/** * @file llsys.cpp * @brief Implementation of the basic system query functions. * * $LicenseInfo:firstyear=2002&license=viewerlgpl$ * Second Life Viewer Source Code * Copyright (C) 2010, Linden Research, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; * version 2.1 of the License only. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * * Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA * $/LicenseInfo$ */ #if LL_WINDOWS #pragma warning (disable : 4355) // 'this' used in initializer list: yes, intentionally #endif #include "linden_common.h" #include "llsys.h" #include #ifdef LL_STANDALONE # include #else # include "zlib/zlib.h" #endif #include "llprocessor.h" #include "llerrorcontrol.h" #include "llevents.h" #include "llformat.h" #include "lltimer.h" #include "llsdserialize.h" #include "llsdutil.h" #include #include #include #include #include #include #include #include #include using namespace llsd; #if LL_WINDOWS # include "llwin32headerslean.h" # include // GetPerformanceInfo() et al. #elif LL_DARWIN # include # include # include # include # include # include # include # include # include # include #elif LL_LINUX # include # include # include # include # include const char MEMINFO_FILE[] = "/proc/meminfo"; # include #elif LL_SOLARIS # include # include # include # define _STRUCTURED_PROC 1 # include # include # include # include # include extern int errno; #endif static const S32 CPUINFO_BUFFER_SIZE = 16383; LLCPUInfo gSysCPU; // Don't log memory info any more often than this. It also serves as our // framerate sample size. static const F32 MEM_INFO_THROTTLE = 20; // Sliding window of samples. We intentionally limit the length of time we // remember "the slowest" framerate because framerate is very slow at login. // If we only triggered FrameWatcher logging when the session framerate // dropped below the login framerate, we'd have very little additional data. static const F32 MEM_INFO_WINDOW = 10*60; #if LL_WINDOWS #ifndef DLLVERSIONINFO typedef struct _DllVersionInfo { DWORD cbSize; DWORD dwMajorVersion; DWORD dwMinorVersion; DWORD dwBuildNumber; DWORD dwPlatformID; }DLLVERSIONINFO; #endif #ifndef DLLGETVERSIONPROC typedef int (FAR WINAPI *DLLGETVERSIONPROC) (DLLVERSIONINFO *); #endif bool get_shell32_dll_version(DWORD& major, DWORD& minor, DWORD& build_number) { bool result = false; const U32 BUFF_SIZE = 32767; WCHAR tempBuf[BUFF_SIZE]; if(GetSystemDirectory((LPWSTR)&tempBuf, BUFF_SIZE)) { std::basic_string shell32_path(tempBuf); // Shell32.dll contains the DLLGetVersion function. // according to msdn its not part of the API // so you have to go in and get it. // http://msdn.microsoft.com/en-us/library/bb776404(VS.85).aspx shell32_path += TEXT("\\shell32.dll"); HMODULE hDllInst = LoadLibrary(shell32_path.c_str()); //load the DLL if(hDllInst) { // Could successfully load the DLL DLLGETVERSIONPROC pDllGetVersion; /* You must get this function explicitly because earlier versions of the DLL don't implement this function. That makes the lack of implementation of the function a version marker in itself. */ pDllGetVersion = (DLLGETVERSIONPROC) GetProcAddress(hDllInst, "DllGetVersion"); if(pDllGetVersion) { // DLL supports version retrieval function DLLVERSIONINFO dvi; ZeroMemory(&dvi, sizeof(dvi)); dvi.cbSize = sizeof(dvi); HRESULT hr = (*pDllGetVersion)(&dvi); if(SUCCEEDED(hr)) { // Finally, the version is at our hands major = dvi.dwMajorVersion; minor = dvi.dwMinorVersion; build_number = dvi.dwBuildNumber; result = true; } } FreeLibrary(hDllInst); // Release DLL } } return result; } #endif // LL_WINDOWS // Wrap boost::regex_match() with a function that doesn't throw. template static bool regex_match_no_exc(const S& string, M& match, const R& regex) { try { return boost::regex_match(string, match, regex); } catch (const std::runtime_error& e) { LL_WARNS("LLMemoryInfo") << "error matching with '" << regex.str() << "': " << e.what() << ":\n'" << string << "'" << LL_ENDL; return false; } } // Wrap boost::regex_search() with a function that doesn't throw. template static bool regex_search_no_exc(const S& string, M& match, const R& regex) { try { return boost::regex_search(string, match, regex); } catch (const std::runtime_error& e) { LL_WARNS("LLMemoryInfo") << "error searching with '" << regex.str() << "': " << e.what() << ":\n'" << string << "'" << LL_ENDL; return false; } } LLOSInfo::LLOSInfo() : mMajorVer(0), mMinorVer(0), mBuild(0), mOSVersionString("") { #if LL_WINDOWS OSVERSIONINFOEX osvi; BOOL bOsVersionInfoEx; // Try calling GetVersionEx using the OSVERSIONINFOEX structure. ZeroMemory(&osvi, sizeof(OSVERSIONINFOEX)); osvi.dwOSVersionInfoSize = sizeof(OSVERSIONINFOEX); if(!