// // ZoneMinder General Utility Functions, $Date$, $Revision$ // Copyright (C) 2001-2008 Philip Coombes // // 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 2 // 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, write to the Free Software // Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. // //#include "zm_logger.h" #include "zm.h" #include "zm_utils.h" #include #include #include #include #include /* Definition of AT_* constants */ #include #if defined(__arm__) #include #endif #ifdef HAVE_CURL_CURL_H #include #endif unsigned int sse_version = 0; unsigned int neonversion = 0; std::string trimSet(std::string str, std::string trimset) { // Trim Both leading and trailing sets size_t startpos = str.find_first_not_of(trimset); // Find the first character position after excluding leading blank spaces size_t endpos = str.find_last_not_of(trimset); // Find the first character position from reverse af // if all spaces or empty return an empty string if ( ( std::string::npos == startpos ) || ( std::string::npos == endpos ) ) return std::string(""); return str.substr(startpos, endpos-startpos+1); } std::string trimSpaces(const std::string &str) { return trimSet(str, " \t"); } std::string replaceAll(std::string str, std::string from, std::string to) { if ( from.empty() ) return str; size_t start_pos = 0; while ( (start_pos = str.find(from, start_pos)) != std::string::npos ) { str.replace(start_pos, from.length(), to); start_pos += to.length(); // In case 'to' contains 'from', like replacing 'x' with 'yx' } return str; } const std::string stringtf( const char *format, ... ) { va_list ap; char tempBuffer[8192]; std::string tempString; va_start(ap, format); vsnprintf(tempBuffer, sizeof(tempBuffer), format , ap); va_end(ap); tempString = tempBuffer; return tempString; } const std::string stringtf(const std::string format, ...) { va_list ap; char tempBuffer[8192]; std::string tempString; va_start(ap, format); vsnprintf(tempBuffer, sizeof(tempBuffer), format.c_str(), ap); va_end(ap); tempString = tempBuffer; return tempString; } bool startsWith(const std::string &haystack, const std::string &needle) { return ( haystack.substr(0, needle.length()) == needle ); } StringVector split(const std::string &string, const std::string &chars, int limit) { StringVector stringVector; std::string tempString = string; std::string::size_type startIndex = 0; std::string::size_type endIndex = 0; //Info( "Looking for '%s' in '%s', limit %d", chars.c_str(), string.c_str(), limit ); do { // Find delimiters endIndex = string.find_first_of( chars, startIndex ); //Info( "Got endIndex at %d", endIndex ); if ( endIndex > 0 ) { //Info( "Adding '%s'", string.substr( startIndex, endIndex-startIndex ).c_str() ); stringVector.push_back( string.substr( startIndex, endIndex-startIndex ) ); } if ( endIndex == std::string::npos ) break; // Find non-delimiters startIndex = tempString.find_first_not_of( chars, endIndex ); if ( limit && (stringVector.size() == (unsigned int)(limit-1)) ) { stringVector.push_back( string.substr( startIndex ) ); break; } //Info( "Got new startIndex at %d", startIndex ); } while ( startIndex != std::string::npos ); //Info( "Finished with %d strings", stringVector.size() ); return stringVector; } const std::string join(const StringVector &v, const char * delim=",") { std::stringstream ss; for (size_t i = 0; i < v.size(); ++i) { if ( i != 0 ) ss << delim; ss << v[i]; } return ss.str(); } const std::string base64Encode(const std::string &inString) { static char base64_table[64] = { '\0' }; if ( !base64_table[0] ) { int i = 0; for ( char c = 'A'; c <= 'Z'; c++ ) base64_table[i++] = c; for ( char c = 'a'; c <= 'z'; c++ ) base64_table[i++] = c; for ( char c = '0'; c <= '9'; c++ ) base64_table[i++] = c; base64_table[i++] = '+'; base64_table[i++] = '/'; } std::string outString; outString.reserve(2 * inString.size()); const char *inPtr = inString.c_str(); while ( *inPtr ) { unsigned char selection = *inPtr >> 2; unsigned char remainder = (*inPtr++ & 0x03) << 4; outString += base64_table[selection]; if ( *inPtr ) { selection = remainder | (*inPtr >> 4); remainder = (*inPtr++ & 0x0f) << 2; outString += base64_table[selection]; if ( *inPtr ) { selection = remainder | (*inPtr >> 6); outString += base64_table[selection]; selection = (*inPtr++ & 0x3f); outString += base64_table[selection]; } else { outString += base64_table[remainder]; outString += '='; } } else { outString += base64_table[remainder]; outString += '='; outString += '='; } } return outString; } int split(const char* string, const char delim, std::vector& items) { if ( string == NULL ) return -1; if ( string[0] == 0 ) return -2; std::string str(string); while ( true ) { size_t pos = str.find(delim); items.push_back(str.substr(0, pos)); str.erase(0, pos+1); if ( pos == std::string::npos ) break; } return items.size(); } int pairsplit(const char* string, const char delim, std::string& name, std::string& value) { if ( string == NULL ) return -1; if ( string[0] == 0 ) return -2; std::string str(string); size_t pos = str.find(delim); if ( pos == std::string::npos || pos == 0 || pos >= str.length() ) return -3; name = str.substr(0, pos); value = str.substr(pos+1, std::string::npos); return 0; } /* Detect special hardware features, such as SIMD instruction sets */ void hwcaps_detect() { neonversion = 0; sse_version = 0; #if (defined(__i386__) || defined(__x86_64__)) /* x86 or x86-64 processor */ uint32_t r_edx, r_ecx, r_ebx; #ifdef __x86_64__ __asm__ __volatile__( "push %%rbx\n\t" "mov $0x0,%%ecx\n\t" "mov $0x7,%%eax\n\t" "cpuid\n\t" "push %%rbx\n\t" "mov $0x1,%%eax\n\t" "cpuid\n\t" "pop %%rax\n\t" "pop %%rbx\n\t" : "=d" (r_edx), "=c" (r_ecx), "=a" (r_ebx) : : ); #else __asm__ __volatile__( "push %%ebx\n\t" "mov $0x0,%%ecx\n\t" "mov $0x7,%%eax\n\t" "cpuid\n\t" "push %%ebx\n\t" "mov $0x1,%%eax\n\t" "cpuid\n\t" "pop %%eax\n\t" "pop %%ebx\n\t" : "=d" (r_edx), "=c" (r_ecx), "=a" (r_ebx) : : ); #endif if ( r_ebx & 0x00000020 ) { sse_version = 52; /* AVX2 */ Debug(1, "Detected a x86\\x86-64 processor with AVX2"); } else if ( r_ecx & 0x10000000 ) { sse_version = 51; /* AVX */ Debug(1, "Detected a x86\\x86-64 processor with AVX"); } else if ( r_ecx & 0x00100000 ) { sse_version = 42; /* SSE4.2 */ Debug(1, "Detected a x86\\x86-64 processor with SSE4.2"); } else if ( r_ecx & 0x00080000 ) { sse_version = 41; /* SSE4.1 */ Debug(1, "Detected a x86\\x86-64 processor with SSE4.1"); } else if ( r_ecx & 0x00000200 ) { sse_version = 35; /* SSSE3 */ Debug(1,"Detected a x86\\x86-64 processor with SSSE3"); } else if ( r_ecx & 0x00000001 ) { sse_version = 30; /* SSE3 */ Debug(1, "Detected a x86\\x86-64 processor with SSE3"); } else if ( r_edx & 0x04000000 ) { sse_version = 20; /* SSE2 */ Debug(1, "Detected a x86\\x86-64 processor with SSE2"); } else if ( r_edx & 0x02000000 ) { sse_version = 10; /* SSE */ Debug(1, "Detected a x86\\x86-64 processor with SSE"); } else { sse_version = 0; Debug(1, "Detected a x86\\x86-64 processor"); } #elif defined(__arm__) // ARM processor in 32bit mode // To see if it supports NEON, we need to get that information from the kernel unsigned long auxval = getauxval(AT_HWCAP); if (auxval & HWCAP_ARM_NEON) { Debug(1,"Detected ARM (AArch32) processor with