/* **************************************************************** * C++ Mathematical Expression Toolkit Library * * * * Author: Arash Partow (1999-2013) * * URL: http://www.partow.net/programming/exprtk/index.html * * * * Copyright notice: * * Free use of the C++ Mathematical Expression Toolkit Library * * is permitted under the guidelines and in accordance with the * * most current version of the Common Public License. * * http://www.opensource.org/licenses/cpl1.0.php * * * * Example expressions: * * (00) (y+x/y)*(x-y/x) * * (01) (x^2/sin(2*pi/y))-x/2 * * (02) sqrt(1-(x^2)) * * (03) 1-sin(2*x)+cos(pi/y) * * (04) a*exp(2*t)+c * * (05) if(((x+2)==3)and((y+5)<=9),1+w,2/z) * * (06) if(avg(x,y)<=x+y,x-y,x*y)+2*pi/x * * (07) z:=x+sin(2*pi/y) * * (08) u:=2*(pi*z)/(w:=x+cos(y/pi)) * * (09) clamp(-1,sin(2*pi*x)+cos(y/2*pi),+1) * * (10) inrange(-2,m,+2)==if(({-2<=m} and [m<=+2]),1,0) * * (11) (12.34sin(x)cos(2y)7+1)==(12.34*sin(x)*cos(2*y)*7+1) * * (12) (x ilike 's*ri?g') and [y<(3z^7+w)] * * * **************************************************************** */ #ifndef INCLUDE_EXPRTK_HPP #define INCLUDE_EXPRTK_HPP #include #include #include #include #include #include #include #include #include #include #include #ifndef exprtk_enable_all_optimizations # define exprtk_lean_and_mean # ifdef exprtk_lean_and_mean_numeric_only # ifndef exprtk_lean_and_mean # define exprtk_lean_and_mean # endif # ifndef exprtk_disable_string_capabilities # define exprtk_disable_string_capabilities # endif # endif # ifdef exprtk_lean_and_mean # ifndef exprtk_disable_extended_operator_optimizations # define exprtk_disable_extended_operator_optimizations # endif # ifndef exprtk_disable_extended_optimisations # define exprtk_disable_extended_optimisations # endif # endif #endif namespace exprtk { namespace details { inline bool is_whitespace(const char c) { return (' ' == c) || ('\n' == c) || ('\r' == c) || ('\t' == c) || ('\b' == c) || ('\v' == c) || ('\f' == c) ; } inline bool is_operator_char(const char c) { return ('+' == c) || ('-' == c) || ('*' == c) || ('/' == c) || ('^' == c) || ('<' == c) || ('>' == c) || ('=' == c) || (',' == c) || ('!' == c) || ('(' == c) || (')' == c) || ('[' == c) || (']' == c) || ('{' == c) || ('}' == c) || ('%' == c) || (':' == c) || ('?' == c); } inline bool is_letter(const char c) { return (('a' <= c) && (c <= 'z')) || (('A' <= c) && (c <= 'Z')); } inline bool is_digit(const char c) { return ('0' <= c) && (c <= '9'); } inline bool is_letter_or_digit(const char c) { return is_letter(c) || is_digit(c); } inline bool is_left_bracket(const char c) { return ('(' == c) || ('[' == c) || ('{' == c); } inline bool is_right_bracket(const char c) { return (')' == c) || (']' == c) || ('}' == c); } inline bool is_bracket(const char c) { return is_left_bracket(c) || is_right_bracket(c); } inline bool is_sign(const char c) { return ('+' == c) || ('-' == c); } inline bool is_invalid(const char c) { return !is_whitespace(c) && !is_operator_char(c) && !is_letter(c) && !is_digit(c) && ('.' != c) && ('_' != c) && ('$' != c) && ('\'' != c); } inline bool imatch(const char c1, const char c2) { return std::tolower(c1) == std::tolower(c2); } inline bool imatch(const std::string& s1, const std::string& s2) { if (s1.size() == s2.size()) { for (std::size_t i = 0; i < s1.size(); ++i) { if (std::tolower(s1[i]) != std::tolower(s2[i])) { return false; } } return true; } return false; } inline bool is_valid_sf_symbol(const std::string& symbol) { //Special function: $f12 or $F34 return (symbol.size() == 4) && ('$' == symbol[0]) && imatch('f',symbol[1]) && is_digit(symbol[2]) && is_digit(symbol[3]); } inline std::string to_str(int i) { if (0 == i) return std::string("0"); std::string result; bool negative = (i < 0); if (negative) i *= -1; while (i) { char digit = '0' + char(i % 10); result = (digit + result); i /= 10; } if (negative) result = "-" + result; return result; } struct ilesscompare { inline bool operator()(const std::string& s1, const std::string& s2) const { const std::size_t length = std::min(s1.size(),s2.size()); for (std::size_t i = 0; i < length; ++i) { if (std::tolower(s1[i]) > std::tolower(s2[i])) return false; else if (std::tolower(s1[i]) < std::tolower(s2[i])) return true; } return s1.size() < s2.size(); } }; static const std::string reserved_words[] = { "and", "false", "for", "if", "ilike", "in", "like", "nand", "nor", "not", "or", "shl", "shr", "true", "while", "xor" }; static const std::size_t reserved_words_size = sizeof(reserved_words) / sizeof(std::string); static const std::string reserved_symbols[] = { "abs", "acos", "and", "asin", "atan", "atan2", "avg", "ceil", "clamp", "cos", "cosh", "cot", "csc", "deg2grad", "deg2rad", "equal", "erf", "erfc", "exp", "false", "floor", "for", "frac", "grad2deg", "hyp", "if", "ilike", "in", "inrange", "like", "log", "log10", "logn", "max", "min", "mod", "mul", "nand", "nor", "not", "not_equal", "or", "pow", "rad2deg", "root", "round", "roundn", "sec", "sgn", "shl", "shr", "sin", "sinh", "sqrt", "sum", "tan", "tanh", "true", "trunc", "while", "xor" }; static const std::size_t reserved_symbols_size = sizeof(reserved_symbols) / sizeof(std::string); inline bool is_reserved_word(const std::string& symbol) { for (std::size_t i = 0; i < reserved_words_size; ++i) { if (imatch(symbol,reserved_words[i])) { return true; } } return false; } inline bool is_reserved_symbol(const std::string& symbol) { for (std::size_t i = 0; i < reserved_symbols_size; ++i) { if (imatch(symbol,reserved_symbols[i])) { return true; } } return false; } struct cs_match { static inline bool cmp(const char c0, const char c1) { return c0 == c1; } }; struct cis_match { static inline bool cmp(const char c0, const char c1) { return std::tolower(c0) == std::tolower(c1); } }; template inline bool match_impl(const Iterator pattern_begin, const Iterator pattern_end, const Iterator data_begin, const Iterator data_end, const typename std::iterator_traits::value_type& zero_or_more, const typename std::iterator_traits::value_type& zero_or_one) { if (0 == std::distance(data_begin,data_end)) return false; Iterator d_itr = data_begin; Iterator p_itr = pattern_begin; Iterator c_itr = data_begin; Iterator m_itr = data_begin; while ((data_end != d_itr) && (zero_or_more != (*p_itr))) { if ((!Compare::cmp((*p_itr),(*d_itr))) && (zero_or_one != (*p_itr))) { return false; } ++p_itr; ++d_itr; } while (data_end != d_itr) { if (zero_or_more == (*p_itr)) { if (pattern_end == (++p_itr)) { return true; } m_itr = p_itr; c_itr = d_itr; ++c_itr; } else if ((Compare::cmp((*p_itr),(*d_itr))) || (zero_or_one == (*p_itr))) { ++p_itr; ++d_itr; } else { p_itr = m_itr; d_itr = c_itr++; } } while ((p_itr != pattern_end) && (zero_or_more == (*p_itr))) ++p_itr; return (p_itr == pattern_end); } inline bool wc_match(const std::string& wild_card, const std::string& str) { return match_impl(wild_card.data(), wild_card.data() + wild_card.size(), str.data(), str.data() + str.size(), '*', '?'); } inline bool wc_imatch(const std::string& wild_card, const std::string& str) { return match_impl(wild_card.data(), wild_card.data() + wild_card.size(), str.data(), str.data() + str.size(), '*', '?'); } static const double pow10[] = { 1.0, 10.0, 100.0, 1000.0, 10000.0, 100000.0, 1000000.0, 10000000.0, 100000000.0, 1000000000.0, 10000000000.0, 100000000000.0, 1000000000000.0, 10000000000000.0, 100000000000000.0, 1000000000000000.0, 10000000000000000.0, }; namespace numeric { namespace constant { static const double e = 2.718281828459045235360; static const double pi = 3.141592653589793238462; static const double pi_2 = 1.570796326794896619231; static const double pi_4 = 0.785398163397448309616; static const double pi_180 = 0.017453292519943295769; static const double _1_pi = 0.318309886183790671538; static const double _2_pi = 0.636619772367581343076; static const double _180_pi = 57.295779513082320876798; } namespace details { struct unknown_type_tag {}; struct real_type_tag {}; struct int_type_tag {}; template struct number_type { typedef unknown_type_tag type; }; #define exprtk_register_real_type_tag(T)\ template<> struct number_type { typedef real_type_tag type; }; #define exprtk_register_int_type_tag(T)\ template<> struct number_type { typedef int_type_tag type; }; exprtk_register_real_type_tag(double) exprtk_register_real_type_tag(long double) exprtk_register_real_type_tag(float) exprtk_register_int_type_tag(short) exprtk_register_int_type_tag(int) exprtk_register_int_type_tag(long long int) exprtk_register_int_type_tag(unsigned short) exprtk_register_int_type_tag(unsigned int) exprtk_register_int_type_tag(unsigned long long int) #undef exprtk_register_real_type_tag #undef exprtk_register_int_type_tag template inline T equal_impl(const T& v0, const T& v1, real_type_tag) { static const T epsilon = T(0.00000000001); return (std::abs(v0 - v1) <= (std::max(T(1),std::max(std::abs(v0),std::abs(v1))) * epsilon)) ? T(1) : T(0); } template inline T equal_impl(const T& v0, const T& v1, int_type_tag) { return (v0 == v1) ? 1 : 0; } template inline T nequal_impl(const T& v0, const T& v1, real_type_tag) { static const T epsilon = T(0.0000000001); return (std::abs(v0 - v1) > (std::max(T(1),std::max(std::abs(v0),std::abs(v1))) * epsilon)) ? T(1) : T(0); } template inline T nequal_impl(const T& v0, const T& v1, int_type_tag) { return (v0 != v1) ? 1 : 0; } template inline T modulus_impl(const T& v0, const T& v1, real_type_tag) { return std::fmod(v0,v1); } template inline T modulus_impl(const T& v0, const T& v1, int_type_tag) { return v0 % v1; } template inline T pow_impl(const T& v0, const T& v1, real_type_tag) { return std::pow(v0,v1); } template inline T pow_impl(const T& v0, const T& v1, int_type_tag) { return std::pow(static_cast(v0),static_cast(v1)); } template inline T logn_impl(const T& v0, const T& v1, real_type_tag) { return std::log(v0) / std::log(v1); } template inline T logn_impl(const T& v0, const T& v1, int_type_tag) { return static_cast(logn_impl(static_cast(v0),static_cast(v1),real_type_tag())); } template inline T root_impl(const T& v0, const T& v1, real_type_tag) { return std::pow(v0,T(1)/v1); } template inline T root_impl(const T& v0, const T& v1, int_type_tag) { return root_impl(static_cast(v0),static_cast(v1),real_type_tag()); } template inline T roundn_impl(const T& v0, const T& v1, real_type_tag) { return T(std::floor((v0 * pow10[(int)std::floor(v1)]) + T(0.5)) / T(pow10[(int)std::floor(v1)])); } template inline T roundn_impl(const T& v0, const T&, int_type_tag) { return v0; } template inline T hyp_impl(const T& v0, const T& v1, real_type_tag) { return std::sqrt((v0 * v0) + (v1 * v1)); } template inline T hyp_impl(const T& v0, const T& v1, int_type_tag) { return static_cast(std::sqrt(static_cast((v0 * v0) + (v1 * v1)))); } template inline T atan2_impl(const T& v0, const T& v1, real_type_tag) { return std::atan2(v0,v1); } template inline T atan2_impl(const T&, const T&, int_type_tag) { return 0; } template inline T shr_impl(const T& v0, const T& v1, real_type_tag) { return v0 * (T(1) / std::pow(T(2),static_cast(static_cast(v1)))); } template inline T shr_impl(const T& v0, const T& v1, int_type_tag) { return v0 >> v1; } template inline T shl_impl(const T& v0, const T& v1, real_type_tag) { return v0 * std::pow(T(2),static_cast(static_cast(v1))); } template inline T shl_impl(const T& v0, const T& v1, int_type_tag) { return v0 << v1; } template inline T sgn_impl(const T& v, real_type_tag) { if (v > T(0.0)) return T(+1.0); else if (v < T(0.0)) return T(-1.0); else return T( 0.0); } template inline T sgn_impl(const T& v, int_type_tag) { if (v > T(0)) return T(+1); else if (v < T(0)) return T(-1); else return T( 0); } template inline T xor_impl(const T& v0, const T& v1, real_type_tag) { return v0 != v1; } template inline T xor_impl(const T& v0, const T& v1, int_type_tag) { return v0 ^ v1; } template inline T erf_impl(T v, real_type_tag) { #if defined(_WIN32) || defined(__WIN32__) || defined(WIN32) //Note: This should not be required for mscv 11.+ T a1 = T(+0.254829592); T a2 = T(-0.284496736); T a3 = T(+1.421413741); T a4 = T(-1.453152027); T a5 = T(+1.061405429); T p = T( 0.327591100); T sign = T(1.0); if (v < 0) { sign = -1; v = abs(v); } T t = T(1.0) / (T(1.0) + p * v); T y = T(1.0) - (((((a5 * t + a4) * t) + a3) * t + a2) * t + a1) * t * std::exp(-v * v); return sign * y; #else return ::erf(v); #endif } template inline T erf_impl(T v, int_type_tag) { return erf_impl(static_cast(v),real_type_tag()); } template inline T erfc_impl(T v, real_type_tag) { #if defined(_WIN32) || defined(__WIN32__) || defined(WIN32) return T(1.0) - erf_impl(v,real_type_tag()); #else return ::erfc(v); #endif } template inline T erfc_impl(T v, int_type_tag) { return erfc_impl(static_cast(v),real_type_tag()); } template inline T abs_impl(const T v, real_type_tag) { return std::abs (v); } template inline T acos_impl(const T v, real_type_tag) { return std::acos (v); } template inline T asin_impl(const T v, real_type_tag) { return std::asin (v); } template inline T atan_impl(const T v, real_type_tag) { return std::atan (v); } template inline T ceil_impl(const T v, real_type_tag) { return std::ceil (v); } template inline T cos_impl(const T v, real_type_tag) { return std::cos (v); } template inline T cosh_impl(const T v, real_type_tag) { return std::cosh (v); } template inline T exp_impl(const T v, real_type_tag) { return std::exp (v); } template inline T floor_impl(const T v, real_type_tag) { return std::floor(v); } template inline T log_impl(const T v, real_type_tag) { return std::log (v); } template inline T log10_impl(const T v, real_type_tag) { return std::log10(v); } template inline T neg_impl(const T v, real_type_tag) { return -v; } template inline T pos_impl(const T v, real_type_tag) { return +v; } template inline T round_impl(const T v, real_type_tag) { return std::floor(v + T(0.5)); } template inline T sin_impl(const T v, real_type_tag) { return std::sin (v); } template inline T sinh_impl(const T v, real_type_tag) { return std::sinh (v); } template inline T sqrt_impl(const T v, real_type_tag) { return std::sqrt (v); } template inline T tan_impl(const T v, real_type_tag) { return std::tan (v); } template inline T tanh_impl(const T v, real_type_tag) { return std::tanh (v); } template inline T cot_impl(const T v, real_type_tag) { return T(1) / std::tan(v); } template inline T sec_impl(const T v, real_type_tag) { return T(1) / std::cos(v); } template inline T csc_impl(const T v, real_type_tag) { return T(1) / std::sin(v); } template inline T r2d_impl(const T v, real_type_tag) { return (v * T(numeric::constant::_180_pi)); } template inline T d2r_impl(const T v, real_type_tag) { return (v * T(numeric::constant::pi_180)); } template inline T d2g_impl(const T v, real_type_tag) { return (v * T(20.0/9.0)); } template inline T g2d_impl(const T v, real_type_tag) { return (v * T(9.0/20.0)); } template inline T notl_impl(const T v, real_type_tag) { return (v != T(0) ? T(0) : T(1)); } template inline T frac_impl(const T v, real_type_tag) { return (v - static_cast(v)); } template inline T trunc_impl(const T v, real_type_tag) { return T(static_cast(v)); } template inline T abs_impl(const T v, int_type_tag) { return std::abs (v); } template inline T exp_impl(const T v, int_type_tag) { return std::exp (v); } template inline T log_impl(const T v, int_type_tag) { return std::log (v); } template inline T log10_impl(const T v, int_type_tag) { return std::log10(v); } template inline T neg_impl(const T v, int_type_tag) { return -v; } template inline T pos_impl(const T v, int_type_tag) { return +v; } template inline T ceil_impl(const T v, int_type_tag) { return v; } template inline T floor_impl(const T v, int_type_tag) { return v; } template inline T round_impl(const T v, int_type_tag) { return v; } template inline T notl_impl(const T v, int_type_tag) { return !v; } template inline T sqrt_impl(const T v, int_type_tag) { return std::sqrt (v); } template inline T frac_impl(const T v, int_type_tag) { return T(0); } template inline T trunc_impl(const T v, int_type_tag) { return v; } template inline T acos_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T asin_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T atan_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T cos_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T cosh_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T sin_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T sinh_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T tan_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T tanh_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T cot_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T sec_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline T csc_impl(const T , int_type_tag) { return std::numeric_limits::quiet_NaN(); } template inline bool is_integer_impl(const T& v, real_type_tag) { return (T(0.0) == std::fmod(v,T(1.0))); } template inline bool is_integer_impl(const T&, int_type_tag) { return true; } } template struct numeric_info { enum { length = 0, size = 32, bound_length = 0, min_exp = 0, max_exp = 0 }; }; template<> struct numeric_info { enum { length = 10, size = 16, bound_length = 9}; }; template<> struct numeric_info { enum { min_exp = -38, max_exp = +38}; }; template<> struct numeric_info { enum { min_exp = -308, max_exp = +308}; }; template<> struct numeric_info { enum { min_exp = -308, max_exp = +308}; }; template inline T equal(const T v0, const T v1) { typename details::number_type::type num_type; return details::equal_impl(v0,v1,num_type); } template inline T nequal(const T v0, const T v1) { typename details::number_type::type num_type; return details::nequal_impl(v0,v1,num_type); } template inline T modulus(const T v0, const T v1) { typename details::number_type::type num_type; return details::modulus_impl(v0,v1,num_type); } template inline T pow(const T v0, const T v1) { typename details::number_type::type num_type; return details::pow_impl(v0,v1,num_type); } template inline T logn(const T v0, const T v1) { typename details::number_type::type num_type; return details::logn_impl(v0,v1,num_type); } template inline T root(const T v0, const T v1) { typename details::number_type::type num_type; return details::root_impl(v0,v1,num_type); } template inline T roundn(const T v0, const T v1) { typename details::number_type::type num_type; return details::roundn_impl(v0,v1,num_type); } template inline T hyp(const T v0, const T v1) { typename details::number_type::type num_type; return details::hyp_impl(v0,v1,num_type); } template inline T atan2(const T v0, const T v1) { typename details::number_type::type num_type; return details::atan2_impl(v0,v1,num_type); } template inline T shr(const T v0, const T v1) { typename details::number_type::type num_type; return details::shr_impl(v0,v1,num_type); } template inline T shl(const T v0, const T v1) { typename details::number_type::type num_type; return details::shl_impl(v0,v1,num_type); } template inline T xor_opr(const T v0, const T v1) { typename details::number_type::type num_type; return details::xor_impl(v0,v1,num_type); } template inline bool is_integer(const T v) { typename details::number_type::type num_type; return details::is_integer_impl(v,num_type); } template struct fast_exp { static inline T result(T v) { unsigned int k = N; T l = T(1); while (k) { if (k & 1) { l *= v; --k; } v *= v; k >>= 1; } return l; } }; template struct fast_exp { static inline T result(T v) { T v_5 = fast_exp::result(v); return v_5 * v_5; } }; template struct fast_exp { static inline T result(T v) { return fast_exp::result(v) * v; } }; template struct fast_exp { static inline T result(T v) { T v_4 = fast_exp::result(v); return v_4 * v_4; } }; template struct fast_exp { static inline T result(T v) { return fast_exp::result(v) * v; } }; template struct fast_exp { static inline T result(T v) { T v_3 = fast_exp::result(v); return v_3 * v_3; } }; template struct fast_exp { static inline T result(T v) { return fast_exp::result(v) * v; } }; template struct fast_exp { static inline T result(T v) { T v_2 = v * v; return v_2 * v_2; } }; template struct fast_exp { static inline T result(T v) { return v * v * v; } }; template struct fast_exp { static inline T result(T v) { return v * v; } }; template struct fast_exp { static inline T result(T v) { return v; } }; template struct fast_exp { static inline T result(T ) { return T(1); } }; #define exprtk_define_unary_function(FunctionName) \ template \ inline T FunctionName (const T v) \ { \ typename details::number_type::type num_type; \ return details:: FunctionName##_impl(v,num_type); \ } exprtk_define_unary_function(abs ) exprtk_define_unary_function(acos ) exprtk_define_unary_function(asin ) exprtk_define_unary_function(atan ) exprtk_define_unary_function(ceil ) exprtk_define_unary_function(cos ) exprtk_define_unary_function(cosh ) exprtk_define_unary_function(exp ) exprtk_define_unary_function(floor) exprtk_define_unary_function(log ) exprtk_define_unary_function(log10) exprtk_define_unary_function(neg ) exprtk_define_unary_function(pos ) exprtk_define_unary_function(round) exprtk_define_unary_function(sin ) exprtk_define_unary_function(sinh ) exprtk_define_unary_function(sqrt ) exprtk_define_unary_function(tan ) exprtk_define_unary_function(tanh ) exprtk_define_unary_function(cot ) exprtk_define_unary_function(sec ) exprtk_define_unary_function(csc ) exprtk_define_unary_function(r2d ) exprtk_define_unary_function(d2r ) exprtk_define_unary_function(d2g ) exprtk_define_unary_function(g2d ) exprtk_define_unary_function(notl ) exprtk_define_unary_function(sgn ) exprtk_define_unary_function(erf ) exprtk_define_unary_function(erfc ) exprtk_define_unary_function(frac ) exprtk_define_unary_function(trunc) #undef exprtk_define_unary_function } template static inline bool string_to_type_converter_impl_ref(Iterator& itr, const Iterator end, Type& result) { if (end == itr) return false; Type t = 0; bool negative = false; if ('+' == (*itr)) ++itr; else if ('-' == (*itr)) { ++itr; negative = true; } if (end == itr) return false; unsigned int digit_count = 0; while ((end != itr) && ('0' == (*itr))) ++itr; bool return_result = true; while (end != itr) { const unsigned char digit = (*itr - '0'); if (digit > 9) { return_result = false; break; } if ((++digit_count) <= numeric::numeric_info::bound_length) { t *= 10; t += digit; } else { typedef unsigned long long int base_type; static const base_type max_limit = +std::numeric_limits::max(); static const base_type min_limit = -std::numeric_limits::min(); base_type tmp = static_cast(t) * 10 + digit; if (negative && static_cast(tmp) > min_limit) return_result = false; else if (static_cast(tmp) > max_limit) return_result = false; t = static_cast(tmp); } ++itr; } result = static_cast((negative) ? -t : t); return return_result; } template static inline bool parse_nan(Iterator& itr, const Iterator end, T& t) { typedef typename std::iterator_traits::value_type type; static const std::size_t nan_length = 3; if (std::distance(itr,end) != static_cast(nan_length)) return false; if (static_cast('n') == (*itr)) { if ((static_cast('a') != *(itr + 1)) || (static_cast('n') != *(itr + 2))) { return false; } } else if ((static_cast('A') != *(itr + 1)) || (static_cast('N') != *(itr + 2))) { return false; } t = std::numeric_limits::quiet_NaN(); return true; } template static inline bool parse_inf(Iterator& itr, const Iterator end, T& t, bool negative) { static const char inf_uc[] = "INFINITY"; static const char inf_lc[] = "infinity"; static const std::size_t inf_length = 8; const std::size_t length = std::distance(itr,end); if ((3 != length) && (inf_length != length)) return false; const char* inf_itr = ('i' == (*itr)) ? inf_lc : inf_uc; while (end != itr) { if (*inf_itr == static_cast(*itr)) { ++itr; ++inf_itr; continue; } else return false; } if (negative) t = -std::numeric_limits::infinity(); else t = std::numeric_limits::infinity(); return true; } template inline bool string_to_real(Iterator& itr_external, const Iterator end, T& t) { if (end == itr_external) return false; Iterator itr = itr_external; double d = 0.0; bool negative = false; if ('+' == (*itr)) ++itr; else if ('-' == (*itr)) { ++itr; negative = true; } if (end == itr) return false; if (('I' <= (*itr)) && ((*itr) <= 'n')) { if (('i' == (*itr)) || ('I' == (*itr))) { return parse_inf(itr,end,t,negative); } else if (('n' == (*itr)) || ('N' == (*itr))) { return parse_nan(itr,end,t); } else return false; } bool instate = false; int pre_decimal = 0; if ('.' != (*itr)) { const Iterator curr = itr; while ((end != itr) && ('0' == (*itr))) ++itr; const Iterator post_zero_cull_itr = itr; unsigned char digit = 0; #define parse_digit_1 \ if ((digit = static_cast((*itr) - '0')) < 10) { d *= 10.0; d += digit; } else break; if (end == ++itr) break; \ #define parse_digit_2 \ if ((digit = static_cast((*itr) - '0')) < 10) { d *= 10.0; d += digit; } else break; ++itr;\ while (end != itr) { parse_digit_1 parse_digit_1 parse_digit_1 parse_digit_1 parse_digit_1 parse_digit_1 parse_digit_1 parse_digit_2 } #undef parse_digit_1 #undef parse_digit_2 if (curr != itr) instate = true; pre_decimal = static_cast(std::distance(post_zero_cull_itr,itr)); } int exponent = 0; if (end != itr) { if ('.' == (*itr)) { ++itr; const Iterator curr = itr; unsigned char digit = 0; #define parse_digit_1 \ if ((digit = static_cast((*itr) - '0')) < 