// -*- mode: cpp; mode: fold -*- // Description /*{{{*/ // $Id: strutl.cc,v 1.48 2003/07/18 14:15:11 mdz Exp $ /* ###################################################################### String Util - Some useful string functions. These have been collected from here and there to do all sorts of useful things to strings. They are useful in file parsers, URI handlers and especially in APT methods. This source is placed in the Public Domain, do with it what you will It was originally written by Jason Gunthorpe ##################################################################### */ /*}}}*/ // Includes /*{{{*/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /*}}}*/ using namespace std; // Strip - Remove white space from the front and back of a string /*{{{*/ // --------------------------------------------------------------------- namespace APT { namespace String { std::string Strip(const std::string &str) { // ensure we have at least one character if (str.empty() == true) return str; char const * const s = str.c_str(); size_t start = 0; for (; isspace(s[start]) != 0; ++start) ; // find the first not-space // string contains only whitespaces if (s[start] == '\0') return ""; size_t end = str.length() - 1; for (; isspace(s[end]) != 0; --end) ; // find the last not-space return str.substr(start, end - start + 1); } bool Endswith(const std::string &s, const std::string &end) { if (end.size() > s.size()) return false; return (s.substr(s.size() - end.size(), s.size()) == end); } bool Startswith(const std::string &s, const std::string &start) { if (start.size() > s.size()) return false; return (s.substr(0, start.size()) == start); } } } /*}}}*/ // UTF8ToCodeset - Convert some UTF-8 string for some codeset /*{{{*/ // --------------------------------------------------------------------- /* This is handy to use before display some information for enduser */ bool UTF8ToCodeset(const char *codeset, const string &orig, string *dest) { iconv_t cd; const char *inbuf; char *inptr, *outbuf; size_t insize, bufsize; dest->clear(); cd = iconv_open(codeset, "UTF-8"); if (cd == (iconv_t)(-1)) { // Something went wrong if (errno == EINVAL) _error->Error("conversion from 'UTF-8' to '%s' not available", codeset); else perror("iconv_open"); return false; } insize = bufsize = orig.size(); inbuf = orig.data(); inptr = (char *)inbuf; outbuf = new char[bufsize]; size_t lastError = -1; while (insize != 0) { char *outptr = outbuf; size_t outsize = bufsize; size_t const err = iconv(cd, &inptr, &insize, &outptr, &outsize); dest->append(outbuf, outptr - outbuf); if (err == (size_t)(-1)) { switch (errno) { case EILSEQ: insize--; inptr++; // replace a series of unknown multibytes with a single "?" if (lastError != insize) { lastError = insize - 1; dest->append("?"); } break; case EINVAL: insize = 0; break; case E2BIG: if (outptr == outbuf) { bufsize *= 2; delete[] outbuf; outbuf = new char[bufsize]; } break; } } } delete[] outbuf; iconv_close(cd); return true; } /*}}}*/ // strstrip - Remove white space from the front and back of a string /*{{{*/ // --------------------------------------------------------------------- /* This is handy to use when parsing a file. It also removes \n's left over from fgets and company */ char *_strstrip(char *String) { for (;*String != 0 && (*String == ' ' || *String == '\t'); String++); if (*String == 0) return String; return _strrstrip(String); } /*}}}*/ // strrstrip - Remove white space from the back of a string /*{{{*/ // --------------------------------------------------------------------- char *_strrstrip(char *String) { char *End = String + strlen(String) - 1; for (;End != String - 1 && (*End == ' ' || *End == '\t' || *End == '\n' || *End == '\r'); End--); End++; *End = 0; return String; } /*}}}*/ // strtabexpand - Converts tabs into 8 spaces /*{{{*/ // --------------------------------------------------------------------- /* */ char *_strtabexpand(char *String,size_t Len) { for (char *I = String; I != I + Len && *I != 0; I++) { if (*I != '\t') continue; if (I + 8 > String + Len) { *I = 0; return String; } /* Assume the start of the string is 0 and find the next 8 char division */ int Len; if (String == I) Len = 1; else Len = 8 - ((String - I) % 8); Len -= 2; if (Len <= 0) { *I = ' '; continue; } memmove(I + Len,I + 1,strlen(I) + 1); for (char *J = I; J + Len != I; *I = ' ', I++); } return String; } /*}}}*/ // ParseQuoteWord - Parse a single word out of a string /*{{{*/ // --------------------------------------------------------------------- /* This grabs a single word, converts any % escaped characters to their proper values and advances the pointer. Double quotes are understood and striped out as well. This is for URI/URL parsing. It also can understand [] brackets.