Utf8Str& Utf8Str::stripFilename()
{
if (length())
{
RTPathStripFilename(m_psz);
jolt();
}
return *this;
}
/**
* @interface_method_impl{VBOXEXTPACKREG,pfnVMConfigureVMM
*/
static DECLCALLBACK(int) vboxBusMouseExtPack_VMConfigureVMM(PCVBOXEXTPACKREG pThis, IConsole *pConsole, PVM pVM)
{
/*
* Find the bus mouse module and tell PDM to load it.
* ASSUME /PDM/Devices exists.
*/
char szPath[RTPATH_MAX];
int rc = g_pHlp->pfnFindModule(g_pHlp, "VBoxBusMouseR3", NULL, VBOXEXTPACKMODKIND_R3, szPath, sizeof(szPath), NULL);
if (RT_FAILURE(rc))
return rc;
PCFGMNODE pCfgRoot = CFGMR3GetRoot(pVM);
AssertReturn(pCfgRoot, VERR_INTERNAL_ERROR_3);
PCFGMNODE pCfgDevices = CFGMR3GetChild(pCfgRoot, "PDM/Devices");
AssertReturn(pCfgDevices, VERR_INTERNAL_ERROR_3);
PCFGMNODE pCfgMine;
rc = CFGMR3InsertNode(pCfgDevices, "VBoxBusMouse", &pCfgMine);
AssertRCReturn(rc, rc);
rc = CFGMR3InsertString(pCfgMine, "Path", szPath);
AssertRCReturn(rc, rc);
/*
* Tell PDM where to find the R0 and RC modules for the bus mouse device.
*/
#ifdef VBOX_WITH_RAW_MODE
rc = g_pHlp->pfnFindModule(g_pHlp, "VBoxBusMouseRC", NULL, VBOXEXTPACKMODKIND_RC, szPath, sizeof(szPath), NULL);
AssertRCReturn(rc, rc);
RTPathStripFilename(szPath);
rc = CFGMR3InsertString(pCfgMine, "RCSearchPath", szPath);
AssertRCReturn(rc, rc);
#endif
rc = g_pHlp->pfnFindModule(g_pHlp, "VBoxBusMouseR0", NULL, VBOXEXTPACKMODKIND_R0, szPath, sizeof(szPath), NULL);
AssertRCReturn(rc, rc);
RTPathStripFilename(szPath);
rc = CFGMR3InsertString(pCfgMine, "R0SearchPath", szPath);
AssertRCReturn(rc, rc);
return VINF_SUCCESS;
}
RTDECL(int) RTDirFlushParent(const char *pszChild)
{
char szPath[RTPATH_MAX];
int rc = RTStrCopy(szPath, sizeof(szPath), pszChild);
if (RT_SUCCESS(rc))
{
RTPathStripFilename(szPath);
rc = RTDirFlush(szPath);
}
return rc;
}
/**
* Hack to strip of the architecture subdirectory from the exec dir.
*
* @returns See RTPathExecDir.
* @param pszPath See RTPathExecDir.
* @param cchPath See RTPathExecDir.
*/
DECLINLINE(int) rtPathSolarisArchHack(char *pszPath, size_t cchPath)
{
int rc = RTPathExecDir(pszPath, cchPath);
if (RT_SUCCESS(rc))
{
const char *pszLast = RTPathFilename(pszPath);
if ( !strcmp(pszLast, "amd64")
|| !strcmp(pszLast, "i386"))
RTPathStripFilename(pszPath);
}
return rc;
}
HRESULT VFSExplorer::cdUp(ComPtr<IProgress> &aProgress)
{
Utf8Str strUpPath;
{
AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS);
/* Remove lowest dir entry in a platform neutral way. */
char *pszNewPath = RTStrDup(m->strPath.c_str());
RTPathStripTrailingSlash(pszNewPath);
RTPathStripFilename(pszNewPath);
strUpPath = pszNewPath;
RTStrFree(pszNewPath);
}
return cd(strUpPath, aProgress);
}
STDMETHODIMP VFSExplorer::CdUp(IProgress **aProgress)
{
AutoCaller autoCaller(this);
if (FAILED(autoCaller.rc())) return autoCaller.rc();
Utf8Str strUpPath;
{
AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS);
/* Remove lowest dir entry in a platform neutral way. */
char *pszNewPath = RTStrDup(m->strPath.c_str());
RTPathStripTrailingSlash(pszNewPath);
RTPathStripFilename(pszNewPath);
strUpPath = pszNewPath;
RTStrFree(pszNewPath);
}
return Cd(Bstr(strUpPath).raw(), aProgress);
}
void XmlFileWriter::write(const char *pcszFilename, bool fSafe)
{
if (!fSafe)
writeInternal(pcszFilename, fSafe);
else
{
/* Empty string and directory spec must be avoid. */
if (RTPathFilename(pcszFilename) == NULL)
throw xml::LogicError(RT_SRC_POS);
/* Construct both filenames first to ease error handling. */
char szTmpFilename[RTPATH_MAX];
int rc = RTStrCopy(szTmpFilename, sizeof(szTmpFilename) - strlen(s_pszTmpSuff), pcszFilename);
if (RT_FAILURE(rc))
throw EIPRTFailure(rc, "RTStrCopy");
strcat(szTmpFilename, s_pszTmpSuff);
char szPrevFilename[RTPATH_MAX];
rc = RTStrCopy(szPrevFilename, sizeof(szPrevFilename) - strlen(s_pszPrevSuff), pcszFilename);
if (RT_FAILURE(rc))
throw EIPRTFailure(rc, "RTStrCopy");
strcat(szPrevFilename, s_pszPrevSuff);
/* Write the XML document to the temporary file. */
writeInternal(szTmpFilename, fSafe);
/* Make a backup of any existing file (ignore failure). */
uint64_t cbPrevFile;
rc = RTFileQuerySize(pcszFilename, &cbPrevFile);
if (RT_SUCCESS(rc) && cbPrevFile >= 16)
RTFileRename(pcszFilename, szPrevFilename, RTPATHRENAME_FLAGS_REPLACE);
/* Commit the temporary file. Just leave the tmp file behind on failure. */
rc = RTFileRename(szTmpFilename, pcszFilename, RTPATHRENAME_FLAGS_REPLACE);
if (RT_FAILURE(rc))
throw EIPRTFailure(rc, "Failed to replace '%s' with '%s'", pcszFilename, szTmpFilename);
/* Flush the directory changes (required on linux at least). */
RTPathStripFilename(szTmpFilename);
rc = RTDirFlush(szTmpFilename);
AssertMsg(RT_SUCCESS(rc) || rc == VERR_NOT_SUPPORTED || rc == VERR_NOT_IMPLEMENTED, ("%Rrc\n", rc));
}
}
/**
* Construct a dot svn filename for the file being rewritten.