10) { d *= 10.0; d += digit; } else break; if (end == ++itr) break; \ #define parse_digit_2 \ if ((digit = static_cast((*itr) - '0')) < 10) { d *= 10.0; d += digit; } else break; ++itr;\ while (end != itr) { parse_digit_1 parse_digit_1 parse_digit_1 parse_digit_1 parse_digit_1 parse_digit_1 parse_digit_1 parse_digit_2 } #undef parse_digit_1 #undef parse_digit_2 if (curr != itr) instate = true; exponent -= static_cast(std::distance(curr,itr)); } if (end != itr) { typename std::iterator_traits::value_type c = (*itr); if (('e' == c) || ('E' == c)) { ++itr; int exp = 0; if (!string_to_type_converter_impl_ref(itr,end,exp)) { if (end == itr) return false; else c = (*itr); } if ( (exp < numeric::numeric_info::min_exp) || (numeric::numeric_info::max_exp < exp) ) return false; exponent += exp; } if (('f' == c) || ('F' == c) || ('l' == c) || ('L' == c)) ++itr; else if ('#' == c) { ++itr; if (end == itr) return false; if ((10.0 != d) || (exponent != -1)) return false; if (('I' <= (*itr)) && ((*itr) <= 'n')) { if (('i' == (*itr)) || ('I' == (*itr))) { return parse_inf(itr,end,t,negative); } else if (('n' == (*itr)) || ('N' == (*itr))) { return parse_nan(itr,end,t); } else return false; } return false; } } } if ((end != itr) || (!instate)) return false; if (0 != exponent) { if ( (std::numeric_limits::max_exponent10 < (exponent + pre_decimal)) || (std::numeric_limits::min_exponent10 > (exponent + pre_decimal)) ) { return false; } const int e = std::abs(exponent); static const double fract10[] = { 0.0, 1.0E+001, 1.0E+002, 1.0E+003, 1.0E+004, 1.0E+005, 1.0E+006, 1.0E+007, 1.0E+008, 1.0E+009, 1.0E+010, 1.0E+011, 1.0E+012, 1.0E+013, 1.0E+014, 1.0E+015, 1.0E+016, 1.0E+017, 1.0E+018, 1.0E+019, 1.0E+020, 1.0E+021, 1.0E+022, 1.0E+023, 1.0E+024, 1.0E+025, 1.0E+026, 1.0E+027, 1.0E+028, 1.0E+029, 1.0E+030, 1.0E+031, 1.0E+032, 1.0E+033, 1.0E+034, 1.0E+035, 1.0E+036, 1.0E+037, 1.0E+038, 1.0E+039, 1.0E+040, 1.0E+041, 1.0E+042, 1.0E+043, 1.0E+044, 1.0E+045, 1.0E+046, 1.0E+047, 1.0E+048, 1.0E+049, 1.0E+050, 1.0E+051, 1.0E+052, 1.0E+053, 1.0E+054, 1.0E+055, 1.0E+056, 1.0E+057, 1.0E+058, 1.0E+059, 1.0E+060, 1.0E+061, 1.0E+062, 1.0E+063, 1.0E+064, 1.0E+065, 1.0E+066, 1.0E+067, 1.0E+068, 1.0E+069, 1.0E+070, 1.0E+071, 1.0E+072, 1.0E+073, 1.0E+074, 1.0E+075, 1.0E+076, 1.0E+077, 1.0E+078, 1.0E+079, 1.0E+080, 1.0E+081, 1.0E+082, 1.0E+083, 1.0E+084, 1.0E+085, 1.0E+086, 1.0E+087, 1.0E+088, 1.0E+089, 1.0E+090, 1.0E+091, 1.0E+092, 1.0E+093, 1.0E+094, 1.0E+095, 1.0E+096, 1.0E+097, 1.0E+098, 1.0E+099, 1.0E+100, 1.0E+101, 1.0E+102, 1.0E+103, 1.0E+104, 1.0E+105, 1.0E+106, 1.0E+107, 1.0E+108, 1.0E+109, 1.0E+110, 1.0E+111, 1.0E+112, 1.0E+113, 1.0E+114, 1.0E+115, 1.0E+116, 1.0E+117, 1.0E+118, 1.0E+119, 1.0E+120, 1.0E+121, 1.0E+122, 1.0E+123, 1.0E+124, 1.0E+125, 1.0E+126, 1.0E+127, 1.0E+128, 1.0E+129, 1.0E+130, 1.0E+131, 1.0E+132, 1.0E+133, 1.0E+134, 1.0E+135, 1.0E+136, 1.0E+137, 1.0E+138, 1.0E+139, 1.0E+140, 1.0E+141, 1.0E+142, 1.0E+143, 1.0E+144, 1.0E+145, 1.0E+146, 1.0E+147, 1.0E+148, 1.0E+149, 1.0E+150, 1.0E+151, 1.0E+152, 1.0E+153, 1.0E+154, 1.0E+155, 1.0E+156, 1.0E+157, 1.0E+158, 1.0E+159, 1.0E+160, 1.0E+161, 1.0E+162, 1.0E+163, 1.0E+164, 1.0E+165, 1.0E+166, 1.0E+167, 1.0E+168, 1.0E+169, 1.0E+170, 1.0E+171, 1.0E+172, 1.0E+173, 1.0E+174, 1.0E+175, 1.0E+176, 1.0E+177, 1.0E+178, 1.0E+179, 1.0E+180, 1.0E+181, 1.0E+182, 1.0E+183, 1.0E+184, 1.0E+185, 1.0E+186, 1.0E+187, 1.0E+188, 1.0E+189, 1.0E+190, 1.0E+191, 1.0E+192, 1.0E+193, 1.0E+194, 1.0E+195, 1.0E+196, 1.0E+197, 1.0E+198, 1.0E+199, 1.0E+200, 1.0E+221, 1.0E+222, 1.0E+223, 1.0E+224, 1.0E+225, 1.0E+226, 1.0E+227, 1.0E+228, 1.0E+229, 1.0E+230, 1.0E+231, 1.0E+232, 1.0E+233, 1.0E+234, 1.0E+235, 1.0E+236, 1.0E+237, 1.0E+238, 1.0E+239, 1.0E+240, 1.0E+241, 1.0E+242, 1.0E+243, 1.0E+244, 1.0E+245, 1.0E+246, 1.0E+247, 1.0E+248, 1.0E+249, 1.0E+250, 1.0E+251, 1.0E+252, 1.0E+253, 1.0E+254, 1.0E+255, 1.0E+256, 1.0E+257, 1.0E+258, 1.0E+259, 1.0E+260, 1.0E+261, 1.0E+262, 1.0E+263, 1.0E+264, 1.0E+265, 1.0E+266, 1.0E+267, 1.0E+268, 1.0E+269, 1.0E+270, 1.0E+271, 1.0E+272, 1.0E+273, 1.0E+274, 1.0E+275, 1.0E+276, 1.0E+277, 1.0E+278, 1.0E+279, 1.0E+280, 1.0E+281, 1.0E+282, 1.0E+283, 1.0E+284, 1.0E+285, 1.0E+286, 1.0E+287, 1.0E+288, 1.0E+289, 1.0E+290, 1.0E+291, 1.0E+292, 1.0E+293, 1.0E+294, 1.0E+295, 1.0E+296, 1.0E+297, 1.0E+298, 1.0E+299, 1.0E+300, 1.0E+301, 1.0E+302, 1.0E+303, 1.0E+304, 1.0E+305, 1.0E+306, 1.0E+307, 1.0E+308 }; static const std::size_t fract10_size = sizeof(fract10) / sizeof(double); if (d != 0.0) { if (static_cast(e) < fract10_size) { if (exponent > 0) d *= fract10[e]; else d /= fract10[e]; } else d *= std::pow(10.0, 1.0 * exponent); } } t = static_cast((negative) ? -d : d); return true; } template inline bool string_to_real(const std::string& s, T& t) { const char* begin = s.data(); const char* end = s.data() + s.size(); return string_to_real(begin,end,t); } } // namespace details namespace lexer { struct token { enum token_type { e_none = 0, e_error = 1, e_err_symbol = 2, e_err_number = 3, e_err_string = 4, e_err_sfunc = 5, e_eof = 6, e_number = 7, e_symbol = 8, e_string = 9, e_assign = 10, e_shr = 11, e_shl = 12, e_lte = 13, e_ne = 14, e_gte = 15, e_lt = '<', e_gt = '>', e_eq = '=', e_rbracket = ')', e_lbracket = '(', e_rsqrbracket = ']', e_lsqrbracket = '[', e_rcrlbracket = '}', e_lcrlbracket = '{', e_comma = ',', e_add = '+', e_sub = '-', e_div = '/', e_mul = '*', e_mod = '%', e_pow = '^', e_colon = ':' }; token() : type(e_none), value(""), position(std::numeric_limits::max()) {} void clear() { type = e_none; value = ""; position = std::numeric_limits::max(); } template inline token& set_operator(const token_type tt, const Iterator begin, const Iterator end, const Iterator base_begin = Iterator(0)) { type = tt; value.assign(begin,end); if (base_begin) position = std::distance(base_begin,begin); return *this; } template inline token& set_symbol(const Iterator begin, const Iterator end, const Iterator base_begin = Iterator(0)) { type = e_symbol; value.assign(begin,end); if (base_begin) position = std::distance(base_begin,begin); return *this; } template inline token& set_numeric(const Iterator begin, const Iterator end, const Iterator base_begin = Iterator(0)) { type = e_number; value.assign(begin,end); if (base_begin) position = std::distance(base_begin,begin); return *this; } template inline token& set_string(const Iterator begin, const Iterator end, const Iterator base_begin = Iterator(0)) { type = e_string; value.assign(begin,end); if (base_begin) position = std::distance(base_begin,begin); return *this; } template inline token& set_error(const token_type et, const Iterator begin, const Iterator end, const Iterator base_begin = Iterator(0)) { if ( (e_error == et) || (e_err_symbol == et) || (e_err_number == et) || (e_err_string == et) || (e_err_sfunc == et) ) { type = et; } else type = e_error; value.assign(begin,end); if (base_begin) position = std::distance(base_begin,begin); return *this; } inline std::string to_str(token_type t) const { switch (t) { case e_none : return "NONE"; case e_error : return "ERROR"; case e_err_symbol : return "ERROR_SYMBOL"; case e_err_number : return "ERROR_NUMBER"; case e_err_string : return "ERROR_STRING"; case e_eof : return "EOF"; case e_number : return "NUMBER"; case e_symbol : return "SYMBOL"; case e_string : return "STRING"; case e_assign : return ":="; case e_shr : return ">>"; case e_shl : return "<<"; case e_lte : return "<="; case e_ne : return "!="; case e_gte : return ">="; case e_lt : return "<"; case e_gt : return ">"; case e_eq : return "="; case e_rbracket : return ")"; case e_lbracket : return "("; case e_rsqrbracket : return "]"; case e_lsqrbracket : return "["; case e_rcrlbracket : return "}"; case e_lcrlbracket : return "{"; case e_comma : return ","; case e_add : return "+"; case e_sub : return "-"; case e_div : return "/"; case e_mul : return "*"; case e_mod : return "%"; case e_pow : return "^"; case e_colon : return ":"; default : return "UNKNOWN"; } } inline bool is_error() const { return ( (e_error == type) || (e_err_symbol == type) || (e_err_number == type) || (e_err_string == type) || (e_err_sfunc == type) ); } token_type type; std::string value; std::size_t position; }; class generator { public: typedef token token_t; typedef std::deque token_list_t; typedef std::deque::iterator token_list_itr_t; generator() : base_itr_(0), s_itr_(0), s_end_(0) { clear(); } inline void clear() { base_itr_ = 0; s_itr_ = 0; s_end_ = 0; token_list_.clear(); token_itr_ = token_list_.end(); store_token_itr_ = token_list_.end(); } inline bool process(const std::string& str) { base_itr_ = str.data(); s_itr_ = str.data(); s_end_ = str.data() + str.size(); eof_token_.set_operator(token_t::e_eof,s_end_,s_end_,base_itr_); token_list_.clear(); while (s_end_ != s_itr_) { scan_token(); if (token_list_.back().is_error()) { return false; } } return true; } inline std::size_t size() const { return token_list_.size(); } inline void begin() { token_itr_ = token_list_.begin(); store_token_itr_ = token_list_.begin(); } inline void store() { store_token_itr_ = token_itr_; } inline void restore() { token_itr_ = store_token_itr_; } inline token_t& next_token() { if (token_list_.end() != token_itr_) { return *token_itr_++; } else return eof_token_; } inline token_t& operator[](const std::size_t index) { if (index < token_list_.size()) return token_list_[index]; else return eof_token_; } inline token_t operator[](const std::size_t index) const { if (index < token_list_.size()) return token_list_[index]; else return eof_token_; } private: inline void skip_whitespace() { while ((s_end_ != s_itr_) && details::is_whitespace(*s_itr_)) { ++s_itr_; } } inline void scan_token() { skip_whitespace(); if (s_end_ == s_itr_) { return; } else if (details::is_operator_char(*s_itr_)) { scan_operator(); return; } else if (details::is_letter(*s_itr_)) { scan_symbol(); return; } else if (details::is_digit((*s_itr_)) || ('.' == (*s_itr_))) { scan_number(); return; } else if ('$' == (*s_itr_)) { scan_special_function(); return; } #ifndef exprtk_disable_string_capabilities else if ('\'' == (*s_itr_)) { scan_string(); return; } #endif else { token_t t; t.set_error(token::e_error,s_itr_,s_itr_ + 2); token_list_.push_back(t); ++s_itr_; } } inline void scan_operator() { token_t t; if ((s_itr_ + 1) != s_end_) { token_t::token_type ttype = token_t::e_none; char c0 = s_itr_[0]; char c1 = s_itr_[1]; if ((c0 == '<') && (c1 == '=')) ttype = token_t::e_lte; else if ((c0 == '>') && (c1 == '=')) ttype = token_t::e_gte; else if ((c0 == '<') && (c1 == '>')) ttype = token_t::e_ne; else if ((c0 == '!') && (c1 == '=')) ttype = token_t::e_ne; else if ((c0 == '=') && (c1 == '=')) ttype = token_t::e_eq; else if ((c0 == ':') && (c1 == '=')) ttype = token_t::e_assign; else if ((c0 == '<') && (c1 == '<')) ttype = token_t::e_shl; else if ((c0 == '>') && (c1 == '>')) ttype = token_t::e_shr; if (token_t::e_none != ttype) { t.set_operator(ttype,s_itr_,s_itr_ + 2,base_itr_); token_list_.push_back(t); s_itr_ += 2; return; } } if ('<' == *s_itr_) t.set_operator(token_t::e_lt,s_itr_,s_itr_ + 1,base_itr_); else if ('>' == *s_itr_) t.set_operator(token_t::e_gt,s_itr_,s_itr_ + 1,base_itr_); else t.set_operator(token_t::token_type(*s_itr_),s_itr_,s_itr_ + 1,base_itr_); token_list_.push_back(t); ++s_itr_; } inline void scan_symbol() { const char* begin = s_itr_; while ( (s_end_ != s_itr_) && (details::is_letter_or_digit(*s_itr_) || ((*s_itr_) == '_')) ) { ++s_itr_; } token_t t; t.set_symbol(begin,s_itr_,base_itr_); token_list_.push_back(t); } inline void scan_number() { /* Attempt to match a valid numeric value in one of the following formats: 1. 123456 2. 123.456 3. 123.456e3 4. 123.456E3 5. 123.456e+3 6. 123.456E+3 7. 123.456e-3 8. 123.456E-3 */ const char* begin = s_itr_; bool dot_found = false; bool e_found = false; bool post_e_sign_found = false; token_t t; while (s_end_ != s_itr_) { if ('.' == (*s_itr_)) { if (dot_found) { t.set_error(token::e_err_number,begin,s_itr_,base_itr_); token_list_.push_back(t); return; } dot_found = true; ++s_itr_; continue; } else if (details::imatch('e',(*s_itr_))) { const char& c = *(s_itr_ + 1); if (s_end_ == (s_itr_ + 1)) { t.set_error(token::e_err_number,begin,s_itr_,base_itr_); token_list_.push_back(t); return; } else if ( ('+' != c) && ('-' != c) && !details::is_digit(c) ) { t.set_error(token::e_err_number,begin,s_itr_,base_itr_); token_list_.push_back(t); return; } e_found = true; ++s_itr_; continue; } else if (e_found && details::is_sign(*s_itr_)) { if (post_e_sign_found) { t.set_error(token::e_err_number,begin,s_itr_,base_itr_); token_list_.push_back(t); return; } post_e_sign_found = true; ++s_itr_; continue; } else if (('.' != (*s_itr_)) && !details::is_digit(*s_itr_)) break; else ++s_itr_; } t.set_numeric(begin,s_itr_,base_itr_); token_list_.push_back(t); return; } inline void scan_special_function() { const char* begin = s_itr_; token_t t; //$fdd(x,x,x) = at least 11 chars if (std::distance(s_itr_,s_end_) < 11) { t.set_error(token::e_err_sfunc,begin,s_itr_,base_itr_); token_list_.push_back(t); return; } if ( !(('$' == *s_itr_) && (details::imatch ('f',*(s_itr_ + 1))) && (details::is_digit(*(s_itr_ + 2))) && (details::is_digit(*(s_itr_ + 3)))) ) { t.set_error(token::e_err_sfunc,begin,s_itr_,base_itr_); token_list_.push_back(t); return; } s_itr_ += 4; //$fdd = 4chars t.set_symbol(begin,s_itr_,base_itr_); token_list_.push_back(t); return; } #ifndef exprtk_disable_string_capabilities inline void scan_string() { const char* begin = s_itr_ + 1; token_t t; if (std::distance(s_itr_,s_end_) < 2) { t.set_error(token::e_err_string,begin,s_itr_,base_itr_); token_list_.push_back(t); return; } ++s_itr_; bool escaped = false; while (s_end_ != s_itr_) { if ('\\' == *s_itr_) { escaped = true; ++s_itr_; continue; } else if (!escaped) { if ('\'' == *s_itr_) break; } else if (escaped) escaped = false; ++s_itr_; } if (s_end_ == s_itr_) { t.set_error(token::e_err_string,begin,s_itr_,base_itr_); token_list_.push_back(t); return; } t.set_string(begin,s_itr_,base_itr_); token_list_.push_back(t); ++s_itr_; return; } #endif private: token_list_t token_list_; token_list_itr_t token_itr_; token_list_itr_t store_token_itr_; token_t eof_token_; const char* base_itr_; const char* s_itr_; const char* s_end_; friend class token_scanner; friend class token_modifier; friend class token_inserter; friend class token_joiner; }; class helper_interface { public: virtual void init() { } virtual void reset() { } virtual bool result() { return true; } virtual std::size_t process(generator&) { return 0; } }; class token_scanner : public helper_interface { public: explicit token_scanner(const std::size_t& stride) : stride_(stride) { if (stride > 4) { throw std::invalid_argument("token_scanner() - Invalid stride value"); } } inline std::size_t process(generator& g) { for (std::size_t i = 0; i < (g.token_list_.size() - stride_ + 1); ++i) { token t; switch (stride_) { case 1 : { const token& t0 = g.token_list_[i]; if (!operator()(t0)) return i; } break; case 2 : { const token& t0 = g.token_list_[i ]; const token& t1 = g.token_list_[i + 1]; if (!operator()(t0,t1)) return i; } break; case 3 : { const token& t0 = g.token_list_[i ]; const token& t1 = g.token_list_[i + 1]; const token& t2 = g.token_list_[i + 2]; if (!operator()(t0,t1,t2)) return i; } break; case 4 : { const token& t0 = g.token_list_[i ]; const token& t1 = g.token_list_[i + 1]; const token& t2 = g.token_list_[i + 2]; const token& t3 = g.token_list_[i + 3]; if (!operator()(t0,t1,t2,t3)) return i; } break; } } return (g.token_list_.size() - stride_ + 1); } virtual bool operator()(const token&) { return false; } virtual bool operator()(const token&, const token&) { return false; } virtual bool operator()(const token&, const token&, const token&) { return false; } virtual bool operator()(const token&, const token&, const token&, const token&) { return false; } private: std::size_t stride_; }; class token_modifier : public helper_interface { public: inline std::size_t process(generator& g) { std::size_t changes = 0; for (std::size_t i = 0; i < g.token_list_.size(); ++i) { if (modify(g.token_list_[i])) changes++; } return changes; } virtual bool modify(token& t) = 0; }; class token_inserter : public helper_interface { public: explicit token_inserter(const std::size_t& stride) : stride_(stride) { if (stride > 5) { throw std::invalid_argument("token_inserter() - Invalid stride value"); } } inline std::size_t process(generator& g) { std::size_t changes = 0; for (std::size_t i = 0; i < (g.token_list_.size() - stride_ + 1); ++i) { token t; int insert_index = -1; switch (stride_) { case 1 : insert_index = insert(g.token_list_[i],t); break; case 2 : insert_index = insert(g.token_list_[i],g.token_list_[i + 1],t); break; case 3 : insert_index = insert(g.token_list_[i],g.token_list_[i + 1],g.token_list_[i + 2],t); break; case 4 : insert_index = insert(g.token_list_[i],g.token_list_[i + 1],g.token_list_[i + 2],g.token_list_[i + 3],t); break; case 5 : insert_index = insert(g.token_list_[i],g.token_list_[i + 1],g.token_list_[i + 2],g.token_list_[i + 3],g.token_list_[i + 4],t); break; } if ((insert_index >= 0) && (insert_index <= (static_cast(stride_) + 1))) { g.token_list_.insert(g.token_list_.begin() + (i + insert_index),t); changes++; } } return changes; } virtual inline int insert(const token&, token& ) { return -1; } virtual inline int insert(const token&, const token&, token&) { return -1; } virtual inline int insert(const token&, const token&, const token&, token&) { return -1; } virtual inline int insert(const token&, const token&, const token&, const token&, token&) { return -1; } virtual inline int insert(const token&, const token&, const token&, const token&, const token&, token&) { return -1; } private: std::size_t stride_; }; class token_joiner : public helper_interface { public: inline std::size_t process(generator& g) { std::size_t changes = 0; for (std::size_t i = 0; i < g.token_list_.size() - 1; ++i) { token t; if (join(g.token_list_[i],g.token_list_[i + 1],t)) { g.token_list_[i] = t; g.token_list_.erase(g.token_list_.begin() + (i + 1)); ++changes; } } return changes; } virtual bool join(const token&, const token&, token&) = 0; }; namespace helper { inline void dump(lexer::generator& generator) { for (std::size_t i = 0; i < generator.size(); ++i) { lexer::token t = generator[i]; printf("Token[%02d] @ %03d %6s --> '%s'\n", static_cast(i), static_cast(t.position), t.to_str(t.type).c_str(), t.value.c_str()); } } class commutative_inserter : public lexer::token_inserter { public: commutative_inserter() : lexer::token_inserter(2) {} inline void ignore_symbol(const std::string& symbol) { ignore_set_.insert(symbol); } inline int insert(const lexer::token& t0, const lexer::token& t1, lexer::token& new_token) { new_token.type = lexer::token::e_mul; new_token.value = "*"; new_token.position = t1.position; bool match = false; if (t0.type == lexer::token::e_symbol) { if (ignore_set_.end() != ignore_set_.find(t0.value)) { return -1; } else if (!t0.value.empty() && ('$' == t0.value[0])) { return -1; } } if (t1.type == lexer::token::e_symbol) { if (ignore_set_.end() != ignore_set_.find(t1.value)) { return -1; } } if ((t0.type == lexer::token::e_number ) && (t1.type == lexer::token::e_symbol )) match = true; else if ((t0.type == lexer::token::e_number ) && (t1.type == lexer::token::e_lbracket )) match = true; else if ((t0.type == lexer::token::e_number ) && (t1.type == lexer::token::e_lcrlbracket)) match = true; else if ((t0.type == lexer::token::e_number ) && (t1.type == lexer::token::e_lsqrbracket)) match = true; else if ((t0.type == lexer::token::e_symbol ) && (t1.type == lexer::token::e_number )) match = true; else if ((t0.type == lexer::token::e_rbracket ) && (t1.type == lexer::token::e_number )) match = true; else if ((t0.type == lexer::token::e_rcrlbracket) && (t1.type == lexer::token::e_number )) match = true; else if ((t0.type == lexer::token::e_rsqrbracket) && (t1.type == lexer::token::e_number )) match = true; else if ((t0.type == lexer::token::e_rbracket ) && (t1.type == lexer::token::e_symbol )) match = true; else if ((t0.type == lexer::token::e_rcrlbracket) && (t1.type == lexer::token::e_symbol )) match = true; else if ((t0.type == lexer::token::e_rsqrbracket) && (t1.type == lexer::token::e_symbol )) match = true; return (match) ? 1 : -1; } private: std::set ignore_set_; }; class operator_joiner : public token_joiner { public: inline bool join(const lexer::token& t0, const lexer::token& t1, lexer::token& t) { //': =' --> ':=' if ((t0.type == lexer::token::e_colon) && (t1.type == lexer::token::e_eq)) { t.type = lexer::token::e_assign; t.value = ":="; t.position = t0.position; return true; } //'> =' --> '>=' else if ((t0.type == lexer::token::e_gt) && (t1.type == lexer::token::e_eq)) { t.type = lexer::token::e_gte; t.value = ">="; t.position = t0.position; return true; } //'< =' --> '<=' else if ((t0.type == lexer::token::e_lt) && (t1.type == lexer::token::e_eq)) { t.type = lexer::token::e_lte; t.value = "<="; t.position = t0.position; return true; } //'= =' --> '==' else if ((t0.type == lexer::token::e_eq) && (t1.type == lexer::token::e_eq)) { t.type = lexer::token::e_eq; t.value = "=="; t.position = t0.position; return true; } //'! =' --> '!=' else if ((static_cast(t0.type) == '!') && (t1.type == lexer::token::e_eq)) { t.type = lexer::token::e_ne; t.value = "!="; t.position = t0.position; return true; } //'< >' --> '<>' else if ((t0.type == lexer::token::e_lt) && (t1.type == lexer::token::e_gt)) { t.type = lexer::token::e_ne; t.value = "<>"; t.position = t0.position; return true; } else return false; } }; class bracket_checker : public lexer::token_scanner { public: bracket_checker() : token_scanner(1), state_(true) {} bool result() { return state_ && stack_.empty(); } lexer::token error_token() { return error_token_; } void reset() { //msvc doesn't support swap properly. stack_ = std::stack(); state_ = true; error_token_.clear(); } bool operator()(const lexer::token& t) { if (!t.value.empty() && (lexer::token::e_string != t.type) && (lexer::token::e_symbol != t.type) && exprtk::details::is_bracket(t.value[0]) ) { char c = t.value[0]; if (t.type == lexer::token::e_lbracket) stack_.push(')'); else if (t.type == lexer::token::e_lcrlbracket) stack_.push('}'); else if (t.type == lexer::token::e_lsqrbracket) stack_.push(']'); else if (exprtk::details::is_right_bracket(c)) { if (stack_.empty()) { state_ = false; error_token_ = t; return false; } else if (c != stack_.top()) { state_ = false; error_token_ = t; return false; } else stack_.pop(); } } return true; } private: bool state_; std::stack stack_; lexer::token error_token_; }; class numeric_checker : public lexer::token_scanner { public: numeric_checker() : token_scanner(1), current_index_(0) {} bool result() { return error_list_.empty(); } void reset() { error_list_.clear(); current_index_ = 0; } bool operator()(const lexer::token& t) { if (token::e_number == t.type) { double v; if (!exprtk::details::string_to_real(t.value,v)) { error_list_.push_back(current_index_); } } ++current_index_; return true; } std::size_t error_count() const { return error_list_.size(); } std::size_t error_index(const std::size_t& i) { if (i < error_list_.size()) return error_list_[i]; else return std::numeric_limits::max(); } private: std::size_t current_index_; std::deque error_list_; }; class symbol_replacer : public lexer::token_modifier { private: typedef std::map,details::ilesscompare> replace_map_t; public: bool add_replace(const std::string& target_symbol, const std::string& replace_symbol, const lexer::token::token_type token_type = lexer::token::e_symbol) { replace_map_t::iterator itr = replace_map_.find(target_symbol); if (replace_map_.end() != itr) { return false; } replace_map_[target_symbol] = std::make_pair(replace_symbol,token_type); return true; } void clear() { replace_map_.clear(); } private: bool modify(lexer::token& t) { if (lexer::token::e_symbol == t.type) { if (replace_map_.empty()) return false; replace_map_t::iterator itr = replace_map_.find(t.value); if (replace_map_.end() != itr) { t.value = itr->second.first; t.type = itr->second.second; return true; } } return false; } replace_map_t replace_map_; }; class sequence_validator : public lexer::token_scanner { private: typedef std::pair token_pair_t; typedef std::set set_t; public: sequence_validator() : lexer::token_scanner(2) { add_invalid(lexer::token::e_number,lexer::token::e_number); add_invalid(lexer::token::e_string,lexer::token::e_string); add_invalid(lexer::token::e_number,lexer::token::e_string); add_invalid(lexer::token::e_string,lexer::token::e_number); add_invalid(lexer::token::e_number,lexer::token::e_colon); add_invalid(lexer::token::e_symbol,lexer::token::e_colon); add_invalid(lexer::token::e_string,lexer::token::e_colon); add_invalid(lexer::token::e_colon,lexer::token::e_number); add_invalid(lexer::token::e_colon,lexer::token::e_symbol); add_invalid(lexer::token::e_colon,lexer::token::e_string); add_invalid_set1(lexer::token::e_assign); add_invalid_set1(lexer::token::e_shr); add_invalid_set1(lexer::token::e_shl); add_invalid_set1(lexer::token::e_lte); add_invalid_set1(lexer::token::e_ne); add_invalid_set1(lexer::token::e_gte); add_invalid_set1(lexer::token::e_lt); add_invalid_set1(lexer::token::e_gt); add_invalid_set1(lexer::token::e_eq); add_invalid_set1(lexer::token::e_comma); add_invalid_set1(lexer::token::e_add); add_invalid_set1(lexer::token::e_sub); add_invalid_set1(lexer::token::e_div); add_invalid_set1(lexer::token::e_mul); add_invalid_set1(lexer::token::e_mod); add_invalid_set1(lexer::token::e_pow); add_invalid_set1(lexer::token::e_colon); } bool