*/ bool ParseQuoteWord(const char *&String,string &Res) { // Skip leading whitespace const char *C = String; for (;*C != 0 && *C == ' '; C++); if (*C == 0) return false; // Jump to the next word for (;*C != 0 && isspace(*C) == 0; C++) { if (*C == '"') { C = strchr(C + 1, '"'); if (C == NULL) return false; } if (*C == '[') { C = strchr(C + 1, ']'); if (C == NULL) return false; } } // Now de-quote characters char Buffer[1024]; char Tmp[3]; const char *Start = String; char *I; for (I = Buffer; I < Buffer + sizeof(Buffer) && Start != C; I++) { if (*Start == '%' && Start + 2 < C && isxdigit(Start[1]) && isxdigit(Start[2])) { Tmp[0] = Start[1]; Tmp[1] = Start[2]; Tmp[2] = 0; *I = (char)strtol(Tmp,0,16); Start += 3; continue; } if (*Start != '"') *I = *Start; else I--; Start++; } *I = 0; Res = Buffer; // Skip ending white space for (;*C != 0 && isspace(*C) != 0; C++); String = C; return true; } /*}}}*/ // ParseCWord - Parses a string like a C "" expression /*{{{*/ // --------------------------------------------------------------------- /* This expects a series of space separated strings enclosed in ""'s. It concatenates the ""'s into a single string. */ bool ParseCWord(const char *&String,string &Res) { // Skip leading whitespace const char *C = String; for (;*C != 0 && *C == ' '; C++); if (*C == 0) return false; char Buffer[1024]; char *Buf = Buffer; if (strlen(String) >= sizeof(Buffer)) return false; for (; *C != 0; C++) { if (*C == '"') { for (C++; *C != 0 && *C != '"'; C++) *Buf++ = *C; if (*C == 0) return false; continue; } if (C != String && isspace(*C) != 0 && isspace(C[-1]) != 0) continue; if (isspace(*C) == 0) return false; *Buf++ = ' '; } *Buf = 0; Res = Buffer; String = C; return true; } /*}}}*/ // QuoteString - Convert a string into quoted from /*{{{*/ // --------------------------------------------------------------------- /* */ string QuoteString(const string &Str, const char *Bad) { std::stringstream Res; for (string::const_iterator I = Str.begin(); I != Str.end(); ++I) { if (strchr(Bad,*I) != 0 || isprint(*I) == 0 || *I == 0x25 || // percent '%' char *I <= 0x20 || *I >= 0x7F) // control chars { ioprintf(Res, "%%%02hhx", *I); } else Res << *I; } return Res.str(); } /*}}}*/ // DeQuoteString - Convert a string from quoted from /*{{{*/ // --------------------------------------------------------------------- /* This undoes QuoteString */ string DeQuoteString(const string &Str) { return DeQuoteString(Str.begin(),Str.end()); } string DeQuoteString(string::const_iterator const &begin, string::const_iterator const &end) { string Res; for (string::const_iterator I = begin; I != end; ++I) { if (*I == '%' && I + 2 < end && isxdigit(I[1]) && isxdigit(I[2])) { char Tmp[3]; Tmp[0] = I[1]; Tmp[1] = I[2]; Tmp[2] = 0; Res += (char)strtol(Tmp,0,16); I += 2; continue; } else Res += *I; } return Res; } /*}}}*/ // SizeToStr - Convert a long into a human readable size /*{{{*/ // --------------------------------------------------------------------- /* A max of 4 digits are shown before conversion to the next highest unit. The max length of the string will be 5 chars unless the size is > 10 YottaBytes (E24) */ string SizeToStr(double Size) { double ASize; if (Size >= 0) ASize = Size; else ASize = -1*Size; /* bytes, KiloBytes, MegaBytes, GigaBytes, TeraBytes, PetaBytes, ExaBytes, ZettaBytes, YottaBytes */ char Ext[] = {'\0','k','M','G','T','P','E','Z','Y'}; int I = 0; while (I <= 8) { if (ASize < 100 && I != 0) { std::string S; strprintf(S, "%'.1f %c", ASize, Ext[I]); return S; } if (ASize < 10000) { std::string S; strprintf(S, "%'.0f %c", ASize, Ext[I]); return S; } ASize /= 1000.0; I++; } return ""; } /*}}}*/ // TimeToStr - Convert the time into a string /*{{{*/ // --------------------------------------------------------------------- /* Converts a number of seconds to a hms format */ string TimeToStr(unsigned long Sec) { std::string S; if (Sec > 60*60*24) { //TRANSLATOR: d means days, h means hours, min means minutes, s means seconds strprintf(S,_("%lid %lih %limin %lis"),Sec/60/60/24,(Sec/60/60) % 24,(Sec/60) % 60,Sec % 60); } else if (Sec > 60*60) { //TRANSLATOR: h means hours, min means minutes, s means seconds strprintf(S,_("%lih %limin %lis"),Sec/60/60,(Sec/60) % 60,Sec % 60); } else if (Sec > 60) { //TRANSLATOR: min means minutes, s means seconds strprintf(S,_("%limin %lis"),Sec/60,Sec % 60); } else { //TRANSLATOR: s means seconds strprintf(S,_("%lis"),Sec); } return S; } /*}}}*/ // SubstVar - Substitute a string for another string /*{{{*/ // --------------------------------------------------------------------- /* This replaces all occurrences of Subst with Contents in Str. */ string SubstVar(const string &Str,const string &Subst,const string &Contents) { if (Subst.empty() == true) return Str; string::size_type Pos = 0; string::size_type OldPos = 0; string Temp; while (OldPos < Str.length() && (Pos = Str.find(Subst,OldPos)) != string::npos) { if (OldPos != Pos) Temp.append(Str, OldPos, Pos - OldPos); if (Contents.empty() == false) Temp.append(Contents); OldPos = Pos + Subst.length(); } if (OldPos == 0) return Str; if (OldPos >= Str.length()) return Temp; Temp.append(Str, OldPos, string::npos); return Temp; } string SubstVar(string Str,const struct SubstVar *Vars) { for (; Vars->Subst != 0; Vars++) Str = SubstVar(Str,Vars->Subst,*Vars->Contents); return Str; } /*}}}*/ // OutputInDepth - return a string with separator multiplied with depth /*{{{*/ // --------------------------------------------------------------------- /* Returns a string with the supplied separator depth + 1 times in it */ std::string OutputInDepth(const unsigned long Depth, const char* Separator) { std::string output = ""; for(unsigned long d=Depth+1; d > 0; d--) output.append(Separator); return output; } /*}}}*/ // URItoFileName - Convert the uri into a unique file name /*{{{*/ // --------------------------------------------------------------------- /* This converts a URI into a safe filename. It quotes all unsafe characters and converts / to _ and removes the scheme identifier. The resulting file name should be unique and never occur again for a different file */ string URItoFileName(const string &URI) { // Nuke 'sensitive' items ::URI U(URI); U.User.clear(); U.Password.clear(); U.Access.clear(); // "\x00-\x20{}|\\\\^\\[\\]<>\"\x7F-\xFF"; string NewURI = QuoteString(U,"\\|{}[]<>\"^~_=!