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How do I change the code from this example

How can I change the code source to display the result?
I could not convert to boost spirit x3
Live Code
#include <string>
#include <vector>
#include <boost/spirit/home/x3.hpp>
#include <boost/spirit/home/x3/support/ast/variant.hpp>
#include <boost/fusion/include/adapt_struct.hpp>
#include <boost/fusion/adapted.hpp>
namespace x3 = boost::spirit::x3;
namespace client { namespace ast {
struct op_or {};
struct op_and {};
struct op_xor {};
struct op_not {};
template <typename tag> struct combination_op;
template <typename tag> struct unop;
typedef std::string var;
typedef boost::variant<
var,
boost::recursive_wrapper<unop<op_not>>,
boost::recursive_wrapper<combination_op<op_and>>,
boost::recursive_wrapper<combination_op<op_xor>>,
boost::recursive_wrapper<combination_op<op_or>>
>expr;
template <typename tag> struct combination_op {
typedef std::vector<expr> operands_t;
combination_op() = default;
combination_op(operands_t const& operands) : operands(operands) {}
operands_t operands;
};
template <typename tag> struct unop {
unop() = default;
unop(const expr& o) : operand(o) {}
expr operand;
};
}}
BOOST_FUSION_ADAPT_STRUCT(client::ast::combination_op<client::ast::op_and>, operands)
BOOST_FUSION_ADAPT_STRUCT(client::ast::combination_op<client::ast::op_xor>, operands)
BOOST_FUSION_ADAPT_STRUCT(client::ast::combination_op<client::ast::op_or>, operands)
BOOST_FUSION_ADAPT_STRUCT(client::ast::unop<client::ast::op_not>, operand)
namespace client { namespace parser {
x3::rule<class var, ast::var> var{ "var" };
x3::rule<class not, ast::unop<ast::op_not>> not{ "not" };
x3::rule<class and, ast::combination_op<ast::op_and>> and{ "and" };
x3::rule<class xor, ast::combination_op<ast::op_xor>> xor{ "xor" };
x3::rule<class or, ast::combination_op<ast::op_or >> or{ "or" };
x3::rule<class expr, ast::expr> expr { "expr" };
auto const expr_def = xor | and | or | not | var;
auto const expr_list = *expr;
auto const or_def = x3::no_case["or"] >> '(' >> expr_list >> ')';
auto const xor_def = x3::no_case["xor"] >> '(' >> expr_list >> ')';
auto const and_def = x3::no_case["and"] >> '(' >> expr_list >> ')';
auto const not_def = x3::no_case["not"] >> expr;
auto const var_def = x3::lexeme[+x3::alpha];
BOOST_SPIRIT_DEFINE(var,not,and,xor,or,expr);
}}
namespace client { namespace ast {
struct printer :boost::static_visitor<void> {
printer() {}
void operator()(const var& v) const{ }
void operator()(const combination_op<op_and>& b) const { recurse(b); }
void operator()(const combination_op<op_xor>& b) const { recurse(b); }
void operator()(const combination_op<op_or>& b) const { recurse(b); }
void operator()(const unop<op_not>& u) const { recurse(u.operand); }
template<typename T>
void recurse(T const& v) const {
//boost::apply_visitor(*this, v);
}
};
}}
int main() {
std::string storage = "a or (b and c)";
client::ast::expr result;
typedef std::string::const_iterator iterator_t;
iterator_t iter = storage.begin(), end = storage.end();
using x3::ascii::space;
bool ok = phrase_parse(iter, end, client::parser::expr, space, result);
if (ok && iter == end) {
boost::apply_visitor(client::ast::printer(), result);
}
return 0;
}

void operator()(const combination_op<op_and>& b) const { recurse(b); }
void operator()(const combination_op<op_xor>& b) const { recurse(b); }
void operator()(const combination_op<op_or>& b) const { recurse(b); }
void operator()(const unop<op_not>& u) const { recurse(u.operand); }
What do you suppose these functions do? If you look at the example you linked, you see concrete implementations:
Originally, here:
struct printer : boost::static_visitor<void>
{
printer(std::ostream& os) : _os(os) {}
std::ostream& _os;
//
void operator()(const var& v) const { _os << v; }
void operator()(const binop<op_and>& b) const { print(" & ", b.oper1, b.oper2); }
void operator()(const binop<op_or >& b) const { print(" | ", b.oper1, b.oper2); }
void operator()(const binop<op_xor>& b) const { print(" ^ ", b.oper1, b.oper2); }
void print(const std::string& op, const expr& l, const expr& r) const
{
_os << "(";
boost::apply_visitor(*this, l);
_os << op;
boost::apply_visitor(*this, r);
_os << ")";
}
void operator()(const unop<op_not>& u) const
{
_os << "(";
_os << "!";
boost::apply_visitor(*this, u.oper1);
_os << ")";
}
};
std::ostream& operator<<(std::ostream& os, const expr& e)
{ boost::apply_visitor(printer(os), e); return os; }
So you'd expect to write something like:
struct printer {
using result_type = void;
std::ostream& _os;
static auto name(op_and /*unused*/) { return "AND"; }
static auto name(op_not /*unused*/) { return "NOT"; }
static auto name(op_or /*unused*/) { return "OR"; }
static auto name(op_xor /*unused*/) { return "XOR"; }
void operator()(const var& v) const { _os << v; }
template <typename Op>
void operator()(const unop<Op>& u) const {
_os << "(" << name(Op{}) << " ";
operator()(u.operand);
_os << ")";
}
template <typename Op>