result() { return error_list_.empty(); } bool operator()(const lexer::token& t0, const lexer::token& t1) { set_t::value_type p = std::make_pair(t0.type,t1.type); if (invalid_bracket_check(t0.type,t1.type)) { invalid_bracket_check(t0.type,t1.type); error_list_.push_back(std::make_pair(t0,t1)); } else if (invalid_comb_.find(p) != invalid_comb_.end()) error_list_.push_back(std::make_pair(t0,t1)); return true; } std::size_t error_count() { return error_list_.size(); } std::pair error(const std::size_t index) { if (index < error_list_.size()) { return error_list_[index]; } else { static const lexer::token error_token; return std::make_pair(error_token,error_token); } } void clear_errors() { error_list_.clear(); } private: void add_invalid(lexer::token::token_type base, lexer::token::token_type t) { invalid_comb_.insert(std::make_pair(base,t)); } void add_invalid_set1(lexer::token::token_type t) { add_invalid(t,lexer::token::e_assign); add_invalid(t,lexer::token::e_shr); add_invalid(t,lexer::token::e_shl); add_invalid(t,lexer::token::e_lte); add_invalid(t,lexer::token::e_ne); add_invalid(t,lexer::token::e_gte); add_invalid(t,lexer::token::e_lt); add_invalid(t,lexer::token::e_gt); add_invalid(t,lexer::token::e_eq); add_invalid(t,lexer::token::e_comma); add_invalid(t,lexer::token::e_div); add_invalid(t,lexer::token::e_mul); add_invalid(t,lexer::token::e_mod); add_invalid(t,lexer::token::e_pow); add_invalid(t,lexer::token::e_colon); } bool invalid_bracket_check(lexer::token::token_type base, lexer::token::token_type t) { if (details::is_right_bracket(static_cast(base))) { if (details::is_left_bracket(static_cast(t))) return true; else { switch (t) { case lexer::token::e_string : return true; case lexer::token::e_assign : return true; case lexer::token::e_colon : return true; default : return false; } } } else if (details::is_left_bracket(static_cast(base))) { if (details::is_right_bracket(static_cast(t))) return false; else if (details::is_left_bracket(static_cast(t))) return false; else { switch (t) { case lexer::token::e_number : return false; case lexer::token::e_symbol : return false; case lexer::token::e_string : return false; case lexer::token::e_add : return false; case lexer::token::e_sub : return false; default : return true; } } } else if (details::is_right_bracket(static_cast(t))) { switch (base) { case lexer::token::e_number : return false; case lexer::token::e_symbol : return false; case lexer::token::e_string : return false; default : return true; } } else if (details::is_left_bracket(static_cast(t))) { switch (base) { case lexer::token::e_string : return true; case lexer::token::e_rbracket : return true; case lexer::token::e_rsqrbracket : return true; case lexer::token::e_rcrlbracket : return true; case lexer::token::e_colon : return true; default : return false; } } return false; } set_t invalid_comb_; std::deque > error_list_; }; struct helper_assembly { inline bool register_scanner(lexer::token_scanner* scanner) { if (token_scanner_list.end() != std::find(token_scanner_list.begin(), token_scanner_list.end(), scanner)) { return false; } token_scanner_list.push_back(scanner); return true; } inline bool register_modifier(lexer::token_modifier* modifier) { if (token_modifier_list.end() != std::find(token_modifier_list.begin(), token_modifier_list.end(), modifier)) { return false; } token_modifier_list.push_back(modifier); return true; } inline bool register_joiner(lexer::token_joiner* joiner) { if (token_joiner_list.end() != std::find(token_joiner_list.begin(), token_joiner_list.end(), joiner)) { return false; } token_joiner_list.push_back(joiner); return true; } inline bool register_inserter(lexer::token_inserter* inserter) { if (token_inserter_list.end() != std::find(token_inserter_list.begin(), token_inserter_list.end(), inserter)) { return false; } token_inserter_list.push_back(inserter); return true; } inline bool run_modifiers(lexer::generator& g) { error_token_modifier = reinterpret_cast(0); bool result = true; for (std::size_t i = 0; i < token_modifier_list.size(); ++i) { lexer::token_modifier& modifier = (*token_modifier_list[i]); modifier.reset(); modifier.process(g); if (!modifier.result()) { error_token_modifier = token_modifier_list[i]; return false; } } return result; } inline bool run_joiners(lexer::generator& g) { error_token_joiner = reinterpret_cast(0); bool result = true; for (std::size_t i = 0; i < token_joiner_list.size(); ++i) { lexer::token_joiner& joiner = (*token_joiner_list[i]); joiner.reset(); joiner.process(g); if (!joiner.result()) { error_token_joiner = token_joiner_list[i]; return false; } } return result; } inline bool run_inserters(lexer::generator& g) { error_token_inserter = reinterpret_cast(0); bool result = true; for (std::size_t i = 0; i < token_inserter_list.size(); ++i) { lexer::token_inserter& inserter = (*token_inserter_list[i]); inserter.reset(); inserter.process(g); if (!inserter.result()) { error_token_inserter = token_inserter_list[i]; return false; } } return result; } inline bool run_scanners(lexer::generator& g) { error_token_scanner = reinterpret_cast(0); bool result = true; for (std::size_t i = 0; i < token_scanner_list.size(); ++i) { lexer::token_scanner& scanner = (*token_scanner_list[i]); scanner.reset(); scanner.process(g); if (!scanner.result()) { error_token_scanner = token_scanner_list[i]; return false; } } return result; } std::deque token_scanner_list; std::deque token_modifier_list; std::deque token_joiner_list; std::deque token_inserter_list; lexer::token_scanner* error_token_scanner; lexer::token_modifier* error_token_modifier; lexer::token_joiner* error_token_joiner; lexer::token_inserter* error_token_inserter; }; } } namespace details { enum operator_type { e_default, e_add , e_sub , e_mul , e_div , e_mod , e_pow , e_atan2 , e_min , e_max , e_avg , e_sum , e_prod , e_lt , e_lte , e_eq , e_equal , e_ne , e_nequal , e_gte , e_gt , e_and , e_nand , e_or , e_nor , e_xor , e_shr , e_shl , e_abs , e_acos , e_asin , e_atan , e_ceil , e_cos , e_cosh , e_exp , e_floor , e_log , e_log10 , e_logn , e_neg , e_pos , e_round , e_roundn , e_root , e_sqrt , e_sin , e_sinh , e_sec , e_csc , e_tan , e_tanh , e_cot , e_clamp , e_inrange, e_sgn , e_r2d , e_d2r , e_d2g , e_g2d , e_hyp , e_notl , e_erf , e_erfc , e_frac , e_trunc , e_assign , e_in , e_like , e_ilike , // Do not add new functions/operators after this point. e_sf00 = 1000, e_sf01 = 1001, e_sf02 = 1002, e_sf03 = 1003, e_sf04 = 1004, e_sf05 = 1005, e_sf06 = 1006, e_sf07 = 1007, e_sf08 = 1008, e_sf09 = 1009, e_sf10 = 1010, e_sf11 = 1011, e_sf12 = 1012, e_sf13 = 1013, e_sf14 = 1014, e_sf15 = 1015, e_sf16 = 1016, e_sf17 = 1017, e_sf18 = 1018, e_sf19 = 1019, e_sf20 = 1020, e_sf21 = 1021, e_sf22 = 1022, e_sf23 = 1023, e_sf24 = 1024, e_sf25 = 1025, e_sf26 = 1026, e_sf27 = 1027, e_sf28 = 1028, e_sf29 = 1029, e_sf30 = 1030, e_sf31 = 1031, e_sf32 = 1032, e_sf33 = 1033, e_sf34 = 1034, e_sf35 = 1035, e_sf36 = 1036, e_sf37 = 1037, e_sf38 = 1038, e_sf39 = 1039, e_sf40 = 1040, e_sf41 = 1041, e_sf42 = 1042, e_sf43 = 1043, e_sf44 = 1044, e_sf45 = 1045, e_sf46 = 1046, e_sf47 = 1047, e_sf48 = 1048, e_sf49 = 1049, e_sf50 = 1050, e_sf51 = 1051, e_sf52 = 1052, e_sf53 = 1053, e_sf54 = 1054, e_sf55 = 1055, e_sf56 = 1056, e_sf57 = 1057, e_sf58 = 1058, e_sf59 = 1059, e_sf60 = 1060, e_sf61 = 1061, e_sf62 = 1062, e_sf63 = 1063, e_sf64 = 1064, e_sf65 = 1065, e_sf66 = 1066, e_sf67 = 1067, e_sf68 = 1068, e_sf69 = 1069, e_sf70 = 1070, e_sf71 = 1071, e_sf72 = 1072, e_sf73 = 1073, e_sf74 = 1074, e_sf75 = 1075, e_sf76 = 1076, e_sf77 = 1077, e_sf78 = 1078, e_sf79 = 1079, e_sf80 = 1080, e_sf81 = 1081, e_sf82 = 1082 }; struct base_operation_t { base_operation_t(const operator_type t, const unsigned int& np) : type(t), num_params(np) {} operator_type type; unsigned int num_params; }; namespace numeric { namespace details { template inline T process_impl(const operator_type operation, const T& arg, real_type_tag) { switch (operation) { case e_abs : return numeric::abs (arg); case e_acos : return numeric::acos (arg); case e_asin : return numeric::asin (arg); case e_atan : return numeric::atan (arg); case e_ceil : return numeric::ceil (arg); case e_cos : return numeric::cos (arg); case e_cosh : return numeric::cosh (arg); case e_exp : return numeric::exp (arg); case e_floor : return numeric::floor(arg); case e_log : return numeric::log (arg); case e_log10 : return numeric::log10(arg); case e_neg : return numeric::neg (arg); case e_pos : return numeric::pos (arg); case e_round : return numeric::round(arg); case e_sin : return numeric::sin (arg); case e_sinh : return numeric::sinh (arg); case e_sqrt : return numeric::sqrt (arg); case e_tan : return numeric::tan (arg); case e_tanh : return numeric::tanh (arg); case e_cot : return numeric::cot (arg); case e_sec : return numeric::sec (arg); case e_csc : return numeric::csc (arg); case e_r2d : return numeric::r2d (arg); case e_d2r : return numeric::d2r (arg); case e_d2g : return numeric::d2g (arg); case e_g2d : return numeric::g2d (arg); case e_notl : return numeric::notl (arg); case e_sgn : return numeric::sgn (arg); case e_erf : return numeric::erf (arg); case e_erfc : return numeric::erfc (arg); case e_frac : return numeric::frac (arg); case e_trunc : return numeric::trunc(arg); default : return std::numeric_limits::quiet_NaN(); } } template inline T process_impl(const operator_type operation, const T& arg, int_type_tag) { switch (operation) { case e_abs : return numeric::abs (arg); case e_exp : return numeric::exp (arg); case e_log : return numeric::log (arg); case e_log10 : return numeric::log10(arg); case e_neg : return numeric::neg (arg); case e_pos : return numeric::pos (arg); case e_sqrt : return numeric::sqrt (arg); case e_notl : return numeric::notl (arg); case e_sgn : return numeric::sgn (arg); default : return std::numeric_limits::quiet_NaN(); } } template inline T process_impl(const operator_type operation, const T& arg0, const T& arg1, real_type_tag) { switch (operation) { case e_add : return (arg0 + arg1); case e_sub : return (arg0 - arg1); case e_mul : return (arg0 * arg1); case e_div : return (arg0 / arg1); case e_mod : return modulus(arg0,arg1); case e_pow : return pow(arg0,arg1); case e_atan2 : return atan2(arg0,arg1); case e_min : return std::min(arg0,arg1); case e_max : return std::max(arg0,arg1); case e_logn : return logn(arg0,arg1); case e_lt : return (arg0 < arg1) ? T(1) : T(0); case e_lte : return (arg0 <= arg1) ? T(1) : T(0); case e_eq : return (arg0 == arg1) ? T(1) : T(0); case e_ne : return (arg0 != arg1) ? T(1) : T(0); case e_gte : return (arg0 >= arg1) ? T(1) : T(0); case e_gt : return (arg0 > arg1) ? T(1) : T(0); case e_and : return ((arg0 != T(0)) && (arg1 != T(0))) ? T(1) : T(0); case e_nand : return ((arg0 != T(0)) && (arg1 != T(0))) ? T(0) : T(1); case e_or : return ((arg0 != T(0)) || (arg1 != T(0))) ? T(1) : T(0); case e_nor : return ((arg0 != T(0)) || (arg1 != T(0))) ? T(0) : T(1); case e_xor : return (arg0 != arg1) ? T(1) : T(0); case e_root : return root(arg0,arg1); case e_roundn : return roundn(arg0,arg1); case e_equal : return equal(arg0,arg1); case e_nequal : return nequal(arg0,arg1); case e_hyp : return hyp(arg0,arg1); case e_avg : return (arg0 + arg1)/T(2); case e_sum : return (arg0 + arg1); case e_prod : return (arg0 * arg1); case e_shr : return shr(arg0,arg1); case e_shl : return shl(arg0,arg1); default : return std::numeric_limits::quiet_NaN(); } } template inline T process_impl(const operator_type operation, const T& arg0, const T& arg1, int_type_tag) { switch (operation) { case e_add : return (arg0 + arg1); case e_sub : return (arg0 - arg1); case e_mul : return (arg0 * arg1); case e_div : return (arg0 / arg1); case e_mod : return arg0 % arg1; case e_pow : return pow(arg0,arg1); case e_min : return std::min(arg0,arg1); case e_max : return std::max(arg0,arg1); case e_logn : return logn(arg0,arg1); case e_lt : return (arg0 < arg1) ? T(1) : T(0); case e_lte : return (arg0 <= arg1) ? T(1) : T(0); case e_eq : return (arg0 == arg1) ? T(1) : T(0); case e_ne : return (arg0 != arg1) ? T(1) : T(0); case e_gte : return (arg0 >= arg1) ? T(1) : T(0); case e_gt : return (arg0 > arg1) ? T(1) : T(0); case e_and : return ((arg0 != T(0)) && (arg1 != T(0))) ? T(1) : T(0); case e_nand : return ((arg0 != T(0)) && (arg1 != T(0))) ? T(0) : T(1); case e_or : return ((arg0 != T(0)) || (arg1 != T(0))) ? T(1) : T(0); case e_nor : return ((arg0 != T(0)) || (arg1 != T(0))) ? T(0) : T(1); case e_xor : return arg0 ^ arg1; case e_root : return root(arg0,arg1); case e_equal : return arg0 == arg1; case e_nequal : return arg0 != arg1; case e_hyp : return hyp(arg0,arg1); case e_avg : return (arg0 + arg1) >> 1; case e_sum : return (arg0 + arg1); case e_prod : return (arg0 * arg1); case e_shr : return arg0 >> arg1; case e_shl : return arg0 << arg1; default : return std::numeric_limits::quiet_NaN(); } } } template inline T process(const operator_type operation, const T& arg) { typename details::number_type::type num_type; return details::process_impl(operation,arg,num_type); } template inline T process(const operator_type operation, const T& arg0, const T& arg1) { typename details::number_type::type num_type; return details::process_impl(operation,arg0,arg1,num_type); } } template class expression_node { public: enum node_type { e_none , e_constant , e_unary , e_binary , e_trinary , e_quaternary , e_quinary , e_senary , e_conditional , e_while , e_variable , e_stringvar , e_stringconst , e_function , e_add , e_sub , e_mul , e_div , e_mod , e_pow , e_lt , e_lte , e_gt , e_gte , e_eq , e_ne , e_and , e_nand , e_or , e_nor , e_xor , e_in , e_like , e_ilike , e_inranges , e_ipow , e_ipowinv , e_vov , e_abs , e_acos , e_asin , e_atan , e_ceil , e_cos , e_cosh , e_exp , e_floor , e_log , e_log10 , e_neg , e_pos , e_round , e_sin , e_sinh , e_sqrt , e_tan , e_tanh , e_cot , e_sec , e_csc , e_r2d , e_d2r , e_d2g , e_g2d , e_notl , e_sgn , e_erf , e_erfc , e_frac , e_trunc }; typedef T value_type; typedef expression_node* expression_ptr; virtual ~expression_node() {} virtual inline T value() const { return std::numeric_limits::quiet_NaN(); } virtual inline bool result() const { return (T(1.0) == value()); } virtual inline expression_node* branch(const std::size_t& index = 0) const { return reinterpret_cast(index * 0); } virtual inline node_type type() const { return e_none; } }; inline bool is_true(const double v) { return (0.0 != v); } inline bool is_true(const float v) { return (0.0f != v); } template inline bool is_true(const expression_node* node) { return (T(0) != node->value()); } template inline bool is_false(const expression_node* node) { return (T(0) == node->value()); } template inline bool is_unary_node(const expression_node* node) { return (details::expression_node::e_unary == node->type()); } template inline bool is_binary_node(const expression_node* node) { return (details::expression_node::e_binary == node->type()); } template inline bool is_variable_node(const expression_node* node) { return (details::expression_node::e_variable == node->type()); } template inline bool is_constant_node(const expression_node* node) { return (details::expression_node::e_constant == node->type()); } template inline bool is_function(const expression_node* node) { return (details::expression_node::e_function == node->type()); } template inline bool branch_deletable(expression_node* node) { return !is_variable_node(node); } template class null_node : public expression_node { public: inline T value() const { return std::numeric_limits::quiet_NaN(); } inline typename expression_node::node_type type() const { return expression_node::e_nul; } }; template class literal_node : public expression_node { public: explicit literal_node(const T& value) : value_(value) {} inline T value() const { return value_; } inline typename expression_node::node_type type() const { return expression_node::e_constant; } inline expression_node* branch(const std::size_t& index = 0) const { return reinterpret_cast*>(index * 0); } private: T value_; }; template class string_literal_node : public expression_node { public: explicit string_literal_node(const std::string& value) : value_(value) {} inline T value() const { return std::numeric_limits::quiet_NaN(); } inline typename expression_node::node_type type() const { return expression_node::e_stringconst; } inline expression_node* branch(const std::size_t& index = 0) const { return reinterpret_cast*>(index * 0); } inline std::string str() { return value_; } private: string_literal_node(const string_literal_node&); string_literal_node& operator=(const string_literal_node&); const std::string value_; }; template class unary_node : public expression_node { public: typedef expression_node* expression_ptr; unary_node(const operator_type& operation, expression_ptr branch) : operation_(operation), branch_(branch), branch_deletable_(branch_deletable(branch_)) {} ~unary_node() { if (branch_ && branch_deletable_) { delete branch_; branch_ = 0; } } inline T value() const { const T arg = branch_->value(); return numeric::process(operation_,arg); } inline typename expression_node::node_type type() const { return expression_node::e_unary; } inline operator_type operation() const { return operation_; } inline expression_node* branch(const std::size_t& index = 0) const { if (0 == index) return branch_; else return reinterpret_cast(0); } private: operator_type operation_; expression_ptr branch_; bool branch_deletable_; }; template struct construct_branch_pair { template static inline void process(std::pair*,bool> (&)[N], expression_node*) {} }; template struct construct_branch_pair { template static inline void process(std::pair*,bool> (&branch)[N], expression_node* b) { if (b) { branch[D] = std::make_pair(b,branch_deletable(b)); } } }; template inline void init_branches(std::pair*,bool> (&branch)[N], expression_node* b0, expression_node* b1 = reinterpret_cast*>(0), expression_node* b2 = reinterpret_cast*>(0), expression_node* b3 = reinterpret_cast*>(0), expression_node* b4 = reinterpret_cast*>(0), expression_node* b5 = reinterpret_cast*>(0), expression_node* b6 = reinterpret_cast*>(0), expression_node* b7 = reinterpret_cast*>(0), expression_node* b8 = reinterpret_cast*>(0), expression_node* b9 = reinterpret_cast*>(0)) { construct_branch_pair 0)>::process(branch,b0); construct_branch_pair 1)>::process(branch,b1); construct_branch_pair 2)>::process(branch,b2); construct_branch_pair 3)>::process(branch,b3); construct_branch_pair 4)>::process(branch,b4); construct_branch_pair 5)>::process(branch,b5); construct_branch_pair 6)>::process(branch,b6); construct_branch_pair 7)>::process(branch,b7); construct_branch_pair 8)>::process(branch,b8); construct_branch_pair 9)>::process(branch,b9); } template struct cleanup_branches { static inline void execute(std::pair*,bool> (&branch)[N]) { for (std::size_t i = 0; i < N; ++i) { if (branch[i].first && branch[i].second) { delete branch[i].first; branch[i].first = 0; } } } }; template class binary_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; binary_node(const operator_type& operation, expression_ptr branch0, expression_ptr branch1) : operation_(operation) { init_branches<2>(branch_,branch0,branch1); } ~binary_node() { cleanup_branches::execute(branch_); } inline T value() const { const T arg0 = branch_[0].first->value(); const T arg1 = branch_[1].first->value(); return numeric::process(operation_,arg0,arg1); } inline typename expression_node::node_type type() const { return expression_node::e_binary; } inline operator_type operation() const { return operation_; } inline expression_node* branch(const std::size_t& index = 0) const { if (0 == index) return branch_[0].first; else if (1 == index) return branch_[1].first; else return reinterpret_cast(0); } protected: operator_type operation_; branch_t branch_[2]; }; template class trinary_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; trinary_node(const operator_type& operation, expression_ptr branch0, expression_ptr branch1, expression_ptr branch2) : operation_(operation) { init_branches<3>(branch_,branch0,branch1,branch2); } ~trinary_node() { cleanup_branches::execute(branch_); } inline T value() const { const T arg0 = branch_[0].first->value(); const T arg1 = branch_[1].first->value(); const T arg2 = branch_[2].first->value(); switch (operation_) { case e_clamp : return (arg1 < arg0) ? arg0 : (arg1 > arg2 ? arg2 : arg1); case e_inrange : return (arg1 < arg0) ? T(0) : ((arg1 > arg2) ? T(0) : T(1)); case e_min : return std::min(std::min(arg0,arg1),arg2); case e_max : return std::max(std::max(arg0,arg1),arg2); case e_avg : return (arg0 + arg1 + arg2) / T(3.0); case e_sum : return (arg0 + arg1 + arg2); case e_prod : return (arg0 * arg1 * arg2); default : return std::numeric_limits::quiet_NaN(); } } inline typename expression_node::node_type type() const { return expression_node::e_trinary; } protected: operator_type operation_; branch_t branch_[3]; }; template class quaternary_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; quaternary_node(const operator_type& operation, expression_ptr branch0, expression_ptr branch1, expression_ptr branch2, expression_ptr branch3) : operation_(operation) { init_branches<4>(branch_,branch0,branch1,branch2,branch3); } ~quaternary_node() { cleanup_branches::execute(branch_); } inline T value() const { const T arg0 = branch_[0].first->value(); const T arg1 = branch_[1].first->value(); const T arg2 = branch_[2].first->value(); const T arg3 = branch_[3].first->value(); switch (operation_) { case e_min : return std::min(std::min(arg0,arg1),std::min(arg2,arg3)); case e_max : return std::max(std::max(arg0,arg1),std::max(arg2,arg3)); case e_avg : return (arg0 + arg1 + arg2 + arg3) / T(4.0); case e_sum : return (arg0 + arg1 + arg2 + arg3); case e_prod : return (arg0 * arg1 * arg2 * arg3); default : return std::numeric_limits::quiet_NaN(); } } inline typename expression_node::node_type type() const { return expression_node::e_quaternary; } protected: operator_type operation_; branch_t branch_[4]; }; template class quinary_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; quinary_node(const operator_type& operation, expression_ptr branch0, expression_ptr branch1, expression_ptr branch2, expression_ptr branch3, expression_ptr branch4) : operation_(operation) { init_branches<5>(branch_,branch0,branch1,branch2,branch3,branch4); } ~quinary_node() { cleanup_branches::execute(branch_); } inline T value() const { const T arg0 = branch_[0].first->value(); const T arg1 = branch_[1].first->value(); const T arg2 = branch_[2].first->value(); const T arg3 = branch_[3].first->value(); const T arg4 = branch_[4].first->value(); switch (operation_) { case e_min : return std::min(std::min(std::min(arg0,arg1),std::min(arg2,arg3)),arg4); case e_max : return std::max(std::max(std::max(arg0,arg1),std::max(arg2,arg3)),arg4); case e_avg : return (arg0 + arg1 + arg2 + arg3 + arg4) / T(5.0); case e_sum : return (arg0 + arg1 + arg2 + arg3 + arg4); case e_prod : return (arg0 * arg1 * arg2 * arg3 * arg4); default : return std::numeric_limits::quiet_NaN(); } } inline typename expression_node::node_type type() const { return expression_node::e_quinary; } private: operator_type operation_; branch_t branch_[5]; }; template class senary_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; senary_node(const operator_type& operation, expression_ptr branch0, expression_ptr branch1, expression_ptr branch2, expression_ptr branch3, expression_ptr branch4, expression_ptr branch5) : operation_(operation) { init_branches<6>(branch_,branch0,branch1,branch2,branch3,branch4,branch5); } ~senary_node() { cleanup_branches::execute(branch_); } inline T value() const { const T arg0 = branch_[0].first->value(); const T arg1 = branch_[1].first->value(); const T arg2 = branch_[2].first->value(); const T arg3 = branch_[3].first->value(); const T arg4 = branch_[4].first->value(); const T arg5 = branch_[5].first->value(); switch (operation_) { case e_min : return std::min(std::min(std::min(arg0,arg1),std::min(arg2,arg3)),std::min(arg4,arg5)); case e_max : return std::max(std::max(std::max(arg0,arg1),std::max(arg2,arg3)),std::max(arg4,arg5)); case e_avg : return (arg0 + arg1 + arg2 + arg3 + arg4 + arg5) / T(6.0); case e_sum : return (arg0 + arg1 + arg2 + arg3 + arg4 + arg5); case e_prod : return (arg0 * arg1 * arg2 * arg3 * arg4 * arg5); case e_default : default : return std::numeric_limits::quiet_NaN(); } } inline typename expression_node::node_type type() const { return expression_node::e_senary; } private: operator_type operation_; branch_t branch_[6]; }; template class conditional_node : public expression_node { public: typedef expression_node* expression_ptr; conditional_node(expression_ptr test, expression_ptr consequent, expression_ptr alternative) : test_(test), consequent_(consequent), alternative_(alternative), test_deletable_(!is_variable_node(test_)), consequent_deletable_(!is_variable_node(consequent_)), alternative_deletable_(!is_variable_node(alternative_)) {} ~conditional_node() { if (test_ && test_deletable_) delete test_; if (consequent_ && consequent_deletable_) delete