@#$%^&*"); replace(NewURI.begin(),NewURI.end(),'/','_'); return NewURI; } /*}}}*/ // Base64Encode - Base64 Encoding routine for short strings /*{{{*/ // --------------------------------------------------------------------- /* This routine performs a base64 transformation on a string. It was ripped from wget and then patched and bug fixed. This spec can be found in rfc2045 */ string Base64Encode(const string &S) { // Conversion table. static char tbl[64] = {'A','B','C','D','E','F','G','H', 'I','J','K','L','M','N','O','P', 'Q','R','S','T','U','V','W','X', 'Y','Z','a','b','c','d','e','f', 'g','h','i','j','k','l','m','n', 'o','p','q','r','s','t','u','v', 'w','x','y','z','0','1','2','3', '4','5','6','7','8','9','+','/'}; // Pre-allocate some space string Final; Final.reserve((4*S.length() + 2)/3 + 2); /* Transform the 3x8 bits to 4x6 bits, as required by base64. */ for (string::const_iterator I = S.begin(); I < S.end(); I += 3) { char Bits[3] = {0,0,0}; Bits[0] = I[0]; if (I + 1 < S.end()) Bits[1] = I[1]; if (I + 2 < S.end()) Bits[2] = I[2]; Final += tbl[Bits[0] >> 2]; Final += tbl[((Bits[0] & 3) << 4) + (Bits[1] >> 4)]; if (I + 1 >= S.end()) break; Final += tbl[((Bits[1] & 0xf) << 2) + (Bits[2] >> 6)]; if (I + 2 >= S.end()) break; Final += tbl[Bits[2] & 0x3f]; } /* Apply the padding elements, this tells how many bytes the remote end should discard */ if (S.length() % 3 == 2) Final += '='; if (S.length() % 3 == 1) Final += "=="; return Final; } /*}}}*/ // stringcmp - Arbitrary string compare /*{{{*/ // --------------------------------------------------------------------- /* This safely compares two non-null terminated strings of arbitrary length */ int stringcmp(const char *A,const char *AEnd,const char *B,const char *BEnd) { for (; A != AEnd && B != BEnd; A++, B++) if (*A != *B) break; if (A == AEnd && B == BEnd) return 0; if (A == AEnd) return 1; if (B == BEnd) return -1; if (*A < *B) return -1; return 1; } #if __GNUC__ >= 3 int stringcmp(string::const_iterator A,string::const_iterator AEnd, const char *B,const char *BEnd) { for (; A != AEnd && B != BEnd; A++, B++) if (*A != *B) break; if (A == AEnd && B == BEnd) return 0; if (A == AEnd) return 1; if (B == BEnd) return -1; if (*A < *B) return -1; return 1; } int stringcmp(string::const_iterator A,string::const_iterator AEnd, string::const_iterator B,string::const_iterator BEnd) { for (; A != AEnd && B != BEnd; A++, B++) if (*A != *B) break; if (A == AEnd && B == BEnd) return 0; if (A == AEnd) return 1; if (B == BEnd) return -1; if (*A < *B) return -1; return 1; } #endif /*}}}*/ // stringcasecmp - Arbitrary case insensitive string compare /*{{{*/ // --------------------------------------------------------------------- /* */ int stringcasecmp(const char *A,const char *AEnd,const char *B,const char *BEnd) { for (; A != AEnd && B != BEnd; A++, B++) if (tolower_ascii(*A) != tolower_ascii(*B)) break; if (A == AEnd && B == BEnd) return 0; if (A == AEnd) return 1; if (B == BEnd) return -1; if (tolower_ascii(*A) < tolower_ascii(*B)) return -1; return 1; } #if __GNUC__ >= 3 int stringcasecmp(string::const_iterator A,string::const_iterator AEnd, const char *B,const char *BEnd) { for (; A != AEnd && B != BEnd; A++, B++) if (tolower_ascii(*A) != tolower_ascii(*B)) break; if (A == AEnd && B == BEnd) return 0; if (A == AEnd) return 1; if (B == BEnd) return -1; if (tolower_ascii(*A) < tolower_ascii(*B)) return -1; return 1; } int stringcasecmp(string::const_iterator A,string::const_iterator AEnd, string::const_iterator B,string::const_iterator BEnd) { for (; A != AEnd && B != BEnd; A++, B++) if (tolower_ascii(*A) != tolower_ascii(*B)) break; if (A == AEnd && B == BEnd) return 0; if (A == AEnd) return 1; if (B == BEnd) return -1; if (tolower_ascii(*A) < tolower_ascii(*B)) return -1; return 1; } #endif /*}}}*/ // LookupTag - Lookup the value of a tag in a taged string /*{{{*/ // --------------------------------------------------------------------- /* The format is like those used in package files and the method communication system */ string LookupTag(const string &Message,const char *Tag,const char *Default) { // Look for a matching tag. int Length = strlen(Tag); for (string::const_iterator I = Message.begin(); I + Length < Message.end(); ++I) { // Found the tag if (I[Length] == ':' && stringcasecmp(I,I+Length,Tag) == 0) { // Find the end of line and strip the leading/trailing spaces string::const_iterator J; I += Length + 1; for (; isspace_ascii(*I) != 0 && I < Message.end(); ++I); for (J = I; *J != '\n' && J < Message.end(); ++J); for (; J > I && isspace_ascii(J[-1]) != 0; --J); return string(I,J); } for (; *I != '\n' && I < Message.end(); ++I); } // Failed to find a match if (Default == 0) return string(); return Default; } /*}}}*/ // StringToBool - Converts a string into a boolean /*{{{*/ // --------------------------------------------------------------------- /* This inspects the string to see if it is true or if it is false and then returns the