// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2011 The Bitcoin developers // Distributed under the MIT/X11 software license, see the accompanying // file license.txt or http://www.opensource.org/licenses/mit-license.php. #ifndef BITCOIN_UTIL_H #define BITCOIN_UTIL_H #include "uint256.h" #ifndef __WXMSW__ #include #include #include #endif #include #include #include #include #include #include #include #include #include #if defined(_MSC_VER) || defined(__BORLANDC__) typedef __int64 int64; typedef unsigned __int64 uint64; #else typedef long long int64; typedef unsigned long long uint64; #endif #if defined(_MSC_VER) && _MSC_VER < 1300 #define for if (false) ; else for #endif #ifndef _MSC_VER #define __forceinline inline #endif #define loop for (;;) #define BEGIN(a) ((char*)&(a)) #define END(a) ((char*)&((&(a))[1])) #define UBEGIN(a) ((unsigned char*)&(a)) #define UEND(a) ((unsigned char*)&((&(a))[1])) #define ARRAYLEN(array) (sizeof(array)/sizeof((array)[0])) #define printf OutputDebugStringF #ifdef snprintf #undef snprintf #endif #define snprintf my_snprintf #ifndef PRI64d #if defined(_MSC_VER) || defined(__BORLANDC__) || defined(__MSVCRT__) #define PRI64d "I64d" #define PRI64u "I64u" #define PRI64x "I64x" #else #define PRI64d "lld" #define PRI64u "llu" #define PRI64x "llx" #endif #endif // This is needed because the foreach macro can't get over the comma in pair #define PAIRTYPE(t1, t2) std::pair // Align by increasing pointer, must have extra space at end of buffer template T* alignup(T* p) { union { T* ptr; size_t n; } u; u.ptr = p; u.n = (u.n + (nBytes-1)) & ~(nBytes-1); return u.ptr; } #ifdef __WXMSW__ #define MSG_NOSIGNAL 0 #define MSG_DONTWAIT 0 #ifndef UINT64_MAX #define UINT64_MAX _UI64_MAX #define INT64_MAX _I64_MAX #define INT64_MIN _I64_MIN #endif #ifndef S_IRUSR #define S_IRUSR 0400 #define S_IWUSR 0200 #endif #define unlink _unlink typedef int socklen_t; #else #define WSAGetLastError() errno #define WSAEINVAL EINVAL #define WSAEALREADY EALREADY #define WSAEWOULDBLOCK EWOULDBLOCK #define WSAEMSGSIZE EMSGSIZE #define WSAEINTR EINTR #define WSAEINPROGRESS EINPROGRESS #define WSAEADDRINUSE EADDRINUSE #define WSAENOTSOCK EBADF #define INVALID_SOCKET (SOCKET)(~0) #define SOCKET_ERROR -1 typedef u_int SOCKET; #define _vsnprintf(a,b,c,d) vsnprintf(a,b,c,d) #define strlwr(psz) to_lower(psz) #define _strlwr(psz) to_lower(psz) #define MAX_PATH 1024 #define Beep(n1,n2) (0) inline void Sleep(int64 n) { boost::thread::sleep(boost::get_system_time() + boost::posix_time::milliseconds(n)); } #endif inline int myclosesocket(SOCKET& hSocket) { if (hSocket == INVALID_SOCKET) return WSAENOTSOCK; #ifdef __WXMSW__ int ret = closesocket(hSocket); #else int ret = close(hSocket); #endif hSocket = INVALID_SOCKET; return ret; } #define closesocket(s) myclosesocket(s) #if !defined(QT_GUI) inline const char* _(const char* psz) { return psz; } #endif extern std::map mapArgs; extern std::map > mapMultiArgs; extern bool fDebug; extern bool fPrintToConsole; extern bool fPrintToDebugger; extern char pszSetDataDir[MAX_PATH]; extern bool fRequestShutdown; extern bool fShutdown; extern bool fDaemon; extern bool fServer; extern bool fCommandLine; extern std::string strMiscWarning; extern bool fTestNet; extern bool fNoListen; extern bool