*
* @returns IPRT status code.
* @param pState The rewrite state (for the name).
* @param pszDir The directory, including ".svn/".
* @param pszSuff The filename suffix.
* @param pszDst The output buffer. RTPATH_MAX in size.
*/
static int scmSvnConstructName(PSCMRWSTATE pState, const char *pszDir, const char *pszSuff, char *pszDst)
{
strcpy(pszDst, pState->pszFilename); /* ASSUMES sizeof(szBuf) <= sizeof(szPath) */
RTPathStripFilename(pszDst);
int rc = RTPathAppend(pszDst, RTPATH_MAX, pszDir);
if (RT_SUCCESS(rc))
{
rc = RTPathAppend(pszDst, RTPATH_MAX, RTPathFilename(pState->pszFilename));
if (RT_SUCCESS(rc))
{
size_t cchDst = strlen(pszDst);
size_t cchSuff = strlen(pszSuff);
if (cchDst + cchSuff < RTPATH_MAX)
{
memcpy(&pszDst[cchDst], pszSuff, cchSuff + 1);
return VINF_SUCCESS;
}
else
rc = VERR_BUFFER_OVERFLOW;
}
}
return rc;
}
static int solarisWalkDeviceNode(di_node_t Node, void *pvArg)
{
PUSBDEVICELIST pList = (PUSBDEVICELIST)pvArg;
AssertPtrReturn(pList, DI_WALK_TERMINATE);
/*
* Check if it's a USB device in the first place.
*/
bool fUSBDevice = false;
char *pszCompatNames = NULL;
int cCompatNames = di_compatible_names(Node, &pszCompatNames);
for (int i = 0; i < cCompatNames; i++, pszCompatNames += strlen(pszCompatNames) + 1)
if (!strncmp(pszCompatNames, "usb", 3))
{
fUSBDevice = true;
break;
}
if (!fUSBDevice)
return DI_WALK_CONTINUE;
/*
* Check if it's a device node or interface.
*/
int *pInt = NULL;
char *pStr = NULL;
int rc = DI_WALK_CONTINUE;
if (di_prop_lookup_ints(DDI_DEV_T_ANY, Node, "interface", &pInt) < 0)
{
/* It's a device node. */
char *pszDevicePath = di_devfs_path(Node);
PUSBDEVICE pCur = (PUSBDEVICE)RTMemAllocZ(sizeof(*pCur));
if (!pCur)
{
LogRel(("USBService: failed to allocate %d bytes for PUSBDEVICE.\n", sizeof(*pCur)));
return DI_WALK_TERMINATE;
}
bool fValidDevice = false;
do
{
AssertBreak(pszDevicePath);
char *pszDriverName = di_driver_name(Node);
/*
* Skip hubs
*/
if ( pszDriverName
&& !strcmp(pszDriverName, "hubd"))
{
break;
}
/*
* Mandatory.
* snv_85 and above have usb-dev-descriptor node properties, but older one's do not.
* So if we cannot obtain the entire device descriptor, we try falling back to the
* individual properties (those must not fail, if it does we drop the device).
*/
uchar_t *pDevData = NULL;
int cbProp = di_prop_lookup_bytes(DDI_DEV_T_ANY, Node, "usb-dev-descriptor", &pDevData);
if ( cbProp > 0
&& pDevData)
{
usb_dev_descr_t *pDeviceDescriptor = (usb_dev_descr_t *)pDevData;
pCur->bDeviceClass = pDeviceDescriptor->bDeviceClass;
pCur->bDeviceSubClass = pDeviceDescriptor->bDeviceSubClass;
pCur->bDeviceProtocol = pDeviceDescriptor->bDeviceProtocol;
pCur->idVendor = pDeviceDescriptor->idVendor;
pCur->idProduct = pDeviceDescriptor->idProduct;
pCur->bcdDevice = pDeviceDescriptor->bcdDevice;
pCur->bcdUSB = pDeviceDescriptor->bcdUSB;
pCur->bNumConfigurations = pDeviceDescriptor->bNumConfigurations;
pCur->fPartialDescriptor = false;
}
else
{
AssertBreak(di_prop_lookup_ints(DDI_DEV_T_ANY, Node, "usb-vendor-id", &pInt) > 0);
pCur->idVendor = (uint16_t)*pInt;
AssertBreak(di_prop_lookup_ints(DDI_DEV_T_ANY, Node, "usb-product-id", &pInt) > 0);
pCur->idProduct = (uint16_t)*pInt;
AssertBreak(di_prop_lookup_ints(DDI_DEV_T_ANY, Node, "usb-revision-id", &pInt) > 0);
pCur->bcdDevice = (uint16_t)*pInt;
AssertBreak(di_prop_lookup_ints(DDI_DEV_T_ANY, Node, "usb-release", &pInt) > 0);
pCur->bcdUSB = (uint16_t)*pInt;
pCur->fPartialDescriptor = true;
}
char *pszPortAddr = di_bus_addr(Node);
if (pszPortAddr)
pCur->bPort = RTStrToUInt8(pszPortAddr); /* Bus & Port are mixed up (kernel driver/userland) */
else
pCur->bPort = 0;
char pathBuf[PATH_MAX];
RTStrPrintf(pathBuf, sizeof(pathBuf), "%s", pszDevicePath);
RTPathStripFilename(pathBuf);
char szBuf[PATH_MAX + 48];
RTStrPrintf(szBuf, sizeof(szBuf), "%#x:%#x:%d:%s", pCur->idVendor, pCur->idProduct, pCur->bcdDevice, pathBuf);
pCur->pszAddress = RTStrDup(szBuf);
pCur->pszDevicePath = RTStrDup(pszDevicePath);
AssertBreak(pCur->pszDevicePath);
