#include #include #include #include #include #include #include #include #include #include "aftypes.h" #include "parser.h" using namespace boost::spirit; using namespace phoenix; namespace px = phoenix; struct parse_error : std::runtime_error { parse_error(char const *what) : std::runtime_error(what) {} }; struct parser_closure : boost::spirit::closure { member1 val; }; namespace { AFPData f_in(AFPData const &a, AFPData const &b) { std::string sa = a, sb = b; return AFPData(std::search(sb.begin(), sb.end(), sa.begin(), sa.end()) != sb.end()); } } struct function_closure : boost::spirit::closure< function_closure, AFPData, boost::function)>, std::vector > { member1 val; member2 func; member3 args; }; struct parser_grammar : public grammar { symbols variables; symbols)> > functions; void add_variable(std::string const &name, AFPData const &value) { variables.add(name.c_str(), value); } void add_function(std::string const &name, boost::function)> func) { functions.add(name.c_str(), func); } template struct definition { typedef rule rule_t; parser_grammar const &self_; struct push_back_impl { template struct result { typedef void type; }; template void operator() (C &c, I const &i) const { c.push_back(i); } }; phoenix::function const push_back; struct call_function_impl { template struct result { typedef AFPData type; }; template AFPData operator() (F const &func, A const &args) const { return func(args); } }; phoenix::function const call_function; definition(parser_grammar const &self) : self_(self) , push_back(push_back_impl()) , call_function(call_function_impl()) { value = real_p[value.val = arg1] | int_p[value.val = arg1] | confix_p('"', *c_escape_ch_p, '"')[ value.val = construct_(arg1 + 1, arg2 - 1) ] ; /* a sequence of uppercase letters is a variable */ variable = self.variables[variable.val = arg1] | (+upper_p)[variable.val = ""] ; /* func(value) */ function = ( self.functions[function.func = arg1] >> '(' >> ( bool_expr[push_back(function.args, arg1)] % ',' ) >> ')' ) [function.val = call_function(function.func, function.args)] ; basic = ( '(' >> bool_expr[basic.val = arg1] >> ')' ) | ch_p('!') >> bool_expr[basic.val = !arg1] | variable[basic.val = arg1] | function[basic.val = arg1] | value[basic.val = arg1] ; in_expr = basic[in_expr.val = arg1] >> *( "in" >> basic[in_expr.val = bind(&f_in)(in_expr.val, arg1)] ) ; mult_expr = in_expr[mult_expr.val = arg1] >> *( '*' >> in_expr[mult_expr.val *= arg1] | '/' >> in_expr[mult_expr.val /= arg1] | '%' >> in_expr[mult_expr.val %= arg1] ) ; plus_expr = mult_expr[plus_expr.val = arg1] >> *( '+' >> mult_expr[plus_expr.val += arg1] | '-' >> mult_expr[plus_expr.val -= arg1] ) ; eq_expr = plus_expr[eq_expr.val = arg1] >> *( "<" >> plus_expr[eq_expr.val = eq_expr.val < arg1] | ">" >> plus_expr[eq_expr.val = eq_expr.val > arg1] | "<=" >> plus_expr[eq_expr.val = eq_expr.val <= arg1] | ">=" >> plus_expr[eq_expr.val = eq_expr.val >= arg1] ) ; eq2_expr = eq_expr[eq2_expr.val = arg1] >> *( "==" >> eq_expr[eq2_expr.val = eq2_expr.val == arg1] | "!=" >> eq_expr[eq2_expr.val = eq2_expr.val != arg1] | "===" >> eq_expr[eq2_expr.val = bind(&AFPData::compare_with_type)(eq2_expr.val, arg1)] | "!==" >> eq_expr[eq2_expr.val = !bind(&AFPData::compare_with_type)(eq2_expr.val, arg1)] ) ; bool_expr = eq2_expr[bool_expr.val = arg1] >> *( '&' >> eq2_expr[bool_expr.val = bool_expr.val && arg1] | '|' >> eq2_expr[bool_expr.val = bool_expr.val || arg1] | '^' >> eq2_expr[bool_expr.val = ((bool_expr.val || arg1) && !(bool_expr.val && arg1)) ] ) ; expr = bool_expr[self.val = arg1]; } rule_t const &start() const { return expr; } rule_t value, variable, basic, bool_expr, eq_expr, eq2_expr, mult_expr, plus_expr, in_expr, not_expr, expr; rule function; }; }; expressor::expressor() : grammar_(new parser_grammar) { } expressor::~expressor() { delete grammar_; } AFPData expressor::evaluate(std::string const &filter) const { AFPData ret; parse_info info = parse(filter.begin(), filter.end(), (*grammar_)[var(ret) = arg1], space_p); if (info.full) { return ret; } else { std::cerr << "stopped at: [" << std::string(info.stop, filter.end()) << "]\n"; throw parse_error("parsing failed"); } } void expressor::add_variable(std::string const &name, AFPData value) { grammar_->add_variable(name, value); } void expressor::add_function(std::string const &name, func_t value) { grammar_->add_function(name, value); } #ifdef TEST_PARSER AFPData f_add(std::vector const &args) { return args[0] + args[1]; } AFPData f_norm(std::vector const &args) { return args[0]; } int main(int argc, char **argv) { expressor e; e.add_variable("ONE", 1); e.add_variable("TWO", 2); e.add_variable("THREE", 3); e.add_function("add", f_add); e.add_function("norm", f_norm); try { std::cout << e.evaluate(argv[1]) << '\n'; } catch (std::exception &e) { std::cout << "parsing failed: " << e.what() << '\n'; } } #endif