMGETTER(AdditionsVersion)(guestString.asOutParam()); if ( SUCCEEDED(rc) && !guestString.isEmpty()) { ULONG uRevision; rc = guest->COMGETTER(AdditionsRevision)(&uRevision); if (FAILED(rc)) uRevision = 0; if (details == VMINFO_MACHINEREADABLE) RTPrintf("GuestAdditionsVersion=\"%ls r%u\"\n", guestString.raw(), uRevision); else RTPrintf("Additions version: %ls r%u\n\n", guestString.raw(), uRevision); } if (details != VMINFO_MACHINEREADABLE) RTPrintf("\nGuest Facilities:\n\n"); /* Print information about known Guest Additions facilities: */ SafeIfaceArray collFac; CHECK_ERROR_RET(guest, COMGETTER(Facilities)(ComSafeArrayAsOutParam(collFac)), rc); LONG64 lLastUpdatedMS; char szLastUpdated[32]; AdditionsFacilityStatus_T curStatus; for (size_t index = 0; index < collFac.size(); ++index) { ComPtr fac = collFac[index]; if (fac) { CHECK_ERROR_RET(fac, COMGETTER(Name)(guestString.asOutParam()), rc); if (!guestString.isEmpty()) { CHECK_ERROR_RET(fac, COMGETTER(Status)(&curStatus), rc); CHECK_ERROR_RET(fac, COMGETTER(LastUpdated)(&lLastUpdatedMS), rc); if (details == VMINFO_MACHINEREADABLE) RTPrintf("GuestAdditionsFacility_%ls=%u,%lld\n", guestString.raw(), curStatus, lLastUpdatedMS); else { makeTimeStr(szLastUpdated, sizeof(szLastUpdated), lLastUpdatedMS); RTPrintf("Facility \"%ls\": %s (last update: %s)\n", guestString.raw(), facilityStateToName(curStatus, false /* No short naming */), szLastUpdated); } } else AssertMsgFailed(("Facility with undefined name retrieved!\n")); } else AssertMsgFailed(("Invalid facility returned!\n")); } if (!collFac.size() && details != VMINFO_MACHINEREADABLE) RTPrintf("No active facilities.\n"); } } if (details != VMINFO_MACHINEREADABLE) RTPrintf("\n"); /* * snapshots */ ComPtr snapshot; rc = machine->FindSnapshot(Bstr().raw(), snapshot.asOutParam()); if (SUCCEEDED(rc) && snapshot) { ComPtr currentSnapshot; rc = machine->COMGETTER(CurrentSnapshot)(currentSnapshot.asOutParam()); if (SUCCEEDED(rc)) { if (details != VMINFO_MACHINEREADABLE) RTPrintf("Snapshots:\n\n"); showSnapshots(snapshot, currentSnapshot, details); } } if (details != VMINFO_MACHINEREADABLE) RTPrintf("\n"); return S_OK; } #if defined(_MSC_VER) # pragma optimize("", on) #endif static const RTGETOPTDEF g_aShowVMInfoOptions[] = { { "--details", 'D', RTGETOPT_REQ_NOTHING }, { "-details", 'D', RTGETOPT_REQ_NOTHING }, // deprecated { "--machinereadable", 'M', RTGETOPT_REQ_NOTHING }, { "-machinereadable", 'M', RTGETOPT_REQ_NOTHING }, // deprecated { "--log", 'l', RTGETOPT_REQ_UINT32 }, }; int handleShowVMInfo(HandlerArg *a) { HRESULT rc; const char *VMNameOrUuid = NULL; bool fLog = false; uint32_t uLogIdx = 0; bool fDetails = false; bool fMachinereadable = false; int c; RTGETOPTUNION ValueUnion; RTGETOPTSTATE GetState; // start at 0 because main() has hacked both the argc and argv given to us RTGetOptInit(&GetState, a->argc, a->argv, g_aShowVMInfoOptions, RT_ELEMENTS(g_aShowVMInfoOptions), 