(bOsVersionInfoEx = GetVersionEx((OSVERSIONINFO *) &osvi))) { // If OSVERSIONINFOEX doesn't work, try OSVERSIONINFO. osvi.dwOSVersionInfoSize = sizeof (OSVERSIONINFO); if(!GetVersionEx( (OSVERSIONINFO *) &osvi)) return; } mMajorVer = osvi.dwMajorVersion; mMinorVer = osvi.dwMinorVersion; mBuild = osvi.dwBuildNumber; DWORD shell32_major, shell32_minor, shell32_build; bool got_shell32_version = get_shell32_dll_version(shell32_major, shell32_minor, shell32_build); switch(osvi.dwPlatformId) { case VER_PLATFORM_WIN32_NT: { // Test for the product. if(osvi.dwMajorVersion <= 4) { mOSStringSimple = "Microsoft Windows NT "; } else if(osvi.dwMajorVersion == 5 && osvi.dwMinorVersion == 0) { mOSStringSimple = "Microsoft Windows 2000 "; } else if(osvi.dwMajorVersion ==5 && osvi.dwMinorVersion == 1) { mOSStringSimple = "Microsoft Windows XP "; } else if(osvi.dwMajorVersion == 5 && osvi.dwMinorVersion == 2) { if(osvi.wProductType == VER_NT_WORKSTATION) mOSStringSimple = "Microsoft Windows XP x64 Edition "; else mOSStringSimple = "Microsoft Windows Server 2003 "; } else if(osvi.dwMajorVersion == 6 && osvi.dwMinorVersion <= 2) { if(osvi.dwMinorVersion == 0) { if(osvi.wProductType == VER_NT_WORKSTATION) mOSStringSimple = "Microsoft Windows Vista "; else mOSStringSimple = "Windows Server 2008 "; } else if(osvi.dwMinorVersion == 1) { if(osvi.wProductType == VER_NT_WORKSTATION) mOSStringSimple = "Microsoft Windows 7 "; else mOSStringSimple = "Windows Server 2008 R2 "; } else if(osvi.dwMinorVersion == 2) { if(osvi.wProductType == VER_NT_WORKSTATION) mOSStringSimple = "Microsoft Windows 8 "; else mOSStringSimple = "Windows Server 2012 "; } ///get native system info if available.. typedef void (WINAPI *PGNSI)(LPSYSTEM_INFO); ///function pointer for loading GetNativeSystemInfo SYSTEM_INFO si; //System Info object file contains architecture info PGNSI pGNSI; //pointer object ZeroMemory(&si, sizeof(SYSTEM_INFO)); //zero out the memory in information pGNSI = (PGNSI) GetProcAddress(GetModuleHandle(TEXT("kernel32.dll")), "GetNativeSystemInfo"); //load kernel32 get function if(NULL != pGNSI) //check if it has failed pGNSI(&si); //success else GetSystemInfo(&si); //if it fails get regular system info //(Warning: If GetSystemInfo it may result in incorrect information in a WOW64 machine, if the kernel fails to load) //msdn microsoft finds 32 bit and 64 bit flavors this way.. //http://msdn.microsoft.com/en-us/library/ms724429(VS.85).aspx (example code that contains quite a few more flavors //of windows than this code does (in case it is needed for the future) if ( si.wProcessorArchitecture==PROCESSOR_ARCHITECTURE_AMD64 ) //check for 64 bit { mOSStringSimple += "64-bit "; } else if (si.wProcessorArchitecture==PROCESSOR_ARCHITECTURE_INTEL ) { mOSStringSimple += "32-bit "; } } else // Use the registry on early versions of Windows NT. { mOSStringSimple = "Microsoft Windows (unrecognized) "; HKEY hKey; WCHAR szProductType[80]; DWORD dwBufLen; RegOpenKeyEx( HKEY_LOCAL_MACHINE, L"SYSTEM\\CurrentControlSet\\Control\\ProductOptions", 0, KEY_QUERY_VALUE, &hKey ); RegQueryValueEx( hKey, L"ProductType", NULL, NULL, (LPBYTE) szProductType, &dwBufLen); RegCloseKey( hKey ); if ( lstrcmpi( L"WINNT", szProductType) == 0 ) { mOSStringSimple += "Professional "; } else if ( lstrcmpi( L"LANMANNT", szProductType) == 0 ) { mOSStringSimple += "Server "; } else if ( lstrcmpi( L"SERVERNT", szProductType) == 0 ) { mOSStringSimple += "Advanced Server "; } } std::string csdversion = utf16str_to_utf8str(osvi.szCSDVersion); // Display version, service pack (if any), and build number. std::string tmpstr; if(osvi.dwMajorVersion <= 4) { tmpstr = llformat("version %d.%d %s (Build %d)", osvi.dwMajorVersion, osvi.dwMinorVersion, csdversion.c_str(), (osvi.dwBuildNumber & 0xffff)); } else { tmpstr = llformat("%s (Build %d)", csdversion.c_str(), (osvi.dwBuildNumber & 0xffff)); } mOSString = mOSStringSimple + tmpstr; } break; case VER_PLATFORM_WIN32_WINDOWS: // Test for the Windows 95 product family. if(osvi.dwMajorVersion == 4 && osvi.dwMinorVersion == 0) { mOSStringSimple = "Microsoft Windows 95 "; if ( osvi.szCSDVersion[1] == 'C' || osvi.szCSDVersion[1] == 'B' ) { mOSStringSimple += "OSR2 "; } } if(osvi.dwMajorVersion == 4 && osvi.dwMinorVersion == 10) { mOSStringSimple = "Microsoft Windows 98 "; if ( osvi.szCSDVersion[1] == 'A' ) { mOSStringSimple += "SE "; } } if(osvi.dwMajorVersion == 4 && osvi.dwMinorVersion == 90) { mOSStringSimple = "Microsoft Windows Millennium Edition "; } mOSString = mOSStringSimple; break; } std::string compatibility_mode; if(got_shell32_version) { if(osvi.dwMajorVersion != shell32_major || osvi.dwMinorVersion != shell32_minor) { compatibility_mode = llformat(" compatibility mode. real ver: %d.