void operator()(const combination_op<Op>& b) const {
_os << "(";
bool first = true;
for (auto& e : b.operands) {
if (!std::exchange(first, false)) {
_os << " " << name(Op{}) << " ";
}
operator()(e);
}
_os << ")";
}
void operator()(expr const& v) const {
boost::apply_visitor(*this, v);
}
};
Which prints (Live On Coliru)
"or(a and(b c))" -> (a OR (b AND c))
If you wanted output similar to the thing you parse:
template <typename Op> void operator()(const unop<Op>& u) const {
operator()(combination_op<Op>{{u.operand}});
}
template <typename Op> void operator()(const combination_op<Op>& b) const {
_os << name(Op{}) << "(";
for (auto& e : b.operands) {
_os << " ";
operator()(e);
}
_os << ")";
}
Printing (Live On Coliru):
"or(a and(b c))" -> OR( a AND( b c))
As you can see, I that implementation highlights that the "function call" syntax doesn't essentially require difference between unary and binary operators
Full Listing
First variation:
// #define BOOST_SPIRIT_X3_DEBUG
#include <boost/fusion/adapted.hpp>
#include <boost/fusion/include/adapt_struct.hpp>
#include <boost/spirit/home/x3.hpp>
#include <boost/spirit/home/x3/support/ast/variant.hpp>
#include <string>
#include <iostream>
#include <iomanip>
#include <vector>
namespace x3 = boost::spirit::x3;
namespace client { namespace ast {
struct op_or {};
struct op_and {};
struct op_xor {};
struct op_not {};
template <typename tag> struct combination_op;
template <typename tag> struct unop;
typedef std::string var;
typedef boost::variant<var, boost::recursive_wrapper<unop<op_not>>,
boost::recursive_wrapper<combination_op<op_and>>,
boost::recursive_wrapper<combination_op<op_xor>>,
boost::recursive_wrapper<combination_op<op_or>>>
expr;
template <typename tag> struct combination_op {
typedef std::vector<expr> operands_t;
combination_op() = default;
combination_op(operands_t const& operands) : operands(operands) {}
operands_t operands;
};
template <typename tag> struct unop {
unop() = default;
unop(const expr& o) : operand(o) {}
expr operand;
};
} }
BOOST_FUSION_ADAPT_STRUCT(client::ast::combination_op<client::ast::op_and>, operands)
BOOST_FUSION_ADAPT_STRUCT(client::ast::combination_op<client::ast::op_xor>, operands)
BOOST_FUSION_ADAPT_STRUCT(client::ast::combination_op<client::ast::op_or>, operands)
BOOST_FUSION_ADAPT_STRUCT(client::ast::unop<client::ast::op_not>, operand)
namespace client { namespace parser {
x3::rule<class var, ast::var> var{ "var" };
x3::rule<class not_, ast::unop<ast::op_not>> not_ { "not" };
x3::rule<class and_, ast::combination_op<ast::op_and>> and_ { "and" };
x3::rule<class xor_, ast::combination_op<ast::op_xor>> xor_ { "xor" };
x3::rule<class or_, ast::combination_op<ast::op_or>> or_ { "or" };
x3::rule<class expr, ast::expr> expr{ "expr" };
auto const expr_def = xor_ | and_ | or_ | not_ | var;
auto const expr_list = *expr;
auto const or__def = x3::no_case["or"] >> '(' >> expr_list >> ')';
auto const xor__def = x3::no_case["xor"] >> '(' >> expr_list >> ')';
auto const and__def = x3::no_case["and"] >> '(' >> expr_list >> ')';
auto const not__def = x3::no_case["not"] >> expr;
auto const var_def = x3::lexeme[+x3::alpha];
BOOST_SPIRIT_DEFINE(var, not_, and_, xor_, or_, expr)
} }
namespace client { namespace ast {
struct printer {
using result_type = void;
std::ostream& _os;
static auto name(op_and /*unused*/) { return "AND"; }
static auto name(op_not /*unused*/) { return "NOT"; }
static auto name(op_or /*unused*/) { return "OR"; }
static auto name(op_xor /*unused*/) { return "XOR"; }
void operator()(const var& v) const { _os << v; }
template <typename Op>
void operator()(const unop<Op>& u) const {
_os << "(" << name(Op{}) << " ";
operator()(u.operand);
_os << ")";
}
template <typename Op>
void operator()(const combination_op<Op>& b) const {
_os << "(";
bool first = true;
for (auto& e : b.operands) {
if (!std::exchange(first, false)) {
_os << " " << name(Op{}) << " ";
}
operator()(e);
}
_os << ")";
}
void operator()(expr const& v) const {
boost::apply_visitor(*this, v);
}
};
} }
int main() {
std::string storage = "or(a and(b c))";
client::ast::expr result;
typedef std::string::const_iterator iterator_t;
iterator_t iter = storage.begin(), end = storage.end();
using x3::ascii::space;
bool ok = phrase_parse(iter, end, client::parser::expr, space, result);
if (ok && iter == end) {
client::ast::printer print{std::cout};
std::cout << std::quoted(storage) << " -> ";
print(result);
std::cout << "\n";
} else {
std::cout << "Failed\n";
}
if (iter != end) {
std::cout << "Remaining: " << std::quoted(std::string(iter, end)) << "\n";
}
}

Boost::Spirit expression parser with defined functions

I'm trying to parse some expression. I started from impressive answers of llonesmiz and Sehe
I wanted to add some:
(1) defined parameters. These prams are given as map by another class. They may have no argument (integer) one or two :
imf ---> $imf
imf(1) ---> $imf(1)
imf(1,2) ---> $imf(1,2)
I'm traying to fist get the parameter name "imf" an then its arguments if they exist (1), (2,2) ...
