#include "utils.h" #include "uint256.h" #include #include #include #include #include #include void getRand(unsigned char *buf, int num) { if (RAND_bytes(buf, num) != 1) { assert(false); throw std::runtime_error("Entropy pool not seeded"); } } // // Time support // We have our own epoch. // boost::posix_time::ptime ptEpoch() { return boost::posix_time::ptime(boost::gregorian::date(2000, boost::gregorian::Jan, 1)); } int iToSeconds(boost::posix_time::ptime ptWhen) { return ptWhen.is_not_a_date_time() ? -1 : (ptWhen-ptEpoch()).total_seconds(); } // Convert our time in seconds to a ptime. boost::posix_time::ptime ptFromSeconds(int iSeconds) { return iSeconds < 0 ? boost::posix_time::ptime(boost::posix_time::not_a_date_time) : ptEpoch() + boost::posix_time::seconds(iSeconds); } // Convert from our time to UNIX time in seconds. uint64_t utFromSeconds(int iSeconds) { boost::posix_time::time_duration tdDelta = boost::posix_time::ptime(boost::gregorian::date(2000, boost::gregorian::Jan, 1)) -boost::posix_time::ptime(boost::gregorian::date(1970, boost::gregorian::Jan, 1)) +boost::posix_time::seconds(iSeconds) ; return tdDelta.total_seconds(); } // // Hex suport // char charHex(int iDigit) { return iDigit < 10 ? '0' + iDigit : 'A' - 10 + iDigit; } int charUnHex(char cDigit) { return cDigit >= '0' && cDigit <= '9' ? cDigit - '0' : cDigit >= 'A' && cDigit <= 'F' ? cDigit - 'A' + 10 : cDigit >= 'a' && cDigit <= 'f' ? cDigit - 'a' + 10 : -1; } int strUnHex(std::string& strDst, const std::string& strSrc) { int iBytes = (strSrc.size()+1)/2; strDst.resize(iBytes); const char* pSrc = &strSrc[0]; char* pDst = &strDst[0]; if (strSrc.size() & 1) { int c = charUnHex(*pSrc++); if (c < 0) { iBytes = -1; } else { *pDst++ = c; } } for (int i=0; iBytes >= 0 && i != iBytes; i++) { int cHigh = charUnHex(*pSrc++); int cLow = charUnHex(*pSrc++); if (cHigh < 0 || cLow < 0) { iBytes = -1; } else { strDst[i] = (cHigh << 4) | cLow; } } if (iBytes < 0) strDst.clear(); return iBytes; } std::vector strUnHex(const std::string& strSrc) { std::string strTmp; strUnHex(strTmp, strSrc); return strCopy(strTmp); } uint64_t uintFromHex(const std::string& strSrc) { uint64_t uValue = 0; BOOST_FOREACH(char c, strSrc) uValue = (uValue << 4) | charUnHex(c); return uValue; } // // Misc string // std::vector strCopy(const std::string& strSrc) { std::vector vucDst; vucDst.resize(strSrc.size()); std::copy(strSrc.begin(), strSrc.end(), vucDst.begin()); return vucDst; } std::string strCopy(const std::vector& vucSrc) { std::string strDst; strDst.resize(vucSrc.size()); std::copy(vucSrc.begin(), vucSrc.end(), strDst.begin()); return strDst; } // // DH support // std::string DH_der_gen(int iKeyLength) { DH* dh = 0; int iCodes; std::string strDer; do { dh = DH_generate_parameters(iKeyLength, DH_GENERATOR_5, NULL, NULL); iCodes = 0; DH_check(dh, &iCodes); } while (iCodes & (DH_CHECK_P_NOT_PRIME|DH_CHECK_P_NOT_SAFE_PRIME|DH_UNABLE_TO_CHECK_GENERATOR|DH_NOT_SUITABLE_GENERATOR)); strDer.resize(i2d_DHparams(dh, NULL)); unsigned char* next = reinterpret_cast(&strDer[0]); (void) i2d_DHparams(dh, &next); return strDer; } DH* DH_der_load(const std::string& strDer) { const unsigned char *pbuf = reinterpret_cast(&strDer[0]); return d2i_DHparams(NULL, &pbuf, strDer.size()); } // // IP Port parsing // // <-- iPort: "" = -1 bool parseIpPort(const std::string& strSource, std::string& strIP, int& iPort) { boost::smatch smMatch; bool bValid = false; static boost::regex reEndpoint("\\`\\s*(\\S+)(?:\\s+(\\d+))?