/* * ZeroTier One - Global Peer to Peer Ethernet * Copyright (C) 2012-2013 ZeroTier Networks LLC * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * * -- * * ZeroTier may be used and distributed under the terms of the GPLv3, which * are available at: http://www.gnu.org/licenses/gpl-3.0.html * * If you would like to embed ZeroTier into a commercial application or * redistribute it in a modified binary form, please contact ZeroTier Networks * LLC. Start here: http://www.zerotier.com/ */ #include #include #include #include #include #include "Constants.hpp" #ifdef __UNIX_LIKE__ #include #include #include #include #include #include #endif #include "Utils.hpp" #include "Mutex.hpp" #include "Salsa20.hpp" namespace ZeroTier { const char Utils::HEXCHARS[16] = { '0','1','2','3','4','5','6','7','8','9','a','b','c','d','e','f' }; std::map Utils::listDirectory(const char *path) { std::map r; #ifdef __WINDOWS__ HANDLE hFind; WIN32_FIND_DATAA ffd; if ((hFind = FindFirstFileA((std::string(path) + "\\*").c_str(),&ffd)) != INVALID_HANDLE_VALUE) { do { if ((strcmp(ffd.cFileName,"."))&&(strcmp(ffd.cFileName,".."))) r[std::string(ffd.cFileName)] = ((ffd.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY) != 0); } while (FindNextFileA(hFind,&ffd)); FindClose(hFind); } #else struct dirent de; struct dirent *dptr; DIR *d = opendir(path); if (!d) return r; dptr = (struct dirent *)0; for(;;) { if (readdir_r(d,&de,&dptr)) break; if (dptr) { if ((strcmp(dptr->d_name,"."))&&(strcmp(dptr->d_name,".."))) r[std::string(dptr->d_name)] = (dptr->d_type == DT_DIR); } else break; } #endif return r; } std::string Utils::hex(const void *data,unsigned int len) { std::string r; r.reserve(len * 2); for(unsigned int i=0;i> 4]); r.push_back(HEXCHARS[((const unsigned char *)data)[i] & 0x0f]); } return r; } std::string Utils::unhex(const char *hex) { int n = 1; unsigned char c,b = 0; std::string r; while ((c = (unsigned char)*(hex++))) { if ((c >= 48)&&(c <= 57)) { // 0..9 if ((n ^= 1)) r.push_back((char)(b | (c - 48))); else b = (c - 48) << 4; } else if ((c >= 65)&&(c <= 70)) { // A..F if ((n ^= 1)) r.push_back((char)(b | (c - (65 - 10)))); else b = (c - (65 - 10)) << 4; } else if ((c >= 97)&&(c <= 102)) { // a..f if ((n ^= 1)) r.push_back((char)(b | (c - (97 - 10)))); else b = (c - (97 - 10)) << 4; } } return r; } unsigned int Utils::unhex(const char *hex,void *buf,unsigned int len) { int n = 1; unsigned char c,b = 0; unsigned int l = 0; while ((c = (unsigned char)*(hex++))) { if ((c >= 48)&&(c <= 57)) { // 0..9 if ((n ^= 1)) { if (l >= len) break; ((unsigned char *)buf)[l++] = (b | (c - 48)); } else b = (c - 48) << 4; } else if ((c >= 65)&&(c <= 70)) { // A..F if ((n ^= 1)) { if (l >= len) break; ((unsigned char *)buf)[l++] = (b | (c - (65 - 10))); } else b = (c - (65 - 10)) << 4; } else if ((c >= 97)&&(c <= 102)) { // a..f if ((n ^= 1)) { if (l >= len) break; ((unsigned char *)buf)[l++] = (b | (c - (97 - 10))); } else b = (c - (97 - 10)) << 4; } } return l; } unsigned int Utils::unhex(const char *hex,unsigned int hexlen,void *buf,unsigned int len) { int n = 1; unsigned char c,b = 0; unsigned int l = 0; const char *const end = hex + hexlen; while (hex != end) { c = (unsigned char)*(hex++); if ((c >= 48)&&(c <= 57)) { // 0..9 if ((n ^= 1)) { if (l >= len) break; ((unsigned char *)buf)[l++] = (b | (c - 48)); } else b = (c - 48) << 4; } else if ((c >= 65)&&(c <= 70)) { // A..F if ((n ^= 1)) { if (l >= len) break; ((unsigned char *)buf)[l++] = (b | (c - (65 - 10))); } else b = (c - (65 - 10)) << 4; } else if ((c >= 97)&&(c <= 102)) { // a..f if ((n ^= 1)) { if (l >= len) break; ((unsigned char *)buf)[l++] = (b | (c - (97 - 10))); } else b = (c - (97 - 10)) << 4; } } return l; } void Utils::getSecureRandom(void *buf,unsigned int bytes) { static Mutex randomLock; static char randbuf[16384]; static unsigned int randptr = sizeof(randbuf); static Salsa20 s20; static bool randInitialized = false; Mutex::Lock _l(randomLock); // A Salsa20/8 instance is used to further mangle whatever our base // random source happens to be. if (!randInitialized) { randInitialized = true; memset(randbuf,0,sizeof(randbuf)); char s20key[33]; uint64_t s20iv = now(); Utils::snprintf(s20key,sizeof(s20key),"%.16llx%.16llx",(unsigned long long)now(),(unsigned long long)((void *)&s20iv)); s20.init(s20key,256,&s20iv,8); } for(unsigned int i=0;i= sizeof(randbuf)) { #ifdef __UNIX_LIKE__ { int fd = ::open("/dev/urandom",O_RDONLY); if (fd < 0) { fprintf(stderr,"FATAL ERROR: unable to open /dev/urandom%s",ZT_EOL_S); exit(-1); } if ((int)::read(fd,randbuf,sizeof(randbuf)) != (int)sizeof(randbuf)) { fprintf(stderr,"FATAL ERROR: unable to read from /dev/urandom%s",ZT_EOL_S); exit(-1); } ::close(fd); } #else #ifdef __WINDOWS__ { struct { double nowf; DWORD processId; DWORD tickCount; uint64_t nowi; char padding[32]; } keyMaterial; keyMaterial.nowf = Utils::nowf(); keyMaterial.processId = GetCurrentProcessId(); keyMaterial.tickCount = GetTickCount(); keyMaterial.nowi = Utils::now(); for(int i=0;i 0) buf.append(tmp,n); else break; } fclose(f); return true; } return false; } bool Utils::writeFile(const char *path,const void *buf,unsigned int len) { FILE *f = fopen(path,"wb"); if (f) { if ((long)fwrite(buf,1,len,f) != (long)len) { fclose(f); return false; } else { fclose(f); return true; } } return false; } std::vector Utils::split(const char *s,const char *const sep,const char *esc,const char *quot) { std::vector fields; std::string buf; if (!esc) esc = ""; if (!quot) quot = ""; bool escapeState = false; char quoteState = 0; while (*s) { if (escapeState) { escapeState = false; buf.push_back(*s); } else if (quoteState) { if (*s == quoteState) { quoteState = 0; fields.push_back(buf); buf.clear(); } else buf.push_back(*s); } else { const char *quotTmp; if (strchr(esc,*s)) escapeState = true; else if ((buf.size() <= 0)&&((quotTmp = strchr(quot,*s)))) quoteState = *quotTmp; else if (strchr(sep,*s)) { if (buf.size() > 0) { fields.push_back(buf); buf.clear(); } // else skip runs of seperators } else buf.push_back(*s); } ++s; } if (buf.size()) fields.push_back(buf); return fields; } std::string Utils::trim(const std::string &s) { unsigned long end = (unsigned long)s.length(); while (end) { char c = s[end - 1]; if ((c == ' ')||(c == '\r')||(c == '\n')||(!c)||(c == '\t')) --end; else break; } unsigned long start = 0; while (start < end) { char c = s[start]; if ((c == ' ')||(c == '\r')||(c == '\n')||(!c)||(c == '\t')) ++start; else break; } return s.substr(start,end - start); } void Utils::stdsprintf(std::string &s,const char *fmt,...) throw(std::bad_alloc,std::length_error) { char buf[65536]; va_list ap; va_start(ap,fmt); int n = vsnprintf(buf,sizeof(buf),fmt,ap); va_end(ap); if ((n >= (int)sizeof(buf))||(n < 0)) throw std::length_error("printf result too large"); s.append(buf); } unsigned int Utils::snprintf(char *buf,unsigned int len,const char *fmt,...) throw(std::length_error) { va_list ap; va_start(ap,fmt); int n = (int)vsnprintf(buf,len,fmt,ap); va_end(ap); if ((n >= (int)len)||(n < 0)) { if (len) buf[len - 1] = (char)0; throw std::length_error("buf[] overflow in Utils::snprintf"); } return (unsigned int)n; } } // namespace ZeroTier