(2) defined function given as a map by another class. They may have one, two or three argument :
cos(1) ---> cos(1)
cross(imf(1),1) ---> cross($imf(1),1)
fun3(1,2,1) ---> fun3(1,2,1)
custom_fold_directive.hpp
namespace custom
{
namespace tag
{
struct fold { BOOST_SPIRIT_IS_TAG() };
}
template <typename Exposed, typename Expr>
boost::spirit::stateful_tag_type<Expr, tag::fold, Exposed>
fold(Expr const& expr)
{
return boost::spirit::stateful_tag_type<Expr, tag::fold, Exposed>(expr);
}
}
namespace boost { namespace spirit
{
template <typename Expr, typename Exposed>
struct use_directive<qi::domain
, tag::stateful_tag<Expr, custom::tag::fold, Exposed> >
: mpl::true_ {};
}}
namespace custom
{
template <typename Exposed, typename InitialParser, typename RepeatingParser>
struct fold_directive
{
fold_directive(InitialParser const& initial, RepeatingParser const& repeating):initial(initial),repeating(repeating){}
template <typename Context, typename Iterator>
struct attribute
{
typedef typename boost::spirit::traits::attribute_of<InitialParser,Context,Iterator>::type type;//This works in this case but is not generic
};
template <typename Iterator, typename Context
, typename Skipper, typename Attribute>
bool parse(Iterator& first, Iterator const& last
, Context& context, Skipper const& skipper, Attribute& attr_) const
{
Iterator start = first;
typename boost::spirit::traits::attribute_of<InitialParser,Context,Iterator>::type initial_attr;
if (!initial.parse(first, last, context, skipper, initial_attr))
{
first=start;
return false;
}
typename boost::spirit::traits::attribute_of<RepeatingParser,Context,Iterator>::type repeating_attr;
if(!repeating.parse(first, last, context, skipper, repeating_attr))
{
boost::spirit::traits::assign_to(initial_attr, attr_);
return true;
}
Exposed current_attr(initial_attr,repeating_attr);
while(repeating.parse(first, last, context, skipper, repeating_attr))
{
boost::spirit::traits::assign_to(Exposed(current_attr,repeating_attr),current_attr);
}
boost::spirit::traits::assign_to(current_attr,attr_);
return true;
}
template <typename Context>
boost::spirit::info what(Context& context) const
{
return boost::spirit::info("fold");
}
InitialParser initial;
RepeatingParser repeating;
};
}
namespace boost { namespace spirit { namespace qi
{
template <typename Expr, typename Exposed, typename Subject, typename Modifiers>
struct make_directive<
tag::stateful_tag<Expr, custom::tag::fold, Exposed>, Subject, Modifiers>
{
typedef custom::fold_directive<Exposed, Expr, Subject> result_type;
template <typename Terminal>
result_type operator()(Terminal const& term, Subject const& subject, Modifiers const&) const
{
typedef tag::stateful_tag<
Expr, custom::tag::fold, Exposed> tag_type;
using spirit::detail::get_stateful_data;
return result_type(get_stateful_data<tag_type>::call(term),subject);
}
};
}}}
main.cpp
//#define BOOST_SPIRIT_DEBUG
#include <iostream>
#include <boost/spirit/include/qi.hpp>
#include <boost/spirit/include/phoenix.hpp>
#include "custom_fold_directive.hpp"
namespace qi = boost::spirit::qi;
// DEFINING TYPES
struct op_not {};
struct op_or {};
struct op_and {};
struct op_equal {};
struct op_unequal {};
struct op_sum {};
struct op_difference {};
struct op_factor {};
struct op_division {};
struct op_component{};
namespace Expression{
typedef std::string var;
template <typename tag> struct binop;
template <typename tag> struct unop;
/*
* tree structure definition
*/
typedef boost::variant<var,
boost::recursive_wrapper<unop <op_not> >,
boost::recursive_wrapper<binop<op_equal> >,
boost::recursive_wrapper<binop<op_unequal> >,
boost::recursive_wrapper<binop<op_and> >,
boost::recursive_wrapper<binop<op_or> >,
boost::recursive_wrapper<binop<op_difference> >,
boost::recursive_wrapper<binop<op_sum> >,
boost::recursive_wrapper<binop<op_factor> >,
boost::recursive_wrapper<binop<op_division> >,
boost::recursive_wrapper<binop<op_component> >
> expressionContainer;
template <typename tag> struct binop
{
explicit binop(const expressionContainer& l
, const expressionContainer& r)
: oper1(l), oper2(r) { }
expressionContainer oper1, oper2;
};
template <typename tag> struct comop
{