/*
* Optional (some devices don't have all these)
*/
if (di_prop_lookup_strings(DDI_DEV_T_ANY, Node, "usb-product-name", &pStr) > 0)
pCur->pszProduct = RTStrDup(pStr);
if (di_prop_lookup_strings(DDI_DEV_T_ANY, Node, "usb-vendor-name", &pStr) > 0)
pCur->pszManufacturer = RTStrDup(pStr);
if (di_prop_lookup_strings(DDI_DEV_T_ANY, Node, "usb-serialno", &pStr) > 0)
pCur->pszSerialNumber = RTStrDup(pStr);
if (di_prop_lookup_ints(DDI_DEV_T_ANY, Node, "low-speed", &pInt) >= 0)
pCur->enmSpeed = USBDEVICESPEED_LOW;
else if (di_prop_lookup_ints(DDI_DEV_T_ANY, Node, "high-speed", &pInt) >= 0)
pCur->enmSpeed = USBDEVICESPEED_HIGH;
else
pCur->enmSpeed = USBDEVICESPEED_FULL;
/* Determine state of the USB device. */
pCur->enmState = solarisDetermineUSBDeviceState(pCur, Node);
/*
* Valid device, add it to the list.
*/
fValidDevice = true;
pCur->pPrev = pList->pTail;
if (pList->pTail)
pList->pTail = pList->pTail->pNext = pCur;
else
pList->pTail = pList->pHead = pCur;
rc = DI_WALK_CONTINUE;
} while(0);
di_devfs_path_free(pszDevicePath);
if (!fValidDevice)
solarisFreeUSBDevice(pCur);
}
return rc;
}
int main()
{
char szPath[RTPATH_MAX];
/*
* Init RT+Test.
*/
RTTEST hTest;
int rc = RTTestInitAndCreate("tstRTPath", &hTest);
if (rc)
return rc;
RTTestBanner(hTest);
/*
* RTPathExecDir, RTPathUserHome and RTProcGetExecutablePath.
*/
RTTestSub(hTest, "RTPathExecDir");
RTTESTI_CHECK_RC(rc = RTPathExecDir(szPath, sizeof(szPath)), VINF_SUCCESS);
if (RT_SUCCESS(rc))
RTTestIPrintf(RTTESTLVL_INFO, "ExecDir={%s}\n", szPath);
RTTestSub(hTest, "RTProcGetExecutablePath");
if (RTProcGetExecutablePath(szPath, sizeof(szPath)) == szPath)
RTTestIPrintf(RTTESTLVL_INFO, "ExecutableName={%s}\n", szPath);
else
RTTestIFailed("RTProcGetExecutablePath -> NULL");
RTTestSub(hTest, "RTPathUserHome");
RTTESTI_CHECK_RC(rc = RTPathUserHome(szPath, sizeof(szPath)), VINF_SUCCESS);
if (RT_SUCCESS(rc))
RTTestIPrintf(RTTESTLVL_INFO, "UserHome={%s}\n", szPath);
RTTestSub(hTest, "RTPathUserDocuments");
RTTESTI_CHECK_RC(rc = RTPathUserDocuments(szPath, sizeof(szPath)), VINF_SUCCESS);
if (RT_SUCCESS(rc))
RTTestIPrintf(RTTESTLVL_INFO, "UserDocuments={%s}\n", szPath);
RTTestSub(hTest, "RTPathTemp");
RTTESTI_CHECK_RC(rc = RTPathTemp(szPath, sizeof(szPath)), VINF_SUCCESS);
if (RT_SUCCESS(rc))
RTTestIPrintf(RTTESTLVL_INFO, "PathTemp={%s}\n", szPath);
size_t cch = strlen(szPath);
RTTESTI_CHECK_RC(RTPathTemp(szPath, cch), VERR_BUFFER_OVERFLOW);
RTTESTI_CHECK_RC(RTPathTemp(szPath, cch+1), VINF_SUCCESS);
RTTESTI_CHECK_RC(RTPathTemp(szPath, cch+2), VINF_SUCCESS);
/*
* RTPathAbsEx
*/
RTTestSub(hTest, "RTPathAbsEx");
static const struct
{
const char *pcszInputBase;
const char *pcszInputPath;
int rc;
const char *pcszOutput;
}
s_aRTPathAbsExTests[] =
{
#if defined (RT_OS_OS2) || defined (RT_OS_WINDOWS)
{ NULL, "", VERR_INVALID_PARAMETER, NULL },
{ NULL, ".", VINF_SUCCESS, "%p" },
{ NULL, "\\", VINF_SUCCESS, "%d\\" },
{ NULL, "\\..", VINF_SUCCESS, "%d\\" },
{ NULL, "/absolute/..", VINF_SUCCESS, "%d\\" },
{ NULL, "/absolute\\\\../..", VINF_SUCCESS, "%d\\" },
{ NULL, "/absolute//../path\\", VINF_SUCCESS, "%d\\path" },
{ NULL, "/absolute/../../path", VINF_SUCCESS, "%d\\path" },
{ NULL, "relative/../dir\\.\\.\\.\\file.txt", VINF_SUCCESS, "%p\\dir\\file.txt" },
{ NULL, "\\data\\", VINF_SUCCESS, "%d\\data" },
{ "relative_base/dir\\", "\\from_root", VINF_SUCCESS, "%d\\from_root" },
{ "relative_base/dir/", "relative_also", VINF_SUCCESS, "%p\\relative_base\\dir\\relative_also" },
#else
{ NULL, "", VERR_INVALID_PARAMETER, NULL },
{ NULL, ".", VINF_SUCCESS, "%p" },
{ NULL, "/", VINF_SUCCESS, "/" },
{ NULL, "/..", VINF_SUCCESS, "/" },
{ NULL, "/absolute/..", VINF_SUCCESS, "/" },
{ NULL, "/absolute\\\\../..", VINF_SUCCESS, "/" },
{ NULL, "/absolute//../path/", VINF_SUCCESS, "/path" },
{ NULL, "/absolute/../../path", VINF_SUCCESS, "/path" },
{ NULL, "relative/../dir/./././file.txt", VINF_SUCCESS, "%p/dir/file.txt" },
{ NULL, "relative/../dir\\.\\.\\.\\file.txt", VINF_SUCCESS, "%p/dir\\.\\.\\.\\file.txt" }, /* linux-specific */