%d (Build %d)", shell32_major, shell32_minor, shell32_build); } } mOSString += compatibility_mode; #elif LL_DARWIN // Initialize mOSStringSimple to something like: // "Mac OS X 10.6.7" { const char * DARWIN_PRODUCT_NAME = "Mac OS X"; SInt32 major_version, minor_version, bugfix_version; OSErr r1 = Gestalt(gestaltSystemVersionMajor, &major_version); OSErr r2 = Gestalt(gestaltSystemVersionMinor, &minor_version); OSErr r3 = Gestalt(gestaltSystemVersionBugFix, &bugfix_version); if((r1 == noErr) && (r2 == noErr) && (r3 == noErr)) { mMajorVer = major_version; mMinorVer = minor_version; mBuild = bugfix_version; std::stringstream os_version_string; os_version_string << DARWIN_PRODUCT_NAME << " " << mMajorVer << "." << mMinorVer << "." << mBuild; // Put it in the OS string we are compiling mOSStringSimple.append(os_version_string.str()); } else { mOSStringSimple.append("Unable to collect OS info"); } } // Initialize mOSString to something like: // "Mac OS X 10.6.7 Darwin Kernel Version 10.7.0: Sat Jan 29 15:17:16 PST 2011; root:xnu-1504.9.37~1/RELEASE_I386 i386" struct utsname un; if(uname(&un) != -1) { mOSString = mOSStringSimple; mOSString.append(" "); mOSString.append(un.sysname); mOSString.append(" "); mOSString.append(un.release); mOSString.append(" "); mOSString.append(un.version); mOSString.append(" "); mOSString.append(un.machine); } else { mOSString = mOSStringSimple; } #elif LL_LINUX struct utsname un; if(uname(&un) != -1) { mOSStringSimple.append(un.sysname); mOSStringSimple.append(" "); mOSStringSimple.append(un.release); mOSString = mOSStringSimple; mOSString.append(" "); mOSString.append(un.version); mOSString.append(" "); mOSString.append(un.machine); // Simplify 'Simple' std::string ostype = mOSStringSimple.substr(0, mOSStringSimple.find_first_of(" ", 0)); if (ostype == "Linux") { // Only care about major and minor Linux versions, truncate at second '.' std::string::size_type idx1 = mOSStringSimple.find_first_of(".", 0); std::string::size_type idx2 = (idx1 != std::string::npos) ? mOSStringSimple.find_first_of(".", idx1+1) : std::string::npos; std::string simple = mOSStringSimple.substr(0, idx2); if (simple.length() > 0) mOSStringSimple = simple; } } else { mOSStringSimple.append("Unable to collect OS info"); mOSString = mOSStringSimple; } const char OS_VERSION_MATCH_EXPRESSION[] = "([0-9]+)\\.([0-9]+)(\\.([0-9]+))?"; boost::regex os_version_parse(OS_VERSION_MATCH_EXPRESSION); boost::smatch matched; std::string glibc_version(gnu_get_libc_version()); if ( regex_match_no_exc(glibc_version, matched, os_version_parse) ) { LL_INFOS("AppInit") << "Using glibc version '" << glibc_version << "' as OS version" << LL_ENDL; std::string version_value; if ( matched[1].matched ) // Major version { version_value.assign(matched[1].first, matched[1].second); if (sscanf(version_value.c_str(), "%d", &mMajorVer) != 1) { LL_WARNS("AppInit") << "failed to parse major version '" << version_value << "' as a number" << LL_ENDL; } } else { LL_ERRS("AppInit") << "OS version regex '" << OS_VERSION_MATCH_EXPRESSION << "' returned true, but major version [1] did not match" << LL_ENDL; } if ( matched[2].matched ) // Minor version { version_value.assign(matched[2].first, matched[2].second); if (sscanf(version_value.c_str(), "%d", &mMinorVer) != 1) { LL_ERRS("AppInit") << "failed to parse minor version '" << version_value << "' as a number" << LL_ENDL; } } else { LL_ERRS("AppInit") << "OS version regex '" << OS_VERSION_MATCH_EXPRESSION << "' returned true, but minor version [1] did not match" << LL_ENDL; } if ( matched[4].matched ) // Build version (optional) - note that [3] includes the '.' { version_value.assign(matched[4].first, matched[4].second); if (sscanf(version_value.c_str(), "%d", &mBuild) != 1) { LL_ERRS("AppInit") << "failed to parse build version '" << version_value << "' as a number" << LL_ENDL; } } else { LL_INFOS("AppInit") << "OS build version not provided; using zero" << LL_ENDL; } } else { LL_WARNS("AppInit") << "glibc version '" << glibc_version << "' cannot be parsed to three numbers; using all zeros" << LL_ENDL; } #else struct utsname un; if(uname(&un) != -1) { mOSStringSimple.append(un.sysname); mOSStringSimple.append(" "); mOSStringSimple.append(un.release); mOSString = mOSStringSimple; mOSString.append(" "); mOSString.append(un.version); mOSString.append(" "); mOSString.append(un.machine); // Simplify 'Simple' std::string ostype = mOSStringSimple.substr(0, mOSStringSimple.find_first_of(" ", 0)); if (ostype == "Linux") { // Only care about major and minor Linux versions, truncate at second '.' std::string::size_type idx1 = mOSStringSimple.find_first_of(".", 0); std::string::size_type idx2 = (idx1 != std::string::npos) ? mOSStringSimple.find_first_of(".", idx1+1) : std::string::npos; std::string simple = mOSStringSimple.substr(0, idx2); if (simple.length() > 0) mOSStringSimple = simple; } } else { mOSStringSimple.append("Unable to collect OS info"); mOSString = mOSStringSimple; } #endif std::stringstream dotted_version_string; dotted_version_string << mMajorVer << "." << mMinorVer << "." << mBuild; mOSVersionString.append(dotted_version_string.str()); } #ifndef LL_WINDOWS // static S32 LLOSInfo::getMaxOpenFiles() { const S32 OPEN_MAX_GUESS = 256; #ifdef OPEN_MAX static S32 open_max = OPEN_MAX; #else static S32 open_max = 0; #endif if (0 == open_max) { // First time through. errno = 0; if ( (open_max = sysconf(_SC_OPEN_MAX)) < 0) { if (0 == errno) { // Indeterminate. open_max = OPEN_MAX_GUESS; } else { LL_ERRS() << "LLOSInfo::getMaxOpenFiles: sysconf error for _SC_OPEN_MAX" << LL_ENDL; } } } return open_max; } #endif void LLOSInfo::stream(std::ostream& s) const { s << mOSString; } const std::string& LLOSInfo::getOSString() const { return mOSString; } const std::string& LLOSInfo::getOSStringSimple() const { return mOSStringSimple; } const std::string& LLOSInfo::getOSVersionString() const { return mOSVersionString; } const S32 STATUS_SIZE = 8192; //static U32 LLOSInfo::getProcessVirtualSizeKB() { U32 virtual_size = 0; #if LL_WINDOWS #endif #if LL_LINUX LLFILE* status_filep = LLFile::fopen("/proc/self/status", "rb"); if (status_filep) { S32 numRead = 0; char buff[STATUS_SIZE]; /* Flawfinder: ignore */ size_t nbytes = fread(buff, 1, STATUS_SIZE-1, status_filep); buff[nbytes] = '\0'; // All these guys return numbers in KB char *memp = strstr(buff, "VmSize:"); if (memp) { numRead += sscanf(memp, "%*s %u", &virtual_size); } fclose(status_filep); } #elif LL_SOLARIS char proc_ps[LL_MAX_PATH]; sprintf(proc_ps, "/proc/%d/psinfo", (int)getpid()); int proc_fd = -1; if((proc_fd = open(proc_ps, O_RDONLY)) == -1){ LL_WARNS() << "unable to open " << proc_ps << LL_ENDL; return 0; } psinfo_t proc_psinfo; if(read(proc_fd, &proc_psinfo, sizeof(psinfo_t)) != sizeof(psinfo_t)){ LL_WARNS() << "Unable to read " << proc_ps << LL_ENDL; close(proc_fd); return 0; } close(proc_fd); virtual_size = proc_psinfo.pr_size; #endif return virtual_size; } //static U32 LLOSInfo::getProcessResidentSizeKB() { U32 resident_size = 0; #if LL_WINDOWS #endif #if LL_LINUX LLFILE* status_filep = LLFile::fopen("/proc/self/status", "rb"); if (status_filep != NULL) { S32 numRead = 0; char buff[STATUS_SIZE]; /* Flawfinder: ignore */ size_t nbytes = fread(buff, 1, STATUS_SIZE-1, status_filep); buff[nbytes] = '\0'; // All these guys return numbers in KB char *memp = strstr(buff, "VmRSS:"); if (memp) { numRead += sscanf(memp, "%*s %u", &resident_size); } fclose(status_filep); } #elif LL_SOLARIS char proc_ps[LL_MAX_PATH]; sprintf(proc_ps, "/proc/%d/psinfo", (int)getpid()); int proc_fd = -1; if((proc_fd = open(proc_ps, O_RDONLY)) == -1){ LL_WARNS() << "unable to open " << proc_ps << LL_ENDL; return 0; } psinfo_t proc_psinfo; if(read(proc_fd, &proc_psinfo, sizeof(psinfo_t)) != sizeof(psinfo_t)){ LL_WARNS() << "Unable to read " << proc_ps << LL_ENDL; close(proc_fd); return 0; } close(proc_fd); resident_size = proc_psinfo.pr_rssize; #endif return resident_size; } LLCPUInfo::LLCPUInfo() { std::ostringstream out; LLProcessorInfo proc; // proc.WriteInfoTextFile("procInfo.txt"); mHasSSE = proc.hasSSE(); mHasSSE2 = proc.hasSSE2(); mHasAltivec = proc.hasAltivec(); mCPUMHz = (F64)proc.getCPUFrequency(); mFamily = proc.getCPUFamilyName(); mCPUString = "Unknown"; out << proc.getCPUBrandName(); if (200 < mCPUMHz && mCPUMHz < 10000) // *NOTE: cpu speed is often way wrong, do a sanity check { out << " (" << mCPUMHz << " MHz)"; } mCPUString = out.str(); LLStringUtil::trim(mCPUString); } bool LLCPUInfo::hasAltivec() const { return mHasAltivec; } bool LLCPUInfo::hasSSE() const { return mHasSSE; } bool LLCPUInfo::hasSSE2() const { return mHasSSE2; } F64 LLCPUInfo::getMHz() const { return mCPUMHz; } std::string LLCPUInfo::getCPUString() const { return mCPUString; } void LLCPUInfo::stream(std::ostream& s) const { // gather machine information. s << LLProcessorInfo().getCPUFeatureDescription(); // These are interesting as they reflect our internal view of the // CPU's attributes regardless of platform s << "->mHasSSE: " << (U32)mHasSSE << std::endl; s << "->mHasSSE2: " << (U32)mHasSSE2 << std::endl; s << "->mHasAltivec: " << (U32)mHasAltivec << std::endl; s << "->mCPUMHz: " << mCPUMHz << std::endl; s << "->mCPUString: " << mCPUString << std::endl; } // Helper class for LLMemoryInfo: accumulate stats in the form we store for // LLMemoryInfo::getStatsMap(). class Stats { public: Stats(): mStats(LLSD::emptyMap()) {} // Store every integer type as LLSD::Integer. template void add(const LLSD::String& name, const T& value, typename boost::enable_if >::type* = 