explicit comop(const expressionContainer& l
, const expressionContainer& r)
: oper1(l), oper2(r) { }
expressionContainer oper1, oper2;
};
template <typename tag> struct unop
{
explicit unop(const expressionContainer& o) : oper1(o) { }
expressionContainer oper1;
};
struct printer : boost::static_visitor<void>
{
printer(std::ostream& os) : _os(os) {}
std::ostream& _os;
//
void operator()(const var& v) const { _os << v;}
// Logical
void operator()(const binop<op_and>& b) const { print(" & ", b.oper1, b.oper2); }
void operator()(const binop<op_or >& b) const { print(" || ", b.oper1, b.oper2); }
void operator()(const binop<op_equal>& b) const { print(" == ", b.oper1, b.oper2); }
void operator()(const binop<op_unequal>& b) const { print(" != ", b.oper1, b.oper2); }
//Math operators
void operator()(const binop<op_difference>& b) const { print("-", b.oper1, b.oper2); }
void operator()(const binop<op_sum>& b) const { print("+", b.oper1, b.oper2); }
void operator()(const binop<op_factor>& b) const { print("*", b.oper1, b.oper2); }
void operator()(const binop<op_division>& b) const { print("/", b.oper1, b.oper2); }
void operator()(const binop<op_component>& b) const { print(",", b.oper1, b.oper2); }
//unique operators
void operator()(const unop<op_not>& u) const{printUnique("!",u.oper1);}
//Printer
void print(const std::string& op, const expressionContainer& l, const expressionContainer& r) const
{
_os << "(";
boost::apply_visitor(*this, l);
_os << op;
boost::apply_visitor(*this, r);
_os << ")";
}
void printUnique(const std::string& op, const expressionContainer& l) const
{
_os << op;
boost::apply_visitor(*this, l);
}
void printPower(const std::string& op, const expressionContainer& l, const expressionContainer& r) const
{
boost::apply_visitor(*this, l);
_os << op;
boost::apply_visitor(*this, r);
}
void printOutSide(const std::string& op, const expressionContainer& l, const expressionContainer& r) const
{
_os << op;
_os << "(";
boost::apply_visitor(*this, l);
_os << ",";
boost::apply_visitor(*this, r);
_os << ")";
}
/**
* void printConst( const expressionContainer& l) const
{
std::map<std::string, std::string> consts;
consts["#pi"] = "3.14";
consts["#ro"]="1.5";
std::string key="#"+l.
boost::apply_visitor(*this, consts(key));
}
* #param l
*/
};
std::ostream& operator<<(std::ostream& os, const expressionContainer& e)
{ boost::apply_visitor(printer(os), e); return os; }
}
/*
* EXPRESSION PARSER DEFINITION
*/
template <typename It, typename Skipper = boost::spirit::standard_wide::space_type>
struct parserExpression : qi::grammar<It, Expression::expressionContainer(), Skipper>
{
parserExpression() : parserExpression::base_type(expr_)
{
using namespace qi;
using namespace Expression;
using custom::fold;
expr_ = or_.alias();
// Logical Operators
or_ = fold<binop<op_or> >(and_.alias())[orOperator_ >> and_];
and_ = fold<binop<op_and> >(equal_.alias())[andOperator_ >> equal_];
equal_ = fold<binop<op_equal> >(unequal_.alias())[equalOperator_ >> unequal_];
unequal_ = fold<binop<op_unequal> >(sum_.alias())[unequalOperator_ >>sum_];
// Numerical Operators
sum_ = fold<binop<op_sum> >(difference_.alias())[sumOperator_ >> difference_];
difference_ = fold<binop<op_difference> >(factor_.alias())[differenceOperator_ >> factor_];
factor_ = fold<binop<op_factor> >(division_.alias())[factorOperator_ >> division_];
division_ = fold<binop<op_division> >(not_.alias())[divisionOperator_ >> not_];
// UNARY OPERATION
not_ = (notOperator_ > param_) [_val = boost::phoenix::construct<Expression::unop <op_not>>(_1)] | param_[_val=_1];
param_ = (definedParams ) [_val =_1] | component_[_val = _1];
component_=definedParams >> '(' >> args_[_val=_1] >>')'| simple[_val = _1];
simple = (('(' > expr_ > ')') | var_);
var_ %= qi::raw[+qi::double_];
args_%=qi::raw[+qi::int_ % ','];
notOperator_ = qi::char_('!');
andOperator_ = qi::string("&&");
orOperator_ = qi::string("||");
xorOperator_ = qi::char_("^");
equalOperator_ = qi::string("==");
unequalOperator_ = qi::string("!=");
sumOperator_ = qi::char_("+");
differenceOperator_ = qi::char_("-");
factorOperator_ = qi::char_("*");
divisionOperator_ = qi::char_("/");
greaterOperator_ = qi::char_(">");