{ NULL, "/data/", VINF_SUCCESS, "/data" },
{ "relative_base/dir/", "/from_root", VINF_SUCCESS, "/from_root" },
{ "relative_base/dir/", "relative_also", VINF_SUCCESS, "%p/relative_base/dir/relative_also" },
#endif
#if defined (RT_OS_OS2) || defined (RT_OS_WINDOWS)
{ NULL, "C:\\", VINF_SUCCESS, "C:\\" },
{ "C:\\", "..", VINF_SUCCESS, "C:\\" },
{ "C:\\temp", "..", VINF_SUCCESS, "C:\\" },
{ "C:\\VirtualBox/Machines", "..\\VirtualBox.xml", VINF_SUCCESS, "C:\\VirtualBox\\VirtualBox.xml" },
{ "C:\\MustDie", "\\from_root/dir/..", VINF_SUCCESS, "C:\\from_root" },
{ "C:\\temp", "D:\\data", VINF_SUCCESS, "D:\\data" },
{ NULL, "\\\\server\\..\\share", VINF_SUCCESS, "\\\\server\\..\\share" /* kind of strange */ },
{ NULL, "\\\\server/", VINF_SUCCESS, "\\\\server" },
{ NULL, "\\\\", VINF_SUCCESS, "\\\\" },
{ NULL, "\\\\\\something", VINF_SUCCESS, "\\\\\\something" /* kind of strange */ },
{ "\\\\server\\share_as_base", "/from_root", VINF_SUCCESS, "\\\\server\\from_root" },
{ "\\\\just_server", "/from_root", VINF_SUCCESS, "\\\\just_server\\from_root" },
{ "\\\\server\\share_as_base", "relative\\data", VINF_SUCCESS, "\\\\server\\share_as_base\\relative\\data" },
{ "base", "\\\\?\\UNC\\relative/edwef/..", VINF_SUCCESS, "\\\\?\\UNC\\relative" },
{ "\\\\?\\UNC\\base", "/from_root", VERR_INVALID_NAME, NULL },
#else
{ "/temp", "..", VINF_SUCCESS, "/" },
{ "/VirtualBox/Machines", "../VirtualBox.xml", VINF_SUCCESS, "/VirtualBox/VirtualBox.xml" },
{ "/MustDie", "/from_root/dir/..", VINF_SUCCESS, "/from_root" },
{ "\\temp", "\\data", VINF_SUCCESS, "%p/\\temp/\\data" },
#endif
};
for (unsigned i = 0; i < RT_ELEMENTS(s_aRTPathAbsExTests); ++ i)
{
rc = RTPathAbsEx(s_aRTPathAbsExTests[i].pcszInputBase,
s_aRTPathAbsExTests[i].pcszInputPath,
szPath, sizeof(szPath));
if (rc != s_aRTPathAbsExTests[i].rc)
{
RTTestIFailed("unexpected result code!\n"
" input base: '%s'\n"
" input path: '%s'\n"
" output: '%s'\n"
" rc: %Rrc\n"
" expected rc: %Rrc",
s_aRTPathAbsExTests[i].pcszInputBase,
s_aRTPathAbsExTests[i].pcszInputPath,
szPath, rc,
s_aRTPathAbsExTests[i].rc);
continue;
}
char szTmp[RTPATH_MAX];
char *pszExpected = NULL;
if (s_aRTPathAbsExTests[i].pcszOutput != NULL)
{
if (s_aRTPathAbsExTests[i].pcszOutput[0] == '%')
{
RTTESTI_CHECK_RC(rc = RTPathGetCurrent(szTmp, sizeof(szTmp)), VINF_SUCCESS);
if (RT_FAILURE(rc))
break;
pszExpected = szTmp;
if (s_aRTPathAbsExTests[i].pcszOutput[1] == 'p')
{
cch = strlen(szTmp);
if (cch + strlen(s_aRTPathAbsExTests[i].pcszOutput) - 2 <= sizeof(szTmp))
strcpy(szTmp + cch, s_aRTPathAbsExTests[i].pcszOutput + 2);
}
#if defined(RT_OS_OS2) || defined(RT_OS_WINDOWS)
else if (s_aRTPathAbsExTests[i].pcszOutput[1] == 'd')
{
if (2 + strlen(s_aRTPathAbsExTests[i].pcszOutput) - 2 <= sizeof(szTmp))
strcpy(szTmp + 2, s_aRTPathAbsExTests[i].pcszOutput + 2);
}
#endif
}
else
{
strcpy(szTmp, s_aRTPathAbsExTests[i].pcszOutput);
pszExpected = szTmp;
}
if (strcmp(szPath, pszExpected))
{
RTTestIFailed("Unexpected result\n"
" input base: '%s'\n"
" input path: '%s'\n"
" output: '%s'\n"
" expected: '%s'",
s_aRTPathAbsExTests[i].pcszInputBase,
s_aRTPathAbsExTests[i].pcszInputPath,
szPath,
s_aRTPathAbsExTests[i].pcszOutput);
}
}
}
/*
* RTPathStripFilename
*/
RTTestSub(hTest, "RTPathStripFilename");
static const char *s_apszStripFilenameTests[] =
{
"/usr/include///", "/usr/include//",
"/usr/include/", "/usr/include",
"/usr/include", "/usr",
"/usr", "/",
"usr", ".",
#if defined (RT_OS_OS2) || defined (RT_OS_WINDOWS)
"c:/windows", "c:/",
"c:/", "c:/",
"D:", "D:",
"C:\\OS2\\DLLS", "C:\\OS2",
#endif
};
for (unsigned i = 0; i < RT_ELEMENTS(s_apszStripFilenameTests); i += 2)
{
const char *pszInput = s_apszStripFilenameTests[i];
const char *pszExpect = s_apszStripFilenameTests[i + 1];
strcpy(szPath, pszInput);
RTPathStripFilename(szPath);
if (strcmp(szPath, pszExpect))
{
RTTestIFailed("Unexpected result\n"
" input: '%s'\n"
" output: '%s'\n"
"expected: '%s'",
pszInput, szPath, pszExpect);
}
}
/*
* RTPathAppend.