0) { mStats[name] = LLSD::Integer(value); } // Store every floating-point type as LLSD::Real. template void add(const LLSD::String& name, const T& value, typename boost::enable_if >::type* = 0) { mStats[name] = LLSD::Real(value); } // Hope that LLSD::Date values are sufficiently unambiguous. void add(const LLSD::String& name, const LLSD::Date& value) { mStats[name] = value; } LLSD get() const { return mStats; } private: LLSD mStats; }; LLMemoryInfo::LLMemoryInfo() { refresh(); } #if LL_WINDOWS static U32 LLMemoryAdjustKBResult(U32 inKB) { // Moved this here from llfloaterabout.cpp //! \bug // For some reason, the reported amount of memory is always wrong. // The original adjustment assumes it's always off by one meg, however // errors of as much as 2520 KB have been observed in the value // returned from the GetMemoryStatusEx function. Here we keep the // original adjustment from llfoaterabout.cpp until this can be // fixed somehow. inKB += 1024; return inKB; } #endif U32 LLMemoryInfo::getPhysicalMemoryKB() const { #if LL_WINDOWS return LLMemoryAdjustKBResult(mStatsMap["Total Physical KB"].asInteger()); #elif LL_DARWIN // This might work on Linux as well. Someone check... uint64_t phys = 0; int mib[2] = { CTL_HW, HW_MEMSIZE }; size_t len = sizeof(phys); sysctl(mib, 2, &phys, &len, NULL, 0); return (U32)(phys >> 10); #elif LL_LINUX U64 phys = 0; phys = (U64)(getpagesize()) * (U64)(get_phys_pages()); return (U32)(phys >> 10); #elif LL_SOLARIS U64 phys = 0; phys = (U64)(getpagesize()) * (U64)(sysconf(_SC_PHYS_PAGES)); return (U32)(phys >> 10); #else return 0; #endif } U32 LLMemoryInfo::getPhysicalMemoryClamped() const { // Return the total physical memory in bytes, but clamp it // to no more than U32_MAX U32 phys_kb = getPhysicalMemoryKB(); if (phys_kb >= 4194304 /* 4GB in KB */) { return U32_MAX; } else { return phys_kb << 10; } } //static void LLMemoryInfo::getAvailableMemoryKB(U32& avail_physical_mem_kb, U32& avail_virtual_mem_kb) { #if LL_WINDOWS // Sigh, this shouldn't be a static method, then we wouldn't have to // reload this data separately from refresh() LLSD statsMap(loadStatsMap()); avail_physical_mem_kb = statsMap["Avail Physical KB"].asInteger(); avail_virtual_mem_kb = statsMap["Avail Virtual KB"].asInteger(); #elif LL_DARWIN // mStatsMap is derived from vm_stat, look for (e.g.) "kb free": // $ vm_stat // Mach Virtual Memory Statistics: (page size of 4096 bytes) // Pages free: 462078. // Pages active: 142010. // Pages inactive: 220007. // Pages wired down: 159552. // "Translation faults": 220825184. // Pages copy-on-write: 2104153. // Pages zero filled: 167034876. // Pages reactivated: 65153. // Pageins: 2097212. // Pageouts: 41759. // Object cache: 841598 hits of 7629869 lookups (11% hit rate) avail_physical_mem_kb = -1 ; avail_virtual_mem_kb = -1 ; #elif LL_LINUX // mStatsMap is derived from MEMINFO_FILE: // $ cat /proc/meminfo // MemTotal: 4108424 kB // MemFree: 1244064 kB // Buffers: 85164 kB // Cached: 1990264 kB // SwapCached: 0 kB // Active: 1176648 kB // Inactive: 1427532 kB // Active(anon): 529152 kB // Inactive(anon): 15924 kB // Active(file): 647496 kB // Inactive(file): 1411608 kB // Unevictable: 16 kB // Mlocked: 16 kB // HighTotal: 3266316 kB // HighFree: 721308 kB // LowTotal: 842108 kB // LowFree: 522756 kB // SwapTotal: 6384632 kB // SwapFree: 6384632 kB // Dirty: 28 kB // Writeback: 0 kB // AnonPages: 528820 kB // Mapped: 89472 kB // Shmem: 16324 kB // Slab: 159624 kB // SReclaimable: 145168 kB // SUnreclaim: 14456 kB // KernelStack: 2560 kB // PageTables: 5560 kB // NFS_Unstable: 0 kB // Bounce: 0 kB // WritebackTmp: 0 kB // CommitLimit: 8438844 kB // Committed_AS: 1271596 kB // VmallocTotal: 122880 kB // VmallocUsed: 65252 kB // VmallocChunk: 52356 kB // HardwareCorrupted: 0 kB // HugePages_Total: 0 // HugePages_Free: 0 // HugePages_Rsvd: 0 // HugePages_Surp: 0 // Hugepagesize: 2048 kB // DirectMap4k: 434168 kB // DirectMap2M: 477184 kB // (could also run 'free', but easier to read a file than run a program) avail_physical_mem_kb = -1 ; avail_virtual_mem_kb = -1 ; #else //do not know how to collect available memory info for other systems. //leave it blank here for now. avail_physical_mem_kb = -1 ; avail_virtual_mem_kb = -1 ; #endif } void LLMemoryInfo::stream(std::ostream& s) const { // We want these memory stats to be easy to grep from the log, along with // the timestamp. So preface each line with the timestamp and a // distinctive marker. Without that, we'd have to search the log for the // introducer line, then read subsequent lines, etc... std::string pfx(LLError::utcTime() + " "); // Max key length size_t key_width(0); BOOST_FOREACH(const MapEntry& pair, inMap(mStatsMap)) { size_t len(pair.first.length()); if (len > key_width) { key_width = len; } } // Now stream stats BOOST_FOREACH(const MapEntry& pair, inMap(mStatsMap)) { s << pfx << std::setw(key_width+1) << (pair.first + ':') << ' '; LLSD value(pair.second); if (value.isInteger()) s << std::setw(12) << value.asInteger(); else if (value.isReal()) s << std::fixed << std::setprecision(1) << value.asReal(); else if (value.isDate()) value.asDate().toStream(s); else s << value; // just use default LLSD formatting s << std::endl; } } LLSD LLMemoryInfo::getStatsMap() const { return mStatsMap; } LLMemoryInfo& LLMemoryInfo::refresh() { mStatsMap = loadStatsMap(); LL_DEBUGS("LLMemoryInfo") << "Populated mStatsMap:\n"; LLSDSerialize::toPrettyXML(mStatsMap, LL_CONT); LL_ENDL; return *this; } LLSD LLMemoryInfo::loadStatsMap() { // This implementation is derived from stream() code (as of 2011-06-29). Stats stats; // associate timestamp for analysis over time stats.add("timestamp", LLDate::now()); #if LL_WINDOWS MEMORYSTATUSEX state; state.dwLength = sizeof(state); GlobalMemoryStatusEx(&state); DWORDLONG div = 1024; stats.add("Percent Memory use", state.dwMemoryLoad/div); stats.add("Total Physical KB", state.ullTotalPhys/div); stats.add("Avail Physical KB", state.ullAvailPhys/div); stats.add("Total page KB", state.ullTotalPageFile/div); stats.add("Avail page KB", state.ullAvailPageFile/div); stats.add("Total Virtual KB", state.ullTotalVirtual/div); stats.add("Avail Virtual KB", state.ullAvailVirtual/div); PERFORMANCE_INFORMATION perf; perf.cb = sizeof(perf); GetPerformanceInfo(&perf, sizeof(perf)); SIZE_T pagekb(perf.PageSize/1024); stats.add("CommitTotal KB", perf.CommitTotal * pagekb); stats.add("CommitLimit KB", perf.CommitLimit * pagekb); stats.add("CommitPeak KB", perf.CommitPeak * pagekb); stats.add("PhysicalTotal KB", perf.PhysicalTotal * pagekb); stats.add("PhysicalAvail KB", perf.PhysicalAvailable * pagekb); stats.add("SystemCache KB", perf.SystemCache * pagekb); stats.add("KernelTotal KB", perf.KernelTotal * pagekb); stats.add("KernelPaged KB", perf.KernelPaged * pagekb); stats.add("KernelNonpaged KB", perf.KernelNonpaged * pagekb); stats.add("PageSize KB", pagekb); stats.add("HandleCount", perf.HandleCount); stats.add("ProcessCount", perf.ProcessCount); stats.add("ThreadCount", perf.ThreadCount); PROCESS_MEMORY_COUNTERS_EX pmem; pmem.cb = sizeof(pmem); // GetProcessMemoryInfo() is documented to accept either // PROCESS_MEMORY_COUNTERS* or PROCESS_MEMORY_COUNTERS_EX*, presumably // using the redundant size info to distinguish. But its prototype // specifically accepts PROCESS_MEMORY_COUNTERS*, and since this is a // classic-C API, PROCESS_MEMORY_COUNTERS_EX isn't a subclass. Cast the // pointer. GetProcessMemoryInfo(GetCurrentProcess(), PPROCESS_MEMORY_COUNTERS(&pmem), sizeof(pmem)); stats.add("Page Fault Count", pmem.PageFaultCount); stats.add("PeakWorkingSetSize KB", pmem.PeakWorkingSetSize/div); stats.add("WorkingSetSize KB", pmem.WorkingSetSize/div); stats.add("QutaPeakPagedPoolUsage KB", pmem.QuotaPeakPagedPoolUsage/div); stats.add("QuotaPagedPoolUsage KB", pmem.QuotaPagedPoolUsage/div); stats.add("QuotaPeakNonPagedPoolUsage KB", pmem.QuotaPeakNonPagedPoolUsage/div); stats.add("QuotaNonPagedPoolUsage KB", pmem.QuotaNonPagedPoolUsage/div); stats.add("PagefileUsage KB", pmem.PagefileUsage/div); stats.add("PeakPagefileUsage KB", pmem.PeakPagefileUsage/div); stats.add("PrivateUsage KB", pmem.PrivateUsage/div); #elif LL_DARWIN const vm_size_t pagekb(vm_page_size / 1024); // // Collect the vm_stat's // { vm_statistics_data_t vmstat; mach_msg_type_number_t vmstatCount = HOST_VM_INFO_COUNT; if (host_statistics(mach_host_self(), HOST_VM_INFO, (host_info_t) &vmstat, &vmstatCount) != KERN_SUCCESS) { LL_WARNS("LLMemoryInfo") << "Unable to collect memory information" << LL_ENDL; } else { stats.add("Pages free KB", pagekb * vmstat.free_count); stats.add("Pages active KB", pagekb * vmstat.active_count); stats.add("Pages inactive KB", pagekb * vmstat.inactive_count); stats.add("Pages wired KB", pagekb * vmstat.wire_count); stats.add("Pages zero fill", vmstat.zero_fill_count); stats.add("Page reactivations", vmstat.reactivations); stats.add("Page-ins", vmstat.pageins); stats.add("Page-outs", vmstat.pageouts); stats.add("Faults", vmstat.faults); stats.add("Faults copy-on-write", vmstat.cow_faults); stats.add("Cache lookups", vmstat.lookups); stats.add("Cache hits", vmstat.hits); stats.add("Page purgeable count", vmstat.purgeable_count); stats.add("Page purges", vmstat.purges); stats.add("Page speculative reads", vmstat.speculative_count); } } // // Collect the misc task info // { task_events_info_data_t taskinfo; unsigned taskinfoSize = sizeof(taskinfo); if (task_info(mach_task_self(), TASK_EVENTS_INFO, (task_info_t) &taskinfo, &taskinfoSize) != KERN_SUCCESS) { LL_WARNS("LLMemoryInfo") << "Unable