fLogTimestamps; void RandAddSeed(); void RandAddSeedPerfmon(); int OutputDebugStringF(const char* pszFormat, ...); int my_snprintf(char* buffer, size_t limit, const char* format, ...); std::string strprintf(const std::string &format, ...); bool error(const std::string &format, ...); void LogException(std::exception* pex, const char* pszThread); void PrintException(std::exception* pex, const char* pszThread); void PrintExceptionContinue(std::exception* pex, const char* pszThread); void ParseString(const std::string& str, char c, std::vector& v); std::string FormatMoney(int64 n, bool fPlus=false); bool ParseMoney(const std::string& str, int64& nRet); bool ParseMoney(const char* pszIn, int64& nRet); std::vector ParseHex(const char* psz); std::vector ParseHex(const std::string& str); void ParseParameters(int argc, char* argv[]); const char* wxGetTranslation(const char* psz); bool WildcardMatch(const char* psz, const char* mask); bool WildcardMatch(const std::string& str, const std::string& mask); int GetFilesize(FILE* file); void GetDataDir(char* pszDirRet); std::string GetConfigFile(); std::string GetPidFile(); void CreatePidFile(std::string pidFile, pid_t pid); void ReadConfigFile(std::map& mapSettingsRet, std::map >& mapMultiSettingsRet); #ifdef __WXMSW__ std::string MyGetSpecialFolderPath(int nFolder, bool fCreate); #endif std::string GetDefaultDataDir(); std::string GetDataDir(); void ShrinkDebugFile(); int GetRandInt(int nMax); uint64 GetRand(uint64 nMax); int64 GetTime(); void SetMockTime(int64 nMockTimeIn); int64 GetAdjustedTime(); void AddTimeData(unsigned int ip, int64 nTime); std::string FormatFullVersion(); // Wrapper to automatically initialize mutex class CCriticalSection { protected: boost::interprocess::interprocess_recursive_mutex mutex; public: explicit CCriticalSection() { } ~CCriticalSection() { } void Enter(const char* pszName, const char* pszFile, int nLine); void Leave(); bool TryEnter(const char* pszName, const char* pszFile, int nLine); }; // Automatically leave critical section when leaving block, needed for exception safety class CCriticalBlock { protected: CCriticalSection* pcs; public: CCriticalBlock(CCriticalSection& csIn, const char* pszName, const char* pszFile, int nLine) { pcs = &csIn; pcs->Enter(pszName, pszFile, nLine); } ~CCriticalBlock() { pcs->Leave(); } }; // WARNING: This will catch continue and break! // break is caught with an assertion, but there's no way to detect continue. // I'd rather be careful than suffer the other more error prone syntax. // The compiler will optimise away all this loop junk. #define CRITICAL_BLOCK(cs) \ for (bool fcriticalblockonce=true; fcriticalblockonce; assert(("break caught by CRITICAL_BLOCK!" && !fcriticalblockonce)), fcriticalblockonce=false) \ for (CCriticalBlock criticalblock(cs, #cs, __FILE__, __LINE__); fcriticalblockonce; fcriticalblockonce=false) class CTryCriticalBlock { protected: CCriticalSection* pcs; public: CTryCriticalBlock(CCriticalSection& csIn, const char* pszName, const char* pszFile, int nLine) { pcs = (csIn.TryEnter(pszName, pszFile, nLine) ? &csIn : NULL); } ~CTryCriticalBlock() { if (pcs) { pcs->Leave(); } } bool Entered() { return pcs != NULL; } }; #define TRY_CRITICAL_BLOCK(cs) \ for (bool fcriticalblockonce=true; fcriticalblockonce; assert(("break