result. Several varients on true/false are checked. */ int StringToBool(const string &Text,int Default) { char *ParseEnd; int Res = strtol(Text.c_str(),&ParseEnd,0); // ensure that the entire string was converted by strtol to avoid // failures on "apt-cache show -a 0ad" where the "0" is converted const char *TextEnd = Text.c_str()+Text.size(); if (ParseEnd == TextEnd && Res >= 0 && Res <= 1) return Res; // Check for positives if (strcasecmp(Text.c_str(),"no") == 0 || strcasecmp(Text.c_str(),"false") == 0 || strcasecmp(Text.c_str(),"without") == 0 || strcasecmp(Text.c_str(),"off") == 0 || strcasecmp(Text.c_str(),"disable") == 0) return 0; // Check for negatives if (strcasecmp(Text.c_str(),"yes") == 0 || strcasecmp(Text.c_str(),"true") == 0 || strcasecmp(Text.c_str(),"with") == 0 || strcasecmp(Text.c_str(),"on") == 0 || strcasecmp(Text.c_str(),"enable") == 0) return 1; return Default; } /*}}}*/ // TimeRFC1123 - Convert a time_t into RFC1123 format /*{{{*/ // --------------------------------------------------------------------- /* This converts a time_t into a string time representation that is year 2000 complient and timezone neutral */ string TimeRFC1123(time_t Date) { struct tm Conv; if (gmtime_r(&Date, &Conv) == NULL) return ""; auto const posix = std::locale::classic(); std::ostringstream datestr; datestr.imbue(posix); datestr << std::put_time(&Conv, "%a, %d %b %Y %H:%M:%S GMT"); return datestr.str(); } /*}}}*/ // ReadMessages - Read messages from the FD /*{{{*/ // --------------------------------------------------------------------- /* This pulls full messages from the input FD into the message buffer. It assumes that messages will not pause during transit so no fancy buffering is used. In particular: this reads blocks from the input until it believes that it's run out of input text. Each block is terminated by a double newline ('\n' followed by '\n'). */ bool ReadMessages(int Fd, vector &List) { char Buffer[64000]; // Represents any left-over from the previous iteration of the // parse loop. (i.e., if a message is split across the end // of the buffer, it goes here) string PartialMessage; do { int const Res = read(Fd, Buffer, sizeof(Buffer)); if (Res < 0 && errno == EINTR) continue; // process we read from has died if (Res == 0) return false; // No data #if EAGAIN != EWOULDBLOCK if (Res < 0 && (errno == EAGAIN || errno == EWOULDBLOCK)) #else if (Res < 0 && errno == EAGAIN) #endif return true; if (Res < 0) return false; // extract the message(s) from the buffer char const *Start = Buffer; char const * const End = Buffer + Res; char const * NL = (char const *) memchr(Start, '\n', End - Start); if (NL == NULL) { // end of buffer: store what we have so far and read new data in PartialMessage.append(Start, End - Start); Start = End; } else ++NL; if (PartialMessage.empty() == false && Start < End) { // if we start with a new line, see if the partial message we have ended with one // so that we properly detect records ending between two read() runs // cases are: \n|\n , \r\n|\r\n and \r\n\r|\n // the case \r|\n\r\n is handled by the usual double-newline handling if ((NL - Start) == 1 || ((NL - Start) == 2 && *Start == '\r')) { if (APT::String::Endswith(PartialMessage, "\n") || APT::String::Endswith(PartialMessage, "\r\n\r")) { PartialMessage.erase(PartialMessage.find_last_not_of("\r\n") + 1); List.push_back(PartialMessage); PartialMessage.clear(); while (NL < End && (*NL == '\n' || *NL == '\r')) ++NL; Start = NL; } } } while (Start < End) { char const * NL2 = (char const *) memchr(NL, '\n', End - NL); if (NL2 == NULL) { // end of buffer: store what we have so far and read new data in PartialMessage.append(Start, End - Start); break; } ++NL2; // did we find a double newline? if ((NL2 - NL) == 1 || ((NL2 - NL) == 2 && *NL == '\r')) { PartialMessage.append(Start, NL2 - Start); PartialMessage.erase(PartialMessage.find_last_not_of("\r\n") + 1); List.push_back(PartialMessage); PartialMessage.clear(); while (NL2 < End && (*NL2 == '\n' || *NL2 == '\r')) ++NL2; Start = NL2; } NL = NL2; } // we have read at least one complete message and nothing left if (PartialMessage.empty() == true) return true; if (WaitFd(Fd) == false) return false; } while (true); } /*}}}*/ // MonthConv - Converts a month string into a number /*{{{*/ // --------------------------------------------------------------------- /* This was lifted from the boa webserver which lifted it from 'wn-v1.07' Made it a bit more robust with a few tolower_ascii though. */ static int MonthConv(char const * const Month) { switch (tolower_ascii(*Month)) { case 'a': return tolower_ascii(Month[1]) == 'p'?3:7; case 'd': return 11; case 'f': return 1; case 'j': if (tolower_ascii(Month[1]) == 'a') return 0; return tolower_ascii(Month[2]) == 'n'?5:6; case 'm': return tolower_ascii(Month[2]) == 'r'?2:4; case 'n': return 10; case 'o': return 9; case 's': return 8; // Pretend it is January.. default: return 0; } } /*}}}*/ // timegm - Internal timegm if the gnu version is not available /*{{{*/ // --------------------------------------------------------------------- /* Converts struct tm to time_t, assuming the data in tm is UTC rather than local timezone (mktime assumes the latter). This function is a nonstandard GNU extension that is also present on the BSDs and maybe other systems. For others we follow the advice of the manpage of timegm and