0, RTGETOPTINIT_FLAGS_NO_STD_OPTS); while ((c = RTGetOpt(&GetState, &ValueUnion))) { switch (c) { case 'D': // --details fDetails = true; break; case 'M': // --machinereadable fMachinereadable = true; break; case 'l': // --log fLog = true; uLogIdx = ValueUnion.u32; break; case VINF_GETOPT_NOT_OPTION: if (!VMNameOrUuid) VMNameOrUuid = ValueUnion.psz; else return errorSyntax(USAGE_SHOWVMINFO, "Invalid parameter '%s'", ValueUnion.psz); break; default: if (c > 0) { if (RT_C_IS_PRINT(c)) return errorSyntax(USAGE_SHOWVMINFO, "Invalid option -%c", c); else return errorSyntax(USAGE_SHOWVMINFO, "Invalid option case %i", c); } else if (c == VERR_GETOPT_UNKNOWN_OPTION) return errorSyntax(USAGE_SHOWVMINFO, "unknown option: %s\n", ValueUnion.psz); else if (ValueUnion.pDef) return errorSyntax(USAGE_SHOWVMINFO, "%s: %Rrs", ValueUnion.pDef->pszLong, c); else return errorSyntax(USAGE_SHOWVMINFO, "error: %Rrs", c); } } /* check for required options */ if (!VMNameOrUuid) return errorSyntax(USAGE_SHOWVMINFO, "VM name or UUID required"); /* try to find the given machine */ ComPtr machine; CHECK_ERROR(a->virtualBox, FindMachine(Bstr(VMNameOrUuid).raw(), machine.asOutParam())); if (FAILED(rc)) return 1; /* Printing the log is exclusive. */ if (fLog && (fMachinereadable || fDetails)) return errorSyntax(USAGE_SHOWVMINFO, "Option --log is exclusive"); if (fLog) { ULONG64 uOffset = 0; SafeArray aLogData; ULONG cbLogData; while (true) { /* Reset the array */ aLogData.setNull(); /* Fetch a chunk of the log file */ CHECK_ERROR_BREAK(machine, ReadLog(uLogIdx, uOffset, _1M, ComSafeArrayAsOutParam(aLogData))); cbLogData = aLogData.size(); if (cbLogData == 0) break; /* aLogData has a platform dependent line ending, standardize on * Unix style, as RTStrmWrite does the LF -> CR/LF replacement on * Windows. Otherwise we end up with CR/CR/LF on Windows. */ ULONG cbLogDataPrint = cbLogData; for (BYTE *s = aLogData.raw(), *d = s; s - aLogData.raw() < (ssize_t)cbLogData; s++, d++) { if (*s == '\r') { /* skip over CR, adjust destination */ d--; cbLogDataPrint--; } else if (s != d) *d = *s; } RTStrmWrite(g_pStdOut, aLogData.raw(), cbLogDataPrint); uOffset += cbLogData; } } else { /* 2nd option can be -details or -argdump */ VMINFO_DETAILS details = VMINFO_NONE; if (fMachinereadable) details = VMINFO_MACHINEREADABLE; else if (fDetails) details = VMINFO_FULL; else details = VMINFO_STANDARD; ComPtr console; /* open an existing session for the VM */ rc = machine->LockMachine(a->session, LockType_Shared); if (SUCCEEDED(rc)) /* get the session machine */ rc = a->session->COMGETTER(Machine)(machine.asOutParam()); if (SUCCEEDED(rc)) /* get the session console */ rc = a->session->COMGETTER(Console)(console.asOutParam()); rc = showVMInfo(a->virtualBox, machine, details, console); if (console) a->session->UnlockMachine(); } return SUCCEEDED(rc) ? 0 : 1; } #endif /* !VBOX_ONLY_DOCS */ /* vi: set tabstop=4 shiftwidth=4 expandtab: */