*/
RTTestSub(hTest, "RTPathAppend");
static const char *s_apszAppendTests[] =
{
/* base append result */
"/", "", "/",
"", "/", "/",
"/", "/", "/",
"/x", "", "/x",
"/x", "/", "/x/",
"/", "x", "/x",
"dir", "file", "dir/file",
"dir", "/file", "dir/file",
"dir", "//file", "dir/file",
"dir", "///file", "dir/file",
"dir/", "/file", "dir/file",
"dir/", "//file", "dir/file",
"dir/", "///file", "dir/file",
"dir//", "file", "dir/file",
"dir//", "/file", "dir/file",
"dir//", "//file", "dir/file",
"dir///", "///file", "dir/file",
"/bin/testcase", "foo.r0", "/bin/testcase/foo.r0",
#if defined (RT_OS_OS2) || defined (RT_OS_WINDOWS)
"/", "\\", "/",
"\\", "/", "\\",
"\\\\srv\\shr", "dir//", "\\\\srv\\shr/dir//",
"\\\\srv\\shr", "dir//file", "\\\\srv\\shr/dir//file",
"\\\\srv\\shr", "//dir//", "\\\\srv\\shr/dir//",
"\\\\srv\\shr", "/\\dir//", "\\\\srv\\shr\\dir//",
"\\\\", "not-srv/not-shr/file", "\\not-srv/not-shr/file",
"C:", "autoexec.bat", "C:autoexec.bat",
"C:", "/autoexec.bat", "C:/autoexec.bat",
"C:", "\\autoexec.bat", "C:\\autoexec.bat",
"C:\\", "/autoexec.bat", "C:\\autoexec.bat",
"C:\\\\", "autoexec.bat", "C:\\autoexec.bat",
"E:\\bin\\testcase", "foo.r0", "E:\\bin\\testcase/foo.r0",
#endif
};
for (unsigned i = 0; i < RT_ELEMENTS(s_apszAppendTests); i += 3)
{
const char *pszInput = s_apszAppendTests[i];
const char *pszAppend = s_apszAppendTests[i + 1];
const char *pszExpect = s_apszAppendTests[i + 2];
strcpy(szPath, pszInput);
RTTESTI_CHECK_RC(rc = RTPathAppend(szPath, sizeof(szPath), pszAppend), VINF_SUCCESS);
if (RT_FAILURE(rc))
continue;
if (strcmp(szPath, pszExpect))
{
RTTestIFailed("Unexpected result\n"
" input: '%s'\n"
" append: '%s'\n"
" output: '%s'\n"
"expected: '%s'",
pszInput, pszAppend, szPath, pszExpect);
}
else
{
size_t const cchResult = strlen(szPath);
strcpy(szPath, pszInput);
RTTESTI_CHECK_RC(rc = RTPathAppend(szPath, cchResult + 2, pszAppend), VINF_SUCCESS);
RTTESTI_CHECK(RT_FAILURE(rc) || !strcmp(szPath, pszExpect));
strcpy(szPath, pszInput);
RTTESTI_CHECK_RC(rc = RTPathAppend(szPath, cchResult + 1, pszAppend), VINF_SUCCESS);
RTTESTI_CHECK(RT_FAILURE(rc) || !strcmp(szPath, pszExpect));
if (strlen(pszInput) < cchResult)
{
strcpy(szPath, pszInput);
RTTESTI_CHECK_RC(RTPathAppend(szPath, cchResult, pszAppend), VERR_BUFFER_OVERFLOW);
}
}
}
/*
* RTPathJoin - reuse the append tests.