use his portable replacement. */ #ifndef HAVE_TIMEGM static time_t timegm(struct tm *t) { char *tz = getenv("TZ"); setenv("TZ", "", 1); tzset(); time_t ret = mktime(t); if (tz) setenv("TZ", tz, 1); else unsetenv("TZ"); tzset(); return ret; } #endif /*}}}*/ // RFC1123StrToTime - Converts a HTTP1.1 full date strings into a time_t /*{{{*/ // --------------------------------------------------------------------- /* tries to parses a full date as specified in RFC7231 §7.1.1.1 with one exception: HTTP/1.1 valid dates need to have GMT as timezone. As we encounter dates from UTC or with a numeric timezone in other places, we allow them here to to be able to reuse the method. Either way, a date must be in UTC or parsing will fail. Previous implementations of this method used to ignore the timezone and assume always UTC. */ bool RFC1123StrToTime(const char* const str,time_t &time) { unsigned short day = 0; signed int year = 0; // yes, Y23K problem – we gonna worry then… std::string weekday, month, datespec, timespec, zone; std::istringstream ss(str); auto const &posix = std::locale::classic(); ss.imbue(posix); ss >> weekday; // we only superficially check weekday, mostly to avoid accepting localized // weekdays here and take only its length to decide which datetime format we // encounter here. The date isn't stored. std::transform(weekday.begin(), weekday.end(), weekday.begin(), ::tolower); std::array c_weekdays = {{ "sun", "mon", "tue", "wed", "thu", "fri", "sat" }}; if (std::find(c_weekdays.begin(), c_weekdays.end(), weekday.substr(0,3)) == c_weekdays.end()) return false; switch (weekday.length()) { case 4: // Sun, 06 Nov 1994 08:49:37 GMT ; RFC 822, updated by RFC 1123 if (weekday[3] != ',') return false; ss >> day >> month >> year >> timespec >> zone; break; case 3: // Sun Nov 6 08:49:37 1994 ; ANSI C's asctime() format ss >> month >> day >> timespec >> year; zone = "UTC"; break; case 0: case 1: case 2: return false; default: // Sunday, 06-Nov-94 08:49:37 GMT ; RFC 850, obsoleted by RFC 1036 if (weekday[weekday.length() - 1] != ',') return false; ss >> datespec >> timespec >> zone; auto const expldate = VectorizeString(datespec, '-'); if (expldate.size() != 3) return false; try { size_t pos; day = std::stoi(expldate[0], &pos); if (pos != expldate[0].length()) return false; year = 1900 + std::stoi(expldate[2], &pos); if (pos != expldate[2].length()) return false; strprintf(datespec, "%.4d-%.2d-%.2d", year, MonthConv(expldate[1].c_str()) + 1, day); } catch (...) { return false; } break; } if (ss.fail() || ss.bad() || !ss.eof()) return false; if (zone != "GMT" && zone != "UTC" && zone != "Z") // RFC 822 { // numeric timezones as a should of RFC 1123 and generally preferred try { size_t pos; auto const z = std::stoi(zone, &pos); if (z != 0 || pos != zone.length()) return false; } catch (...) { return false; } } if (datespec.empty()) { if (month.empty()) return false; strprintf(datespec, "%.4d-%.2d-%.2d", year, MonthConv(month.c_str()) + 1, day); } std::string const datetime = datespec + ' ' + timespec; struct tm Tm; if (strptime(datetime.c_str(), "%Y-%m-%d %H:%M:%S", &Tm) == nullptr) return false; time = timegm(&Tm); return true; } /*}}}*/ // FTPMDTMStrToTime - Converts a ftp modification date into a time_t /*{{{*/ // --------------------------------------------------------------------- /* */ bool FTPMDTMStrToTime(const char* const str,time_t &time) { struct tm Tm; // MDTM includes no whitespaces but recommend and ignored by strptime if (strptime(str, "%Y %m %d %H %M %S", &Tm) == NULL) return false; time = timegm(&Tm); return true; } /*}}}*/ // StrToTime - Converts a string into a time_t /*{{{*/ // --------------------------------------------------------------------- /* This handles all 3 popular time formats including RFC 1123, RFC 1036 and the C library asctime format. It requires the GNU library function 'timegm' to convert a struct tm in UTC to a time_t. For some bizzar reason the C library does not provide any such function :< This also handles the weird, but unambiguous FTP time format*/ bool StrToTime(const string &Val,time_t &Result) { struct tm Tm; char Month[10]; // Skip the day of the week const char *I = strchr(Val.c_str(), ' '); // Handle RFC 1123 time Month[0] = 0; if (sscanf(I," %2d %3s %4d %2d:%2d:%2d GMT",&Tm.tm_mday,Month,&Tm.tm_year, &Tm.tm_hour,&Tm.tm_min,&Tm.tm_sec) != 6) { // Handle RFC 1036 time if (sscanf(I," %2d-%3s-%3d %2d:%2d:%2d GMT",&Tm.tm_mday,Month, &Tm.tm_year,&Tm.tm_hour,&Tm.tm_min,&Tm.tm_sec) == 6) Tm.tm_year += 1900; else { // asctime format if (sscanf(I," %3s %2d %2d:%2d:%2d %4d",Month,&Tm.tm_mday, &Tm.tm_hour,&Tm.tm_min,&Tm.tm_sec,&Tm.tm_year) != 6) { // 'ftp' time if (sscanf(Val.c_str(),"%4d%2d%2d%2d%2d%2d",&Tm.tm_year,&Tm.tm_mon, &Tm.tm_mday,&Tm.tm_hour,&Tm.tm_min,&Tm.tm_sec) != 6) return false; Tm.tm_mon--; } } } Tm.tm_isdst = 0; if (Month[0] != 0) Tm.tm_mon = MonthConv(Month); else Tm.tm_mon = 0; // we don't have a month, so pick something Tm.tm_year -= 1900; // Convert to local time and then to GMT Result = timegm(&Tm); return true; } /*}}}*/ // StrToNum - Convert a fixed length string to a number /*{{{*/ // --------------------------------------------------------------------- /* This is used in decoding the crazy fixed length string headers in tar and ar files. */ bool StrToNum(const char *Str,unsigned long &Res,unsigned Len,unsigned