/* * Cppcheck - A tool for static C/C++ code analysis * Copyright (C) 2007-2014 Daniel Marjamäki and Cppcheck team. * * 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 . */ #include "mathlib.h" #include "errorlogger.h" #include #include #include #include #include #include MathLib::bigint MathLib::toLongNumber(const std::string &str) { // hexadecimal numbers: if (isHex(str)) { if (str[0] == '-') { bigint ret = 0; std::istringstream istr(str); istr >> std::hex >> ret; return ret; } else { unsigned long long ret = 0; std::istringstream istr(str); istr >> std::hex >> ret; return (bigint)ret; } } // octal numbers: if (isOct(str)) { bigint ret = 0; std::istringstream istr(str); istr >> std::oct >> ret; return ret; } // binary numbers: if (isBin(str)) { bigint ret = 0; for (std::string::size_type i = str[0] == '0'?2:3; i < str.length(); i++) { ret <<= 1; if (str[i] == '1') ret |= 1; } if (str[0] == '-') ret = -ret; return ret; } if (isFloat(str)) return static_cast(std::atof(str.c_str())); bigint ret = 0; std::istringstream istr(str); istr >> ret; return ret; } double MathLib::toDoubleNumber(const std::string &str) { if (isHex(str)) return static_cast(toLongNumber(str)); // nullcheck else if (isNullValue(str)) return 0.0; // otherwise, convert to double std::istringstream istr(str); double ret; istr >> ret; return ret; } template<> std::string MathLib::toString(double value) { std::ostringstream result; result.precision(12); result << value; if (result.str() == "-0") return "0.0"; if (result.str().find(".") == std::string::npos) return result.str() + ".0"; return result.str(); } bool MathLib::isFloat(const std::string &s) { if (s.empty()) return false; enum {START, BASE_PLUSMINUS, BASE_DIGITS1, LEADING_DECIMAL, TRAILING_DECIMAL, BASE_DIGITS2, E, MANTISSA_PLUSMINUS, MANTISSA_DIGITS, F} state = START; for (std::string::const_iterator it = s.begin(); it != s.end(); ++it) { switch (state) { case START: if (*it=='+' || *it=='-') state=BASE_PLUSMINUS; else if (*it=='.') state=LEADING_DECIMAL; else if (std::isdigit(*it)) state=BASE_DIGITS1; else return false; break; case BASE_PLUSMINUS: if (*it=='.') state=LEADING_DECIMAL; else if (std::isdigit(*it)) state=BASE_DIGITS1; else if (*it=='e' || *it=='E') state=E; else return false; break; case LEADING_DECIMAL: if (std::isdigit(*it)) state=BASE_DIGITS2; else if (*it=='e' || *it=='E') state=E; else return false; break; case BASE_DIGITS1: if (*it=='e' || *it=='E') state=E; else if (*it=='.') state=TRAILING_DECIMAL; else if (!std::isdigit(*it)) return false; break; case TRAILING_DECIMAL: if (*it=='e' || *it=='E') state=E; else if (std::isdigit(*it)) state=BASE_DIGITS2; else return false; break; case BASE_DIGITS2: if (*it=='e' || *it=='E') state=E; else if (*it=='f' || *it=='F') state=F; else if (!std::isdigit(*it)) return false; break; case E: if (*it=='+' || *it=='-') state=MANTISSA_PLUSMINUS; else if (std::isdigit(*it)) state=MANTISSA_DIGITS; else return false; break; case MANTISSA_PLUSMINUS: if (!std::isdigit(*it)) return false; else state=MANTISSA_DIGITS; break; case MANTISSA_DIGITS: if (*it=='f' || *it=='F') state=F; else if (!std::isdigit(*it)) return false; break; case F: return false; } } return (state==BASE_DIGITS2 || state == MANTISSA_DIGITS || state == TRAILING_DECIMAL || state == F); } bool MathLib::isNegative(const std::string &s) { // remember position std::string::size_type n = 0; // eat up whitespace while (std::isspace(s[n])) ++n; // every negative number has a negative sign return (s[n] == '-'); } bool MathLib::isPositive(const std::string &s) { return !MathLib::isNegative(s); } bool MathLib::isOct(const std::string& str) { const bool sign = str[0]=='-' || str[0]=='+'; return (str[sign?1:0] == '0' && (str.size() == 1 || isOctalDigit(str[sign?2:1])) && !isFloat(str)); } bool MathLib::isHex(const std::string& str) { const bool sign = str[0]=='-' || str[0]=='+'; return (str.compare(sign?1:0, 2, "0x") == 0 || str.compare(sign?1:0, 2, "0X") == 0); } /*! \brief Does the string represent a binary number? * In case leading or trailing white space is provided, the function * returns false. * Additional information can be found here: * http://gcc.gnu.org/onlinedocs/gcc/Binary-constants.html * * \param[in] s The string to check. In case the string is empty, the function returns false. * \return Return true in case a binary number is provided and false otherwise. **/ bool MathLib::isBin(const std::string& s) { enum {START, PLUSMINUS, GNU_BIN_PREFIX, DIGIT, DIGITS, SUFFIX_U, SUFFIX_UL, SUFFIX_ULL, SUFFIX_L, SUFFIX_LU, SUFFIX_LL, SUFFIX_LLU} state = START; for (std::string::const_iterator it = s.begin(); it != s.end(); ++it) { switch (state) { case START: if (*it == '+' || *it == '-') state = PLUSMINUS; else if (*it == '0') state = GNU_BIN_PREFIX; else return false; break; case PLUSMINUS: if (*it == '0') state = GNU_BIN_PREFIX; else return false; break; case GNU_BIN_PREFIX: if (*it == 'b' || *it == 'B') state = DIGIT; else return false; break; case DIGIT: if (*it == '0' || *it == '1') state = DIGITS; else return false; break; case DIGITS: if (*it == '0' || *it == '1') state = DIGITS; else if (*it == 'u' || *it == 'U') state = SUFFIX_U; else if (*it == 'l' || *it == 'L') state = SUFFIX_L; else return false; break; case SUFFIX_U: if (*it == 'l' || *it == 'L') state = SUFFIX_UL; // UL else return false; break; case SUFFIX_UL: if (*it == 'l' || *it == 'L') state = SUFFIX_ULL; // ULL else return false; break; case SUFFIX_L: if (*it == 'u' || *it == 'U') state = SUFFIX_LU; // LU else if (*it == 'l' || *it == 'L') state = SUFFIX_LL; // LL else return false; break; case SUFFIX_LU: return false; break; case SUFFIX_LL: if (*it == 'u' || *it == 'U') state = SUFFIX_LLU; // LLU else return false; break; default: return false; } } return (state == DIGITS) || (state == SUFFIX_U) || (state == SUFFIX_L) || (state == SUFFIX_UL) || (state == SUFFIX_LU) || (state == SUFFIX_LL) || (state == SUFFIX_ULL) || (state == SUFFIX_LLU); } bool MathLib::isInt(const std::string & s) { // perform prechecks: // ------------------ // first check, if a point is found, it is an floating point value const std::string charsToIndicateAFloat=".eE"; if (s.find_last_of(charsToIndicateAFloat) != std::string::npos) return false; // prechecking has nothing found,... // gather information enum Representation { eOctal, // starts with 0 eHex, // starts with 0x eDefault // Numbers with a (possible) trailing u or U or l or L for unsigned or long datatypes }; // create an instance Representation Mode = eDefault; // remember position unsigned long n = 0; // eat up whitespace while (std::isspace(s[n])) ++n; // determine type if (isHex(s)) { Mode = eHex; } else if (isOct(s)) { Mode = eOctal; } // check sign if (s[n] == '-' || s[n] == '+') ++n; if (Mode == eHex) { ++n; // 0 ++n; // x while (std::isxdigit(s[n])) ++n; while (std::tolower(s[n]) == 'u' || std::tolower(s[n]) == 'l') ++n; // unsigned or long (long) } // check octal notation else if (Mode == eOctal) { ++n; // 0 while (isOctalDigit(s[n])) ++n; while (std::tolower(s[n]) == 'u' || std::tolower(s[n]) == 'l') ++n; // unsigned or long (long) } else if (Mode == eDefault) { // starts with digit bool bStartsWithDigit=false; while (std::isdigit(s[n])) { bStartsWithDigit=true; ++n; }; while (std::tolower(s[n]) == 'u' || std::tolower(s[n]) == 'l') ++n; // unsigned or long (long) if (!bStartsWithDigit) return false; } // eat up whitespace while (std::isspace(s[n])) ++n; // if everything goes good, we are at the end of the string and no digits/character // is here --> return true, but if something was found e.g. 12E+12AA return false return (n >= s.length()); } std::string MathLib::add(const std::string & first, const std::string & second) { if (MathLib::isInt(first) && MathLib::isInt(second)) { return toString(toLongNumber(first) + toLongNumber(second)); } double d1 = toDoubleNumber(first); double d2 = toDoubleNumber(second); int count = 0; while (d1 > 100000.0 * d2 && toString(d1+d2)==first && ++count<5) d2 *= 10.0; while (d2 > 100000.0 * d1 && toString(d1+d2)==second && ++count<5) d1 *= 10.0; return toString(d1 + d2); } std::string MathLib::subtract(const std::string &first, const std::string &second) { if (MathLib::isInt(first) && MathLib::isInt(second)) { return toString(toLongNumber(first) - toLongNumber(second)); } if (first == second) return "0.0" ; double d1 = toDoubleNumber(first); double