consequent_; if (alternative_ && alternative_deletable_) delete alternative_; } inline T value() const { if (is_true(test_)) return consequent_->value(); else return alternative_->value(); } inline typename expression_node::node_type type() const { return expression_node::e_conditional; } private: expression_ptr test_; expression_ptr consequent_; expression_ptr alternative_; bool test_deletable_; bool consequent_deletable_; bool alternative_deletable_; }; template class while_loop_node : public expression_node { public: typedef expression_node* expression_ptr; while_loop_node(expression_ptr test, expression_ptr branch) : test_(test), branch_(branch), test_deletable_(!is_variable_node(test_)), branch_deletable_(!is_variable_node(branch_)) {} ~while_loop_node() { if (test_ && test_deletable_) delete test_; if (branch_ && branch_deletable_) delete branch_; } inline T value() const { T result = T(0); while (is_true(test_)) { result = branch_->value(); } return result; } inline typename expression_node::node_type type() const { return expression_node::e_while; } private: expression_ptr test_; expression_ptr branch_; bool test_deletable_; bool branch_deletable_; }; template class variable_node : public expression_node { public: static T null_value; explicit variable_node() : value_(&null_value) {} explicit variable_node(T& value) : value_(&value) {} inline bool operator <(const variable_node& v) const { return this < (&v); } inline T value() const { return (*value_); } inline T& ref() { return (*value_); } inline const T& ref() const { return (*value_); } inline typename expression_node::node_type type() const { return expression_node::e_variable; } private: T* value_; }; template T variable_node::null_value = T(std::numeric_limits::quiet_NaN()); #ifndef exprtk_disable_string_capabilities template class stringvar_node : public expression_node { public: static std::string null_value; explicit stringvar_node() : value_(&null_value) {} explicit stringvar_node(std::string& value) : value_(&value) {} inline bool operator <(const stringvar_node& v) const { return this < (&v); } inline T value() const { return std::numeric_limits::quiet_NaN(); } inline std::string str() const { return (*value_); } inline virtual std::string& ref() { return (*value_); } inline virtual const std::string& ref() const { return (*value_); } inline typename expression_node::node_type type() const { return expression_node::e_stringvar; } private: std::string* value_; }; template std::string stringvar_node::null_value = std::string(""); #endif template inline T axn(T a, T x) { return a * exprtk::details::numeric::fast_exp::result(x); } // a*x^n template inline T axnb(T a, T x, T b) { return a * exprtk::details::numeric::fast_exp::result(x) + b; } // a*x^n+b template struct sf00_op { static inline T process(const T x, const T y, const T z) { return (x + y) / z; } }; template struct sf01_op { static inline T process(const T x, const T y, const T z) { return (x + y) * z; } }; template struct sf02_op { static inline T process(const T x, const T y, const T z) { return (x - y) / z; } }; template struct sf03_op { static inline T process(const T x, const T y, const T z) { return (x - y) * z; } }; template struct sf04_op { static inline T process(const T x, const T y, const T z) { return (x * y) + z; } }; template struct sf05_op { static inline T process(const T x, const T y, const T z) { return (x * y) - z; } }; template struct sf06_op { static inline T process(const T x, const T y, const T z) { return (x * y) / z; } }; template struct sf07_op { static inline T process(const T x, const T y, const T z) { return (x * y) * z; } }; template struct sf08_op { static inline T process(const T x, const T y, const T z) { return (x / y) + z; } }; template struct sf09_op { static inline T process(const T x, const T y, const T z) { return (x / y) - z; } }; template struct sf10_op { static inline T process(const T x, const T y, const T z) { return (x / y) / z; } }; template struct sf11_op { static inline T process(const T x, const T y, const T z) { return (x / y) * z; } }; template struct sf12_op { static inline T process(const T x, const T y, const T z) { return x / (y + z); } }; template struct sf13_op { static inline T process(const T x, const T y, const T z) { return x / (y - z); } }; template struct sf14_op { static inline T process(const T x, const T y, const T z) { return x / (y * z); } }; template struct sf15_op { static inline T process(const T x, const T y, const T z) { return x / (y / z); } }; template struct sf16_op { static inline T process(const T x, const T y, const T z) { return x - (y / z); } }; template struct sf17_op { static inline T process(const T x, const T y, const T z) { return x - (y / z); } }; template struct sf18_op { static inline T process(const T x, const T y, const T z) { return axnb(x,y,z); } }; //x * y^2 + z template struct sf19_op { static inline T process(const T x, const T y, const T z) { return axnb(x,y,z); } }; //x * y^3 + z template struct sf20_op { static inline T process(const T x, const T y, const T z) { return axnb(x,y,z); } }; //x * y^4 + z template struct sf21_op { static inline T process(const T x, const T y, const T z) { return axnb(x,y,z); } }; //x * y^5 + z template struct sf22_op { static inline T process(const T x, const T y, const T z) { return axnb(x,y,z); } }; //x * y^6 + z template struct sf23_op { static inline T process(const T x, const T y, const T z) { return axnb(x,y,z); } }; //x * y^7 + z template struct sf24_op { static inline T process(const T x, const T y, const T z) { return axnb(x,y,z); } }; //x * y^8 + z template struct sf25_op { static inline T process(const T x, const T y, const T z) { return axnb(x,y,z); } }; //x * y^9 + z template struct sf26_op { static inline T process(const T x, const T y, const T z) { return x * numeric::log(y) + z; } }; template struct sf27_op { static inline T process(const T x, const T y, const T z) { return x * numeric::log(y) - z; } }; template struct sf28_op { static inline T process(const T x, const T y, const T z) { return x * numeric::log10(y) + z; } }; template struct sf29_op { static inline T process(const T x, const T y, const T z) { return x * numeric::log10(y) - z; } }; template struct sf30_op { static inline T process(const T x, const T y, const T z) { return x * numeric::sin(y) + z; } }; template struct sf31_op { static inline T process(const T x, const T y, const T z) { return x * numeric::sin(y) - z; } }; template struct sf32_op { static inline T process(const T x, const T y, const T z) { return x * numeric::cos(y) + z; } }; template struct sf33_op { static inline T process(const T x, const T y, const T z) { return x * numeric::cos(y) - z; } }; template struct sf34_op { static inline T process(const T x, const T y, const T z) { return is_true(x) ? y : z; } }; template struct sf35_op { static inline T process(const T x, const T y, const T z, const T w) { return x + ((y + z) / w); } }; template struct sf36_op { static inline T process(const T x, const T y, const T z, const T w) { return x + ((y + z) * w); } }; template struct sf37_op { static inline T process(const T x, const T y, const T z, const T w) { return x + ((y - z) / w); } }; template struct sf38_op { static inline T process(const T x, const T y, const T z, const T w) { return x + ((y - z) * w); } }; template struct sf39_op { static inline T process(const T x, const T y, const T z, const T w) { return x + ((y * z) / w); } }; template struct sf40_op { static inline T process(const T x, const T y, const T z, const T w) { return x + ((y * z) * w); } }; template struct sf41_op { static inline T process(const T x, const T y, const T z, const T w) { return x + ((y / z) + w); } }; template struct sf42_op { static inline T process(const T x, const T y, const T z, const T w) { return x + ((y / z) / w); } }; template struct sf43_op { static inline T process(const T x, const T y, const T z, const T w) { return x + ((y / z) * w); } }; template struct sf44_op { static inline T process(const T x, const T y, const T z, const T w) { return x - ((y + z) / w); } }; template struct sf45_op { static inline T process(const T x, const T y, const T z, const T w) { return x - ((y + z) * w); } }; template struct sf46_op { static inline T process(const T x, const T y, const T z, const T w) { return x - ((y - z) / w); } }; template struct sf47_op { static inline T process(const T x, const T y, const T z, const T w) { return x - ((y - z) * w); } }; template struct sf48_op { static inline T process(const T x, const T y, const T z, const T w) { return x - ((y * z) / w); } }; template struct sf49_op { static inline T process(const T x, const T y, const T z, const T w) { return x - ((y * z) * w); } }; template struct sf50_op { static inline T process(const T x, const T y, const T z, const T w) { return x - ((y / z) / w); } }; template struct sf51_op { static inline T process(const T x, const T y, const T z, const T w) { return x - ((y / z) * w); } }; template struct sf52_op { static inline T process(const T x, const T y, const T z, const T w) { return ((x + y) * z) - w; } }; template struct sf53_op { static inline T process(const T x, const T y, const T z, const T w) { return ((x - y) * z) - w; } }; template struct sf54_op { static inline T process(const T x, const T y, const T z, const T w) { return ((x * y) * z) - w; } }; template struct sf55_op { static inline T process(const T x, const T y, const T z, const T w) { return ((x / y) * z) - w; } }; template struct sf56_op { static inline T process(const T x, const T y, const T z, const T w) { return ((x + y) / z) - w; } }; template struct sf57_op { static inline T process(const T x, const T y, const T z, const T w) { return ((x - y) / z) - w; } }; template struct sf58_op { static inline T process(const T x, const T y, const T z, const T w) { return ((x * y) / z) - w; } }; template struct sf59_op { static inline T process(const T x, const T y, const T z, const T w) { return ((x / y) / z) - w; } }; template struct sf60_op { static inline T process(const T x, const T y, const T z, const T w) { return (x * y) + (z * w); } }; template struct sf61_op { static inline T process(const T x, const T y, const T z, const T w) { return (x * y) - (z * w); } }; template struct sf62_op { static inline T process(const T x, const T y, const T z, const T w) { return (x * y) + (z / w); } }; template struct sf63_op { static inline T process(const T x, const T y, const T z, const T w) { return (x * y) - (z / w); } }; template struct sf64_op { static inline T process(const T x, const T y, const T z, const T w) { return (x / y) + (z / w); } }; template struct sf65_op { static inline T process(const T x, const T y, const T z, const T w) { return (x / y) - (z / w); } }; template struct sf66_op { static inline T process(const T x, const T y, const T z, const T w) { return (x / y) - (z * w); } }; template struct sf67_op { static inline T process(const T x, const T y, const T z, const T w) { return axn(x,y) + axn(z,w); } }; //x*y^2+z*w^2 template struct sf68_op { static inline T process(const T x, const T y, const T z, const T w) { return axn(x,y) + axn(z,w); } }; //x*y^3+z*w^3 template struct sf69_op { static inline T process(const T x, const T y, const T z, const T w) { return axn(x,y) + axn(z,w); } }; //x*y^4+z*w^4 template struct sf70_op { static inline T process(const T x, const T y, const T z, const T w) { return axn(x,y) + axn(z,w); } }; //x*y^5+z*w^5 template struct sf71_op { static inline T process(const T x, const T y, const T z, const T w) { return axn(x,y) + axn(z,w); } }; //x*y^6+z*w^6 template struct sf72_op { static inline T process(const T x, const T y, const T z, const T w) { return axn(x,y) + axn(z,w); } }; //x*y^7+z*w^7 template struct sf73_op { static inline T process(const T x, const T y, const T z, const T w) { return axn(x,y) + axn(z,w); } }; //x*y^8+z*w^8 template struct sf74_op { static inline T process(const T x, const T y, const T z, const T w) { return axn(x,y) + axn(z,w); } }; //x*y^9+z*w^9 template struct sf75_op { static inline T process(const T x, const T y, const T z, const T w) { return (is_true(x) && is_true(y)) ? z : w; } }; template struct sf76_op { static inline T process(const T x, const T y, const T z, const T w) { return (is_true(x) || is_true(y)) ? z : w; } }; template struct sf77_op { static inline T process(const T x, const T y, const T z, const T w) { return (x < y) ? z : w; } }; template struct sf78_op { static inline T process(const T x, const T y, const T z, const T w) { return (x <= y) ? z : w; } }; template struct sf79_op { static inline T process(const T x, const T y, const T z, const T w) { return (x > y) ? z : w; } }; template struct sf80_op { static inline T process(const T x, const T y, const T z, const T w) { return (x >= y) ? z : w; } }; template struct sf81_op { static inline T process(const T x, const T y, const T z, const T w) { return numeric::equal(x,y) ? z : w; } }; template struct sf82_op { static inline T process(const T x, const T y, const T z, const T w) { return x * numeric::sin(y) + z * numeric::cos(w); } }; template class sf3_node : public trinary_node { public: typedef expression_node* expression_ptr; sf3_node(const operator_type& operation, expression_ptr branch0, expression_ptr branch1, expression_ptr branch2) : trinary_node(operation,branch0,branch1,branch2) {} inline T value() const { const T x = trinary_node::branch_[0].first->value(); const T y = trinary_node::branch_[1].first->value(); const T z = trinary_node::branch_[2].first->value(); return SpecialFunction::process(x,y,z); } }; template class sf4_node : public quaternary_node { public: typedef expression_node* expression_ptr; sf4_node(const operator_type& operation, expression_ptr branch0, expression_ptr branch1, expression_ptr branch2, expression_ptr branch3) : quaternary_node(operation,branch0,branch1,branch2,branch3) {} inline T value() const { const T x = quaternary_node::branch_[0].first->value(); const T y = quaternary_node::branch_[1].first->value(); const T z = quaternary_node::branch_[2].first->value(); const T w = quaternary_node::branch_[3].first->value(); return SpecialFunction::process(x,y,z,w); } }; template class sf3_var_node : public expression_node { public: typedef expression_node* expression_ptr; sf3_var_node(const T& v0, const T& v1, const T& v2) : v0_(v0), v1_(v1), v2_(v2) {} inline T value() const { return SpecialFunction::process(v0_,v1_,v2_); } inline typename expression_node::node_type type() const { return expression_node::e_trinary; } private: sf3_var_node(sf3_var_node&); sf3_var_node& operator=(sf3_var_node&); const T& v0_; const T& v1_; const T& v2_; }; template class sf4_var_node : public expression_node { public: typedef expression_node* expression_ptr; sf4_var_node(const T& v0, const T& v1, const T& v2, const T& v3) : v0_(v0), v1_(v1), v2_(v2), v3_(v3) {} inline T value() const { return SpecialFunction::process(v0_,v1_,v2_,v3_); } inline typename expression_node::node_type type() const { return expression_node::e_trinary; } private: sf4_var_node(sf4_var_node&); sf4_var_node& operator=(sf4_var_node&); const T& v0_; const T& v1_; const T& v2_; const T& v3_; }; template class assignment_node : public binary_node { public: typedef expression_node* expression_ptr; assignment_node(const operator_type& operation, expression_ptr branch0, expression_ptr branch1) : binary_node(operation,branch0,branch1) {} inline T value() const { if (is_variable_node(binary_node::branch_[0].first)) { variable_node* var_node_ptr = dynamic_cast*>(binary_node::branch_[0].first); if (var_node_ptr) { T& result = var_node_ptr->ref(); result = binary_node::branch_[1].first->value(); return result; } } return std::numeric_limits::quiet_NaN(); } }; template class function_N_node : public expression_node { public: //function of N paramters. typedef expression_node* expression_ptr; typedef std::pair branch_t; typedef IFunction ifunction; function_N_node(ifunction* func) : function_((N == func->param_count) ? func : reinterpret_cast(0)), parameter_count_(func->param_count) {} ~function_N_node() { cleanup_branches::execute(branch_); } template bool init_branches(expression_ptr (&b)[NumBranches]) { //Needed for incompetent and broken msvc compiler versions #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (N != NumBranches) return false; else { for (std::size_t i = 0; i < NumBranches; ++i) { if (b[i]) branch_[i] = std::make_pair(b[i],branch_deletable(b[i])); else return false; } return true; } #ifdef _MSC_VER #pragma warning(pop) #endif } inline bool operator <(const function_N_node& fn) const { return this < (&fn); } inline T value() const { //Needed for incompetent and broken msvc compiler versions #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if ((0 == function_) || (0 == N)) return std::numeric_limits::quiet_NaN(); else { T v[N]; evaluate_branches::execute(v,branch_); return invoke::execute(*function_,v); } #ifdef _MSC_VER #pragma warning(pop) #endif } template struct evaluate_branches { static inline void execute(T_ (&v)[BranchCount], const branch_t (&b)[BranchCount]) { for (std::size_t i = 0; i < BranchCount; ++i) { v[i] = b[i].first->value(); } } }; template struct evaluate_branches { static inline void execute(T_ (&v)[5], const branch_t (&b)[5]) { v[0] = b[0].first->value(); v[1] = b[1].first->value(); v[2] = b[2].first->value(); v[3] = b[3].first->value(); v[4] = b[4].first->value(); } }; template struct evaluate_branches { static inline void execute(T_ (&v)[4], const branch_t (&b)[4]) { v[0] = b[0].first->value(); v[1] = b[1].first->value(); v[2] = b[2].first->value(); v[3] = b[3].first->value(); } }; template struct evaluate_branches { static inline void execute(T_ (&v)[3], const branch_t (&b)[3]) { v[0] = b[0].first->value(); v[1] = b[1].first->value(); v[2] = b[2].first->value(); } }; template struct evaluate_branches { static inline void execute(T_ (&v)[2], const branch_t (&b)[2]) { v[0] = b[0].first->value(); v[1] = b[1].first->value(); } }; template struct evaluate_branches { static inline void execute(T_ (&v)[1], const branch_t (&b)[1]) { v[0] = b[0].first->value(); } }; template struct invoke { static inline T execute(ifunction*, branch_t (&)[ParamCount]) { return std::numeric_limits::quiet_NaN(); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[20]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9],v[10],v[11],v[12],v[13],v[14],v[15],v[16],v[17],v[18],v[19]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[19]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9],v[10],v[11],v[12],v[13],v[14],v[15],v[16],v[17],v[18]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[18]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9],v[10],v[11],v[12],v[13],v[14],v[15],v[16],v[17]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[17]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9],v[10],v[11],v[12],v[13],v[14],v[15],v[16]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[16]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9],v[10],v[11],v[12],v[13],v[14],v[15]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[15]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9],v[10],v[11],v[12],v[13],v[14]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[14]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9],v[10],v[11],v[12],v[13]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[13]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9],v[10],v[11],v[12]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[12]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9],v[10],v[11]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[11]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9],v[10]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[10]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8],v[9]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[9]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7],v[8]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[8]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6],v[7]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[ 7]) { return f(v[0],v[1],v[2],v[3],v[4],v[5],v[6]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[6]) { return f(v[0],v[1],v[2],v[3],v[4],v[5]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[5]) { return f(v[0],v[1],v[2],v[3],v[4]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[4]) { return f(v[0],v[1],v[2],v[3]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[3]) { return f(v[0],v[1],v[2]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[2]) { return f(v[0],v[1]); } }; template struct invoke { static inline T_ execute(ifunction& f, T_ (&v)[1]) { return f(v[0]); } }; inline typename expression_node::node_type type() const { return expression_node::e_function; } private: ifunction* function_; std::size_t parameter_count_; branch_t branch_[N]; }; template class function_N_node : public expression_node { public: typedef expression_node* expression_ptr; typedef IFunction ifunction; function_N_node(ifunction* func) : function_((0 == func->param_count) ? func : reinterpret_cast(0)) {} inline bool operator <(const function_N_node& fn) const { return this < (&fn); } inline T value() const { if (0 == function_) return std::numeric_limits::quiet_NaN(); else return (*function_)(); } inline typename expression_node::node_type type() const { return expression_node::e_function; } private: ifunction* function_; std::size_t parameter_count_; }; #define exprtk_def_unary_op(OpName) \ template \ struct OpName##_op \ { \ static inline T process(const T v) { return numeric:: OpName (v); } \ static inline typename expression_node::node_type type() { return expression_node::e_##OpName; } \ static inline details::operator_type operation() { return details::e_##OpName; } \ }; exprtk_def_unary_op(abs ) exprtk_def_unary_op(acos ) exprtk_def_unary_op(asin ) exprtk_def_unary_op(atan ) exprtk_def_unary_op(ceil ) exprtk_def_unary_op(cos ) exprtk_def_unary_op(cosh ) exprtk_def_unary_op(cot ) exprtk_def_unary_op(csc ) exprtk_def_unary_op(d2g ) exprtk_def_unary_op(d2r ) exprtk_def_unary_op(erf ) exprtk_def_unary_op(erfc ) exprtk_def_unary_op(exp ) exprtk_def_unary_op(floor) exprtk_def_unary_op(frac ) exprtk_def_unary_op(g2d ) exprtk_def_unary_op(log ) exprtk_def_unary_op(log10) exprtk_def_unary_op(neg ) exprtk_def_unary_op(notl ) exprtk_def_unary_op(pos ) exprtk_def_unary_op(r2d ) exprtk_def_unary_op(round) exprtk_def_unary_op(sec ) exprtk_def_unary_op(sgn ) exprtk_def_unary_op(sin ) exprtk_def_unary_op(sinh ) exprtk_def_unary_op(sqrt ) exprtk_def_unary_op(tan ) exprtk_def_unary_op(tanh ) exprtk_def_unary_op(trunc) #undef exprtk_def_unary_op template struct add_op { static inline T process(const T t1, const T t2) { return t1 + t2; } static inline T process(const T t1, const T t2, const T t3) { return t1 + t2 + t3; } static inline typename expression_node::node_type type() { return expression_node::e_add; } static inline details::operator_type operation() { return details::e_add; } }; template struct mul_op { static inline T process(const T t1, const T t2) { return t1 * t2; } static inline T process(const T t1, const T t2, const T t3) { return t1 * t2 * t3; } static inline typename expression_node::node_type type() { return expression_node::e_mul; } static inline details::operator_type operation() { return details::e_mul; } }; template struct sub_op { static inline T process(const T t1, const T t2) { return t1 - t2; } static inline T process(const T t1, const T t2, const T t3) { return t1 - t2 - t3; } static inline typename expression_node::node_type type() { return expression_node::e_sub; } static inline details::operator_type operation() { return details::e_sub; } }; template struct div_op { static inline T process(const T t1, const T t2) { return t1 / t2; } static inline T process(const T t1, const T t2, const T t3) { return t1 / t2 / t3; } static inline typename expression_node::node_type type() { return expression_node::e_div; } static inline details::operator_type operation() { return details::e_div; } }; template struct mod_op { static inline T process(const T t1, const T t2) { return numeric::modulus(t1,t2); } static inline typename expression_node::node_type type() { return expression_node::e_mod; } static inline details::operator_type operation() { return details::e_mod; } }; template struct pow_op { static inline T process(const T t1, const T t2) { return numeric::pow(t1,t2); } static inline typename expression_node::node_type type() { return expression_node::e_pow; } static inline details::operator_type operation() { return details::e_pow; } }; template struct lt_op { static inline T process(const T t1, const T t2) { return ((t1 < t2) ? T(1) : T(0)); } static inline T process(const std::string& t1, const std::string& t2) { return ((t1 < t2) ? T(1) : T(0)); } static inline typename expression_node::node_type type() { return expression_node::e_lt; } static inline details::operator_type operation() { return details::e_lt; } }; template struct lte_op { static inline T process(const T t1, const T t2) { return ((t1 <= t2) ? T(1) : T(0)); } static inline T process(const std::string& t1, const std::string& t2) { return ((t1 <= t2) ? T(1) : T(0)); } static inline typename expression_node::node_type type() { return expression_node::e_lte; } static inline details::operator_type operation() { return