/* * Parser Functions * (C) 1999-2007 Jack Lloyd * * Distributed under the terms of the Botan license */ #include #include #include #include namespace Botan { /* * Convert a string into an integer */ u32bit to_u32bit(const std::string& number) { u32bit n = 0; for(std::string::const_iterator j = number.begin(); j != number.end(); ++j) { const u32bit OVERFLOW_MARK = 0xFFFFFFFF / 10; if(*j == ' ') continue; byte digit = Charset::char2digit(*j); if((n > OVERFLOW_MARK) || (n == OVERFLOW_MARK && digit > 5)) throw Decoding_Error("to_u32bit: Integer overflow"); n *= 10; n += digit; } return n; } /* * Convert an integer into a string */ std::string to_string(u64bit n, u32bit min_len) { std::string lenstr; if(n) { while(n > 0) { lenstr = Charset::digit2char(n % 10) + lenstr; n /= 10; } } else lenstr = "0"; while(lenstr.size() < min_len) lenstr = "0" + lenstr; return lenstr; } /* * Convert a string into a time duration */ u32bit timespec_to_u32bit(const std::string& timespec) { if(timespec == "") return 0; const char suffix = timespec[timespec.size()-1]; std::string value = timespec.substr(0, timespec.size()-1); u32bit scale = 1; if(Charset::is_digit(suffix)) value += suffix; else if(suffix == 's') scale = 1; else if(suffix == 'm') scale = 60; else if(suffix == 'h') scale = 60 * 60; else if(suffix == 'd') scale = 24 * 60 * 60; else if(suffix == 'y') scale = 365 * 24 * 60 * 60; else throw Decoding_Error("timespec_to_u32bit: Bad input " + timespec); return scale * to_u32bit(value); } /* * Parse a SCAN-style algorithm name */ std::vector parse_algorithm_name(const std::string& namex) { if(namex.find('(') == std::string::npos && namex.find(')') == std::string::npos) return std::vector(1, namex); std::string name = namex, substring; std::vector elems; u32bit level = 0; elems.push_back(name.substr(0, name.find('('))); name = name.substr(name.find('(')); for(std::string::const_iterator j = name.begin(); j != name.end(); ++j) { char c = *j; if(c == '(') ++level; if(c == ')') { if(level == 1 && j == name.end() - 1) { if(elems.size() == 1) elems.push_back(substring.substr(1)); else elems.push_back(substring); return elems; } if(level == 0 || (level == 1 && j != name.end() - 1)) throw Invalid_Algorithm_Name(namex); --level; } if(c == ',' && level == 1) { if(elems.size() == 1) elems.push_back(substring.substr(1)); else elems.push_back(substring); substring.clear(); } else substring += c; } if(substring != "") throw Invalid_Algorithm_Name(namex); return elems; } /* * Split the string on slashes */ std::vector split_on(const std::string& str, char delim) { std::vector elems; if(str == "") return elems; std::string substr; for(std::string::const_iterator j = str.begin(); j != str.end(); ++j) { if(*j == delim) { if(substr != "") elems.push_back(substr); substr.clear(); } else substr += *j; } if(substr == "") throw Format_Error("Unable to split string: " + str); elems.push_back(substr); return elems; } /* * Parse an ASN.1 OID string */ std::vector parse_asn1_oid(const std::string& oid) { std::string substring; std::vector oid_elems; for(std::string::const_iterator j = oid.begin(); j != oid.end(); ++j) { char c = *j; if(c == '.') { if(substring == "") throw Invalid_OID(oid); oid_elems.push_back(to_u32bit(substring)); substring.clear(); } else substring += c; } if(substring == "") throw Invalid_OID(oid); oid_elems.push_back(to_u32bit(substring)); if(oid_elems.size() < 2) throw Invalid_OID(oid); return oid_elems; } /* * X.500 String Comparison */ bool x500_name_cmp(const std::string& name1, const std::string& name2) { std::string::const_iterator p1 = name1.begin(); std::string::const_iterator p2 = name2.begin(); while((p1 != name1.end()) && Charset::is_space(*p1)) ++p1; while((p2 != name2.end()) && Charset::is_space(*p2)) ++p2; while(p1 != name1.end() && p2 != name2.end()) { if(Charset::is_space(*p1)) { if(!Charset::is_space(*p2)) return false; while((p1 != name1.end()) && Charset::is_space(*p1)) ++p1; while((p2 != name2.end()) && Charset::is_space(*p2)) ++p2; if(p1 == name1.end() && p2 == name2.end()) return true; } if(!Charset::caseless_cmp(*p1, *p2)) return false; ++p1; ++p2; } while((p1 != name1.end()) && Charset::is_space(*p1)) ++p1; while((p2 != name2.end()) && Charset::is_space(*p2)) ++p2; if((p1 != name1.end()) || (p2 != name2.end())) return false; return true; } /* * Convert a decimal-dotted string to binary IP */ u32bit string_to_ipv4(const std::string& str) { std::vector parts = split_on(str, '.'); if(parts.size() != 4) throw Decoding_Error("Invalid IP string " + str); u32bit ip = 0; for(size_t j = 0; j != parts.size(); j++) { u32bit octet = to_u32bit(parts[j]); if(octet > 255) throw Decoding_Error("Invalid IP string " + str); ip = (ip << 8) | (octet & 0xFF); } return ip; } /* * Convert an IP address to decimal-dotted string */ std::string ipv4_to_string(u32bit ip) { std::string str; for(size_t j = 0; j != sizeof(ip); j++) { if(j) str += "."; str += to_string(get_byte(j, ip)); } return str; } }