*/
RTTestSub(hTest, "RTPathJoin");
for (unsigned i = 0; i < RT_ELEMENTS(s_apszAppendTests); i += 3)
{
const char *pszInput = s_apszAppendTests[i];
const char *pszAppend = s_apszAppendTests[i + 1];
const char *pszExpect = s_apszAppendTests[i + 2];
memset(szPath, 'a', sizeof(szPath)); szPath[sizeof(szPath) - 1] = '\0';
RTTESTI_CHECK_RC(rc = RTPathJoin(szPath, sizeof(szPath), pszInput, pszAppend), VINF_SUCCESS);
if (RT_FAILURE(rc))
continue;
if (strcmp(szPath, pszExpect))
{
RTTestIFailed("Unexpected result\n"
" input: '%s'\n"
" append: '%s'\n"
" output: '%s'\n"
"expected: '%s'",
pszInput, pszAppend, szPath, pszExpect);
}
else
{
size_t const cchResult = strlen(szPath);
memset(szPath, 'a', sizeof(szPath)); szPath[sizeof(szPath) - 1] = '\0';
RTTESTI_CHECK_RC(rc = RTPathJoin(szPath, cchResult + 2, pszInput, pszAppend), VINF_SUCCESS);
RTTESTI_CHECK(RT_FAILURE(rc) || !strcmp(szPath, pszExpect));
memset(szPath, 'a', sizeof(szPath)); szPath[sizeof(szPath) - 1] = '\0';
RTTESTI_CHECK_RC(rc = RTPathJoin(szPath, cchResult + 1, pszInput, pszAppend), VINF_SUCCESS);
RTTESTI_CHECK(RT_FAILURE(rc) || !strcmp(szPath, pszExpect));
RTTESTI_CHECK_RC(rc = RTPathJoin(szPath, cchResult, pszInput, pszAppend), VERR_BUFFER_OVERFLOW);
}
}
/*
* RTPathJoinA - reuse the append tests.
*/
RTTestSub(hTest, "RTPathJoinA");
for (unsigned i = 0; i < RT_ELEMENTS(s_apszAppendTests); i += 3)
{
const char *pszInput = s_apszAppendTests[i];
const char *pszAppend = s_apszAppendTests[i + 1];
const char *pszExpect = s_apszAppendTests[i + 2];
char *pszPathDst;
RTTESTI_CHECK(pszPathDst = RTPathJoinA(pszInput, pszAppend));
if (!pszPathDst)
continue;
if (strcmp(pszPathDst, pszExpect))
{
RTTestIFailed("Unexpected result\n"
" input: '%s'\n"
" append: '%s'\n"
" output: '%s'\n"
"expected: '%s'",
pszInput, pszAppend, pszPathDst, pszExpect);
}
RTStrFree(pszPathDst);
}
/*
* RTPathStripTrailingSlash
*/
static const char *s_apszStripTrailingSlash[] =
{
/* input result */
"/", "/",
"//", "/",
"////////////////////", "/",
"/tmp", "/tmp",
"/tmp////////////////", "/tmp",
"tmp", "tmp",
"tmp////////////////", "tmp",
"./", ".",
#if defined (RT_OS_OS2) || defined (RT_OS_WINDOWS)
"////////////////////", "/",
"D:", "D:",
"D:/", "D:/",
"D:\\", "D:\\",
"D:\\/\\", "D:\\",
"D:/\\/\\", "D:/",
"C:/Temp", "D:/Temp",
"C:/Temp/", "D:/Temp/",
"C:/Temp\\/", "D:/Temp",
#endif
};
for (unsigned i = 0; i < RT_ELEMENTS(s_apszStripTrailingSlash); i += 2)
{
const char *pszInput = s_apszStripTrailingSlash[i];
const char *pszExpect = s_apszStripTrailingSlash[i + 1];
strcpy(szPath, pszInput);
cch = RTPathStripTrailingSlash(szPath);
if (strcmp(szPath, pszExpect))
RTTestIFailed("Unexpected result\n"
" input: '%s'\n"
" output: '%s'\n"
"expected: '%s'",
pszInput, szPath, pszExpect);
else
RTTESTI_CHECK(cch == strlen(szPath));
}
/*
* RTPathCountComponents
*/
RTTestSub(hTest, "RTPathCountComponents");
RTTESTI_CHECK(RTPathCountComponents("") == 0);
RTTESTI_CHECK(RTPathCountComponents("/") == 1);
RTTESTI_CHECK(RTPathCountComponents("//") == 1);
RTTESTI_CHECK(RTPathCountComponents("//////////////") == 1);
RTTESTI_CHECK(RTPathCountComponents("//////////////bin") == 2);
RTTESTI_CHECK(RTPathCountComponents("//////////////bin/") == 2);
RTTESTI_CHECK(RTPathCountComponents("//////////////bin/////") == 2);
RTTESTI_CHECK(RTPathCountComponents("..") == 1);
RTTESTI_CHECK(RTPathCountComponents("../") == 1);
RTTESTI_CHECK(RTPathCountComponents("../..") == 2);
RTTESTI_CHECK(RTPathCountComponents("../../") == 2);
#if defined (RT_OS_OS2) || defined (RT_OS_WINDOWS)
RTTESTI_CHECK(RTPathCountComponents("d:") == 1);
RTTESTI_CHECK(RTPathCountComponents("d:/") == 1);
RTTESTI_CHECK(RTPathCountComponents("d:/\\") == 1);
RTTESTI_CHECK(RTPathCountComponents("d:\\") == 1);
RTTESTI_CHECK(RTPathCountComponents("c:\\config.sys") == 2);
RTTESTI_CHECK(RTPathCountComponents("c:\\windows") == 2);
RTTESTI_CHECK(RTPathCountComponents("c:\\windows\\") == 2);
RTTESTI_CHECK(RTPathCountComponents("c:\\windows\\system32") == 3);