details::e_lte; } }; template struct gt_op { static inline T process(const T t1, const T t2) { return ((t1 > t2) ? T(1) : T(0)); } static inline T process(const std::string& t1, const std::string& t2) { return ((t1 > t2) ? T(1) : T(0)); } static inline typename expression_node::node_type type() { return expression_node::e_gt; } static inline details::operator_type operation() { return details::e_gt; } }; template struct gte_op { static inline T process(const T t1, const T t2) { return ((t1 >= t2) ? T(1) : T(0)); } static inline T process(const std::string& t1, const std::string& t2) { return ((t1 >= t2) ? T(1) : T(0)); } static inline typename expression_node::node_type type() { return expression_node::e_gte; } static inline details::operator_type operation() { return details::e_gte; } }; template struct eq_op { static inline T process(const T t1, const T t2) { return ((t1 == t2) ? T(1) : T(0)); } static inline T process(const std::string& t1, const std::string& t2) { return ((t1 == t2) ? T(1) : T(0)); } static inline typename expression_node::node_type type() { return expression_node::e_eq; } static inline details::operator_type operation() { return details::e_eq; } }; template struct ne_op { static inline T process(const T t1, const T t2) { return ((t1 != t2) ? T(1) : T(0)); } static inline T process(const std::string& t1, const std::string& t2) { return ((t1 != t2) ? T(1) : T(0)); } static inline typename expression_node::node_type type() { return expression_node::e_ne; } static inline details::operator_type operation() { return details::e_ne; } }; template struct and_op { static inline T process(const T t1, const T t2) { return (details::is_true(t1) && details::is_true(t2)) ? T(1) : T(0); } static inline typename expression_node::node_type type() { return expression_node::e_and; } static inline details::operator_type operation() { return details::e_and; } }; template struct nand_op { static inline T process(const T t1, const T t2) { return (details::is_true(t1) && details::is_true(t2)) ? T(0) : T(1); } static inline typename expression_node::node_type type() { return expression_node::e_nand; } static inline details::operator_type operation() { return details::e_nand; } }; template struct or_op { static inline T process(const T t1, const T t2) { return (details::is_true(t1) || details::is_true(t2)) ? T(1) : T(0); } static inline typename expression_node::node_type type() { return expression_node::e_or; } static inline details::operator_type operation() { return details::e_or; } }; template struct nor_op { static inline T process(const T t1, const T t2) { return (details::is_true(t1) || details::is_true(t2)) ? T(0) : T(1); } static inline typename expression_node::node_type type() { return expression_node::e_nor; } static inline details::operator_type operation() { return details::e_nor; } }; template struct xor_op { static inline T process(const T t1, const T t2) { return numeric::xor_opr(t1,t2); } static inline typename expression_node::node_type type() { return expression_node::e_nor; } static inline details::operator_type operation() { return details::e_xor; } }; template struct in_op { static inline T process(const T&, const T&) { return std::numeric_limits::quiet_NaN(); } static inline T process(const std::string& t1, const std::string& t2) { return ((std::string::npos != t2.find(t1)) ? T(1) : T(0)); } static inline typename expression_node::node_type type() { return expression_node::e_in; } static inline details::operator_type operation() { return details::e_in; } }; template struct like_op { static inline T process(const T&, const T&) { return std::numeric_limits::quiet_NaN(); } static inline T process(const std::string& t1, const std::string& t2) { return (details::wc_match(t2,t1) ? T(1) : T(0)); } static inline typename expression_node::node_type type() { return expression_node::e_like; } static inline details::operator_type operation() { return details::e_like; } }; template struct ilike_op { static inline T process(const T&, const T&) { return std::numeric_limits::quiet_NaN(); } static inline T process(const std::string& t1, const std::string& t2) { return (details::wc_imatch(t2,t1) ? T(1) : T(0)); } static inline typename expression_node::node_type type() { return expression_node::e_ilike; } static inline details::operator_type operation() { return details::e_ilike; } }; template struct inrange_op { static inline T process(const T& t0, const T& t1, const T& t2) { return ((t0 <= t1) && (t1 <= t2)) ? T(1) : T(0); } static inline T process(const std::string& t0, const std::string& t1, const std::string& t2) { return ((t0 <= t1) && (t1 <= t2)) ? T(1) : T(0); } static inline typename expression_node::node_type type() { return expression_node::e_inranges; } static inline details::operator_type operation() { return details::e_ilike; } }; template class vov_base_node : public expression_node { public: inline virtual operator_type operation() const { return details::e_default; } }; template class cov_base_node : public expression_node { public: inline virtual operator_type operation() const { return details::e_default; } }; template class voc_base_node : public expression_node { public: inline virtual operator_type operation() const { return details::e_default; } }; template class uv_base_node : public expression_node { public: inline virtual operator_type operation() const { return details::e_default; } }; template class sos_base_node : public expression_node { public: inline virtual operator_type operation() const { return details::e_default; } }; template class sosos_base_node : public expression_node { public: inline virtual operator_type operation() const { return details::e_default; } }; template class unary_variable_node : public uv_base_node { public: typedef expression_node* expression_ptr; typedef Operation operation_t; explicit unary_variable_node(const T& v) : v_(v) {} inline T value() const { return Operation::process(v_); } inline typename expression_node::node_type type() const { return Operation::type(); } inline operator_type operation() const { return Operation::operation(); } inline const T& v() { return v_; } private: unary_variable_node(unary_variable_node&); unary_variable_node& operator=(unary_variable_node&); const T& v_; }; template class uvouv_node : public expression_node { public: // UOpr1(v0) Op UOpr2(v1) typedef expression_node* expression_ptr; typedef UOpr1 opr1_t; typedef UOpr2 opr2_t; typedef Operation op_t; explicit uvouv_node(const T& v0,const T& v1) : v0_(v0), v1_(v1) {} inline T value() const { return Operation::process(UOpr1::process(v0_),UOpr2::process(v1_)); } inline typename expression_node::node_type type() const { return Operation::type(); } inline operator_type operation() const { return Operation::operation(); } inline const T& v0() { return v0_; } inline const T& v1() { return v1_; } private: uvouv_node(uvouv_node&); uvouv_node& operator=(uvouv_node&); const T& v0_; const T& v1_; }; template class unary_branch_node : public expression_node { public: typedef expression_node* expression_ptr; typedef Operation operation_t; explicit unary_branch_node(expression_ptr branch) : branch_(branch), branch_deletable_(branch_deletable(branch_)) {} ~unary_branch_node() { if (branch_ && branch_deletable_) { delete branch_; branch_ = 0; } } inline T value() const { return Operation::process(branch_->value()); } inline typename expression_node::node_type type() const { return Operation::type(); } inline operator_type operation() const { return Operation::operation(); } private: unary_branch_node(unary_branch_node&); unary_branch_node& operator=(unary_branch_node&); expression_ptr branch_; bool branch_deletable_; }; template class vov_node : public vov_base_node { public: typedef expression_node* expression_ptr; typedef Operation operation_t; //variable op variable node explicit vov_node(const T& v0, const T& v1) : v0_(v0), v1_(v1) {} inline T value() const { return Operation::process(v0_,v1_); } inline typename expression_node::node_type type() const { return Operation::type(); } inline operator_type operation() const { return Operation::operation(); } inline const T& v0() const { return v0_; } inline const T& v1() const { return v1_; } protected: const T& v0_; const T& v1_; private: vov_node(vov_node&); vov_node& operator=(vov_node&); }; template class cov_node : public cov_base_node { public: typedef expression_node* expression_ptr; typedef Operation operation_t; //constant op variable node explicit cov_node(const T& c, const T& v) : c_(c), v_(v) {} inline T value() const { return Operation::process(c_,v_); } inline typename expression_node::node_type type() const { return Operation::type(); } inline operator_type operation() const { return Operation::operation(); } inline T c() { return c_; } inline const T& v() const { return v_; } protected: const T c_; const T& v_; private: cov_node(const cov_node&); cov_node& operator=(const cov_node&); }; template class voc_node : public voc_base_node { public: typedef expression_node* expression_ptr; typedef Operation operation_t; //variable op constant node explicit voc_node(const T& v, const T& c) : v_(v), c_(c) {} inline T value() const { return Operation::process(v_,c_); } inline operator_type operation() const { return Operation::operation(); } inline T c() { return c_; } inline const T& v() const { return v_; } protected: const T& v_; const T c_; private: voc_node(const voc_node&); voc_node& operator=(const voc_node&); }; template class vovov1_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //variable0 op1 (variable1 op2 variable2) node explicit vovov1_node(const T& v0, vov_node& vn) : v0_(v0), v1_(vn.v0()), v2_(vn.v1()) {} inline T value() const { return Operation1::process(v0_,Operation2::process(v1_,v2_)); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T& v0_; const T& v1_; const T& v2_; private: vovov1_node(const vovov1_node&); vovov1_node& operator=(const vovov1_node&); }; template class vovov2_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //(variable0 op1 variable1) op2 variable2 node explicit vovov2_node(vov_node& vn, const T& v2) : v0_(vn.v0()), v1_(vn.v1()), v2_(v2) {} inline T value() const { return Operation2::process(Operation1::process(v0_,v1_),v2_); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T& v0_; const T& v1_; const T& v2_; private: vovov2_node(const vovov2_node&); vovov2_node& operator=(const vovov2_node&); }; template class covov1_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //constant op1 (variable0 op2 variable1) node explicit covov1_node(const T& c, vov_node& vn) : c_ (c), v0_(vn.v0()), v1_(vn.v1()) {} inline T value() const { return Operation1::process(c_,Operation2::process(v0_,v1_)); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T c_; const T& v0_; const T& v1_; private: covov1_node(const covov1_node&); covov1_node& operator=(const covov1_node&); }; template class covov2_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //(constant op1 variable0) op2 variable1 node explicit covov2_node(cov_node& cvn, const T& v1) : c_ (cvn.c()), v0_(cvn.v()), v1_(v1) {} inline T value() const { return Operation2::process(Operation1::process(c_,v0_),v1_); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T c_; const T& v0_; const T& v1_; private: covov2_node(covov2_node&); covov2_node& operator=(covov2_node&); }; template class vovoc1_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //variable0 op1 (variable1 op2 constant) node explicit vovoc1_node(const T& v0, voc_node& vcn) : v0_(v0), v1_(vcn.v()), c_ (vcn.c()) {} inline T value() const { return Operation1::process(v0_,Operation2::process(v1_,c_)); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T& v0_; const T& v1_; const T c_; private: vovoc1_node(const vovoc1_node&); vovoc1_node& operator=(const vovoc1_node&); }; template class vovoc2_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //(variable0 op1 variable1) op2 constant node explicit vovoc2_node(vov_node& vvn, const T& c) : v0_(vvn.v0()), v1_(vvn.v1()), c_ (c) {} inline T value() const { return Operation2::process(Operation1::process(v0_,v1_),c_); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T& v0_; const T& v1_; const T c_; private: vovoc2_node(vovoc2_node&); vovoc2_node& operator=(vovoc2_node&); }; template class covoc1_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //const0 op1 (variable op2 const1) node explicit covoc1_node(const T& c0, voc_node& vcn) : c0_(c0), v_ (vcn.v()), c1_(vcn.c()) {} inline T value() const { return Operation1::process(c0_,Operation2::process(v_,c1_)); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T c0_; const T& v_; const T c1_; private: covoc1_node(const covoc1_node&); covoc1_node& operator=(const covoc1_node&); }; template class covoc2_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //(const0 op1 variable) op2 const1 node explicit covoc2_node(cov_node& cvn, const T& c1) : c0_(cvn.c()), v_ (cvn.v()), c1_(c1) {} inline T value() const { return Operation2::process(Operation1::process(c0_,v_),c1_); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T c0_; const T& v_; const T c1_; private: covoc2_node(const covoc2_node&); covoc2_node& operator=(const covoc2_node&); }; template class vocov1_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //variable0 op1 (const op2 variable1) node explicit vocov1_node(const T& v0, cov_node& cvn) : v0_(v0), c_ (cvn.c()), v1_(cvn.v()) {} inline T value() const { return Operation1::process(v0_,Operation2::process(c_,v1_)); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T& v0_; const T c_; const T& v1_; private: vocov1_node(const vocov1_node&); vocov1_node& operator=(const vocov1_node&); }; template class vocov2_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //(variable0 op1 constant) op2 variable1 node explicit vocov2_node(voc_node& vcn, const T& v1) : v0_(vcn.v()), c_ (vcn.c()), v1_(v1) {} inline T value() const { return Operation2::process(Operation1::process(v0_,c_),v1_); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T& v0_; const T c_; const T& v1_; private: vocov2_node(const vocov2_node&); vocov2_node& operator=(const vocov2_node&); }; template class vovovov_node : public expression_node { public: typedef expression_node* expression_ptr; typedef std::pair branch_t; //(variable0 op1 variable1) op2 (variable2 op3 variable3) node explicit vovovov_node(vov_node& vn0, vov_node& vn1) : v0_(vn0.v0()), v1_(vn0.v1()), v2_(vn1.v0()), v3_(vn1.v1()) {} inline T value() const { return Operation2::process(Operation1::process(v0_,v1_),Operation3::process(v2_,v3_)); } inline typename expression_node::node_type type() const { return expression_node::e_none; } inline typename expression_node::node_type type1() const { return Operation1::type(); } inline typename expression_node::node_type type2() const { return Operation2::type(); } protected: const T& v0_; const T& v1_; const T& v2_; const T& v3_; private: vovovov_node(vovovov_node&); vovovov_node& operator=(const vovovov_node&); }; #ifndef exprtk_disable_string_capabilities template class sos_node : public sos_base_node { public: typedef expression_node* expression_ptr; typedef Operation operation_t; //variable op variable node explicit sos_node(SType0 s0, SType1 s1) : s0_(s0), s1_(s1) {} inline T value() const { return Operation::process(s0_,s1_); } inline typename expression_node::node_type type() const { return Operation::type(); } inline operator_type operation() const { return Operation::operation(); } inline std::string& s0() { return s0_; } inline std::string& s1() { return s1_; } protected: SType0 s0_; SType1 s1_; private: sos_node(sos_node&); sos_node& operator=(sos_node&); }; template class sosos_node : public sosos_base_node { public: typedef expression_node* expression_ptr; typedef Operation operation_t; //variable op variable node explicit sosos_node(SType0 s0, SType1 s1, SType2 s2) : s0_(s0), s1_(s1), s2_(s2) {} inline T value() const { return Operation::process(s0_,s1_,s2_); } inline typename expression_node::node_type type() const { return Operation::type(); } inline operator_type operation() const { return Operation::operation(); } inline std::string& s0() { return s0_; } inline std::string& s1() { return s1_; } inline std::string& s2() { return s2_; } protected: SType0 s0_; SType1 s1_; SType2 s2_; private: sosos_node(sosos_node&); sosos_node& operator=(sosos_node&); }; #endif template class ipow_node : public expression_node { public: typedef expression_node* expression_ptr; typedef PowOp operation_t; explicit ipow_node(T& v) : v_(v) {} inline T value() const { return PowOp::result(v_); } inline typename expression_node::node_type type() const { return expression_node::e_ipow; } private: ipow_node(const ipow_node&); ipow_node& operator=(const ipow_node&); const T& v_; }; template class ipowinv_node : public expression_node { public: typedef expression_node* expression_ptr; typedef PowOp operation_t; explicit ipowinv_node(T& v) : v_(v) {} inline T value() const { return (T(1.0) / PowOp::result(v_)); } inline typename expression_node::node_type type() const { return expression_node::e_ipowinv; } private: ipowinv_node(const ipowinv_node&); ipowinv_node& operator=(const ipowinv_node&); const T& v_; }; template inline bool is_vov_node(const expression_node* node) { return (0 != dynamic_cast*>(node)); } template inline bool is_cov_node(const expression_node* node) { return (0 != dynamic_cast*>(node)); } template inline bool is_voc_node(const expression_node* node) { return (0 != dynamic_cast*>(node)); } template inline bool is_uv_node(const expression_node* node) { return (0 != dynamic_cast*>(node)); } template inline bool is_string_node(const expression_node* node) { return (expression_node::e_stringvar == node->type()); } template inline bool is_const_string_node(const expression_node* node) { return (expression_node::e_stringconst == node->type()); } class node_allocator { public: template inline expression_node* allocate(OpType& operation, ExprNode (&branch)[1]) { return allocate(operation,branch[0]); } template inline expression_node* allocate(OpType& operation, ExprNode (&branch)[2]) { return allocate(operation,branch[0],branch[1]); } template inline expression_node* allocate(OpType& operation, ExprNode (&branch)[3]) { return allocate(operation,branch[0],branch[1],branch[2]); } template inline expression_node* allocate(OpType& operation, ExprNode (&branch)[4]) { return allocate(operation,branch[0],branch[1],branch[2],branch[3]); } template inline expression_node* allocate(OpType& operation, ExprNode (&branch)[5]) { return allocate(operation,branch[0],branch[1],branch[2],branch[3],branch[4]); } template inline expression_node* allocate(OpType& operation, ExprNode (&branch)[6]) { return allocate(operation,branch[0],branch[1],branch[2],branch[3],branch[4],branch[5]); } template inline expression_node* allocate(T1& t1) const { return new node_type(t1); } template inline expression_node* allocate_c(const T1& t1) const { return new node_type(t1); } template inline expression_node* allocate(const T1& t1, const T2& t2) const { return new node_type(t1,t2); } template inline expression_node* allocate_cr(const T1& t1, T2& t2) const { return new node_type(t1,t2); } template inline expression_node* allocate_rc(T1& t1, const T2& t2) const { return new node_type(t1,t2); } template inline expression_node* allocate_rr(T1& t1, T2& t2) const { return new node_type(t1,t2); } template inline expression_node* allocate_tt(T1 t1, T2 t2) const { return new node_type(t1,t2); } template inline expression_node* allocate_rrr(T1& t1, T2& t2, T3& t3) const { return new node_type(t1,t2,t3); } template inline expression_node* allocate_rrrr(T1& t1, T2& t2, T3& t3, T4& t4) const { return new node_type(t1,t2,t3,t4); } template inline expression_node* allocate_type(T1 t1, T2 t2, T3 t3) const { return new node_type(t1,t2,t3); } template inline expression_node* allocate(const T1& t1, const T2& t2, const T3& t3) const { return new node_type(t1,t2,t3); } template inline expression_node* allocate(const T1& t1, const T2& t2, const T3& t3, const T4& t4) const { return new node_type(t1,t2,t3,t4); } template inline expression_node* allocate(const T1& t1, const T2& t2, const T3& t3, const T4& t4, const T5& t5) const { return new node_type(t1,t2,t3,t4,t5); } template inline expression_node* allocate(const T1& t1, const T2& t2, const T3& t3, const T4& t4, const T5& t5, const T6& t6) const { return new node_type(t1,t2,t3,t4,t5,t6); } template inline expression_node* allocate(const T1& t1, const T2& t2, const T3& t3, const T4& t4, const T5& t5, const T6& t6, const T7& t7) const { return new node_type(t1,t2,t3,t4,t5,t6,t7); } template inline expression_node* allocate(const T1& t1, const T2& t2, const T3& t3, const T4& t4, const T5& t5, const T6& t6, const T7& t7, const T8& t8) const { return new node_type(t1,t2,t3,t4,t5,t6,t7,t8); } template inline expression_node* allocate(const T1& t1, const T2& t2, const T3& t3, const T4& t4, const T5& t5, const T6& t6, const T7& t7, const T8& t8, const T9& t9) const { return new node_type(t1,t2,t3,t4,t5,t6,t7,t8,t9); } template inline expression_node* allocate(const T1& t1, const T2& t2, const T3& t3, const T4& t4, const T5& t5, const T6& t6, const T7& t7, const T8& t8, const T9& t9, const T10& t10) const { return new node_type(t1,t2,t3,t4,t5,t6,t7,t8,t9,t10); } template void inline free(expression_node*& e) const { delete e; e = 0; } }; inline void load_operations_map(std::multimap& m) { #define register_op(Symbol,Type,Args) m.insert(std::make_pair(std::string(Symbol),details::base_operation_t(Type,Args))); register_op( "abs",e_abs , 1) register_op( "acos",e_acos , 1) register_op( "asin",e_asin , 1) register_op( "atan",e_atan , 1) register_op( "ceil",e_ceil , 1) register_op( "cos",e_cos , 1) register_op( "cosh",e_cosh , 1) register_op( "exp",e_exp , 1) register_op( "floor",e_floor , 1) register_op( "log",e_log , 1) register_op( "log10",e_log10 , 1) register_op( "round",e_round , 1) register_op( "sin",e_sin , 1) register_op( "sinh",e_sinh , 1) register_op( "sec",e_sec , 1) register_op( "csc",e_csc , 1) register_op( "sqrt",e_sqrt , 1) register_op( "tan",e_tan , 1) register_op( "tanh",e_tanh , 1) register_op( "cot",e_cot , 1) register_op( "rad2deg",e_r2d , 1) register_op( "deg2rad",e_d2r , 1) register_op( "deg2grad",e_d2g , 1) register_op( "grad2deg",e_g2d , 1) register_op( "sgn",e_sgn , 1) register_op( "not",e_notl , 1) register_op( "erf",e_erf , 1) register_op( "erfc",e_erfc , 1) register_op( "frac",e_frac , 1) register_op( "trunc",e_trunc , 1) register_op( "atan2",e_atan2 , 2) register_op( "min",e_min , 2) register_op( "max",e_max , 2) register_op( "avg",e_avg , 2) register_op( "sum",e_sum , 2) register_op( "mul",e_prod , 2) register_op( "mod",e_mod , 2) register_op( "logn",e_logn , 2) register_op( "pow",e_pow , 2) register_op( "root",e_root , 2) register_op( "roundn",e_roundn , 2) register_op( "equal",e_equal , 2) register_op("not_equal",e_nequal , 2) register_op( "hyp",e_hyp , 2) register_op( "shr",e_shr , 2) register_op( "shl",e_shl , 2) register_op( "clamp",e_clamp , 3) register_op( "inrange",e_inrange , 3) register_op( "min",e_min , 3) register_op( "max",e_max , 3) register_op( "avg",e_avg , 3) register_op( "sum",e_sum , 3) register_op( "mul",e_prod , 3) register_op( "min",e_min , 4) register_op( "max",e_max , 4) register_op( "avg",e_avg , 4) register_op( "sum",e_sum , 4) register_op( "mul",e_prod , 4) register_op( "min",e_min , 5) register_op( "max",e_max , 5) register_op( "avg",e_avg , 5) register_op( "sum",e_sum , 5) register_op( "mul",e_prod , 5) register_op( "min",e_min , 6) register_op( "max",e_max , 6) register_op( "avg",e_avg , 6) register_op( "sum",e_sum , 6) register_op( "mul",e_prod , 6) #undef register_op } } // namespace details template class ifunction { public: explicit ifunction(const std::size_t& pc) : param_count(pc) {} virtual ~ifunction() {} std::size_t param_count; inline virtual T operator()() { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&,const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } inline virtual T operator()(const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&, const T&) { return std::numeric_limits::quiet_NaN(); } }; template class symbol_table { private: template struct type_store { typedef typename details::variable_node variable_node_t; typedef ifunction ifunction_t; #ifndef exprtk_disable_string_capabilities typedef typename details::stringvar_node stringvar_node_t; #endif typedef Type type_t; typedef type_t* type_ptr; typedef std::pair type_pair_t; typedef std::map type_map_t; typedef typename type_map_t::iterator tm_itr_t; typedef typename type_map_t::const_iterator tm_const_itr_t; enum { lut_size = 256 }; type_pair_t short_type_lut[lut_size]; type_map_t map; std::size_t size; type_store() : size(0) {} inline bool symbol_exists(const std::string& symbol_name) const { if (symbol_name.empty()) return false; else if ((1 == symbol_name.size()) && short_type_lut[static_cast(std::tolower(symbol_name[0]))].second) return true; else if (map.end() != map.find(symbol_name)) return true; else return false; } inline bool is_constant(const std::string& symbol_name) const { if (symbol_name.empty()) return false; else if (1 == symbol_name.size() && short_type_lut[static_cast(std::tolower(symbol_name[0]))].first) return true; else { tm_const_itr_t itr = map.find(symbol_name); if (map.end() == itr) return