caught by TRY_CRITICAL_BLOCK!" && !fcriticalblockonce)), fcriticalblockonce=false) \ for (CTryCriticalBlock criticalblock(cs, #cs, __FILE__, __LINE__); fcriticalblockonce && (fcriticalblockonce = criticalblock.Entered()); fcriticalblockonce=false) inline std::string i64tostr(int64 n) { return strprintf("%"PRI64d, n); } inline std::string itostr(int n) { return strprintf("%d", n); } inline int64 atoi64(const char* psz) { #ifdef _MSC_VER return _atoi64(psz); #else return strtoll(psz, NULL, 10); #endif } inline int64 atoi64(const std::string& str) { #ifdef _MSC_VER return _atoi64(str.c_str()); #else return strtoll(str.c_str(), NULL, 10); #endif } inline int atoi(const std::string& str) { return atoi(str.c_str()); } inline int roundint(double d) { return (int)(d > 0 ? d + 0.5 : d - 0.5); } inline int64 roundint64(double d) { return (int64)(d > 0 ? d + 0.5 : d - 0.5); } inline int64 abs64(int64 n) { return (n >= 0 ? n : -n); } template std::string HexStr(const T itbegin, const T itend, bool fSpaces=false) { if (itbegin == itend) return ""; const unsigned char* pbegin = (const unsigned char*)&itbegin[0]; const unsigned char* pend = pbegin + (itend - itbegin) * sizeof(itbegin[0]); std::string str; str.reserve((pend-pbegin) * (fSpaces ? 3 : 2)); for (const unsigned char* p = pbegin; p != pend; p++) str += strprintf((fSpaces && p != pend-1 ? "%02x " : "%02x"), *p); return str; } inline std::string HexStr(const std::vector& vch, bool fSpaces=false) { return HexStr(vch.begin(), vch.end(), fSpaces); } template std::string HexNumStr(const T itbegin, const T itend, bool f0x=true) { if (itbegin == itend) return ""; const unsigned char* pbegin = (const unsigned char*)&itbegin[0]; const unsigned char* pend = pbegin + (itend - itbegin) * sizeof(itbegin[0]); std::string str = (f0x ? "0x" : ""); str.reserve(str.size() + (pend-pbegin) * 2); for (const unsigned char* p = pend-1; p >= pbegin; p--) str += strprintf("%02x", *p); return str; } inline std::string HexNumStr(const std::vector& vch, bool f0x=true) { return HexNumStr(vch.begin(), vch.end(), f0x); } template void PrintHex(const T pbegin, const T pend, const char* pszFormat="%s", bool fSpaces=true) { printf(pszFormat, HexStr(pbegin, pend, fSpaces).c_str()); } inline void PrintHex(const std::vector& vch, const char* pszFormat="%s", bool fSpaces=true) { printf(pszFormat, HexStr(vch, fSpaces).c_str()); } inline int64 GetPerformanceCounter() { int64 nCounter = 0; #ifdef __WXMSW__ QueryPerformanceCounter((LARGE_INTEGER*)&nCounter); #else timeval t; gettimeofday(&t, NULL); nCounter = t.tv_sec * 1000000 + t.tv_usec; #endif return nCounter; } inline int64 GetTimeMillis() { return (boost::posix_time::ptime(boost::posix_time::microsec_clock::universal_time()) - boost::posix_time::ptime(boost::gregorian::date(1970,1,1))).total_milliseconds(); } inline std::string DateTimeStrFormat(const char* pszFormat, int64 nTime) { time_t n = nTime; struct tm* ptmTime = gmtime(&n); char pszTime[200]; strftime(pszTime, sizeof(pszTime), pszFormat, ptmTime); return pszTime; } template void skipspaces(T& it) { while (isspace(*it)) ++it; } inline bool IsSwitchChar(char c) { #ifdef __WXMSW__ return c == '-' || c == '/'; #else return c == '-'; #endif } inline std::string GetArg(const