greaterOrEqualOperator_ = qi::string(">=");
lowerOrEqualOperator_ = qi::string("<=");
lowerOperator_ = qi::char_("<");
componentOperator_=qi::char_(",");
// Defined Function
std::map<std::string, std::string> functions;
functions["fun1"] = "cos";
functions["fun2"] = "sin";
for(auto const&x:functions){
definedFunctions.add (x.first, x.second) ;
}
//defined parameters
std::map<std::string, std::string> paramsList;
paramsList["imf"] = "imf";
paramsList["spect"] = "spectro";
for(auto const&x:paramsList){
definedParams.add (x.first, x.second) ;
}
BOOST_SPIRIT_DEBUG_NODES((expr_)(or_)(xor_)(and_)(equal_)(unequal_)(greaterOrEqual_)(lowerOrEqual_)(lower_)(sum_)
(difference_)(factor_)(division_)(simple)(notOperator_)(andOperator_)(orOperator_)(xorOperator_)(equalOperator_)(unequalOperator_)
(sumOperator_)(differenceOperator_)(factorOperator_)(divisionOperator_)(greater_)(lower_));
}
private:
qi::rule<It, Expression::var(), Skipper> var_, args_;
qi::rule<It, Expression::expressionContainer(), Skipper> not_
, and_
, xor_
, or_
, equal_
, unequal_
, sum_
, difference_
, factor_
, division_
, simple
, expr_
,plusSign_
,minusSign_
,greater_
,greaterOrEqual_
,lowerOrEqual_
,lower_
,functions_
,param_
,component_;
qi::rule<It, Skipper> notOperator_
, andOperator_
, orOperator_
, xorOperator_
, equalOperator_
, unequalOperator_
, sumOperator_
, differenceOperator_
, factorOperator_
, divisionOperator_
, greaterOperator_
, greaterOrEqualOperator_
,lowerOrEqualOperator_
,lowerOperator_
,componentOperator_;
qi::symbols<char, std::string> definedFunctions;
qi::symbols<char, std::string> definedParams;
};
void parse(const std::string& str)
{
std::string::const_iterator iter = str.begin(), end = str.end();
parserExpression<std::string::const_iterator,qi::space_type> parser;
Expression::expressionContainer expr;
bool result = qi::phrase_parse(iter,end,parser,qi::space, expr);
if(result && iter==end)
{
std::cout << "Success." << std::endl;
std::cout << str << " => " << expr << std::endl;
}
else
{
std::cout << "Failure." << std::endl;
}
}
int main()
{
parse("imf");
parse("spect");
parse("imf(1)");
parse("spect(1,2)");
}
Success.
imf => imf thats working
Success.
spect => spectro thats working
imf(1) => Failure. expected imf(1)
spect(1,2) => Failure. expected spectro(1,2)

The output for (1) isn't empty. It's ASCII 0x01:
00000000: 2831 2920 3d3e 2001 0a (1) => ..
That's because
var_ %= qi::lexeme[+qi::int_];
doesn't do what you want. It parses 1 as an integer and then puts that into the container of char (std::string is a container). To simply parse a number, only parse int_ and to treat is as a string, consider raw[]:
var_ = qi::raw[qi::int_];
Now it prints:
Success.
(1) => 1
Success.
1+1 => (1+1)
With regards to the rest, it's completely unclear to me how you want to parse things. I have a suspicion it's unclear to yourself too:
unary operators are unary, not unique
unary operators are operators, not expression subtypes or identifiers
if you want functions to take argument lists, why is there no rule that says so
if the "definedParams" are arguments - what's the difference between that and a variable?
For inspiration look at these answers that already do parser function calls with parameters:
Spirit qi parsing to an Abstract Syntax Tree for nested functions
Nice for comparison: This answer to Boost::spirit how to parse and call c++ function-like expressions interprets the parsed expressions on-the-fly (this mimics the approach with [std::cout << "Parse multiplication: " << (qi::_1 * qi::_2)] in your own parser)
The other answer there (Boost::spirit how to parse and call c++ function-like expressions) achieves the goal but using a dedicated AST representation, and a separate interpretation phase.
More slightly advanced/related:
Defining functions as well detecting function call with regex
Implementing operator precedence with boost spirit
Highly advanced: How to provider user with autocomplete suggestions for given boost::spirit grammar?

Following sehe suggestions, I added rules for parameters and functions. For function I build 3 lists “qi::symbols” depending on the number of arguments.