RTTESTI_CHECK(RTPathCountComponents("//./C$") == 1);
RTTESTI_CHECK(RTPathCountComponents("\\\\.\\C$") == 1);
RTTESTI_CHECK(RTPathCountComponents("/\\.\\C$") == 1);
RTTESTI_CHECK(RTPathCountComponents("//myserver") == 1);
RTTESTI_CHECK(RTPathCountComponents("//myserver/") == 1);
RTTESTI_CHECK(RTPathCountComponents("//myserver/share") == 1);
RTTESTI_CHECK(RTPathCountComponents("//myserver/share/") == 1);
RTTESTI_CHECK(RTPathCountComponents("//myserver/share\\") == 1);
RTTESTI_CHECK(RTPathCountComponents("//myserver/share\\x") == 2);
RTTESTI_CHECK(RTPathCountComponents("//myserver/share\\x\\y") == 3);
RTTESTI_CHECK(RTPathCountComponents("//myserver/share\\x\\y\\") == 3);
#endif
/*
* RTPathCopyComponents
*/
struct
{
const char *pszSrc;
size_t cComponents;
const char *pszResult;
} s_aCopyComponents[] =
{
{ "", 0, "" },
{ "", 5, "" },
{ "/", 0, "" },
{ "/", 1, "/" },
{ "/", 2, "/" },
{ "/usr/bin/sed", 0, "" },
{ "/usr/bin/sed", 1, "/" },
{ "/usr/bin/sed", 2, "/usr/" },
{ "/usr/bin/sed", 3, "/usr/bin/" },
{ "/usr/bin/sed", 4, "/usr/bin/sed" },
{ "/usr/bin/sed", 5, "/usr/bin/sed" },
{ "/usr/bin/sed", 6, "/usr/bin/sed" },
{ "/usr///bin/sed", 2, "/usr///" },
};
for (unsigned i = 0; i < RT_ELEMENTS(s_aCopyComponents); i++)
{
const char *pszInput = s_aCopyComponents[i].pszSrc;
size_t cComponents = s_aCopyComponents[i].cComponents;
const char *pszResult = s_aCopyComponents[i].pszResult;
memset(szPath, 'a', sizeof(szPath));
rc = RTPathCopyComponents(szPath, sizeof(szPath), pszInput, cComponents);
RTTESTI_CHECK_RC(rc, VINF_SUCCESS);
if (RT_SUCCESS(rc) && strcmp(szPath, pszResult))
RTTestIFailed("Unexpected result\n"
" input: '%s' cComponents=%u\n"
" output: '%s'\n"
"expected: '%s'",
pszInput, cComponents, szPath, pszResult);
else if (RT_SUCCESS(rc))
{
RTTESTI_CHECK_RC(RTPathCopyComponents(szPath, strlen(pszResult) + 1, pszInput, cComponents), VINF_SUCCESS);
RTTESTI_CHECK_RC(RTPathCopyComponents(szPath, strlen(pszResult), pszInput, cComponents), VERR_BUFFER_OVERFLOW);
}
}
/*
* RTPathStripExt
*/
RTTestSub(hTest, "RTPathStripExt");
struct
{
const char *pszSrc;
const char *pszResult;
} s_aStripExt[] =
{
{ "filename.ext", "filename" },
{ "filename.ext1.ext2.ext3", "filename.ext1.ext2" },
{ "filename..ext", "filename." },
{ "filename.ext.", "filename.ext" }, /** @todo This is a bit weird/wrong, but not half as weird as the way Windows+OS/2 deals with a trailing dots. */
};
for (unsigned i = 0; i < RT_ELEMENTS(s_aStripExt); i++)
{
const char *pszInput = s_aStripExt[i].pszSrc;
const char *pszResult = s_aStripExt[i].pszResult;
strcpy(szPath, pszInput);
RTPathStripExt(szPath);
if (strcmp(szPath, pszResult))
RTTestIFailed("Unexpected result\n"
" input: '%s'\n"
" output: '%s'\n"
"expected: '%s'",
pszInput, szPath, pszResult);
}
/*
* RTPathCalcRelative
*/
RTTestSub(hTest, "RTPathCalcRelative");
struct
{
const char *pszFrom;
const char *pszTo;
int rc;
const char *pszExpected;
} s_aRelPath[] =
{
{ "/home/test.ext", "/home/test2.ext", VINF_SUCCESS, "test2.ext"},
{ "/dir/test.ext", "/dir/dir2/test2.ext", VINF_SUCCESS, "dir2/test2.ext"},
{ "/dir/dir2/test.ext", "/dir/test2.ext", VINF_SUCCESS, "../test2.ext"},
{ "/dir/dir2/test.ext", "/dir/dir3/test2.ext", VINF_SUCCESS, "../dir3/test2.ext"},
#if defined (RT_OS_OS2) || defined (RT_OS_WINDOWS)
{ "\\\\server\\share\\test.ext", "\\\\server\\share2\\test2.ext", VERR_NOT_SUPPORTED, ""},
{ "c:\\dir\\test.ext", "f:\\dir\\test.ext", VERR_NOT_SUPPORTED, ""}
#endif
};
for (unsigned i = 0; i < RT_ELEMENTS(s_aRelPath); i++)
{
const char *pszFrom = s_aRelPath[i].pszFrom;
const char *pszTo = s_aRelPath[i].pszTo;
rc = RTPathCalcRelative(szPath, sizeof(szPath), pszFrom, pszTo);
if (rc != s_aRelPath[i].rc)
RTTestIFailed("Unexpected return code\n"
" got: %Rrc\n"
"expected: %Rrc",
rc, s_aRelPath[i].rc);
else if ( RT_SUCCESS(rc)
&& strcmp(szPath, s_aRelPath[i].pszExpected))
RTTestIFailed("Unexpected result\n"
" from: '%s'\n"
" to: '%s'\n"
" output: '%s'\n"
"expected: '%s'",
pszFrom, pszTo, szPath, s_aRelPath[i].pszExpected);
}
/*
* Summary.