std::string& strArg, const std::string& strDefault) { if (mapArgs.count(strArg)) return mapArgs[strArg]; return strDefault; } inline int64 GetArg(const std::string& strArg, int64 nDefault) { if (mapArgs.count(strArg)) return atoi64(mapArgs[strArg]); return nDefault; } inline bool GetBoolArg(const std::string& strArg) { if (mapArgs.count(strArg)) { if (mapArgs[strArg].empty()) return true; return (atoi(mapArgs[strArg]) != 0); } return false; } inline void heapchk() { #ifdef __WXMSW__ /// for debugging //if (_heapchk() != _HEAPOK) // DebugBreak(); #endif } // Randomize the stack to help protect against buffer overrun exploits #define IMPLEMENT_RANDOMIZE_STACK(ThreadFn) \ { \ static char nLoops; \ if (nLoops <= 0) \ nLoops = GetRand(20) + 1; \ if (nLoops-- > 1) \ { \ ThreadFn; \ return; \ } \ } #define CATCH_PRINT_EXCEPTION(pszFn) \ catch (std::exception& e) { \ PrintException(&e, (pszFn)); \ } catch (...) { \ PrintException(NULL, (pszFn)); \ } template inline uint256 Hash(const T1 pbegin, const T1 pend) { static unsigned char pblank[1]; uint256 hash1; SHA256((pbegin == pend ? pblank : (unsigned char*)&pbegin[0]), (pend - pbegin) * sizeof(pbegin[0]), (unsigned char*)&hash1); uint256 hash2; SHA256((unsigned char*)&hash1, sizeof(hash1), (unsigned char*)&hash2); return hash2; } template inline uint256 Hash(const T1 p1begin, const T1 p1end, const T2 p2begin, const T2 p2end) { static unsigned char pblank[1]; uint256 hash1; SHA256_CTX ctx; SHA256_Init(&ctx); SHA256_Update(&ctx, (p1begin == p1end ? pblank : (unsigned char*)&p1begin[0]), (p1end - p1begin) * sizeof(p1begin[0])); SHA256_Update(&ctx, (p2begin == p2end ? pblank : (unsigned char*)&p2begin[0]), (p2end - p2begin) * sizeof(p2begin[0])); SHA256_Final((unsigned char*)&hash1, &ctx); uint256 hash2; SHA256((unsigned char*)&hash1, sizeof(hash1), (unsigned char*)&hash2); return hash2; } template inline uint256 Hash(const T1 p1begin, const T1 p1end, const T2 p2begin, const T2 p2end, const T3 p3begin, const T3 p3end) { static unsigned char pblank[1]; uint256 hash1; SHA256_CTX ctx; SHA256_Init(&ctx); SHA256_Update(&ctx, (p1begin == p1end ? pblank : (unsigned char*)&p1begin[0]), (p1end - p1begin) * sizeof(p1begin[0])); SHA256_Update(&ctx, (p2begin == p2end ? pblank : (unsigned char*)&p2begin[0]), (p2end - p2begin) * sizeof(p2begin[0])); SHA256_Update(&ctx, (p3begin == p3end ? pblank : (unsigned char*)&p3begin[0]), (p3end - p3begin) * sizeof(p3begin[0])); SHA256_Final((unsigned char*)&hash1, &ctx); uint256 hash2; SHA256((unsigned char*)&hash1, sizeof(hash1), (unsigned char*)&hash2); return hash2; } template uint256 SerializeHash(const T& obj, int nType=SER_GETHASH, int nVersion=VERSION) { // Most of the time is spent allocating and deallocating CDataStream's // buffer. If this ever needs to be optimized further, make a CStaticStream // class with its buffer on the stack. CDataStream ss(nType, nVersion); ss.reserve(10000); ss << obj; return Hash(ss.begin(), ss.end()); } inline uint160 Hash160(const std::vector& vch) { uint256 hash1; SHA256(&vch[0], vch.size(), (unsigned char*)&hash1); uint160 hash2; RIPEMD160((unsigned char*)&hash1, sizeof(hash1), (unsigned char*)&hash2); return hash2; } // Median filter over a stream of values // Returns the median of the last N numbers template