Base) { char S[30]; if (Len >= sizeof(S)) return false; memcpy(S,Str,Len); S[Len] = 0; // All spaces is a zero Res = 0; unsigned I; for (I = 0; S[I] == ' '; I++); if (S[I] == 0) return true; char *End; Res = strtoul(S,&End,Base); if (End == S) return false; return true; } /*}}}*/ // StrToNum - Convert a fixed length string to a number /*{{{*/ // --------------------------------------------------------------------- /* This is used in decoding the crazy fixed length string headers in tar and ar files. */ bool StrToNum(const char *Str,unsigned long long &Res,unsigned Len,unsigned Base) { char S[30]; if (Len >= sizeof(S)) return false; memcpy(S,Str,Len); S[Len] = 0; // All spaces is a zero Res = 0; unsigned I; for (I = 0; S[I] == ' '; I++); if (S[I] == 0) return true; char *End; Res = strtoull(S,&End,Base); if (End == S) return false; return true; } /*}}}*/ // Base256ToNum - Convert a fixed length binary to a number /*{{{*/ // --------------------------------------------------------------------- /* This is used in decoding the 256bit encoded fixed length fields in tar files */ bool Base256ToNum(const char *Str,unsigned long long &Res,unsigned int Len) { if ((Str[0] & 0x80) == 0) return false; else { Res = Str[0] & 0x7F; for(unsigned int i = 1; i < Len; ++i) Res = (Res<<8) + Str[i]; return true; } } /*}}}*/ // Base256ToNum - Convert a fixed length binary to a number /*{{{*/ // --------------------------------------------------------------------- /* This is used in decoding the 256bit encoded fixed length fields in tar files */ bool Base256ToNum(const char *Str,unsigned long &Res,unsigned int Len) { unsigned long long Num = 0; bool rc; rc = Base256ToNum(Str, Num, Len); // rudimentary check for overflow (Res = ulong, Num = ulonglong) Res = Num; if (Res != Num) return false; return rc; } /*}}}*/ // HexDigit - Convert a hex character into an integer /*{{{*/ // --------------------------------------------------------------------- /* Helper for Hex2Num */ static int HexDigit(int c) { if (c >= '0' && c <= '9') return c - '0'; if (c >= 'a' && c <= 'f') return c - 'a' + 10; if (c >= 'A' && c <= 'F') return c - 'A' + 10; return -1; } /*}}}*/ // Hex2Num - Convert a long hex number into a buffer /*{{{*/ // --------------------------------------------------------------------- /* The length of the buffer must be exactly 1/2 the length of the string. */ bool Hex2Num(const string &Str,unsigned char *Num,unsigned int Length) { return Hex2Num(APT::StringView(Str), Num, Length); } bool Hex2Num(const APT::StringView Str,unsigned char *Num,unsigned int Length) { if (Str.length() != Length*2) return false; // Convert each digit. We store it in the same order as the string int J = 0; for (auto I = Str.begin(); I != Str.end();J++, I += 2) { int first_half = HexDigit(I[0]); int second_half; if (first_half < 0) return false; second_half = HexDigit(I[1]); if (second_half < 0) return false; Num[J] = first_half << 4; Num[J] += second_half; } return true; } /*}}}*/ // TokSplitString - Split a string up by a given token /*{{{*/ // --------------------------------------------------------------------- /* This is intended to be a faster splitter, it does not use dynamic memories. Input is changed to insert nulls at each token location. */ bool TokSplitString(char Tok,char *Input,char **List, unsigned long ListMax) { // Strip any leading spaces char *Start = Input; char *Stop = Start + strlen(Start); for (; *Start != 0 && isspace(*Start) != 0; Start++); unsigned long Count = 0; char *Pos = Start; while (Pos != Stop) { // Skip to the next Token for (; Pos != Stop && *Pos != Tok; Pos++); // Back remove spaces char *End = Pos; for (; End > Start && (End[-1] == Tok || isspace(End[-1]) != 0); End--); *End = 0; List[Count++] = Start; if (Count >= ListMax) { List[Count-1] = 0; return false; } // Advance pos for (; Pos != Stop && (*Pos == Tok || isspace(*Pos) != 0 || *Pos == 0); Pos++); Start = Pos; } List[Count] = 0; return true; } /*}}}*/ // VectorizeString - Split a string up into a vector of strings /*{{{*/ // --------------------------------------------------------------------- /* This can be used to split a given string up into a vector, so the propose is the same as in the method above and this one is a bit slower also, but the advantage is that we have an iteratable vector */ vector VectorizeString(string const &haystack, char const &split) { vector exploded; if (haystack.empty() == true) return exploded; string::const_iterator start = haystack.begin(); string::const_iterator end = start; do { for (; end != haystack.end() && *end != split; ++end); exploded.push_back(string(start, end)); start = end + 1; } while (end != haystack.end() && (++end) != haystack.end()); return exploded; } /*}}}*/ // StringSplit - split a string into a string vector by token /*{{{*/ // --------------------------------------------------------------------- /* See header for details. */ vector StringSplit(std::string const &s, std::string const &sep, unsigned int maxsplit) { vector split; size_t start, pos; // no separator given, this is bogus if(sep.size() == 0) return split; start = pos = 0; while (pos != string::npos) { pos = s.find(sep, start); split.push_back(s.substr(start, pos-start)); // if maxsplit is reached, the remaining string is the last item if(split.size() >= maxsplit) { split[split.size()-1] = s.substr(start); break; } start = pos+sep.size(); } return split; } /*}}}*/ // RegexChoice - Simple regex list/list matcher /*{{{*/ // --------------------------------------------------------------------- /* */ unsigned long RegexChoice(RxChoiceList *Rxs,const char **ListBegin, const char **ListEnd) { for (RxChoiceList *R = Rxs; R->Str != 0; R++) R->Hit = false; unsigned long Hits = 0; for (; ListBegin < ListEnd; ++ListBegin) { // Check if the name is a regex const char *I; bool Regex = true; for (I = *ListBegin; *I != 0; I++) if (*I == '.' || *I == '?' || *I == '*' || *I == '|') break; if (*I == 0) Regex = false; // Compile the regex pattern regex_t Pattern; if (Regex == true) if (regcomp(&Pattern,*ListBegin,REG_EXTENDED | REG_ICASE | REG_NOSUB) != 0) Regex = false; // Search the list bool Done = false; for (RxChoiceList *R = Rxs; R->Str != 0; R++) { if (R->Str[0] == 0) continue; if (strcasecmp(R->Str,*ListBegin) != 0) { if (Regex == false) continue; if (regexec(&Pattern,R->Str,0,0,0) != 0) continue; } Done = true; if (R->Hit == false) Hits++; R->Hit = true; } if (Regex == true) regfree(&Pattern); if (Done == false) _error->Warning(_("Selection %s not found"),*ListBegin); } return Hits; } /*}}}*/ // {str,io}printf - C format string outputter to C++ strings/iostreams /*{{{*/ // --------------------------------------------------------------------- /* This is used to make the internationalization strings easier to translate and to allow reordering of parameters */ static bool iovprintf(ostream &out, const char *format, va_list &args, ssize_t &size) { char *S = (char*)malloc(size); ssize_t const n = vsnprintf(S, size, format, args); if (n > -1 && n < size) { out << S; free(S); return true; } else { if (n > -1) size = n + 1; else size *= 2; } free(S); return false; } void ioprintf(ostream &out,const char *format,...) { va_list args; ssize_t size = 400; while (true) { bool ret; va_start(args,format); ret = iovprintf(out, format, args, size); va_end(args); if (ret == true) return; } } void strprintf(string &out,const char *format,...) { va_list args; ssize_t size = 400; std::ostringstream outstr; while (true) { bool ret; va_start(args,format); ret = iovprintf(outstr, format, args, size); va_end(args); if (ret == true) break; } out = outstr.str(); } /*}}}*/ // safe_snprintf - Safer snprintf /*{{{*/ // --------------------------------------------------------------------- /* This is a snprintf that will never (ever) go past 'End' and returns a pointer to the end of the new string. The returned string is always null terminated unless Buffer == end. This is a better alterantive to using consecutive snprintfs. */ char *safe_snprintf(char *Buffer,char *End,const char *Format,...) { va_list args; int Did; if (End <= Buffer) return End; va_start(args,Format); Did = vsnprintf(Buffer,End - Buffer,Format,args); va_end(args); if (Did < 0 || Buffer + Did > End) return End; return Buffer + Did; } /*}}}*/ // StripEpoch - Remove the version "epoch" from a version string /*{{{*/ // --------------------------------------------------------------------- string StripEpoch(const string &VerStr) { size_t i = VerStr.find(":"); if (i == string::npos) return VerStr; return VerStr.substr(i+1); } /*}}}*/ // tolower_ascii - tolower() function that ignores the locale /*{{{*/ // --------------------------------------------------------------------- /* This little function is the most called method we have and tries therefore to do the absolut minimum - and is notable faster than standard tolower/toupper and as a bonus avoids problems with different locales - we only operate on ascii chars anyway. */ #undef tolower_ascii int tolower_ascii(int const c) APT_CONST APT_COLD; int tolower_ascii(int const c) { return tolower_ascii_inline(c); } /*}}}*/ // isspace_ascii - isspace() function that ignores the locale /*{{{*/ // --------------------------------------------------------------------- /* This little function is one of the most called methods we have and tries therefore to do the absolut minimum - and is notable faster than standard isspace() and as a bonus avoids problems with different locales - we only operate on ascii chars anyway. */ #undef isspace_ascii int isspace_ascii(int const c) APT_CONST APT_COLD; int isspace_ascii(int const c) { return isspace_ascii_inline(c); } /*}}}*/ // CheckDomainList - See if Host is in a , separate list /*{{{*/ // --------------------------------------------------------------------- /* The domain list is a comma separate list of domains that are suffix matched against the argument */ bool CheckDomainList(const string &Host,const string &List) { string::const_iterator Start = List.begin(); for (string::const_iterator Cur = List.begin(); Cur <= List.end(); ++Cur) { if (Cur < List.end() && *Cur != ',') continue; // Match the end of the string.. if ((Host.size() >= (unsigned)(Cur - Start)) && Cur - Start != 0 && stringcasecmp(Host.end() - (Cur - Start),Host.end(),Start,Cur) == 0) return true; Start = Cur + 1; } return false; } /*}}}*/ // strv_length - Return the length of a NULL-terminated string array /*{{{*/ // --------------------------------------------------------------------- /* */ size_t strv_length(const char **str_array) { size_t i; for (i=0; str_array[i] != NULL; i++) /* nothing */ ; return i; } /*}}}*/ // DeEscapeString - unescape (\0XX and \xXX) from a string /*{{{*/ // --------------------------------------------------------------------- /* */ string DeEscapeString(const string &input) { char tmp[3]; string::const_iterator it; string output; for (it = input.begin(); it != input.end(); ++it) { // just copy non-escape chars if (*it != '\\') { output += *it; continue; } // deal with double escape if (*it == '\\' && (it + 1 < input.end()) && it[1] == '\\') { // copy output += *it; // advance iterator one step further ++it; continue; } // ensure we have a char to read if (it + 1 == input.end()) continue; // read it ++it; switch (*it) { case '0': if (it + 2 <= input.end()) { tmp[0] = it[1]; tmp[1] = it[2]; tmp[2] = 0; output += (char)strtol(tmp, 0, 8); it += 2; } break; case 'x': if (it + 2 <= input.end()) { tmp[0] = it[1]; tmp[1] = it[2]; tmp[2] = 0; output += (char)strtol(tmp, 0, 16); it += 2; } break; default: // FIXME: raise exception here? break; } } return output; } /*}}}*/ // URI::CopyFrom - Copy from an object /*{{{*/ // --------------------------------------------------------------------- /* This parses the URI into all of its components */ void URI::CopyFrom(const string &U) { string::const_iterator I = U.begin(); // Locate the first colon, this separates the scheme for (; I < U.end() && *I != ':' ; ++I); string::const_iterator FirstColon = I; /* Determine if this is a host type URI with a leading double // and then search for the first single / */ string::const_iterator SingleSlash = I; if (I + 3 < U.end() && I[1] == '/' && I[2] == '/') SingleSlash += 3; /* Find the / indicating the end of the hostname, ignoring /'s in the square brackets */ bool InBracket = false; for (; SingleSlash < U.end() && (*SingleSlash != '/' || InBracket == true); ++SingleSlash) { if (*SingleSlash == '[') InBracket = true; if (InBracket == true && *SingleSlash == ']') InBracket = false; } if (SingleSlash > U.end()) SingleSlash = U.end(); // We can now write the access and path specifiers Access.assign(U.begin(),FirstColon); if (SingleSlash != U.end()) Path.assign(SingleSlash,U.end()); if (Path.empty() == true) Path = "/"; // Now we attempt to locate a user:pass@host fragment if (FirstColon + 2 <= U.end() && FirstColon[1] == '/' && FirstColon[2] == '/') FirstColon += 3; else FirstColon += 1; if (FirstColon >= U.end()) return; if (FirstColon > SingleSlash) FirstColon = SingleSlash; // Find the colon... I = FirstColon + 1; if (I > SingleSlash) I = SingleSlash; // Search for the @ separating user:pass from host auto const RevAt = std::find( std::string::const_reverse_iterator(SingleSlash), std::string::const_reverse_iterator(I), '@'); string::const_iterator const At = RevAt.base() == I ? SingleSlash : std::prev(RevAt.base()); // and then look for the colon between user and pass string::const_iterator const SecondColon = std::find(I, At, ':'); // Now write the host and user/pass if (At == SingleSlash) { if (FirstColon < SingleSlash) Host.assign(FirstColon,SingleSlash); } else { Host.assign(At+1,SingleSlash); // username and password must be encoded (RFC 3986) User.assign(DeQuoteString(FirstColon,SecondColon)); if (SecondColon < At) Password.assign(DeQuoteString(SecondColon+1,At)); } // Now we parse the RFC 2732 [] hostnames. unsigned long PortEnd = 0; InBracket = false; for (unsigned I = 0; I != Host.length();) { if (Host[I] == '[') { InBracket = true; Host.erase(I,1); continue; } if (InBracket == true && Host[I] == ']') { InBracket = false; Host.erase(I,1); PortEnd = I; continue; } I++; } // Tsk, weird. if (InBracket == true) { Host.clear(); return; } // Now we parse off a port number from the hostname Port = 0; string::size_type Pos = Host.rfind(':'); if (Pos == string::npos || Pos < PortEnd) return; Port = atoi(string(Host,Pos+1).c_str()); Host.assign(Host,0,Pos); } /*}}}*/ // URI::operator string - Convert the URI to a string /*{{{*/ // --------------------------------------------------------------------- /* */ URI::operator string() { std::stringstream Res; if (Access.empty() == false) Res << Access << ':'; if (Host.empty() == false) { if (Access.empty() == false) Res << "//"; if (User.empty() == false) { // FIXME: Technically userinfo is permitted even less // characters than these, but this is not conveniently // expressed with a blacklist. Res << QuoteString(User, ":/?#[]@"); if (Password.empty() == false) Res << ":" << QuoteString(Password, ":/?#[]@"); Res << "@"; } // Add RFC 2732 escaping characters if (Access.empty() == false && Host.find_first_of("/:") != string::npos) Res << '[' << Host << ']'; else Res << Host; if (Port != 0) Res << ':' << std::to_string(Port); } if (Path.empty() == false) { if (Path[0] != '/') Res << "/" << Path; else Res << Path; } return Res.str(); } /*}}}*/ // URI::SiteOnly - Return the schema and site for the URI /*{{{*/ string URI::SiteOnly(const string &URI) { ::URI U(URI); U.User.clear(); U.Password.clear(); U.Path.clear(); return U; } /*}}}*/ // URI::ArchiveOnly - Return the schema, site and cleaned path for the URI /*{{{*/ string URI::ArchiveOnly(const string &URI) { ::URI U(URI); U.User.clear(); U.Password.clear(); if (U.Path.empty() == false && U.Path[U.Path.length() - 1] == '/') U.Path.erase(U.Path.length() - 1); return U; } /*}}}*/ // URI::NoUserPassword - Return the schema, site and path for the URI /*{{{*/ string URI::NoUserPassword(const string &URI) { ::URI U(URI); U.User.clear(); U.Password.clear(); return U; } /*}}}*/