/* Copyright (C) 2002-2005 RealVNC Ltd. All Rights Reserved. * Copyright 2011-2023 Pierre Ossman for Cendio AB * * This 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 software 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 software; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, * USA. */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include namespace rfb { std::string format(const char *fmt, ...) { va_list ap; int len; char *buf; std::string out; va_start(ap, fmt); len = vsnprintf(NULL, 0, fmt, ap); va_end(ap); if (len < 0) return ""; buf = new char[len+1]; va_start(ap, fmt); vsnprintf(buf, len+1, fmt, ap); va_end(ap); out = buf; delete [] buf; return out; } std::vector split(const char* src, const char delimiter) { std::vector out; const char *start, *stop; start = src; do { stop = strchr(start, delimiter); if (stop == NULL) { out.push_back(start); } else { out.push_back(std::string(start, stop-start)); start = stop + 1; } } while (stop != NULL); return out; } static char intToHex(uint8_t i) { if (i<=9) return '0'+i; else if ((i>=10) && (i<=15)) return 'a'+(i-10); assert(false); return '\0'; } void binToHex(const uint8_t* in, size_t inlen, char* out, size_t outlen) { if (inlen > outlen/2) inlen = outlen/2; if (inlen > 0) { assert(in); assert(out); } for (size_t i=0; i> 4) & 15); out[i*2+1] = intToHex((in[i] & 15)); } } std::string binToHex(const uint8_t* in, size_t inlen) { char* buffer = new char[inlen*2+1](); std::string out; binToHex(in, inlen, buffer, inlen*2); out = buffer; delete [] buffer; return out; } static bool readHexAndShift(char c, uint8_t* v) { c=tolower(c); if ((c >= '0') && (c <= '9')) *v = (*v << 4) + (c - '0'); else if ((c >= 'a') && (c <= 'f')) *v = (*v << 4) + (c - 'a' + 10); else return false; return true; } bool hexToBin(const char* in, size_t inlen, uint8_t* out, size_t outlen) { assert(in); assert(out); if (inlen & 1) return false; if (inlen > outlen*2) inlen = outlen*2; for(size_t i=0; i hexToBin(const char* in, size_t inlen) { std::vector out(inlen/2); if (!hexToBin(in, inlen, out.data(), inlen/2)) return std::vector(); return out; } std::string convertLF(const char* src, size_t bytes) { size_t sz; std::string out; const char* in; size_t in_len; // Compute output size sz = 0; in = src; in_len = bytes; while ((in_len > 0) && (*in != '\0')) { if (*in != '\r') { sz++; in++; in_len--; continue; } if ((in_len < 2) || (*(in+1) != '\n')) sz++; in++; in_len--; } // Reserve space out.reserve(sz); // And convert in = src; in_len = bytes; while ((in_len > 0) && (*in != '\0')) { if (*in != '\r') { out += *in++; in_len--; continue; } if ((in_len < 2) || (*(in+1) != '\n')) out += '\n'; in++; in_len--; } return out; } std::string convertCRLF(const char* src, size_t bytes) { std::string out; size_t sz; const char* in; size_t in_len; // Compute output size sz = 0; in = src; in_len = bytes; while ((in_len > 0) && (*in != '\0')) { sz++; if (*in == '\r') { if ((in_len < 2) || (*(in+1) != '\n')) sz++; } else if (*in == '\n') { if ((in == src) || (*(in-1) != '\r')) sz++; } in++; in_len--; } // Reserve space out.reserve(sz); // And convert in = src; in_len = bytes; while ((in_len > 0) && (*in != '\0')) { if (*in == '\n') { if ((in == src) || (*(in-1) != '\r')) out += '\r'; } out += *in; if (*in == '\r') { if ((in_len < 2) || (*(in+1) != '\n')) out += '\n'; } in++; in_len--; } return out; } size_t ucs4ToUTF8(unsigned src, char dst[5]) { if (src < 0x80) { *dst++ = src; *dst++ = '\0'; return 1; } else if (src < 0x800) { *dst++ = 0xc0 | (src >> 6); *dst++ = 0x80 | (src & 0x3f); *dst++ = '\0'; return 2; } else if (src < 0x10000) { *dst++ = 0xe0 | (src >> 12); *dst++ = 0x80 | ((src >> 6) & 0x3f); *dst++ = 0x80 | (src & 0x3f); *dst++ = '\0'; return 3; } else if (src < 0x110000) { *dst++ = 0xf0 | (src >> 18); *dst++ = 0x80 | ((src >> 12) & 0x3f); *dst++ = 0x80 | ((src >> 6) & 0x3f); *dst++ = 0x80 | (src & 0x3f); *dst++ = '\0'; return 4; } else { return ucs4ToUTF8(0xfffd, dst); } } size_t utf8ToUCS4(const char* src, size_t max, unsigned* dst) { size_t count, consumed; *dst = 0xfffd; if (max == 0) return 0; consumed = 1; if ((*src & 0x80) == 0) { *dst = *src; count = 0; } else if ((*src & 0xe0) == 0xc0) { *dst = *src & 0x1f; count = 1; } else if ((*src & 0xf0) == 0xe0) { *dst = *src & 0x0f; count = 2; } else if ((*src & 0xf8) == 0xf0) { *dst = *src & 0x07; count = 3; } else { // Invalid sequence, consume all continuation characters src++; max--; while ((max-- > 0) && ((*src++ & 0xc0) == 0x80)) consumed++; return consumed; } src++; max--; while (count--) { consumed++; // Invalid or truncated sequence? if ((max == 0) || ((*src & 0xc0) != 0x80)) { *dst = 0xfffd; return consumed; } *dst <<= 6; *dst |= *src & 0x3f; src++; max--; } return consumed; } size_t ucs4ToUTF16(unsigned src, wchar_t dst[3]) { if ((src < 0xd800) || ((src >= 0xe000) && (src < 0x10000))) { *dst++ = src; *dst++ = L'\0'; return 1; } else if ((src >= 0x10000) && (src < 0x110000)) { src -= 0x10000; *dst++ = 0xd800 | ((src >> 10) & 0x03ff); *dst++ = 0xdc00 | (src & 0x03ff); *dst++ = L'\0'; return 2; } else { return ucs4ToUTF16(0xfffd, dst); } } size_t utf16ToUCS4(const wchar_t* src, size_t max, unsigned* dst) { *dst = 0xfffd; if (max == 0) return 0; if ((*src < 0xd800) || (*src >= 0xe000)) { *dst = *src; return 1; } if (*src & 0x0400) { size_t consumed; // Invalid sequence, consume all continuation characters consumed = 0; while ((max > 0) && (*src & 0x0400)) { src++; max--; consumed++; } return consumed; } *dst = *src++; max--; // Invalid or truncated sequence? if ((max == 0) || ((*src & 0xfc00) != 0xdc00)) { *dst = 0xfffd; return 1; } *dst = 0x10000 + ((*dst & 0x03ff) << 10); *dst |= *src & 0x3ff; return 2; } std::string latin1ToUTF8(const char* src, size_t bytes) { std::string out; size_t sz; const char* in; size_t in_len; // Compute output size sz = 0; in = src; in_len = bytes; while ((in_len > 0) && (*in != '\0')) { char buf[5]; sz += ucs4ToUTF8(*(const unsigned char*)in, buf); in++; in_len--; } // Reserve space out.reserve(sz); // And convert in = src; in_len = bytes; while ((in_len > 0) && (*in != '\0')) { char buf[5]; ucs4ToUTF8(*(const unsigned char*)in, buf); out += buf; in++; in_len--; } return out; } std::string utf8ToLatin1(const char* src, size_t bytes) { std::string out; size_t sz; const char* in; size_t in_len; // Compute output size sz = 0; in = src; in_len = bytes; while ((in_len > 0) && (*in != '\0')) { size_t len; unsigned ucs; len = utf8ToUCS4(in, in_len, &ucs); in += len; in_len -= len; sz++; } // Reserve space out.reserve(sz); // And convert in = src; in_len = bytes; while ((in_len > 0) && (*in != '\0')) { size_t len; unsigned ucs; len = utf8ToUCS4(in, in_len, &ucs); in += len; in_len -= len; if (ucs > 0xff) out += '?'; else out += (unsigned char)ucs; } return out; } std::string utf16ToUTF8(const wchar_t* src, size_t units) { std::string out; size_t sz; const wchar_t* in; size_t in_len; // Compute output size sz = 0; in = src; in_len = units; while ((in_len > 0) && (*in != '\0')) { size_t len; unsigned ucs; char buf[5]; len = utf16ToUCS4(in, in_len, &ucs); in += len; in_len -= len; sz += ucs4ToUTF8(ucs, buf); } // Reserve space out.reserve(sz); // And convert in = src; in_len = units; while ((in_len > 0) && (*in != '\0')) { size_t len; unsigned ucs; char buf[5]; len = utf16ToUCS4(in, in_len, &ucs); in += len; in_len -= len; ucs4ToUTF8(ucs, buf); out += buf; } return out; } std::wstring utf8ToUTF16(const char* src, size_t bytes) { std::wstring out; size_t sz; const char* in; size_t in_len; // Compute output size sz = 0; in = src; in_len = bytes; while ((in_len > 0) && (*in != '\0')) { size_t len; unsigned ucs; wchar_t buf[3]; len = utf8ToUCS4(in, in_len, &ucs); in += len; in_len -= len; sz += ucs4ToUTF16(ucs, buf); } // Reserve space out.reserve(sz); // And convert in = src; in_len = bytes; while ((in_len > 0) && (*in != '\0')) { size_t len; unsigned ucs; wchar_t buf[3]; len = utf8ToUCS4(in, in_len, &ucs); in += len; in_len -= len; ucs4ToUTF16(ucs, buf); out += buf; } return out; } unsigned msBetween(const struct timeval *first, const struct timeval *second) { unsigned diff; diff = (second->tv_sec - first->tv_sec) * 1000; diff += second->tv_usec / 1000; diff -= first->tv_usec / 1000; return diff; } unsigned msSince(const struct timeval *then) { struct timeval now; gettimeofday(&now, NULL); return msBetween(then, &now); } bool isBefore(const struct timeval *first, const struct timeval *second) { if (first->tv_sec < second->tv_sec) return true; if (first->tv_sec > second->tv_sec) return false; if (first->tv_usec < second->tv_usec) return true; return false; } static std::string doPrefix(long long value, const char *unit, unsigned divisor, const char **prefixes, size_t prefixCount, int precision) { char buffer[256]; double newValue; size_t prefix; newValue = value; prefix = 0; while (newValue >= divisor) { if (prefix >= prefixCount) break; newValue /= divisor; prefix++; } snprintf(buffer, sizeof(buffer), "%.*g %s%s", precision, newValue, (prefix == 0) ? "" : prefixes[prefix-1], unit); buffer[sizeof(buffer)-1] = '\0'; return buffer; } static const char *siPrefixes[] = { "k", "M", "G", "T", "P", "E", "Z", "Y" }; static const char *iecPrefixes[] = { "Ki", "Mi", "Gi", "Ti", "Pi", "Ei", "Zi", "Yi" }; std::string siPrefix(long long value, const char *unit, int precision) { return doPrefix(value, unit, 1000, siPrefixes, sizeof(siPrefixes)/sizeof(*siPrefixes), precision); } std::string iecPrefix(long long value, const char *unit, int precision) { return doPrefix(value, unit, 1024, iecPrefixes, sizeof(iecPrefixes)/sizeof(*iecPrefixes), precision); } };