class CMedianFilter { private: std::vector vValues; std::vector vSorted; int nSize; public: CMedianFilter(int size, T initial_value): nSize(size) { vValues.reserve(size); vValues.push_back(initial_value); vSorted = vValues; } void input(T value) { if(vValues.size() == nSize) { vValues.erase(vValues.begin()); } vValues.push_back(value); vSorted.resize(vValues.size()); std::copy(vValues.begin(), vValues.end(), vSorted.begin()); std::sort(vSorted.begin(), vSorted.end()); } T median() const { int size = vSorted.size(); assert(size>0); if(size & 1) // Odd number of elements { return vSorted[size/2]; } else // Even number of elements { return (vSorted[size/2-1] + vSorted[size/2]) / 2; } } }; // Note: It turns out we might have been able to use boost::thread // by using TerminateThread(boost::thread.native_handle(), 0); #ifdef __WXMSW__ typedef HANDLE pthread_t; inline pthread_t CreateThread(void(*pfn)(void*), void* parg, bool fWantHandle=false) { DWORD nUnused = 0; HANDLE hthread = CreateThread( NULL, // default security 0, // inherit stack size from parent (LPTHREAD_START_ROUTINE)pfn, // function pointer parg, // argument 0, // creation option, start immediately &nUnused); // thread identifier if (hthread == NULL) { printf("Error: CreateThread() returned %d\n", GetLastError()); return (pthread_t)0; } if (!fWantHandle) { CloseHandle(hthread); return (pthread_t)-1; } return hthread; } inline void SetThreadPriority(int nPriority) { SetThreadPriority(GetCurrentThread(), nPriority); } #else inline pthread_t CreateThread(void(*pfn)(void*), void* parg, bool fWantHandle=false) { pthread_t hthread = 0; int ret = pthread_create(&hthread, NULL, (void*(*)(void*))pfn, parg); if (ret != 0) { printf("Error: pthread_create() returned %d\n", ret); return (pthread_t)0; } if (!fWantHandle) { pthread_detach(hthread); return (pthread_t)-1; } return hthread; } #define THREAD_PRIORITY_LOWEST PRIO_MAX #define THREAD_PRIORITY_BELOW_NORMAL 2 #define THREAD_PRIORITY_NORMAL 0 #define THREAD_PRIORITY_ABOVE_NORMAL 0 inline void SetThreadPriority(int nPriority) { // It's unclear if it's even possible to change thread priorities on Linux, // but we really and truly need it for the generation threads. #ifdef PRIO_THREAD setpriority(PRIO_THREAD, 0, nPriority); #else setpriority(PRIO_PROCESS, 0, nPriority); #endif } inline bool TerminateThread(pthread_t hthread, unsigned int nExitCode) { return (pthread_cancel(hthread) == 0); } inline void ExitThread(size_t nExitCode) { pthread_exit((void*)nExitCode); } #endif inline bool AffinityBugWorkaround(void(*pfn)(void*)) { #ifdef __WXMSW__ // Sometimes after a few hours affinity gets stuck on one processor DWORD dwProcessAffinityMask = -1; DWORD dwSystemAffinityMask = -1; GetProcessAffinityMask(GetCurrentProcess(), &dwProcessAffinityMask, &dwSystemAffinityMask); DWORD dwPrev1 = SetThreadAffinityMask(GetCurrentThread(), dwProcessAffinityMask); DWORD dwPrev2 = SetThreadAffinityMask(GetCurrentThread(), dwProcessAffinityMask); if (dwPrev2 != dwProcessAffinityMask) { printf("AffinityBugWorkaround() : SetThreadAffinityMask=%d, ProcessAffinityMask=%d, restarting thread\n", dwPrev2, dwProcessAffinityMask); if (!CreateThread(pfn, NULL)) printf("Error: CreateThread() failed\n"); return true; } #endif return false; } #endif