The parser works fine.
custom_fold_directive.hpp
namespace custom
{
namespace tag
{
struct fold { BOOST_SPIRIT_IS_TAG() };
}
template <typename Exposed, typename Expr>
boost::spirit::stateful_tag_type<Expr, tag::fold, Exposed>
fold(Expr const& expr)
{
return boost::spirit::stateful_tag_type<Expr, tag::fold, Exposed>(expr);
}
}
namespace boost { namespace spirit
{
template <typename Expr, typename Exposed>
struct use_directive<qi::domain
, tag::stateful_tag<Expr, custom::tag::fold, Exposed> >
: mpl::true_ {};
}}
namespace custom
{
template <typename Exposed, typename InitialParser, typename RepeatingParser>
struct fold_directive
{
fold_directive(InitialParser const& initial, RepeatingParser const& repeating):initial(initial),repeating(repeating){}
template <typename Context, typename Iterator>
struct attribute
{
typedef typename boost::spirit::traits::attribute_of<InitialParser,Context,Iterator>::type type;//This works in this case but is not generic
};
template <typename Iterator, typename Context
, typename Skipper, typename Attribute>
bool parse(Iterator& first, Iterator const& last
, Context& context, Skipper const& skipper, Attribute& attr_) const
{
Iterator start = first;
typename boost::spirit::traits::attribute_of<InitialParser,Context,Iterator>::type initial_attr;
if (!initial.parse(first, last, context, skipper, initial_attr))
{
first=start;
return false;
}
typename boost::spirit::traits::attribute_of<RepeatingParser,Context,Iterator>::type repeating_attr;
if(!repeating.parse(first, last, context, skipper, repeating_attr))
{
boost::spirit::traits::assign_to(initial_attr, attr_);
return true;
}
Exposed current_attr(initial_attr,repeating_attr);
while(repeating.parse(first, last, context, skipper, repeating_attr))
{
boost::spirit::traits::assign_to(Exposed(current_attr,repeating_attr),current_attr);
}
boost::spirit::traits::assign_to(current_attr,attr_);
return true;
}
template <typename Context>
boost::spirit::info what(Context& context) const
{
return boost::spirit::info("fold");
}
InitialParser initial;
RepeatingParser repeating;
};
}
namespace boost { namespace spirit { namespace qi
{
template <typename Expr, typename Exposed, typename Subject, typename Modifiers>
struct make_directive<
tag::stateful_tag<Expr, custom::tag::fold, Exposed>, Subject, Modifiers>
{
typedef custom::fold_directive<Exposed, Expr, Subject> result_type;
template <typename Terminal>
result_type operator()(Terminal const& term, Subject const& subject, Modifiers const&) const
{
typedef tag::stateful_tag<
Expr, custom::tag::fold, Exposed> tag_type;
using spirit::detail::get_stateful_data;
return result_type(get_stateful_data<tag_type>::call(term),subject);
}
};
}}}
main.cpp
#include <boost/mpl/list.hpp>
//#define BOOST_SPIRIT_DEBUG
#include <iostream>
#include <boost/spirit/include/qi.hpp>
#include <boost/spirit/include/phoenix.hpp>
#include "custom_fold_directive.hpp"
namespace qi = boost::spirit::qi;
// Expression::triop <fun_generic>
// DEFINING TYPES
struct op_not {};
struct op_or {};
struct op_and {};
struct op_xor {};
struct op_equal {};
struct op_unequal {};
struct op_sum {};
struct op_difference {};
struct op_factor {};
struct op_division {};
struct op_power{};
struct op_powerTen{};
struct op_plusSign {};
struct op_minusSign {};
struct op_const {};
struct fun_three{};
struct fun_two{};
struct fun_one{};
namespace Expression{
typedef std::string var;
template <typename tag> struct binop;
template <typename tag> struct unop;
template <typename tag> struct triop;
template <typename tag> struct forop;
/*
* tree structure definition
*/
typedef boost::variant<var,
boost::recursive_wrapper<unop <op_not> >,
boost::recursive_wrapper<binop<op_equal> >,
boost::recursive_wrapper<binop<op_unequal> >,
boost::recursive_wrapper<binop<op_and> >,
boost::recursive_wrapper<binop<op_xor> >,
boost::recursive_wrapper<binop<op_or> >,
boost::recursive_wrapper<binop<op_difference> >,
boost::recursive_wrapper<binop<op_sum> >,
boost::recursive_wrapper<binop<op_factor> >,
boost::recursive_wrapper<binop<op_division> >,
boost::recursive_wrapper<binop<op_power> >,
boost::recursive_wrapper<binop<op_powerTen> >,
boost::recursive_wrapper<unop<op_minusSign> >,
boost::recursive_wrapper<unop<op_plusSign> >,
boost::recursive_wrapper<unop<op_const> >,
boost::recursive_wrapper<binop<fun_one> >,