to collect task information" << LL_ENDL; } else { stats.add("Task page-ins", taskinfo.pageins); stats.add("Task copy-on-write faults", taskinfo.cow_faults); stats.add("Task messages sent", taskinfo.messages_sent); stats.add("Task messages received", taskinfo.messages_received); stats.add("Task mach system call count", taskinfo.syscalls_mach); stats.add("Task unix system call count", taskinfo.syscalls_unix); stats.add("Task context switch count", taskinfo.csw); } } // // Collect the basic task info // { task_basic_info_64_data_t taskinfo; unsigned taskinfoSize = sizeof(taskinfo); if (task_info(mach_task_self(), TASK_BASIC_INFO_64, (task_info_t) &taskinfo, &taskinfoSize) != KERN_SUCCESS) { LL_WARNS("LLMemoryInfo") << "Unable to collect task information" << LL_ENDL; } else { stats.add("Basic suspend count", taskinfo.suspend_count); stats.add("Basic virtual memory KB", taskinfo.virtual_size / 1024); stats.add("Basic resident memory KB", taskinfo.resident_size / 1024); stats.add("Basic new thread policy", taskinfo.policy); } } #elif LL_SOLARIS U64 phys = 0; phys = (U64)(sysconf(_SC_PHYS_PAGES)) * (U64)(sysconf(_SC_PAGESIZE)/1024); stats.add("Total Physical KB", phys); #elif LL_LINUX std::ifstream meminfo(MEMINFO_FILE); if (meminfo.is_open()) { // MemTotal: 4108424 kB // MemFree: 1244064 kB // Buffers: 85164 kB // Cached: 1990264 kB // SwapCached: 0 kB // Active: 1176648 kB // Inactive: 1427532 kB // ... // VmallocTotal: 122880 kB // VmallocUsed: 65252 kB // VmallocChunk: 52356 kB // HardwareCorrupted: 0 kB // HugePages_Total: 0 // HugePages_Free: 0 // HugePages_Rsvd: 0 // HugePages_Surp: 0 // Hugepagesize: 2048 kB // DirectMap4k: 434168 kB // DirectMap2M: 477184 kB // Intentionally don't pass the boost::no_except flag. This // boost::regex object is constructed with a string literal, so it // should be valid every time. If it becomes invalid, we WANT an // exception, hopefully even before the dev checks in. boost::regex stat_rx("(.+): +([0-9]+)( kB)?"); boost::smatch matched; std::string line; while (std::getline(meminfo, line)) { LL_DEBUGS("LLMemoryInfo") << line << LL_ENDL; if (regex_match_no_exc(line, matched, stat_rx)) { // e.g. "MemTotal: 4108424 kB" LLSD::String key(matched[1].first, matched[1].second); LLSD::String value_str(matched[2].first, matched[2].second); LLSD::Integer value(0); try { value = boost::lexical_cast(value_str); } catch (const boost::bad_lexical_cast&) { LL_WARNS("LLMemoryInfo") << "couldn't parse '" << value_str << "' in " << MEMINFO_FILE << " line: " << line << LL_ENDL; continue; } // Store this statistic. stats.add(key, value); } else { LL_WARNS("LLMemoryInfo") << "unrecognized " << MEMINFO_FILE << " line: " << line << LL_ENDL; } } } else { LL_WARNS("LLMemoryInfo") << "Unable to collect memory information" << LL_ENDL; } #else LL_WARNS("LLMemoryInfo") << "Unknown system; unable to collect memory information" << LL_ENDL; #endif return stats.get(); } std::ostream& operator<<(std::ostream& s, const LLOSInfo& info) { info.stream(s); return s; } std::ostream& operator<<(std::ostream& s, const LLCPUInfo& info) { info.stream(s); return s; } std::ostream& operator<<(std::ostream& s, const LLMemoryInfo& info) { info.stream(s); return s; } class FrameWatcher { public: FrameWatcher(): // Hooking onto the "mainloop" event pump gets us one call per frame. mConnection(LLEventPumps::instance() .obtain("mainloop") .listen("FrameWatcher", boost::bind(&FrameWatcher::tick, this, _1))), // Initializing mSampleStart to an invalid timestamp alerts us to skip // trying to compute framerate on the first call. mSampleStart(-1), // Initializing mSampleEnd to 0 ensures that we treat the first call // as the completion of a sample window. mSampleEnd(0), mFrames(0), // Both MEM_INFO_WINDOW and MEM_INFO_THROTTLE are in seconds. We need // the number of integer MEM_INFO_THROTTLE sample slots that will fit // in MEM_INFO_WINDOW. Round up. mSamples(int((MEM_INFO_WINDOW / MEM_INFO_THROTTLE) + 0.7)), // Initializing to F32_MAX means that the first real frame will become // the slowest ever, which sounds like a good idea. mSlowest(F32_MAX) {} bool tick(const LLSD&) { F32 timestamp(mTimer.getElapsedTimeF32()); // Count this frame in the interval just completed. ++mFrames; // Have we finished a sample window yet? if (timestamp < mSampleEnd) { // no, just keep waiting return false; } // Set up for next sample window. Capture values for previous frame in // local variables and reset data members. U32 frames(mFrames); F32 sampleStart(mSampleStart); // No frames yet in next window mFrames = 0; // which starts right now mSampleStart = timestamp; // and ends MEM_INFO_THROTTLE seconds in the future mSampleEnd = mSampleStart + MEM_INFO_THROTTLE; // On the very first call, that's all we can do, no framerate // computation is possible. if (sampleStart < 0) { return false; } // How long did this actually take? As framerate slows, the duration // of the frame we just finished could push us WELL beyond our desired // sample window size. F32 elapsed(timestamp - sampleStart); F32 framerate(frames/elapsed); // Remember previous slowest framerate because we're just about to // update it. F32 slowest(mSlowest); // Remember previous number of samples. boost::circular_buffer::size_type prevSize(mSamples.size()); // Capture new framerate in our samples buffer. Once the buffer is // full (after MEM_INFO_WINDOW seconds), this will displace the oldest // sample. ("So they all rolled over, and one fell out...") mSamples.push_back(framerate); // Calculate the new minimum framerate. I know of no way to update a // rolling minimum without ever rescanning the buffer. But since there // are only a few tens of items in this buffer, rescanning it is // probably cheaper (and certainly easier to reason about) than // attempting to optimize away some of the scans. mSlowest = framerate; // pick an arbitrary entry to start for (boost::circular_buffer::const_iterator si(mSamples.begin()), send(mSamples.end()); si != send; ++si) { if (*si < mSlowest) { mSlowest = *si; } } // We're especially interested in memory as framerate drops. Only log // when framerate drops below the slowest framerate we remember. // (Should always be true for the end of the very first sample // window.) if (framerate >= slowest) { return false; } // Congratulations, we've hit a new low. :-P LL_INFOS("FrameWatcher") << ' '; if (! prevSize) { LL_CONT << "initial framerate "; } else { LL_CONT << "slowest framerate for last " << int(prevSize * MEM_INFO_THROTTLE) << " seconds "; } S32 precision = LL_CONT.precision(); LL_CONT << std::fixed << std::setprecision(1) << framerate << '\n' << LLMemoryInfo(); LL_CONT.precision(precision); LL_CONT << LL_ENDL; return false; } private: // Storing the connection in an LLTempBoundListener ensures it will be // disconnected when we're destroyed. LLTempBoundListener mConnection; // Track elapsed time LLTimer mTimer; // Some of what you see here is in fact redundant with functionality you // can get from LLTimer. Unfortunately the LLTimer API is missing the // feature we need: has at least the stated interval elapsed, and if so, // exactly how long has passed? So we have to do it by hand, sigh. // Time at start, end of sample window F32 mSampleStart, mSampleEnd; // Frames this sample window U32 mFrames; // Sliding window of framerate samples boost::circular_buffer mSamples; // Slowest framerate in mSamples F32 mSlowest; }; // Need an instance of FrameWatcher before it does any good static FrameWatcher sFrameWatcher; BOOL gunzip_file(const std::string& srcfile, const std::string& dstfile) { std::string tmpfile; const S32 UNCOMPRESS_BUFFER_SIZE = 32768; BOOL retval = FALSE; gzFile src = NULL; U8 buffer[UNCOMPRESS_BUFFER_SIZE]; LLFILE *dst = NULL; S32 bytes = 0; tmpfile = dstfile + ".t"; src = gzopen(srcfile.c_str(), "rb"); if (! src) goto err; dst = LLFile::fopen(tmpfile, "wb"); /* Flawfinder: ignore */ if (! dst) goto err; do { bytes = gzread(src, buffer, UNCOMPRESS_BUFFER_SIZE); size_t nwrit = fwrite(buffer, sizeof(U8), bytes, dst); if (nwrit < (size_t) bytes) { LL_WARNS() << "Short write on " << tmpfile << ": Wrote " << nwrit << " of " << bytes << " bytes." << LL_ENDL; goto err; } } while(gzeof(src) == 0); fclose(dst); dst = NULL; if (LLFile::rename(tmpfile, dstfile) == -1) goto err; /* Flawfinder: ignore */ retval = TRUE; err: if (src != NULL) gzclose(src); if (dst != NULL) fclose(dst); return retval; } BOOL gzip_file(const std::string& srcfile, const std::string& dstfile) { const S32 COMPRESS_BUFFER_SIZE = 32768; std::string tmpfile; BOOL retval = FALSE; U8 buffer[COMPRESS_BUFFER_SIZE]; gzFile dst = NULL; LLFILE *src = NULL; S32 bytes = 0; tmpfile = dstfile + ".t"; dst = gzopen(tmpfile.c_str(), "wb"); /* Flawfinder: ignore */ if (! dst) goto err; src = LLFile::fopen(srcfile, "rb"); /* Flawfinder: ignore */ if (! src) goto err; while ((bytes = (S32)fread(buffer, sizeof(U8), COMPRESS_BUFFER_SIZE, src)) > 0) { if (gzwrite(dst, buffer, bytes) <= 0) { LL_WARNS() << "gzwrite failed: " << gzerror(dst, NULL) << LL_ENDL; goto err; } } if (ferror(src)) { LL_WARNS() << "Error reading " << srcfile << LL_ENDL; goto err; } gzclose(dst); dst = NULL; #if LL_WINDOWS // Rename in windows needs the dstfile to not exist. LLFile::remove(dstfile); #endif if (LLFile::rename(tmpfile, dstfile) == -1) goto err; /* Flawfinder: ignore */ retval = TRUE; err: if (src != NULL) fclose(src); if (dst != NULL) gzclose(dst); return retval; }