*/
return RTTestSummaryAndDestroy(hTest);
}
int main(int argc, char **argv)
{
RTR3InitExe(argc, &argv, 0);
if (argc == 1)
{
char szPath[RTPATH_MAX];
int rc = RTPathExecDir(szPath, sizeof(szPath) - sizeof("/.."));
if (RT_FAILURE(rc))
{
RTPrintf("fatal error: RTPathExecDir -> %Rrc\n", rc);
return 1;
}
rc = RTPathSetCurrent(strcat(szPath, "/.."));
if (RT_FAILURE(rc))
{
RTPrintf("fatal error: RTPathSetCurrent -> %Rrc\n", rc);
return 1;
}
Process("testcase/tst*", "testcase");
Process("tst*", ".");
}
else
{
char szDir[RTPATH_MAX];
for (int i = 1; i < argc; i++)
{
if (argv[i][0] == '-')
{
switch (argv[i][1])
{
/* case '':... */
default:
RTPrintf("syntax error: Option '%s' is not recognized\n", argv[i]);
return 1;
}
}
else
{
size_t cch = strlen(argv[i]);
if (cch >= sizeof(szDir))
{
RTPrintf("syntax error: '%s' is too long!\n", argv[i]);
return 1;
}
memcpy(szDir, argv[i], cch + 1);
char *pszFilename = RTPathFilename(szDir);
if (!pszFilename)
{
RTPrintf("syntax error: '%s' does not include a file name or file name mask!\n", argv[i]);
return 1;
}
RTPathStripFilename(szDir);
Process(argv[i], szDir);
}
}
}
RTPrintf("\n"
"********************\n"
"*** PASSED: %u\n"
"*** FAILED: %u\n"
"*** SKIPPED: %u\n"
"*** TOTAL: %u\n",
g_cPasses,
g_cFailures,
g_cSkipped,
g_cPasses + g_cFailures + g_cSkipped);
return !!g_cFailures;
}
/**
* VirtualBox component constructor.
*
* This constructor is responsible for starting the VirtualBox server
* process, connecting to it, and redirecting the constructor request to the
* VirtualBox component defined on the server.
*/
static NS_IMETHODIMP
VirtualBoxConstructor(nsISupports *aOuter, REFNSIID aIID,
void **aResult)
{
LogFlowFuncEnter();
nsresult rc = NS_OK;
int vrc = VINF_SUCCESS;
do
{
*aResult = NULL;
if (NULL != aOuter)
{
rc = NS_ERROR_NO_AGGREGATION;
break;
}
if (!IsVBoxSVCPathSet)
{
/* Get the directory containing XPCOM components -- the VBoxSVC
* executable is expected in the parent directory. */
nsCOMPtr<nsIProperties> dirServ = do_GetService(NS_DIRECTORY_SERVICE_CONTRACTID, &rc);
if (NS_SUCCEEDED(rc))
{
nsCOMPtr<nsIFile> componentDir;
rc = dirServ->Get(NS_XPCOM_COMPONENT_DIR,
NS_GET_IID(nsIFile), getter_AddRefs(componentDir));
if (NS_SUCCEEDED(rc))
{
nsCAutoString path;
componentDir->GetNativePath(path);
LogFlowFunc(("component directory = \"%s\"\n", path.get()));
AssertBreakStmt(path.Length() + strlen(VBoxSVC_exe) < RTPATH_MAX,
rc = NS_ERROR_FAILURE);
#if defined(RT_OS_SOLARIS) && defined(VBOX_WITH_HARDENING)
char achKernArch[128];
int cbKernArch = sysinfo(SI_ARCHITECTURE_K, achKernArch, sizeof(achKernArch));
if (cbKernArch > 0)
{
sprintf(VBoxSVCPath, "/opt/VirtualBox/%s%s", achKernArch, VBoxSVC_exe);
IsVBoxSVCPathSet = true;
}
else
rc = NS_ERROR_UNEXPECTED;
#else
strcpy(VBoxSVCPath, path.get());
RTPathStripFilename(VBoxSVCPath);
strcat(VBoxSVCPath, VBoxSVC_exe);
IsVBoxSVCPathSet = true;
#endif
}
}
if (NS_FAILED(rc))
break;
}
nsCOMPtr<ipcIService> ipcServ = do_GetService(IPC_SERVICE_CONTRACTID, &rc);
if (NS_FAILED(rc))
break;
/* connect to the VBoxSVC server process */
bool startedOnce = false;
unsigned timeLeft = VBoxSVC_Timeout;
do
{
LogFlowFunc(("Resolving server name \"%s\"...\n", VBOXSVC_IPC_NAME));
PRUint32 serverID = 0;
rc = ipcServ->ResolveClientName(VBOXSVC_IPC_NAME, &serverID);
if (NS_FAILED(rc))
{
LogFlowFunc(("Starting server \"%s\"...\n", VBoxSVCPath));
startedOnce = true;
rc = vboxsvcSpawnDaemon();
if (NS_FAILED(rc))
break;
/* wait for the server process to establish a connection */
do
{
RTThreadSleep(VBoxSVC_WaitSlice);
rc = ipcServ->ResolveClientName(VBOXSVC_IPC_NAME, &serverID);
if (NS_SUCCEEDED(rc))
break;
if (timeLeft <= VBoxSVC_WaitSlice)
{
timeLeft = 0;
break;
}
timeLeft -= VBoxSVC_WaitSlice;
}
while (1);
if (!timeLeft)
{
rc = IPC_ERROR_WOULD_BLOCK;
break;
}
}
LogFlowFunc(("Connecting to server (ID=%d)...\n", serverID));
nsCOMPtr<ipcIDConnectService> dconServ =
do_GetService(IPC_DCONNECTSERVICE_CONTRACTID, &rc);
if (NS_FAILED(rc))
break;
rc = dconServ->CreateInstance(serverID,
CLSID_VirtualBox,
aIID, aResult);
if (NS_SUCCEEDED(rc))
break;
LogFlowFunc(("Failed to connect (rc=%Rhrc (%#08x))\n", rc, rc));
/* It's possible that the server gets shut down after we
* successfully resolve the server name but before it
* receives our CreateInstance() request. So, check for the
* name again, and restart the cycle if it fails. */
if (!startedOnce)
{
nsresult rc2 =
ipcServ->ResolveClientName(VBOXSVC_IPC_NAME, &serverID);
if (NS_SUCCEEDED(rc2))
break;
LogFlowFunc(("Server seems to have terminated before receiving our request. Will try again.\n"));
}
else
break;
}
while (1);
}
while (0);
LogFlowFunc(("rc=%Rhrc (%#08x), vrc=%Rrc\n", rc, rc, vrc));
LogFlowFuncLeave();
return rc;
}