d2 = toDoubleNumber(second); int count = 0; while (d1 > 100000.0 * d2 && toString(d1-d2)==first && ++count<5) d2 *= 10.0; while (d2 > 100000.0 * d1 && toString(d1-d2)==second && ++count<5) d1 *= 10.0; return toString(d1 - d2); } std::string MathLib::divide(const std::string &first, const std::string &second) { if (MathLib::isInt(first) && MathLib::isInt(second)) { const bigint a = toLongNumber(first); const bigint b = toLongNumber(second); if (a == std::numeric_limits::min()) throw InternalError(0, "Internal Error: Division overflow"); if (b == 0) throw InternalError(0, "Internal Error: Division by zero"); return toString(toLongNumber(first) / b); } else if (second == "0.0") { if (first=="0.0" || first=="+0.0") return "nan.0"; if (first=="-0.0") return "-nan.0"; return (first[0] == '-') ? "-inf.0" : "inf.0"; } return toString(toDoubleNumber(first) / toDoubleNumber(second)); } std::string MathLib::multiply(const std::string &first, const std::string &second) { if (MathLib::isInt(first) && MathLib::isInt(second)) { return toString(toLongNumber(first) * toLongNumber(second)); } return toString(toDoubleNumber(first) * toDoubleNumber(second)); } std::string MathLib::mod(const std::string &first, const std::string &second) { if (MathLib::isInt(first) && MathLib::isInt(second)) { bigint b = toLongNumber(second); if (b == 0) throw InternalError(0, "Internal Error: Division by zero"); return toString(toLongNumber(first) % b); } return toString(std::fmod(toDoubleNumber(first),toDoubleNumber(second))); } std::string MathLib::calculate(const std::string &first, const std::string &second, char action) { switch (action) { case '+': return MathLib::add(first, second); case '-': return MathLib::subtract(first, second); case '*': return MathLib::multiply(first, second); case '/': return MathLib::divide(first, second); case '%': return MathLib::mod(first, second); case '&': return MathLib::toString(MathLib::toLongNumber(first) & MathLib::toLongNumber(second)); case '|': return MathLib::toString(MathLib::toLongNumber(first) | MathLib::toLongNumber(second)); case '^': return MathLib::toString(MathLib::toLongNumber(first) ^ MathLib::toLongNumber(second)); default: throw InternalError(0, std::string("Unexpected action '") + action + "' in MathLib::calculate(). Please report this to Cppcheck developers."); } } std::string MathLib::sin(const std::string &tok) { return toString(std::sin(toDoubleNumber(tok))); } std::string MathLib::cos(const std::string &tok) { return toString(std::cos(toDoubleNumber(tok))); } std::string MathLib::tan(const std::string &tok) { return toString(std::tan(toDoubleNumber(tok))); } std::string MathLib::abs(const std::string &tok) { return toString(std::abs(toDoubleNumber(tok))); } bool MathLib::isEqual(const std::string &first, const std::string &second) { // this conversion is needed for formatting // e.g. if first=0.1 and second=1.0E-1, the direct comparison of the strings would fail return toString(toDoubleNumber(first)) == toString(toDoubleNumber(second)); } bool MathLib::isNotEqual(const std::string &first, const std::string &second) { return !isEqual(first, second); } bool MathLib::isGreater(const std::string &first, const std::string &second) { return toDoubleNumber(first) > toDoubleNumber(second); } bool MathLib::isGreaterEqual(const std::string &first, const std::string &second) { return toDoubleNumber(first) >= toDoubleNumber(second); } bool MathLib::isLess(const std::string &first, const std::string &second) { return toDoubleNumber(first) < toDoubleNumber(second); } bool MathLib::isLessEqual(const std::string &first, const std::string &second) { return toDoubleNumber(first) <= toDoubleNumber(second); } bool MathLib::isNullValue(const std::string &str) { return (str == "-0" || str == "0" || str == "+0" || str == "-0.0" || str == "0.0" || str == "+0.0" || str == "-0." || str == "+0." || str == "-0E-00" || str == "-0E+00" || str == "+0E+00" || str == "+0E-00" || str == "-0e-00" || str == "-0e+00" || str == "+0e+00" || str == "+0e-00" || str == "-0E-0"); } bool MathLib::isOctalDigit(char c) { return (c == '0' || c == '1' || c == '2' || c == '3' || c == '4' || c == '5' || c == '6' || c == '7'); }