false; else return (*itr).second.first; } } inline bool add(const std::string& symbol_name, RawType& t, const bool is_constant = false) { struct tie { static inline std::pair make(T& t,const bool is_constant = false) { return std::make_pair(is_constant,new variable_node_t(t)); } #ifndef exprtk_disable_string_capabilities static inline std::pair make(std::string& t,const bool is_constant = false) { return std::make_pair(is_constant,new stringvar_node_t(t)); } #endif static inline std::pair make(function_t& t, const bool is_constant = false) { return std::make_pair(is_constant,&t); } }; if (1 == symbol_name.size()) { short_type_lut[static_cast(std::tolower(symbol_name[0]))] = tie::make(t,is_constant); ++size; } else { for (std::size_t i = 0; i < details::reserved_symbols_size; ++i) { if (details::imatch(symbol_name,details::reserved_symbols[i])) { return false; } } tm_itr_t itr = map.find(symbol_name); if (map.end() == itr) { map[symbol_name] = tie::make(t,is_constant); ++size; } } return true; } inline type_ptr get(const std::string& symbol_name) { if (1 == symbol_name.size()) { type_pair_t& tp = short_type_lut[static_cast(std::tolower(symbol_name[0]))]; if (tp.second) return tp.second; else return reinterpret_cast(0); } else { tm_const_itr_t itr = map.find(symbol_name); if (map.end() == itr) return reinterpret_cast(0); else return itr->second.second; } } inline bool remove(const std::string& symbol_name) { if (1 == symbol_name.size()) { type_pair_t& tp = short_type_lut[static_cast(std::tolower(symbol_name[0]))]; if (0 == tp.second) return false; struct deleter { static inline void process(std::pair& n) { delete n.second; } #ifndef exprtk_disable_string_capabilities static inline void process(std::pair& n) { delete n.second; } #endif static inline void process(std::pair&) { } }; deleter::process(tp); tp.first = false; tp.second = 0; --size; return true; } else { tm_itr_t itr = map.find(symbol_name); if (map.end() != itr) { struct deleter { static inline void process(std::pair& n) { delete n.second; } #ifndef exprtk_disable_string_capabilities static inline void process(std::pair& n) { delete n.second; } #endif static inline void process(std::pair&) { } }; deleter::process((*itr).second); map.erase(itr); --size; return true; } else return false; } } inline RawType& type_ref(const std::string& symbol_name) { struct init_type { static inline double set(long double) { return (0.0); } static inline float set(float) { return (0.0f); } static inline std::string set(std::string) { return std::string(""); } }; static RawType null_type = init_type::set(RawType()); if (1 == symbol_name.size()) { type_pair_t& tp = short_type_lut[static_cast(std::tolower(symbol_name[0]))]; if (tp.second) return tp->second.ref(); else return null_type; } else { tm_const_itr_t itr = map.find(symbol_name); if (map.end() == itr) return null_type; else return itr->second.second->ref(); } } inline void clear() { for (std::size_t i = 0; i < lut_size; ++i) { if (short_type_lut[i].second) { delete (short_type_lut[i]).second; short_type_lut[i].first = false; short_type_lut[i].second = reinterpret_cast(0); } } if (!map.empty()) { tm_itr_t itr = map.begin(); tm_itr_t end = map.end(); while (end != itr) { struct deleter { static inline void process(std::pair& n) { delete n.second; } static inline void process(std::pair&) { } #ifndef exprtk_disable_string_capabilities static inline void process(std::pair& n) { delete n.second; } #endif }; deleter::process((*itr).second); ++itr; } map.clear(); } } template class Sequence> inline std::size_t get_list(Sequence,Allocator>& list) const { std::size_t count = 0; for (std::size_t i = 0; i < lut_size; ++i) { const type_pair_t& tp = short_type_lut[static_cast(i)]; if (0 != tp.second) { list.push_back(std::make_pair(std::string("") + static_cast(i),tp.second->ref())); ++count; } } if (!map.empty()) { tm_const_itr_t itr = map.begin(); tm_const_itr_t end = map.end(); while (end != itr) { list.push_back(std::make_pair((*itr).first,itr->second.second->ref())); ++itr; ++count; } } return count; } template class Sequence> inline std::size_t get_list(Sequence& vlist) const { std::size_t count = 0; for (std::size_t i = 0; i < lut_size; ++i) { const type_pair_t& tp = short_type_lut[static_cast(i)]; if (0 != tp.second) { vlist.push_back(std::string("") + static_cast(i)); ++count; } } if (!map.empty()) { tm_const_itr_t itr = map.begin(); tm_const_itr_t end = map.end(); while (end != itr) { vlist.push_back((*itr).first); ++itr; ++count; } } return count; } }; typedef typename details::variable_node variable_t; typedef variable_t* variable_ptr; #ifndef exprtk_disable_string_capabilities typedef typename details::stringvar_node stringvar_t; typedef stringvar_t* stringvar_ptr; #endif typedef ifunction function_t; typedef function_t* function_ptr; static const std::size_t lut_size = 256; //Symbol Table Holder struct st_holder { struct st_data { type_store,T> variable_store; #ifndef exprtk_disable_string_capabilities type_store,std::string> stringvar_store; #endif type_store,ifunction > function_store; st_data() { for (std::size_t i = 0; i < details::reserved_words_size; ++i) { reserved_symbol_table_.insert(details::reserved_words[i]); } for (std::size_t i = 0; i < details::reserved_symbols_size; ++i) { reserved_symbol_table_.insert(details::reserved_symbols[i]); } } inline bool is_reserved_symbol(const std::string& symbol) const { return (reserved_symbol_table_.end() != reserved_symbol_table_.find(symbol)); } std::list local_symbol_list_; std::list local_stringvar_list_; std::set reserved_symbol_table_; }; st_holder() : ref_count(1), data_(new st_data) {} st_holder(st_data* data) : ref_count(1), data_(data) {} ~st_holder() { if (data_ && (0 == ref_count)) { delete data_; data_ = 0; } } std::size_t ref_count; st_data* data_; }; public: symbol_table() : holder_(new st_holder) { clear(); } ~symbol_table() { if (holder_) { if (0 == --holder_->ref_count) { clear(); delete holder_; } } } symbol_table(const symbol_table& st) { holder_ = st.holder_; holder_->ref_count++; } inline symbol_table& operator=(const symbol_table& st) { if (holder_) { if (0 == --holder_->ref_count) { delete holder_; } holder_ = 0; } holder_ = st.holder_; holder_->ref_count++; return *this; } inline bool operator==(const symbol_table& st) { return (this == *st); } inline void clear() { if (!valid()) return; local_data().variable_store.clear(); local_data().function_store.clear(); #ifndef exprtk_disable_string_capabilities local_data().stringvar_store.clear(); #endif } inline std::size_t variable_count() const { if (valid()) return local_data().variable_store().size; else return 0; } #ifndef exprtk_disable_string_capabilities inline std::size_t stringvar_count() const { if (valid()) return local_data().stringvar_store().size; else return 0; } #endif inline std::size_t function_count() const { if (valid()) return local_data().function_store().size; else return 0; } inline variable_ptr get_variable(const std::string& variable_name) { if (!valid()) return reinterpret_cast(0); else if (!valid_symbol(variable_name)) return reinterpret_cast(0); else return local_data().variable_store.get(variable_name); } #ifndef exprtk_disable_string_capabilities inline stringvar_ptr get_stringvar(const std::string& string_name) { if (!valid()) return reinterpret_cast(0); else if (!valid_symbol(string_name)) return reinterpret_cast(0); else return local_data().stringvar_store.get(string_name); } #endif inline function_ptr get_function(const std::string& function_name) { if (!valid()) return reinterpret_cast(0); else if (!valid_symbol(function_name)) return reinterpret_cast(0); else return local_data().function_store.get(function_name); } inline T& variable_ref(const std::string& symbol_name) { static T null_var = T(0); if (!valid()) return null_var; else if (!valid_symbol(symbol_name)) return null_var; else return local_data().variable_store.type_ref(symbol_name); } #ifndef exprtk_disable_string_capabilities inline std::string& stringvar_ref(const std::string& symbol_name) { static std::string null_stringvar; if (!valid()) return null_stringvar; else if (!valid_symbol(symbol_name)) return null_stringvar; else return local_data().stringvar_store.type_ref(symbol_name); } #endif inline bool is_constant_node(const std::string& symbol_name) const { if (!valid()) return false; else if (!valid_symbol(symbol_name)) return false; else if (!local_data().variable_store.symbol_exists(symbol_name)) return false; else return local_data().variable_store.is_constant(symbol_name); } #ifndef exprtk_disable_string_capabilities inline bool is_constant_string(const std::string& symbol_name) const { if (!valid()) return false; else if (!valid_symbol(symbol_name)) return false; else if (!local_data().stringvar_store.symbol_exists(symbol_name)) return false; else return local_data().stringvar_store.is_constant(symbol_name); } #endif inline bool create_variable(const std::string& variable_name, const T& value = T(0)) { if (!valid()) return false; else if (!valid_symbol(variable_name)) return false; else if (symbol_exists(variable_name)) return false; local_data().local_symbol_list_.push_back(value); T& t = local_data().local_symbol_list_.back(); return add_variable(variable_name,t); } #ifndef exprtk_disable_string_capabilities inline bool create_stringvar(const std::string& stringvar_name, const std::string& value = std::string("")) { if (!valid()) return false; else if (!valid_symbol(stringvar_name)) return false; else if (symbol_exists(stringvar_name)) return false; local_data().local_stringvar_list_.push_back(value); std::string& s = local_data().local_stringvar_list_.back(); return add_stringvar(stringvar_name,s); } #endif inline bool add_variable(const std::string& variable_name, T& t, const bool is_constant = false) { if (!valid()) return false; else if (!valid_symbol(variable_name)) return false; else if (symbol_exists(variable_name)) return false; else return local_data().variable_store.add(variable_name,t,is_constant); } inline bool add_constant(const std::string& constant_name, const T& value) { if (!valid()) return false; else if (!valid_symbol(constant_name)) return false; else if (symbol_exists(constant_name)) return false; local_data().local_symbol_list_.push_back(value); T& t = local_data().local_symbol_list_.back(); return add_variable(constant_name,t,true); } #ifndef exprtk_disable_string_capabilities inline bool add_stringvar(const std::string& stringvar_name, std::string& s, const bool is_constant = false) { if (!valid()) return false; else if (!valid_symbol(stringvar_name)) return false; else if (symbol_exists(stringvar_name)) return false; else return local_data().stringvar_store.add(stringvar_name,s,is_constant); } #endif inline bool add_function(const std::string& function_name, function_t& function) { if (!valid()) return false; else if (!valid_symbol(function_name)) return false; else if (symbol_exists(function_name)) return false; else return local_data().function_store.add(function_name,function); } inline bool remove_variable(const std::string& variable_name) { if (!valid()) return false; else return local_data().variable_store.remove(variable_name); } #ifndef exprtk_disable_string_capabilities inline bool remove_stringvar(const std::string& string_name) { if (!valid()) return false; else return local_data().stringvar_store.remove(string_name); } #endif inline bool remove_function(const std::string& function_name) { if (!valid()) return false; else return local_data().function_store.remove(function_name); } inline bool add_constants() { return add_pi() && add_epsilon() && add_infinity(); } inline bool add_pi() { static const T local_pi = T(details::numeric::constant::pi); return add_constant("pi",local_pi); } inline bool add_epsilon() { static const T local_epsilon = std::numeric_limits::epsilon(); return add_constant("epsilon",local_epsilon); } inline bool add_infinity() { static const T local_infinity = std::numeric_limits::infinity(); return add_constant("inf",local_infinity); } template class Sequence> inline std::size_t get_variable_list(Sequence,Allocator>& vlist) const { if (!valid()) return 0; else return local_data().variable_store.get_list(vlist); } template class Sequence> inline std::size_t get_variable_list(Sequence& vlist) const { if (!valid()) return 0; else return local_data().variable_store.get_list(vlist); } #ifndef exprtk_disable_string_capabilities template class Sequence> inline std::size_t get_stringvar_list(Sequence,Allocator>& svlist) const { if (!valid()) return 0; else return local_data().stringvar_store.get_list(svlist); } template class Sequence> inline std::size_t get_stringvar_list(Sequence& svlist) const { if (!valid()) return 0; else return local_data().stringvar_store.get_list(svlist); } #endif inline bool symbol_exists(const std::string& symbol_name) const { /* Will return true if symbol_name exists as either a reserved symbol, variable, stringvar or function name in any of the type stores. */ if (!valid()) return false; else if (local_data().variable_store.symbol_exists(symbol_name)) return true; #ifndef exprtk_disable_string_capabilities else if (local_data().stringvar_store.symbol_exists(symbol_name)) return true; #endif else if (local_data().function_store.symbol_exists(symbol_name)) return true; else if (local_data().is_reserved_symbol(symbol_name)) return true; else return false; } inline bool is_variable(const std::string& variable_name) const { if (!valid()) return false; else return local_data().variable_store.symbol_exists(variable_name); } #ifndef exprtk_disable_string_capabilities inline bool is_stringvar(const std::string& stringvar_name) const { if (!valid()) return false; else return local_data().stringvar_store.symbol_exists(stringvar_name); } #endif inline bool is_function(const std::string& function_name) const { if (!valid()) return false; else return local_data().function_store.symbol_exists(function_name); } inline bool valid() const { //symbol table sanity check. return holder_ && holder_->data_; } private: inline bool valid_symbol(const std::string& symbol) const { if (symbol.empty()) return false; if (!details::is_letter(symbol[0])) return false; else if (symbol.size() > 1) { for (std::size_t i = 1; i < symbol.size(); ++i) { if ( (!details::is_letter(symbol[i])) && (!details:: is_digit(symbol[i])) && ('_' != symbol[i]) ) return false; } } return (!local_data().is_reserved_symbol(symbol)); } inline typename st_holder::st_data& local_data() { return *(holder_->data_); } inline const typename st_holder::st_data& local_data() const { return *(holder_->data_); } st_holder* holder_; }; template class parser; template class expression_helper; template class expression { private: typedef details::expression_node* expression_ptr; struct expression_holder { expression_holder() : ref_count(0), expr(0) {} expression_holder(expression_ptr e) : ref_count(1), expr(e) {} ~expression_holder() { if (expr && !is_variable_node(expr)) { delete expr; } } std::size_t ref_count; expression_ptr expr; }; public: expression() : expression_holder_(0) {} expression(const expression& e) : expression_holder_(e.expression_holder_), symbol_table_(e.symbol_table_) { expression_holder_->ref_count++; } inline expression& operator=(const expression& e) { if (this != &e) { if (expression_holder_) { if (0 == --expression_holder_->ref_count) { delete expression_holder_; } expression_holder_ = 0; } expression_holder_ = e.expression_holder_; expression_holder_->ref_count++; symbol_table_ = e.symbol_table_; } return *this; } inline bool operator==(const expression& e) { return (this == &e); } inline bool operator!() const { return ((0 == expression_holder_) || (0 == expression_holder_->expr)); } inline expression& release() { if (expression_holder_) { if (0 == --expression_holder_->ref_count) { delete expression_holder_; } expression_holder_ = 0; } return *this; } ~expression() { if (expression_holder_) { if (0 == --expression_holder_->ref_count) { delete expression_holder_; } } } inline T value() const { return expression_holder_->expr->value(); } inline T operator()() const { return value(); } inline operator T() const { return value(); } inline operator bool() const { return details::is_true(value()); } inline void register_symbol_table(symbol_table& st) { symbol_table_ = st; } inline const symbol_table& get_symbol_table() const { return symbol_table_; } inline symbol_table& get_symbol_table() { return symbol_table_; } private: inline void set_expression(const expression_ptr expr) { if (expr) { if (expression_holder_) { if (0 == --expression_holder_->ref_count) { delete expression_holder_; } } expression_holder_ = new expression_holder(expr); } } expression_holder* expression_holder_; symbol_table symbol_table_; friend class parser; friend class expression_helper; }; template class expression_helper { public: static inline bool is_head_constant(const expression& expr) { return details::is_constant_node(expr.expression_holder_->expr); } static inline bool is_head_variable(const expression& expr) { return details::is_variable_node(expr.expression_holder_->expr); } static inline bool is_head_unary(const expression& expr) { return details::is_unary_node(expr.expression_holder_->expr); } static inline bool is_head_binary(const expression& expr) { return details::is_binary_node(expr.expression_holder_->expr); } static inline bool is_head_function(const expression& expr) { return details::is_function(expr.expression_holder_->expr); } }; namespace parser_error { enum error_mode { e_unknown = 0, e_syntax = 1, e_token = 2, e_numeric = 4, e_symtab = 5, e_lexer = 6, e_helper = 7 }; struct type { lexer::token token; error_mode mode; std::string diagnostic; }; inline type make_error(error_mode mode, const std::string& diagnostic = "") { type t; t.mode = mode; t.token.type = lexer::token::e_error; t.diagnostic = diagnostic; return t; } inline type make_error(error_mode mode, const lexer::token tk, const std::string& diagnostic = "") { type t; t.mode = mode; t.token = tk; t.diagnostic = diagnostic; return t; } inline std::string to_str(error_mode mode) { switch (mode) { case e_unknown : return std::string("Unknown Error"); case e_syntax : return std::string("Syntax Error"); case e_token : return std::string("Token Error"); case e_numeric : return std::string("Numeric Error"); case e_symtab : return std::string("Symbol Error"); case e_lexer : return std::string("Lexer Error"); case e_helper : return std::string("Helper Error"); default : return std::string("Unknown Error"); } } inline void dump_error(const type& error) { printf("Position: %02d Type: [%s] Msg: %s\n", static_cast(error.token.position), exprtk::parser_error::to_str(error.mode).c_str(), error.diagnostic.c_str()); } } template class parser { private: enum precedence_level { e_level00, e_level01, e_level02, e_level03, e_level04, e_level05, e_level06, e_level07, e_level08, e_level09, e_level10, e_level11, e_level12, e_level13 }; typedef ifunction F; typedef ifunction ifunction_t; typedef details::expression_node expression_node_t; typedef details::literal_node literal_node_t; typedef details::string_literal_node string_literal_node_t; typedef details::unary_node unary_node_t; typedef details::binary_node binary_node_t; typedef details::trinary_node trinary_node_t; typedef details::quaternary_node quaternary_node_t; typedef details::quinary_node quinary_node_t; typedef details::senary_node senary_node_t; typedef details::conditional_node conditional_node_t; typedef details::while_loop_node while_loop_node_t; typedef details::variable_node variable_node_t; #ifndef exprtk_disable_string_capabilities typedef details::stringvar_node stringvar_node_t; #endif typedef details::assignment_node assignment_node_t; typedef lexer::token token_t; typedef expression_node_t* expression_node_ptr; public: enum optimization_level { e_none = 0, e_level1 = 1, e_level2 = 2, e_level3 = 4, e_all = 7 }; enum precompilation_step { e_unknown = 0, e_replacer = 1, e_joiner = 2, e_numeric_check = 4, e_bracket_check = 8, e_sequence_check = 16, e_commutative_check = 32 }; static const std::size_t precompile_all_opts = e_replacer + e_joiner + e_numeric_check + e_bracket_check + e_sequence_check + e_commutative_check; parser(const std::size_t precompile_options = precompile_all_opts) : symbol_name_caching_(false), precompile_options_(precompile_options) { init_precompilation(); load_operations_map(base_ops_map_); } inline void init_precompilation() { if (replacer_enabled()) { symbol_replacer_.clear(); symbol_replacer_.add_replace("true" ,"1",lexer::token::e_number); symbol_replacer_.add_replace("false","0",lexer::token::e_number); helper_assembly_.token_modifier_list.clear(); helper_assembly_.register_modifier(&symbol_replacer_); } if (commutative_check_enabled()) { for (std::size_t i = 0; i < details::reserved_words_size; ++i) { commutative_inserter_.ignore_symbol(details::reserved_words[i]); } helper_assembly_.token_inserter_list.clear(); helper_assembly_.register_inserter(&commutative_inserter_); } if (joiner_enabled()) { helper_assembly_.token_joiner_list.clear(); helper_assembly_.register_joiner(&operator_joiner_); } if ( numeric_check_enabled() || bracket_check_enabled() || sequence_check_enabled() ) { helper_assembly_.token_scanner_list.clear(); if (numeric_check_enabled()) { helper_assembly_.register_scanner(&numeric_checker_); } if (bracket_check_enabled()) { helper_assembly_.register_scanner(&bracket_checker_); } if (sequence_check_enabled()) { helper_assembly_.register_scanner(&sequence_validator_); } } } inline bool compile(const std::string& expression_string, expression& expr, const optimization_level& opt_level = e_all) { error_list_.clear(); expression_generator_.set_optimization_level(opt_level); expression_generator_.set_allocator(node_allocator_); if (!lexer_.process(expression_string)) { process_lexer_errors(); return false; } if (!run_assemblies()) { return false; } symbol_table_ = expr.get_symbol_table(); symbol_name_cache_.clear(); lexer_.begin(); next_token(); expression_node_ptr e = parse_expression(); if ((0 != e) && (token_t::e_eof == current_token_.type)) { expr.set_expression(e); return !