\\s*\\'"); if (boost::regex_match(strSource, smMatch, reEndpoint)) { boost::system::error_code err; std::string strIPRaw = smMatch[1]; std::string strPortRaw = smMatch[2]; boost::asio::ip::address addrIP = boost::asio::ip::address::from_string(strIPRaw, err); bValid = !err; if (bValid) { strIP = addrIP.to_string(); iPort = strPortRaw.empty() ? -1 : boost::lexical_cast(strPortRaw); } } return bValid; } bool parseUrl(const std::string& strUrl, std::string& strScheme, std::string& strDomain, int& iPort, std::string& strPath) { // scheme://username:password@hostname:port/rest static boost::regex reUrl("(?i)\\`\\s*([[:alpha:]][-+.[:alpha:][:digit:]]*)://([^:/]+)(?::(\\d+))?(/.*)?\\s*?\\'"); boost::smatch smMatch; bool bMatch = boost::regex_match(strUrl, smMatch, reUrl); // Match status code. if (bMatch) { std::string strPort; strScheme = smMatch[1]; strDomain = smMatch[2]; strPort = smMatch[3]; strPath = smMatch[4]; boost::algorithm::to_lower(strScheme); iPort = strPort.empty() ? -1 : lexical_cast_s(strPort); // std::cerr << strUrl << " : " << bMatch << " : '" << strDomain << "' : '" << strPort << "' : " << iPort << " : '" << strPath << "'" << std::endl; } // std::cerr << strUrl << " : " << bMatch << " : '" << strDomain << "' : '" << strPath << "'" << std::endl; return bMatch; } // // Quality parsing // - integers as is. // - floats multiplied by a billion bool parseQuality(const std::string& strSource, uint32& uQuality) { uQuality = lexical_cast_s(strSource); if (!uQuality) { float fQuality = lexical_cast_s(strSource); if (fQuality) uQuality = (uint32)(QUALITY_ONE*fQuality); } return !!uQuality; } /* void intIPtoStr(int ip,std::string& retStr) { unsigned char bytes[4]; bytes[0] = ip & 0xFF; bytes[1] = (ip >> 8) & 0xFF; bytes[2] = (ip >> 16) & 0xFF; bytes[3] = (ip >> 24) & 0xFF; retStr=str(boost::format("%d.%d.%d.%d") % bytes[3] % bytes[2] % bytes[1] % bytes[0] ); } int strIPtoInt(std::string& ipStr) { } */ #ifdef WIN32 #define _WINSOCK_ #include //#include "Winsock2.h" //#include // from: http://stackoverflow.com/questions/3022552/is-there-any-standard-htonl-like-function-for-64-bits-integers-in-c // but we don't need to check the endianness uint64_t htobe64(uint64_t value) { // The answer is 42 //static const int num = 42; // Check the endianness //if (*reinterpret_cast(&num) == num) //{ const uint32_t high_part = htonl(static_cast(value >> 32)); const uint32_t low_part = htonl(static_cast(value & 0xFFFFFFFFLL)); return (static_cast(low_part) << 32) | high_part; //} else //{ // return value; //} } uint64_t be64toh(uint64_t value) { return(_byteswap_uint64(value)); } uint32_t htobe32(uint32_t value) { return(htonl(value)); } uint32_t be32toh(uint32_t value) { return( _byteswap_ulong(value)); } #endif BOOST_AUTO_TEST_SUITE( Utils) BOOST_AUTO_TEST_CASE( ParseUrl ) { std::string strScheme; std::string strDomain; int iPort; std::string strPath; if (!parseUrl("lower://domain", strScheme, strDomain, iPort, strPath)) BOOST_FAIL("parseUrl: lower://domain failed"); if (strScheme != "lower") BOOST_FAIL("parseUrl: lower://domain : scheme failed"); if (strDomain != "domain") BOOST_FAIL("parseUrl: lower://domain : domain failed"); if (iPort != -1) BOOST_FAIL("parseUrl: lower://domain : port failed"); if (strPath != "") BOOST_FAIL("parseUrl: lower://domain : path failed"); if (!parseUrl("UPPER://domain:234/", strScheme, strDomain, iPort, strPath)) BOOST_FAIL("parseUrl: UPPER://domain:234/ failed"); if (strScheme != "upper") BOOST_FAIL("parseUrl: UPPER://domain:234/ : scheme failed"); if (iPort != 234) BOOST_FAIL(boost::str(boost::format("parseUrl: UPPER://domain:234/ : port failed: %d") % iPort)); if (strPath != "/") BOOST_FAIL("parseUrl: UPPER://domain:234/ : path failed"); if (!parseUrl("Mixed://domain/path", strScheme, strDomain, iPort, strPath)) BOOST_FAIL("parseUrl: Mixed://domain/path failed"); if (strScheme != "mixed") BOOST_FAIL("parseUrl: Mixed://domain/path tolower failed"); if (strPath != "/path") BOOST_FAIL("parseUrl: Mixed://domain/path path failed"); } BOOST_AUTO_TEST_SUITE_END() // vim:ts=4