boost::recursive_wrapper<triop<fun_two> >,
boost::recursive_wrapper<forop<fun_three> >
> expressionContainer;
template <typename tag> struct binop
{
explicit binop(const expressionContainer& l
, const expressionContainer& r)
: oper1(l), oper2(r) { }
expressionContainer oper1, oper2;
};
template <typename tag> struct unop
{
explicit unop(const expressionContainer& o) : oper1(o) { }
expressionContainer oper1;
};
template <typename tag> struct triop
{
explicit triop(const expressionContainer& functionId,
const expressionContainer& l
, const expressionContainer& r)
: oper1(functionId), oper2(l), oper3(r) { }
expressionContainer oper1, oper2, oper3;
};
template <typename tag> struct forop
{
explicit forop(const expressionContainer& functionId,
const expressionContainer& l,
const expressionContainer& m,
const expressionContainer& r)
: oper1(functionId), oper2(l), oper3(m),oper4(r) { }
expressionContainer oper1, oper2, oper3,oper4;
};
struct printer : boost::static_visitor<void>
{
printer(std::ostream& os) : _os(os) {}
std::ostream& _os;
void operator()(const var& v) const { _os << v; }
// Logical
void operator()(const binop<op_and>& b) const { print(" & ", b.oper1, b.oper2); }
void operator()(const binop<op_or >& b) const { print(" || ", b.oper1, b.oper2); }
void operator()(const binop<op_xor>& b) const { print(" | ", b.oper1, b.oper2); }
void operator()(const binop<op_equal>& b) const { print(" == ", b.oper1, b.oper2); }
void operator()(const binop<op_unequal>& b) const { print(" != ", b.oper1, b.oper2); }
//Math operators
void operator()(const binop<op_difference>& b) const { print("-", b.oper1, b.oper2); }
void operator()(const binop<op_sum>& b) const { print("+", b.oper1, b.oper2); }
void operator()(const binop<op_factor>& b) const { print("*", b.oper1, b.oper2); }
void operator()(const binop<op_division>& b) const { print("/", b.oper1, b.oper2); }
//Power Math operators
void operator()(const binop<op_power>& b) const { print("pow", b.oper1, b.oper2); }
void operator()(const binop<op_powerTen>& b) const { printPower("e", b.oper1, b.oper2); }
//unique operators
void operator()(const unop<op_not>& u) const{printUnique("!",u.oper1);}
void operator()(const unop<op_plusSign>& u) const{printUnique("",u.oper1);}
void operator()(const unop<op_minusSign>& u) const{printUnique("-",u.oper1);}
void operator()(const unop<op_const>& u) const{printUnique("",u.oper1);}
// print Functions
void operator()(const forop<fun_three>& b) const { printFunctionThree(b.oper1, b.oper2, b.oper3, b.oper4); }
void operator()(const triop<fun_two>& b) const { printFunctionTwo(b.oper1, b.oper2, b.oper3); }
void operator()(const binop<fun_one>& b) const { printFunctionOne(b.oper1, b.oper2); }
//Printer
void print(const std::string& op, const expressionContainer& l, const expressionContainer& r) const
{
_os << "(";
boost::apply_visitor(*this, l);
_os << op;
boost::apply_visitor(*this, r);
_os << ")";
}
void printUnique(const std::string& op, const expressionContainer& l) const
{
_os << op;
boost::apply_visitor(*this, l);
}
void printPower(const std::string& op, const expressionContainer& l, const expressionContainer& r) const
{
boost::apply_visitor(*this, l);
_os << op;
boost::apply_visitor(*this, r);
}
void printOutSide(const std::string& op, const expressionContainer& l, const expressionContainer& r) const
{
_os << op;
_os << "(";
boost::apply_visitor(*this, l);
_os << ",";
boost::apply_visitor(*this, r);
_os << ")";
}
void printFunctionThree(const expressionContainer& functionId, const expressionContainer& l, const expressionContainer& m, const expressionContainer& r) const
{
boost::apply_visitor(*this, functionId);
_os << "(";
boost::apply_visitor(*this, l);
_os << ',';
boost::apply_visitor(*this, m);
_os << ',';
boost::apply_visitor(*this, r);
_os << ")";
}
void printFunctionTwo(const expressionContainer& functionId, const expressionContainer& l, const expressionContainer& r) const
{
boost::apply_visitor(*this, functionId);
_os << "(";
boost::apply_visitor(*this, l);
_os << ',';
boost::apply_visitor(*this, r);
_os << ")";
}
void printFunctionOne(const expressionContainer& functionId, const expressionContainer& l) const
{
boost::apply_visitor(*this, functionId);
_os << "(";
boost::apply_visitor(*this, l);
_os << ")";
}
};
std::ostream& operator<<(std::ostream& os, const expressionContainer& e)