Neon"); neonversion = 1; } else { Debug(1,"Detected ARM (AArch32) processor"); } #elif defined(__aarch64__) // ARM processor in 64bit mode // Neon is mandatory, no need to check for it neonversion = 1; Debug(1,"Detected ARM (AArch64) processor with Neon"); #else // Unknown processor Debug(1,"Detected unknown processor architecture"); #endif } /* SSE2 aligned memory copy. Useful for big copying of aligned memory like image buffers in ZM */ /* For platforms without SSE2 we will use standard x86 asm memcpy or glibc's memcpy() */ #if defined(__i386__) || defined(__x86_64__) __attribute__((noinline,__target__("sse2"))) #endif void* sse2_aligned_memcpy(void* dest, const void* src, size_t bytes) { #if ((defined(__i386__) || defined(__x86_64__) || defined(ZM_KEEP_SSE)) && !defined(ZM_STRIP_SSE)) if(bytes > 128) { unsigned int remainder = bytes % 128; const uint8_t* lastsrc = (uint8_t*)src + (bytes - remainder); __asm__ __volatile__( "sse2_copy_iter:\n\t" "movdqa (%0),%%xmm0\n\t" "movdqa 0x10(%0),%%xmm1\n\t" "movdqa 0x20(%0),%%xmm2\n\t" "movdqa 0x30(%0),%%xmm3\n\t" "movdqa 0x40(%0),%%xmm4\n\t" "movdqa 0x50(%0),%%xmm5\n\t" "movdqa 0x60(%0),%%xmm6\n\t" "movdqa 0x70(%0),%%xmm7\n\t" "movntdq %%xmm0,(%1)\n\t" "movntdq %%xmm1,0x10(%1)\n\t" "movntdq %%xmm2,0x20(%1)\n\t" "movntdq %%xmm3,0x30(%1)\n\t" "movntdq %%xmm4,0x40(%1)\n\t" "movntdq %%xmm5,0x50(%1)\n\t" "movntdq %%xmm6,0x60(%1)\n\t" "movntdq %%xmm7,0x70(%1)\n\t" "add $0x80, %0\n\t" "add $0x80, %1\n\t" "cmp %2, %0\n\t" "jb sse2_copy_iter\n\t" "test %3, %3\n\t" "jz sse2_copy_finish\n\t" "cld\n\t" "rep movsb\n\t" "sse2_copy_finish:\n\t" : : "S" (src), "D" (dest), "r" (lastsrc), "c" (remainder) : "%xmm0", "%xmm1", "%xmm2", "%xmm3", "%xmm4", "%xmm5", "%xmm6", "%xmm7", "cc", "memory" ); } else { /* Standard memcpy */ __asm__ __volatile__("cld; rep movsb" :: "S"(src), "D"(dest), "c"(bytes) : "cc", "memory"); } #else /* Non x86\x86-64 platform, use memcpy */ memcpy(dest,src,bytes); #endif return dest; } void timespec_diff(struct timespec *start, struct timespec *end, struct timespec *diff) { if (((end->tv_nsec)-(start->tv_nsec))<0) { diff->tv_sec = end->tv_sec-start->tv_sec-1; diff->tv_nsec = 1000000000+end->tv_nsec-start->tv_nsec; } else { diff->tv_sec = end->tv_sec-start->tv_sec; diff->tv_nsec = end->tv_nsec-start->tv_nsec; } } char *timeval_to_string( struct timeval tv ) { time_t nowtime; struct tm *nowtm; static char tmbuf[20], buf[28]; nowtime = tv.tv_sec; nowtm = localtime(&nowtime); strftime(tmbuf, sizeof tmbuf, "%Y-%m-%d %H:%M:%S", nowtm); snprintf(buf, sizeof buf-1, "%s.%06ld", tmbuf, tv.tv_usec); return buf; } std::string UriDecode( const std::string &encoded ) { char a, b; const char *src = encoded.c_str(); std::string retbuf; retbuf.resize(encoded.length() + 1); char *dst = &retbuf[0]; while (*src) { if ((*src == '%') && ((a = src[1]) && (b = src[2])) && (isxdigit(a) && isxdigit(b))) { if (a >= 'a') a -= 'a'-'A'; if (a >= 'A') a -= ('A' - 10); else a -= '0'; if (b >= 'a') b -= 'a'-'A'; if (b >= 'A') b -= ('A' - 10); else b -= '0'; *dst++ = 16*a+b; src+=3; } else if (*src == '+') { *dst++ = ' '; src++; } else { *dst++ = *src++; } } *dst++ = '\0'; return retbuf; } void string_toupper( std::string& str) { std::transform(str.begin(), str.end(), str.begin(), ::toupper); } void touch(const char *pathname) { int fd = open(pathname, O_WRONLY|O_CREAT|O_NOCTTY|O_NONBLOCK, 0666); if ( fd < 0 ) { // Couldn't open that path. Error("Couldn't open() path %s in touch", pathname); return; } int rc = utimensat(AT_FDCWD, pathname, nullptr, 0); if ( rc ) { Error("Couldn't utimensat() path %s in touch", pathname); return; } }