(!expr); } else { set_error(parser_error::make_error(parser_error::e_syntax, "ERR01 - Incomplete expression!")); symbol_name_cache_.clear(); if (0 != e) delete e; return false; } } void process_lexer_errors() { for (std::size_t i = 0; i < lexer_.size(); ++i) { if (lexer_[i].is_error()) { std::string diagnostic = "ERR02 - "; switch (lexer_[i].type) { case lexer::token::e_error : diagnostic + "General token error"; break; case lexer::token::e_err_symbol : diagnostic + "Symbol error"; break; case lexer::token::e_err_number : diagnostic + "Invalid numeric token"; break; case lexer::token::e_err_string : diagnostic + "Invalid string token"; break; case lexer::token::e_err_sfunc : diagnostic + "Invalid special function token"; break; default : diagnostic + "Unknown compiler error"; break; } set_error(make_error(parser_error::e_lexer,lexer_[i],diagnostic + ": " + lexer_[i].value)); } } } inline bool replacer_enabled() const { return ((precompile_options_ & e_replacer) == e_replacer); } inline bool commutative_check_enabled() const { return ((precompile_options_ & e_commutative_check) == e_commutative_check); } inline bool joiner_enabled() const { return ((precompile_options_ & e_joiner) == e_joiner); } inline bool numeric_check_enabled() const { return ((precompile_options_ & e_numeric_check) == e_numeric_check); } inline bool bracket_check_enabled() const { return ((precompile_options_ & e_bracket_check) == e_bracket_check); } inline bool sequence_check_enabled() const { return ((precompile_options_ & e_sequence_check) == e_sequence_check); } inline bool run_assemblies() { if (commutative_check_enabled()) { helper_assembly_.run_inserters(lexer_); } if (joiner_enabled()) { helper_assembly_.run_joiners(lexer_); } if (replacer_enabled()) { helper_assembly_.run_modifiers(lexer_); } if ( numeric_check_enabled() || bracket_check_enabled() || sequence_check_enabled() ) { if (!helper_assembly_.run_scanners(lexer_)) { if (helper_assembly_.error_token_scanner) { lexer::helper::bracket_checker* bracket_checker_ptr = 0; lexer::helper::numeric_checker* numeric_checker_ptr = 0; lexer::helper::sequence_validator* sequence_validator_ptr = 0; if (0 != (bracket_checker_ptr = dynamic_cast(helper_assembly_.error_token_scanner))) { set_error( make_error(parser_error::e_token, bracket_checker_ptr->error_token(), "ERR03 - Mismatched brackets: " + bracket_checker_ptr->error_token().value)); } else if (0 != (numeric_checker_ptr = dynamic_cast(helper_assembly_.error_token_scanner))) { for (std::size_t i = 0; i < numeric_checker_ptr->error_count(); ++i) { lexer::token error_token = lexer_[numeric_checker_ptr->error_index(i)]; set_error( make_error(parser_error::e_token, error_token, "ERR04 - Invalid numeric token: " + error_token.value)); } } else if (0 != (sequence_validator_ptr = dynamic_cast(helper_assembly_.error_token_scanner))) { for (std::size_t i = 0; i < sequence_validator_ptr->error_count(); ++i) { std::pair error_token = sequence_validator_ptr->error(i); set_error( make_error(parser_error::e_token, error_token.first, "ERR05 - Invalid token sequence: " + error_token.first.value + " " + error_token.second.value)); } } } return false; } } return true; } inline parser_error::type get_error(const std::size_t& index) { if (index < error_list_.size()) return error_list_[index]; else throw std::invalid_argument("parser::get_error() - Invalid error index specificed."); } inline std::string error() const { if (!error_list_.empty()) { return error_list_[0].diagnostic; } else return std::string("No Error"); } inline std::size_t error_count() const { return error_list_.size(); } inline bool& cache_symbols() { return symbol_name_caching_; } template class Sequence> inline std::size_t expression_symbols(Sequence& symbols_list) { if (!symbol_name_caching_) return 0; if (symbol_name_cache_.empty()) return 0; std::copy(symbol_name_cache_.begin(), symbol_name_cache_.end(), std::back_inserter(symbols_list)); return symbol_name_cache_.size(); } inline bool replace_symbol(const std::string& old_symbol, const std::string& new_symbol) { if (details::is_reserved_word(old_symbol)) return false; else if (!replacer_enabled()) return false; else return symbol_replacer_.add_replace(old_symbol,new_symbol,lexer::token::e_symbol); } private: inline bool valid_base_operation(const std::string& symbol) { const std::size_t length = symbol.size(); if ( (length < 3) || //Shortest base op symbol length (length > 9) //Longest base op symbol length ) return false; else return (base_ops_map_.end() != base_ops_map_.find(symbol)); } inline void store_token() { lexer_.store(); store_current_token_ = current_token_; } inline void restore_token() { lexer_.restore(); current_token_ = store_current_token_; } inline void next_token() { current_token_ = lexer_.next_token(); } static const precedence_level default_precedence = e_level00; struct state_t { inline void set(const precedence_level& l, const precedence_level& r, const details::operator_type& o) { left = l; right = r; operation = o; } inline void reset() { left = e_level00; right = e_level00; } precedence_level left; precedence_level right; details::operator_type operation; }; inline expression_node_ptr parse_expression(precedence_level precedence = e_level00) { expression_node_ptr expr = parse_branch(); if (0 == expr) { return expr; } bool break_loop = false; state_t current_state; for ( ; ; ) { current_state.reset(); switch (current_token_.type) { case token_t::e_assign : current_state.set(e_level00,e_level00,details::e_assign); break; case token_t::e_lt : current_state.set(e_level05,e_level06,details:: e_lt); break; case token_t::e_lte : current_state.set(e_level05,e_level06,details:: e_lte); break; case token_t::e_eq : current_state.set(e_level05,e_level06,details:: e_eq); break; case token_t::e_ne : current_state.set(e_level05,e_level06,details:: e_ne); break; case token_t::e_gte : current_state.set(e_level05,e_level06,details:: e_gte); break; case token_t::e_gt : current_state.set(e_level05,e_level06,details:: e_gt); break; case token_t::e_add : current_state.set(e_level07,e_level08,details:: e_add); break; case token_t::e_sub : current_state.set(e_level07,e_level08,details:: e_sub); break; case token_t::e_div : current_state.set(e_level10,e_level11,details:: e_div); break; case token_t::e_mul : current_state.set(e_level10,e_level11,details:: e_mul); break; case token_t::e_mod : current_state.set(e_level10,e_level11,details:: e_mod); break; case token_t::e_pow : current_state.set(e_level12,e_level12,details:: e_pow); break; default : if (token_t::e_symbol == current_token_.type) { static const std::string s_and = "and"; static const std::string s_nand = "nand"; static const std::string s_or = "or"; static const std::string s_nor = "nor"; static const std::string s_xor = "xor"; static const std::string s_in = "in"; static const std::string s_like = "like"; static const std::string s_ilike = "ilike"; if (details::imatch(current_token_.value,s_and)) { current_state.set(e_level01,e_level02,details::e_and); break; } else if (details::imatch(current_token_.value,s_nand)) { current_state.set(e_level01,e_level02,details::e_nand); break; } else if (details::imatch(current_token_.value,s_or)) { current_state.set(e_level03,e_level04,details::e_or); break; } else if (details::imatch(current_token_.value,s_nor)) { current_state.set(e_level03,e_level04,details::e_nor); break; } else if (details::imatch(current_token_.value,s_xor)) { current_state.set(e_level03,e_level04,details::e_xor); break; } else if (details::imatch(current_token_.value,s_in)) { current_state.set(e_level03,e_level04,details::e_in); break; } else if (details::imatch(current_token_.value,s_like)) { current_state.set(e_level03,e_level04,details::e_like); break; } else if (details::imatch(current_token_.value,s_ilike)) { current_state.set(e_level03,e_level04,details::e_ilike); break; } } break_loop = true; } if (break_loop) break; else if (current_state.left < precedence) break; next_token(); expr = expression_generator_(current_state.operation,expr,parse_expression(current_state.right)); if (0 == expr) { return expr; } } return expr; } static inline expression_node_ptr error_node() { return reinterpret_cast(0); } template struct scoped_delete { typedef Type* ptr_t; scoped_delete(parser& pr, ptr_t& p) : delete_ptr(true), parser_(pr), p_(&p) {} scoped_delete(parser& pr, ptr_t (&p)[N]) : delete_ptr(true), parser_(pr), p_(&p[0]) {} ~scoped_delete() { if (delete_ptr) { for (std::size_t i = 0; i < N; ++i) { if (p_[i] && !is_variable_node(p_[i])) { parser_.node_allocator_.free(p_[i]); } } } } bool delete_ptr; parser& parser_; ptr_t* p_; private: scoped_delete& operator=(const scoped_delete&); }; template inline expression_node_ptr parse_function_call(const details::operator_type& opt_type) { expression_node_ptr branch[NumberofParameters]; expression_node_ptr result = 0; std::fill_n(branch,NumberofParameters,reinterpret_cast(0)); scoped_delete sd(*this,branch); store_token(); next_token(); if (!token_is(token_t::e_lbracket)) { return error_node(); } for (int i = 0; i < static_cast(NumberofParameters); ++i) { branch[i] = parse_expression(); if (0 == branch[i]) { return error_node(); } else if (i < static_cast(NumberofParameters - 1)) { if (!token_is(token_t::e_comma)) { return error_node(); } } } if (!token_is(token_t::e_rbracket)) { return error_node(); } else result = expression_generator_(opt_type,branch); sd.delete_ptr = false; return result; } template inline expression_node_ptr parse_function_call(ifunction* function, const std::string& function_name) { expression_node_ptr branch[NumberofParameters]; expression_node_ptr result = 0; std::fill_n(branch,NumberofParameters,reinterpret_cast(0)); scoped_delete sd(*this,branch); next_token(); if (!token_is(token_t::e_lbracket)) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR06 - Expecting argument list for function: '" + function_name + "'")); return error_node(); } for (int i = 0; i < static_cast(NumberofParameters); ++i) { branch[i] = parse_expression(); if (0 == branch[i]) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR07 - Failed to parse argument " + details::to_str(i) + " for function: '" + function_name + "'")); return error_node(); } else if (i < static_cast(NumberofParameters - 1)) { if (!token_is(token_t::e_comma)) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR08 - Invalid number of arguments for function: '" + function_name + "'")); return error_node(); } } } if (!token_is(token_t::e_rbracket)) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR09 - Invalid number of arguments for function: '" + function_name + "'")); return error_node(); } else result = expression_generator_.function(function,branch); sd.delete_ptr = false; return result; } inline expression_node_ptr parse_base_operation() { typedef std::multimap map_t; typedef std::pair map_range_t; const std::string operation_name = current_token_.value; map_range_t itr_range = base_ops_map_.equal_range(operation_name); if (0 == std::distance(itr_range.first,itr_range.second)) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR10 - No entries found for base operation: " + operation_name)); return error_node(); } for (map_t::iterator itr = itr_range.first; itr != itr_range.second; ++itr) { store_token(); expression_node_ptr branch = reinterpret_cast(0); details::base_operation_t& operation = itr->second; switch (operation.num_params) { case 1 : branch = parse_function_call<1>(operation.type); break; case 2 : branch = parse_function_call<2>(operation.type); break; case 3 : branch = parse_function_call<3>(operation.type); break; case 4 : branch = parse_function_call<4>(operation.type); break; case 5 : branch = parse_function_call<5>(operation.type); break; case 6 : branch = parse_function_call<6>(operation.type); break; default : { set_error( make_error(parser_error::e_syntax, current_token_, "ERR11 - Impossible argument count for base function: " + operation_name)); return error_node(); } } if (branch) { return branch; } remove_last_error(); restore_token(); } set_error( make_error(parser_error::e_syntax, current_token_, "ERR12 - Invalid parameter count for function: " + operation_name)); return error_node(); } inline expression_node_ptr parse_conditional_statement() { //Parse: [if][(][condition][,][consequent][,][alternative][)] expression_node_ptr condition = 0; expression_node_ptr consequent = 0; expression_node_ptr alternative = 0; next_token(); if (!token_is(token_t::e_lbracket)) return error_node(); else if (0 == (condition = parse_expression())) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR13 - Failed to parse condition for if-statement")); return error_node(); } else if (!token_is(token_t::e_comma)) return error_node(); else if (0 == (consequent = parse_expression())) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR14 - Failed to parse consequent for if-statement")); return error_node(); } else if (!token_is(token_t::e_comma)) return error_node(); else if (0 == (alternative = parse_expression())) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR15 - Failed to parse alternative for if-statement")); return error_node(); } else if (!token_is(token_t::e_rbracket)) return error_node(); else return expression_generator_.conditional(condition,consequent,alternative); } inline expression_node_ptr parse_while_loop() { //Parse: [while][(][test expr][)][{][expression][}] expression_node_ptr condition = 0; expression_node_ptr branch = 0; next_token(); if (!token_is(token_t::e_lbracket)) return error_node(); else if (0 == (condition = parse_expression())) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR16 - Failed to parse condition for while-loop")); return error_node(); } else if (!token_is(token_t::e_rbracket)) return error_node(); else if (!token_is(token_t::e_lcrlbracket)) return error_node(); else if (0 == (branch = parse_expression())) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR17 - Failed to parse branch for while-loop")); return error_node(); } else if (!token_is(token_t::e_rcrlbracket)) return error_node(); else return expression_generator_.while_loop(condition,branch); } template struct parse_special_function_impl { static inline expression_node_ptr process(parser& p,const details::operator_type opt_type) { expression_node_ptr branch[NumberOfParameters]; expression_node_ptr result = 0; std::fill_n(branch,NumberOfParameters,reinterpret_cast(0)); scoped_delete sd(p,branch); p.next_token(); if (!p.token_is(token_t::e_lbracket)) { return error_node(); } for (std::size_t i = 0; i < NumberOfParameters; ++i) { branch[i] = p.parse_expression(); if (0 == branch[i]) { return p.error_node(); } else if (i < (NumberOfParameters - 1)) { if (!p.token_is(token_t::e_comma)) { return p.error_node(); } } } if (!p.token_is(token_t::e_rbracket)) return p.error_node(); else result = p.expression_generator_.special_function(opt_type,branch); sd.delete_ptr = false; return result; } }; inline expression_node_ptr parse_special_function() { //Expect: $fDD(expr0,expr1,expr2) or $fDD(expr0,expr1,expr2,expr3) if ( !details::is_digit(current_token_.value[2]) || !details::is_digit(current_token_.value[3]) ) { set_error( make_error(parser_error::e_token, current_token_, "ERR18 - Invalid special function[1]: " + current_token_.value)); return error_node(); } const unsigned int id = (current_token_.value[2] - '0') * 10 + (current_token_.value[3] - '0'); if (id > 82) { set_error( make_error(parser_error::e_token, current_token_, "ERR19 - Invalid special function[2]: " + current_token_.value)); return error_node(); } const std::size_t sf_3_to_4 = details::e_sf35; const details::operator_type opt_type = details::operator_type(id + 1000); const std::size_t NumberOfParameters = (id < (sf_3_to_4 - 1000)) ? 3 : 4; switch (NumberOfParameters) { case 3 : return parse_special_function_impl::process(*this,opt_type); case 4 : return parse_special_function_impl::process(*this,opt_type); default : return error_node(); } } inline expression_node_ptr parse_symtab_symbol() { const std::string symbol = current_token_.value; //Are we dealing with a variable or a special constant? expression_node_ptr variable = symbol_table_.get_variable(symbol); if (variable) { if (symbol_name_caching_) { symbol_name_cache_.push_back(symbol); } if (symbol_table_.is_constant_node(symbol)) { variable = expression_generator_(variable->value()); } next_token(); return variable; } #ifndef exprtk_disable_string_capabilities //Are we dealing with a string variable? variable = symbol_table_.get_stringvar(symbol); if (variable) { if (symbol_name_caching_) { symbol_name_cache_.push_back(symbol); } if (symbol_table_.is_constant_node(symbol)) { variable = expression_generator_(dynamic_cast*>(variable)->str()); } next_token(); return variable; } #endif //Are we dealing with a function? ifunction* function = symbol_table_.get_function(symbol); if (function) { expression_node_ptr func_node = reinterpret_cast(0); switch (function->param_count) { case 0 : func_node = expression_generator_.function(function); break; case 1 : func_node = parse_function_call< 1>(function,symbol); break; case 2 : func_node = parse_function_call< 2>(function,symbol); break; case 3 : func_node = parse_function_call< 3>(function,symbol); break; case 4 : func_node = parse_function_call< 4>(function,symbol); break; case 5 : func_node = parse_function_call< 5>(function,symbol); break; case 6 : func_node = parse_function_call< 6>(function,symbol); break; case 7 : func_node = parse_function_call< 7>(function,symbol); break; case 8 : func_node = parse_function_call< 8>(function,symbol); break; case 9 : func_node = parse_function_call< 9>(function,symbol); break; case 10 : func_node = parse_function_call<10>(function,symbol); break; case 11 : func_node = parse_function_call<11>(function,symbol); break; case 12 : func_node = parse_function_call<12>(function,symbol); break; case 13 : func_node = parse_function_call<13>(function,symbol); break; case 14 : func_node = parse_function_call<14>(function,symbol); break; case 15 : func_node = parse_function_call<15>(function,symbol); break; case 16 : func_node = parse_function_call<16>(function,symbol); break; case 17 : func_node = parse_function_call<17>(function,symbol); break; case 18 : func_node = parse_function_call<18>(function,symbol); break; case 19 : func_node = parse_function_call<19>(function,symbol); break; case 20 : func_node = parse_function_call<20>(function,symbol); break; default : { set_error( make_error(parser_error::e_syntax, current_token_, "ERR20 - Invalid number of parameters for function: " + symbol)); return expression_node_ptr(0); } } if (func_node) return func_node; else { set_error( make_error(parser_error::e_syntax, current_token_, "ERR21 - Failed to generate node for function: '" + symbol + "'")); return error_node(); } } else { set_error( make_error(parser_error::e_syntax, current_token_, "ERR22 - Undefined variable or function: '" + symbol + "'")); return error_node(); } } inline expression_node_ptr parse_symbol() { static const std::string symbol_if = "if"; static const std::string symbol_while = "while"; if (valid_base_operation(current_token_.value)) { return parse_base_operation(); } else if (details::imatch(current_token_.value,symbol_if)) { return parse_conditional_statement(); } else if (details::imatch(current_token_.value,symbol_while)) { return parse_while_loop(); } else if (details::is_valid_sf_symbol(current_token_.value)) { return parse_special_function(); } else if (symbol_table_.valid()) { return parse_symtab_symbol(); } else { set_error( make_error(parser_error::e_symtab, current_token_, "ERR23 - Variable or function detected, yet symbol-table is invalid, Symbol: " + current_token_.value)); return error_node(); } } inline expression_node_ptr parse_branch() { if (token_t::e_number == current_token_.type) { T numeric_value = T(0); if (details::string_to_real(current_token_.value,numeric_value)) { expression_node_ptr literal_exp = expression_generator_(numeric_value); next_token(); return literal_exp; } else return error_node(); } else if (token_t::e_symbol == current_token_.type) { return parse_symbol(); } #ifndef exprtk_disable_string_capabilities else if (token_t::e_string == current_token_.type) { expression_node_ptr literal_exp = expression_generator_(current_token_.value); next_token(); return literal_exp; } #endif else if (token_t::e_lbracket == current_token_.type) { next_token(); expression_node_ptr branch = parse_expression(); if (token_is(token_t::e_rbracket)) return branch; else return error_node(); } else if (token_t::e_lsqrbracket == current_token_.type) { next_token(); expression_node_ptr branch = parse_expression(); if (token_is(token_t::e_rsqrbracket)) return branch; else return error_node(); } else if (token_t::e_lcrlbracket == current_token_.type) { next_token(); expression_node_ptr branch = parse_expression(); if (token_is(token_t::e_rcrlbracket)) return branch; else return error_node(); } else if (token_t::e_sub == current_token_.type) { next_token(); return expression_generator_(details::e_neg,parse_expression(e_level09)); } else if (token_t::e_add == current_token_.type) { next_token(); return expression_generator_(details::e_pos,parse_expression(e_level09)); } else if (token_t::e_eof == current_token_.type) { set_error( make_error(parser_error::e_syntax, current_token_, "ERR24 - Premature end of expression.[1]")); return error_node(); } else { set_error( make_error(parser_error::e_syntax, current_token_, "ERR25 - Premature end of expression.[2]")); return error_node(); } } inline bool token_is(const typename token_t::token_type& ttype) { if (current_token_.type != ttype) { if (!((']' == current_token_.type) && (token_t::e_rbracket == ttype))) { set_error( make_error(parser_error::e_token, current_token_, std::string("ERR26 - Expected token: '") + static_cast(ttype) + "'")); return false; } } next_token(); return true; } template class expression_generator { public: typedef details::expression_node* expression_node_ptr; inline void set_optimization_level(const optimization_level& optimization_level) { optimization_level_ = optimization_level; } inline void set_allocator(details::node_allocator& na) { node_allocator_ = &na; } inline expression_node_ptr operator()(const Type& v) const { return node_allocator_->allocate(v); } inline expression_node_ptr operator()(const std::string& s) const { return node_allocator_->allocate(s); } inline bool unary_optimizable(const details::operator_type& operation) const { return (details::e_abs == operation) || (details::e_acos == operation) || (details::e_asin == operation) || (details::e_atan == operation) || (details::e_ceil == operation) || (details::e_cos == operation) || (details::e_cosh == operation) || (details::e_exp == operation) || (details::e_floor == operation) || (details::e_log == operation) || (details::e_log10 == operation) || (details::e_neg == operation) || (details::e_pos == operation) || (details::e_round == operation) || (details::e_sin == operation) || (details::e_sinh == operation) || (details::e_sqrt == operation) || (details::e_tan == operation) || (details::e_tanh == operation) || (details::e_cot == operation) || (details::e_sec == operation) || (details::e_csc == operation) || (details::e_r2d == operation) || (details::e_d2r == operation) || (details::e_d2g == operation) || (details::e_g2d == operation) || (details::e_notl == operation) || (details::e_sgn == operation) || (details::e_erf == operation) || (details::e_erfc == operation) || (details::e_frac == operation) || (details::e_trunc == operation); } inline expression_node_ptr operator()(const details::operator_type& operation, expression_node_ptr (&branch)[1]) { if (0 == branch[0]) return error_node(); else if (details::is_constant_node(branch[0])) return synthesize_expression(operation,branch); else if (unary_optimizable(operation) && details::is_variable_node(branch[0])) return synthesize_uv_expression(operation,branch); else return synthesize_unary_expression(operation,branch); } #ifndef exprtk_disable_string_capabilities inline bool valid_string_operation(const details::operator_type& operation) const { return (details::e_add == operation) || (details::e_lt == operation) || (details::e_lte == operation) || (details::e_gt == operation) || (details::e_gte == operation) || (details::e_eq == operation) || (details::e_ne == operation) || (details::e_in == operation) || (details::e_like == operation) || (details::e_ilike == operation); } #else inline bool valid_string_operation(const details::operator_type&) const { return false; } #endif inline bool operation_optimizable(const details::operator_type& operation) const { return (details::e_add == operation) || (details::e_sub == operation) || (details::e_mul == operation) || (details::e_div == operation) || (details::e_mod == operation) || (details::e_pow == operation) || #ifndef exprtk_disable_extended_operator_optimizations (details::e_lt == operation) || (details::e_lte == operation) || (details::e_gt == operation) || (details::e_gte == operation) || (details::e_eq == operation) || (details::e_ne == operation) || (details::e_and == operation) || (details::e_nand == operation) || (details::e_or == operation) || (details::e_nor == operation) || (details::e_xor == operation) || #endif false; } inline bool is_level_optimizable(const std::size_t& level = 0) const { switch (level) { case 1 : return (e_level1 == (optimization_level_ & e_level1)); case 2 : return (e_level2 == (optimization_level_ & e_level2)) && is_level_optimizable(1); case 3 : return (e_level3 == (optimization_level_ & e_level3)) && is_level_optimizable(2); case 0 : return (e_all == (optimization_level_ & e_all)); default : return false; } } inline bool cov_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(1)) return false; else return (details::is_constant_node(branch[0]) && details::is_variable_node(branch[1])); } inline bool voc_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(1)) return false; else return (details::is_variable_node(branch[0]) && details::is_constant_node(branch[1])); } inline bool vov_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(1)) return false; else return (details::is_variable_node(branch[0]) && details::is_variable_node(branch[1])); } inline bool vovov1_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_variable_node(branch[0]) && details::is_vov_node(branch[1])); } inline bool vovov2_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_vov_node(branch[0]) && details::is_variable_node(branch[1])); } inline bool covov1_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_constant_node(branch[0]) && details::is_vov_node(branch[1])); } inline bool covov2_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_cov_node(branch[0]) && details::is_variable_node(branch[1])); } inline bool vovoc1_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_variable_node(branch[0]) && details::is_voc_node(branch[1])); } inline bool vovoc2_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_vov_node(branch[0]) && details::is_constant_node(branch[1])); } inline bool covoc1_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_constant_node(branch[0]) && details::is_voc_node(branch[1])); } inline bool covoc2_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_cov_node(branch[0]) && details::is_constant_node(branch[1])); } inline bool vocov1_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_variable_node(branch[0]) && details::is_cov_node(branch[1])); } inline bool vocov2_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_voc_node(branch[0]) && details::is_variable_node(branch[1])); } inline bool uvouv_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(2)) return false; else return (details::is_uv_node(branch[0]) && details::is_uv_node(branch[1])); } inline bool is_invalid_string_op(const details::operator_type& operation, expression_node_ptr (&branch)[2]) { const bool b0_string = details::is_string_node(branch[0]) || details::is_const_string_node(branch[0]); const bool b1_string = details::is_string_node(branch[1]) || details::is_const_string_node(branch[1]); if ((b0_string || b1_string) && !(b0_string && b1_string)) return true; if (!valid_string_operation(operation) && b0_string && b1_string) return true; else return false; } inline bool is_invalid_string_op(const details::operator_type& operation, expression_node_ptr (&branch)[3]) { bool b0_string = details::is_string_node(branch[0]) || details::is_const_string_node(branch[0]); bool b1_string = details::is_string_node(branch[1]) || details::is_const_string_node(branch[1]); bool b2_string = details::is_string_node(branch[2]) || details::is_const_string_node(branch[2]); if ((b0_string || b1_string || b2_string) && !(b0_string && b1_string && b2_string)) return true; if ((details::e_inrange != operation) && b0_string && b1_string && b2_string) return true; else return false; } inline bool is_string_operation(const details::operator_type& operation, expression_node_ptr (&branch)[2]) { const bool b0_string = details::is_string_node(branch[0]) || details::is_const_string_node(branch[0]); const bool b1_string = details::is_string_node(branch[1]) || details::is_const_string_node(branch[1]); return (b0_string && b1_string && valid_string_operation(operation)); } inline bool is_string_operation(const details::operator_type& operation, expression_node_ptr (&branch)[3]) { const bool b0_string = details::is_string_node(branch[0]) || details::is_const_string_node(branch[0]); const bool b1_string = details::is_string_node(branch[1]) || details::is_const_string_node(branch[1]); const bool b2_string = details::is_string_node(branch[2]) || details::is_const_string_node(branch[2]); return (b0_string && b1_string && b2_string && (details::e_inrange == operation)); } // Note: Extended Optimisations // When using older C++ compilers due to the large number of type instantiations // required by the extended optimisations the compiler may crash or not be able // to compile this translation unit properly. #if defined(_WIN32) || defined(__WIN32__) || defined(WIN32) #if (defined(_MSC_VER) && (_MSC_VER <= 1400)) #ifndef exprtk_disable_extended_optimisations #define exprtk_disable_extended_optimisations #endif #endif #endif #ifndef exprtk_disable_extended_optimisations inline bool vovovov_optimizable(const details::operator_type& operation, expression_node_ptr (&branch)[2]) const { if (!operation_optimizable(operation)) return false; else if (!is_level_optimizable(3)) return false; else return (details::is_vov_node(branch[0]) && details::is_vov_node(branch[1])); } #else inline bool vovovov_optimizable(const details::operator_type&, expression_node_ptr (&)[2]) const { return false; } #endif inline expression_node_ptr operator()(const details::operator_type& operation, expression_node_ptr (&branch)[2]) { if ((0 == branch[0]) || (0 == branch[1])) return error_node(); else if (is_invalid_string_op(operation,branch)) return error_node(); else if (details::e_assign == operation) return synthesize_assignment_expression(operation,branch); else if (is_string_operation(operation,branch)) return synthesize_string_expression(operation,branch); else if (cov_optimizable(operation,branch)) return synthesize_cov_expression(operation,branch); else if (voc_optimizable(operation,branch)) return synthesize_voc_expression(operation,branch); else if (vov_optimizable(operation,branch)) return synthesize_vov_expression(operation,branch); else if (vovov1_optimizable(operation,branch)) return synthesize_vovov1_expression(operation,branch); else if (vovov2_optimizable(operation,branch)) return synthesize_vovov2_expression(operation,branch); else if (covov1_optimizable(operation,branch)) return synthesize_covov1_expression(operation,branch); else if (covov2_optimizable(operation,branch)) return synthesize_covov2_expression(operation,branch); else if (vovoc1_optimizable(operation,branch)) return synthesize_vovoc1_expression(operation,branch); else if (vovoc2_optimizable(operation,branch)) return synthesize_vovoc2_expression(operation,branch); else if (covoc1_optimizable(operation,branch)) return synthesize_covoc1_expression(operation,branch); else if (covoc2_optimizable(operation,branch)) return synthesize_covoc2_expression(operation,branch); else if (vocov1_optimizable(operation,branch)) return synthesize_vocov1_expression(operation,branch); else if (vocov2_optimizable(operation,branch)) return synthesize_vocov2_expression(operation,branch); else if (vovovov_optimizable(operation,branch)) return synthesize_vovovov_expression(operation,branch); else if (uvouv_optimizable(operation,branch)) return synthesize_uvouv_expression(operation,branch); else return synthesize_expression(operation,branch); } inline expression_node_ptr operator()(const details::operator_type& operation, expression_node_ptr (&branch)[3]) { if ((0 == branch[0]) || (0 == branch[1]) || (0 == branch[2])) return error_node(); else if (is_invalid_string_op(operation,branch)) return error_node(); else if (is_string_operation(operation,branch)) return synthesize_string_expression(operation,branch); else return synthesize_expression(operation,branch); } inline expression_node_ptr operator()(const details::operator_type& operation, expression_node_ptr (&branch)[4]) { return synthesize_expression(operation,branch); } inline expression_node_ptr operator()(const details::operator_type& operation, expression_node_ptr (&branch)[5]) { return synthesize_expression(operation,branch); } inline expression_node_ptr operator()(const details::operator_type& operation, expression_node_ptr (&branch)[6]) { return synthesize_expression(operation,branch); } inline expression_node_ptr operator()(const details::operator_type& operation, expression_node_ptr b0) { expression_node_ptr branch[1] = { b0 }; return synthesize_expression(operation,branch); } inline expression_node_ptr operator()(const details::operator_type& operation, expression_node_ptr b0, expression_node_ptr b1) { if ((0 == b0) || (0 == b1)) return error_node(); else { expression_node_ptr branch[2] = { b0, b1 }; return expression_generator::operator()(operation,branch); } } inline expression_node_ptr conditional(expression_node_ptr condition, expression_node_ptr consequent, expression_node_ptr alternative) const { if ((0 == condition) || (0 == consequent) || (0 == alternative)) return error_node(); //Can the condition be immediately evaluated? if so optimize. else if (details::is_constant_node(condition)) { // True branch if (details::is_true(condition)) { node_allocator_->free(condition); node_allocator_->free(alternative); return consequent; } // False branch else { node_allocator_->free(condition); node_allocator_->free(consequent); return alternative; } } else return node_allocator_->allocate(condition,consequent,alternative); } inline expression_node_ptr while_loop(expression_node_ptr condition, expression_node_ptr branch) const { return node_allocator_->allocate(condition,branch); } #define unary_opr_switch_statements \ case_stmt(details:: e_abs,details:: abs_op) \ case_stmt(details:: e_acos,details:: acos_op) \ case_stmt(details:: e_asin,details:: asin_op) \ case_stmt(details:: e_atan,details:: atan_op) \ case_stmt(details:: e_ceil,details:: ceil_op) \ case_stmt(details:: e_cos,details:: cos_op) \ case_stmt(details:: e_cosh,details:: cosh_op) \ case_stmt(details:: e_exp,details:: exp_op) \ case_stmt(details::e_floor,details::floor_op) \ case_stmt(details:: e_log,details:: log_op) \ case_stmt(details::e_log10,details::log10_op) \ case_stmt(details:: e_neg,details:: neg_op) \ case_stmt(details:: e_pos,details:: pos_op) \ case_stmt(details::e_round,details::round_op) \ case_stmt(details:: e_sin,details:: sin_op) \ case_stmt(details:: e_sinh,details:: sinh_op) \ case_stmt(details:: e_sqrt,details:: sqrt_op) \ case_stmt(details:: e_tan,details:: tan_op) \ case_stmt(details:: e_tanh,details:: tanh_op) \ case_stmt(details:: e_cot,details:: cot_op) \ case_stmt(details:: e_sec,details:: sec_op) \ case_stmt(details:: e_csc,details:: csc_op) \ case_stmt(details:: e_r2d,details:: r2d_op) \ case_stmt(details:: e_d2r,details:: d2r_op) \ case_stmt(details:: e_d2g,details:: d2g_op) \ case_stmt(details:: e_g2d,details:: g2d_op) \ case_stmt(details:: e_notl,details:: notl_op) \ case_stmt(details:: e_sgn,details:: sgn_op) \ case_stmt(details:: e_erf,details:: erf_op) \ case_stmt(details:: e_erfc,details:: erfc_op) \ case_stmt(details:: e_frac,details:: frac_op) \ case_stmt(details::e_trunc,details::trunc_op) \ inline expression_node_ptr synthesize_uv_expression(const details::operator_type& operation, expression_node_ptr (&branch)[1]) { T& v = dynamic_cast*>(branch[0])->ref(); switch (operation) { #define case_stmt(op0,op1) case op0 : return node_allocator_->allocate > >(v); unary_opr_switch_statements #undef case_stmt default : return error_node(); } } inline expression_node_ptr synthesize_unary_expression(const details::operator_type& operation, expression_node_ptr (&branch)[1]) { switch (operation) { #define case_stmt(op0,op1) case op0 : return node_allocator_->allocate > >(branch[0]); unary_opr_switch_statements #undef case_stmt default : return error_node(); } } inline expression_node_ptr const_optimize_sf3(const details::operator_type& operation, expression_node_ptr (&branch)[3]) { expression_node_ptr temp_node = error_node(); switch (operation) { #define case_stmt(op0,op1) case op0 : temp_node = node_allocator_->allocate > >(operation,branch); break; case_stmt(details::e_sf00,details::sf00_op) case_stmt(details::e_sf01,details::sf01_op) case_stmt(details::e_sf02,details::sf02_op) case_stmt(details::e_sf03,details::sf03_op) case_stmt(details::e_sf04,details::sf04_op) case_stmt(details::e_sf05,details::sf05_op) case_stmt(details::e_sf06,details::sf06_op) case_stmt(details::e_sf07,details::sf07_op) case_stmt(details::e_sf08,details::sf08_op) case_stmt(details::e_sf09,details::sf09_op) case_stmt(details::e_sf10,details::sf10_op) case_stmt(details::e_sf11,details::sf11_op) case_stmt(details::e_sf12,details::sf12_op) case_stmt(details::e_sf13,details::sf13_op) case_stmt(details::e_sf14,details::sf14_op) case_stmt(details::e_sf15,details::sf15_op) case_stmt(details::e_sf16,details::sf16_op) case_stmt(details::e_sf17,details::sf17_op) case_stmt(details::e_sf18,details::sf18_op) case_stmt(details::e_sf19,details::sf19_op) case_stmt(details::e_sf20,details::sf20_op) case_stmt(details::e_sf21,details::sf21_op) case_stmt(details::e_sf22,details::sf22_op) case_stmt(details::e_sf23,details::sf23_op) case_stmt(details::e_sf24,details::sf24_op) case_stmt(details::e_sf25,details::sf25_op) case_stmt(details::e_sf26,details::sf26_op) case_stmt(details::e_sf27,details::sf27_op) case_stmt(details::e_sf28,details::sf28_op) case_stmt(details::e_sf29,details::sf29_op) case_stmt(details::e_sf30,details::sf30_op) case_stmt(details::e_sf31,details::sf31_op) case_stmt(details::e_sf32,details::sf32_op) case_stmt(details::e_sf33,details::sf33_op) case_stmt(details::e_sf34,details::sf34_op) #undef case_stmt default : return error_node(); } T v = temp_node->value(); node_allocator_->free(temp_node); return node_allocator_->allocate(v); } inline expression_node_ptr varnode_optimize_sf3(const details::operator_type& operation, expression_node_ptr (&branch)[3]) { Type& v0 = dynamic_cast*>(branch[0])->ref(); Type& v1 = dynamic_cast*>(branch[1])->ref(); Type& v2 = dynamic_cast*>(branch[2])->ref(); switch (operation) { #define case_stmt(op0,op1) case op0 : return node_allocator_->allocate_rrr > >(v0,v1,v2); case_stmt(details::e_sf00,details::sf00_op) case_stmt(details::e_sf01,details::sf01_op) case_stmt(details::e_sf02,details::sf02_op) case_stmt(details::e_sf03,details::sf03_op) case_stmt(details::e_sf04,details::sf04_op) case_stmt(details::e_sf05,details::sf05_op) case_stmt(details::e_sf06,details::sf06_op) case_stmt(details::e_sf07,details::sf07_op) case_stmt(details::e_sf08,details::sf08_op) case_stmt(details::e_sf09,details::sf09_op) case_stmt(details::e_sf10,details::sf10_op) case_stmt(details::e_sf11,details::sf11_op) case_stmt(details::e_sf12,details::sf12_op) case_stmt(details::e_sf13,details::sf13_op) case_stmt(details::e_sf14,details::sf14_op) case_stmt(details::e_sf15,details::sf15_op) case_stmt(details::e_sf16,details::sf16_op) case_stmt(details::e_sf17,details::sf17_op) case_stmt(details::e_sf18,details::sf18_op) case_stmt(details::e_sf19,details::sf19_op) case_stmt(details::e_sf20,details::sf20_op) case_stmt(details::e_sf21,details::sf21_op) case_stmt(details::e_sf22,details::sf22_op) case_stmt(details::e_sf23,details::sf23_op) case_stmt(details::e_sf24,details::sf24_op) case_stmt(details::e_sf25,details::sf25_op) case_stmt(details::e_sf26,details::sf26_op) case_stmt(details::e_sf27,details::sf27_op) case_stmt(details::e_sf28,details::sf28_op) case_stmt(details::e_sf29,details::sf29_op) case_stmt(details::e_sf30,details::sf30_op) case_stmt(details::e_sf31,details::sf31_op) case_stmt(details::e_sf32,details::sf32_op) case_stmt(details::e_sf33,details::sf33_op) case_stmt(details::e_sf34,details::sf34_op) #undef case_stmt default : return error_node(); } } inline expression_node_ptr special_function(const details::operator_type& operation, expression_node_ptr (&branch)[3]) { if (!all_nodes_valid(branch)) return error_node(); else if (is_constant_foldable(branch)) return const_optimize_sf3(operation,branch); else if (all_nodes_variables(branch)) return varnode_optimize_sf3(operation,branch); else switch (operation) { #define case_stmt(op0,op1) case op0 : return node_allocator_->allocate > >(operation,branch); case_stmt(details::e_sf00,details::sf00_op) case_stmt(details::e_sf01,details::sf01_op) case_stmt(details::e_sf02,details::sf02_op) case_stmt(details::e_sf03,details::sf03_op) case_stmt(details::e_sf04,details::sf04_op) case_stmt(details::e_sf05,details::sf05_op) case_stmt(details::e_sf06,details::sf06_op) case_stmt(details::e_sf07,details::sf07_op) case_stmt(details::e_sf08,details::sf08_op) case_stmt(details::e_sf09,details::sf09_op) case_stmt(details::e_sf10,details::sf10_op) case_stmt(details::e_sf11,details::sf11_op) case_stmt(details::e_sf12,details::sf12_op) case_stmt(details::e_sf13,details::sf13_op) case_stmt(details::e_sf14,details::sf14_op) case_stmt(details::e_sf15,details::sf15_op) case_stmt(details::e_sf16,details::sf16_op) case_stmt(details::e_sf17,details::sf17_op) case_stmt(details::e_sf18,details::sf18_op) case_stmt(details::e_sf19,details::sf19_op) case_stmt(details::e_sf20,details::sf20_op) case_stmt(details::e_sf21,details::sf21_op) case_stmt(details::e_sf22,details::sf22_op) case_stmt(details::e_sf23,details::sf23_op) case_stmt(details::e_sf24,details::sf24_op) case_stmt(details::e_sf25,details::sf25_op) case_stmt(details::e_sf26,details::sf26_op) case_stmt(details::e_sf27,details::sf27_op) case_stmt(details::e_sf28,details::sf28_op) case_stmt(details::e_sf29,details::sf29_op) case_stmt(details::e_sf30,details::sf30_op) case_stmt(details::e_sf31,details::sf31_op) case_stmt(details::e_sf32,details::sf32_op) case_stmt(details::e_sf33,details::sf33_op) case_stmt(details::e_sf34,details::sf34_op) #undef case_stmt default : return error_node(); } } inline expression_node_ptr const_optimize_sf4(const details::operator_type& operation, expression_node_ptr (&branch)[4]) { expression_node_ptr temp_node = error_node(); switch (operation) { #define case_stmt(op0,op1) case op0 : temp_node = node_allocator_->allocate > >(operation,branch); break; case_stmt(details::e_sf35,details::sf35_op) case_stmt(details::e_sf36,details::sf36_op) case_stmt(details::e_sf37,details::sf37_op) case_stmt(details::e_sf38,details::sf38_op) case_stmt(details::e_sf39,details::sf39_op) case_stmt(details::e_sf40,details::sf40_op) case_stmt(details::e_sf41,details::sf41_op) case_stmt(details::e_sf42,details::sf42_op) case_stmt(details::e_sf43,details::sf43_op) case_stmt(details::e_sf44,details::sf44_op) case_stmt(details::e_sf45,details::sf45_op) case_stmt(details::e_sf46,details::sf46_op) case_stmt(details::e_sf47,details::sf47_op) case_stmt(details::e_sf48,details::sf48_op) case_stmt(details::e_sf49,details::sf49_op) case_stmt(details::e_sf50,details::sf50_op) case_stmt(details::e_sf51,details::sf51_op) case_stmt(details::e_sf52,details::sf52_op) case_stmt(details::e_sf53,details::sf53_op) case_stmt(details::e_sf54,details::sf54_op) case_stmt(details::e_sf55,details::sf55_op) case_stmt(details::e_sf56,details::sf56_op) case_stmt(details::e_sf57,details::sf57_op) case_stmt(details::e_sf58,details::sf58_op) case_stmt(details::e_sf59,details::sf59_op) case_stmt(details::e_sf60,details::sf60_op) case_stmt(details::e_sf61,details::sf61_op) case_stmt(details::e_sf62,details::sf62_op) case_stmt(details::e_sf63,details::sf63_op) case_stmt(details::e_sf64,details::sf64_op) case_stmt(details::e_sf65,details::sf65_op) case_stmt(details::e_sf66,details::sf66_op) case_stmt(details::e_sf67,details::sf67_op) case_stmt(details::e_sf68,details::sf68_op) case_stmt(details::e_sf69,details::sf69_op) case_stmt(details::e_sf70,details::sf70_op) case_stmt(details::e_sf71,details::sf71_op) case_stmt(details::e_sf72,details::sf72_op) case_stmt(details::e_sf73,details::sf73_op) case_stmt(details::e_sf74,details::sf74_op) case_stmt(details::e_sf75,details::sf75_op) case_stmt(details::e_sf76,details::sf76_op) case_stmt(details::e_sf77,details::sf77_op) case_stmt(details::e_sf78,details::sf78_op) case_stmt(details::e_sf79,details::sf79_op) case_stmt(details::e_sf80,details::sf80_op) case_stmt(details::e_sf81,details::sf81_op) case_stmt(details::e_sf82,details::sf82_op) #undef case_stmt default : return error_node(); } T v = temp_node->value(); node_allocator_->free(temp_node); return node_allocator_->allocate(v); } inline expression_node_ptr varnode_optimize_sf4(const details::operator_type& operation, expression_node_ptr (&branch)[4]) { Type& v0 = dynamic_cast*>(branch[0])->ref(); Type& v1 = dynamic_cast*>(branch[1])->ref(); Type& v2 = dynamic_cast*>(branch[2])->ref(); Type& v3 = dynamic_cast*>(branch[3])->ref(); switch (operation) { #define case_stmt(op0,op1) case op0 : return node_allocator_->allocate_rrrr > >(v0,v1,v2,v3); case_stmt(details::e_sf35,details::sf35_op) case_stmt(details::e_sf36,details::sf36_op) case_stmt(details::e_sf37,details::sf37_op) case_stmt(details::e_sf38,details::sf38_op) case_stmt(details::e_sf39,details::sf39_op) case_stmt(details::e_sf40,details::sf40_op) case_stmt(details::e_sf41,details::sf41_op) case_stmt(details::e_sf42,details::sf42_op) case_stmt(details::e_sf43,details::sf43_op) case_stmt(details::e_sf44,details::sf44_op) case_stmt(details::e_sf45,details::sf45_op) case_stmt(details::e_sf46,details::sf46_op) case_stmt(details::e_sf47,details::sf47_op) case_stmt(details::e_sf48,details::sf48_op) case_stmt(details::e_sf49,details::sf49_op) case_stmt(details::e_sf50,details::sf50_op) case_stmt(details::e_sf51,details::sf51_op) case_stmt(details::e_sf52,details::sf52_op) case_stmt(details::e_sf53,details::sf53_op) case_stmt(details::e_sf54,details::sf54_op) case_stmt(details::e_sf55,details::sf55_op) case_stmt(details::e_sf56,details::sf56_op) case_stmt(details::e_sf57,details::sf57_op) case_stmt(details::e_sf58,details::sf58_op) case_stmt(details::e_sf59,details::sf59_op) case_stmt(details::e_sf60,details::sf60_op) case_stmt(details::e_sf61,details::sf61_op) case_stmt(details::e_sf62,details::sf62_op) case_stmt(details::e_sf63,details::sf63_op) case_stmt(details::e_sf64,details::sf64_op) case_stmt(details::e_sf65,details::sf65_op) case_stmt(details::e_sf66,details::sf66_op) case_stmt(details::e_sf67,details::sf67_op) case_stmt(details::e_sf68,details::sf68_op) case_stmt(details::e_sf69,details::sf69_op) case_stmt(details::e_sf70,details::sf70_op) case_stmt(details::e_sf71,details::sf71_op) case_stmt(details::e_sf72,details::sf72_op) case_stmt(details::e_sf73,details::sf73_op) case_stmt(details::e_sf74,details::sf74_op) case_stmt(details::e_sf75,details::sf75_op) case_stmt(details::e_sf76,details::sf76_op) case_stmt(details::e_sf77,details::sf77_op) case_stmt(details::e_sf78,details::sf78_op) case_stmt(details::e_sf79,details::sf79_op) case_stmt(details::e_sf80,details::sf80_op) case_stmt(details::e_sf81,details::sf81_op) case_stmt(details::e_sf82,details::sf82_op) #undef case_stmt default : return error_node(); } } inline expression_node_ptr special_function(const details::operator_type& operation, expression_node_ptr (&branch)[4]) { if (!all_nodes_valid(branch)) return error_node(); else if (is_constant_foldable(branch)) return const_optimize_sf4(operation,branch); else if (all_nodes_variables(branch)) return varnode_optimize_sf4(operation,branch); switch (operation) { #define case_stmt(op0,op1) case op0 : return node_allocator_->allocate > >(operation,branch); case_stmt(details::e_sf35,details::sf35_op) case_stmt(details::e_sf36,details::sf36_op) case_stmt(details::e_sf37,details::sf37_op) case_stmt(details::e_sf38,details::sf38_op) case_stmt(details::e_sf39,details::sf39_op) case_stmt(details::e_sf40,details::sf40_op) case_stmt(details::e_sf41,details::sf41_op) case_stmt(details::e_sf42,details::sf42_op) case_stmt(details::e_sf43,details::sf43_op) case_stmt(details::e_sf44,details::sf44_op) case_stmt(details::e_sf45,details::sf45_op) case_stmt(details::e_sf46,details::sf46_op) case_stmt(details::e_sf47,details::sf47_op) case_stmt(details::e_sf48,details::sf48_op) case_stmt(details::e_sf49,details::sf49_op) case_stmt(details::e_sf50,details::sf50_op) case_stmt(details::e_sf51,details::sf51_op) case_stmt(details::e_sf52,details::sf52_op) case_stmt(details::e_sf53,details::sf53_op) case_stmt(details::e_sf54,details::sf54_op) case_stmt(details::e_sf55,details::sf55_op) case_stmt(details::e_sf56,details::sf56_op) case_stmt(details::e_sf57,details::sf57_op) case_stmt(details::e_sf58,details::sf58_op) case_stmt(details::e_sf59,details::sf59_op) case_stmt(details::e_sf60,details::sf60_op) case_stmt(details::e_sf61,details::sf61_op) case_stmt(details::e_sf62,details::sf62_op) case_stmt(details::e_sf63,details::sf63_op) case_stmt(details::e_sf64,details::sf64_op) case_stmt(details::e_sf65,details::sf65_op) case_stmt(details::e_sf66,details::sf66_op) case_stmt(details::e_sf67,details::sf67_op) case_stmt(details::e_sf68,details::sf68_op) case_stmt(details::e_sf69,details::sf69_op) case_stmt(details::e_sf70,details::sf70_op) case_stmt(details::e_sf71,details::sf71_op) case_stmt(details::e_sf72,details::sf72_op) case_stmt(details::e_sf73,details::sf73_op) case_stmt(details::e_sf74,details::sf74_op) case_stmt(details::e_sf75,details::sf75_op) case_stmt(details::e_sf76,details::sf76_op) case_stmt(details::e_sf77,details::sf77_op) case_stmt(details::e_sf78,details::sf78_op) case_stmt(details::e_sf79,details::sf79_op) case_stmt(details::e_sf80,details::sf80_op) case_stmt(details::e_sf81,details::sf81_op) case_stmt(details::e_sf82,details::sf82_op) #undef case_stmt default : return error_node(); } } template inline expression_node_ptr function(ifunction_t* f, expression_node_ptr (&b)[N]) { typedef typename details::function_N_node function_N_node_t; expression_node_ptr result = synthesize_expression(f,b); if (0 == result) return error_node(); else { //has the function call been completely optimized? if (details::is_constant_node(result)) return result; else if (!all_nodes_valid(b)) return error_node(); else if (N != f->param_count) return error_node(); function_N_node_t* func_node_ptr = dynamic_cast(result); if (func_node_ptr) { if (func_node_ptr->init_branches(b)) return result; else return error_node(); } else return error_node(); } } inline expression_node_ptr function(ifunction_t* f) { typedef typename details::function_N_node function_N_node_t; return node_allocator_->allocate(f); } private: template inline bool is_constant_foldable(NodePtr (&b)[N]) const { for (std::size_t i = 0; i < N; ++i) { if (0 == b[i]) return false; else if (!details::is_constant_node(b[i])) return false; } return true; } template inline bool all_nodes_valid(expression_node_ptr (&b)[N]) const { for (std::size_t i = 0; i < N; ++i) { if (0 == b[i]) return false; } return true; } template inline bool all_nodes_variables(expression_node_ptr (&b)[N]) const { for (std::size_t i = 0; i < N; ++i) { if (0 == b[i]) return false; else if (!is_variable_node(b[i])) return false; } return true; } inline expression_node_ptr synthesize_assignment_expression(const details::operator_type& operation, expression_node_ptr (&branch)[2]) { if (details::is_variable_node(branch[0])) return synthesize_expression(operation,branch); else return error_node(); } #define basic_opr_switch_statements \ case_stmt(details:: e_add,details:: add_op) \ case_stmt(details:: e_sub,details:: sub_op) \ case_stmt(details:: e_mul,details:: mul_op) \ case_stmt(details:: e_div,details:: div_op) \ case_stmt(details:: e_mod,details:: mod_op) \ case_stmt(details:: e_pow,details:: pow_op) \ #define extended_opr_switch_statements \ case_stmt(details:: e_lt,details:: lt_op) \ case_stmt(details:: e_lte,details:: lte_op) \ case_stmt(details:: e_gt,details:: gt_op) \ case_stmt(details:: e_gte,details:: gte_op) \ case_stmt(details:: e_eq,details:: eq_op) \ case_stmt(details:: e_ne,details:: ne_op) \ case_stmt(details:: e_and,details:: and_op) \ case_stmt(details::e_nand,details::nand_op) \ case_stmt(details:: e_or,details:: or_op) \ case_stmt(details:: e_nor,details:: nor_op) \ case_stmt(details:: e_xor,details:: xor_op) \ inline expression_node_ptr synthesize_cov_expression(const details::operator_type& operation, expression_node_ptr (&branch)[2]) { T c = dynamic_cast* >(branch[0])->value(); T& v = dynamic_cast*>(branch[1])->ref(); node_allocator_->free(branch[0]); switch (operation) { #define case_stmt(op0,op1) case op0 : return node_allocator_->allocate_cr > >(c,v); basic_opr_switch_statements #ifndef exprtk_disable_extended_operator_optimizations extended_opr_switch_statements #endif #undef case_stmt default : return error_node(); } } #ifndef exprtk_disable_cardinal_pow_optimisation template