{ boost::apply_visitor(printer(os), e); return os; }
}
/*
* EXPRESSION PARSER DEFINITION
*/
template <typename It, typename Skipper = boost::spirit::standard_wide::space_type>
struct parserExpression : qi::grammar<It, Expression::expressionContainer(), Skipper>
{
parserExpression() : parserExpression::base_type(expr_)
{
using namespace qi;
using namespace Expression;
using custom::fold;
expr_ = or_.alias();
// Logical Operators
or_ = fold<binop<op_or> >(and_.alias())[orOperator_ >> and_];
and_ = fold<binop<op_and> >(equal_.alias())[andOperator_ >> equal_];
equal_ = fold<binop<op_equal> >(unequal_.alias())[equalOperator_ >> unequal_];
unequal_ = fold<binop<op_unequal> >(sum_.alias())[unequalOperator_ >>sum_];
// Numerical Operators
sum_ = fold<binop<op_sum> >(difference_.alias())[sumOperator_ >> difference_];
difference_ = fold<binop<op_difference> >(factor_.alias())[differenceOperator_ >> factor_];
factor_ = fold<binop<op_factor> >(division_.alias())[factorOperator_ >> division_];
division_ = fold<binop<op_division> >(functions_.alias())[divisionOperator_ >> functions_];
functions_ = (threeArgsFunction>>"(">>funArgs_>>componentOperator_>>funArgs_>>componentOperator_>>funArgs_>>")")[_val= boost::phoenix::construct<Expression::forop <fun_three>>(_1,_2,_3,_4)] ||
(twoArgsFunction>>"(">>funArgs_>>componentOperator_>>funArgs_>>")")[_val= boost::phoenix::construct<Expression::triop <fun_two>>(_1,_2,_3)]||
(oneArgsFunction>>"(">>funArgs_>>")")[_val= boost::phoenix::construct<Expression::binop <fun_one>>(_1,_2)]|not_[_val=_1];
// UNARY OPERATION
not_ = (notOperator_ > param_) [_val = boost::phoenix::construct<Expression::unop <op_not>>(_1)] | param_[_val=_1];
param_= (definedParams >>('(' >> (spectArgs_|vectorArgs_)>>')'))[_val='$'+_1+"("+qi::_2+")"] ||
definedParams[_val='$'+_1]| simple[_val = _1];
funArgs_=((expr_ |var_) |functions_);
simple = (('(' > expr_ > ')') | var_);
var_ = (+qi::char_('0','9') >> -qi::char_('.') >> -(+qi::char_('0','9'))) | ((qi::char_('.') >> +qi::char_('0','9')));
vectorArgs_%=qi::raw[qi::int_ > -(qi::char_(',')>>qi::int_) ];
spectArgs_ %=qi::raw[(qi::int_>>qi::char_(',')>>'*')|(qi::char_('*')>>qi::char_(',')>>qi::int_)];
notOperator_ = qi::char_('!');
andOperator_ = qi::string("&&");
orOperator_ = qi::string("||");
xorOperator_ = qi::char_("^");
equalOperator_ = qi::string("==");
unequalOperator_ = qi::string("!=");
sumOperator_ = qi::char_("+");
differenceOperator_ = qi::char_("-");
factorOperator_ = qi::char_("*");
divisionOperator_ = qi::char_("/");
greaterOperator_ = qi::char_(">");
greaterOrEqualOperator_ = qi::string(">=");
lowerOrEqualOperator_ = qi::string("<=");
lowerOperator_ = qi::char_("<");
componentOperator_=qi::char_(",");
// Defined Function
std::map<std::string, std::string> oneFunctions;
oneFunctions["fun1_1"] = "f11";
oneFunctions["fun1_2"] = "f12";
for(auto const&x:oneFunctions){
oneArgsFunction.add (x.first, x.second) ;
}
std::map<std::string, std::string> twoFunctions;
twoFunctions["fun2_1"] = "f21";
twoFunctions["fun2_2"] = "f22";
for(auto const&x:twoFunctions){
twoArgsFunction.add (x.first, x.second) ;
}
std::map<std::string, std::string> threeFunctions;
threeFunctions["fun3_1"] = "f31";
threeFunctions["fun3_2"] = "f32";
for(auto const&x:threeFunctions){
threeArgsFunction.add (x.first, x.second) ;
}
//defined parameters
std::map<std::string, std::string> paramsList;
paramsList["imf"] = "imf";
paramsList["param"] = "param";
for(auto const&x:paramsList){
definedParams.add (x.first, x.second) ;
}
BOOST_SPIRIT_DEBUG_NODES((expr_)(or_)(xor_)(and_)(equal_)(unequal_)(sum_)(difference_)(factor_)(division_)
(simple)(notOperator_)(andOperator_)(orOperator_)(xorOperator_)(equalOperator_)(unequalOperator_)
(sumOperator_)(differenceOperator_)(factorOperator_)(divisionOperator_)(functions_));
}
private:
qi::rule<It, Expression::var(), Skipper> var_, vectorArgs_, spectArgs_;
qi::rule<It, Expression::expressionContainer(), Skipper> not_
, and_
, xor_
, or_
, equal_
, unequal_
, sum_
, difference_
, factor_
, division_
, simple
, expr_
,plusSign_
,minusSign_
,greater_
,greaterOrEqual_
,lowerOrEqual_
,lower_
,functions_
,param_
,funArgs_;
qi::rule<It, Skipper> notOperator_
, andOperator_
, orOperator_
, xorOperator_
, equalOperator_
, unequalOperator_
, sumOperator_
, differenceOperator_
, factorOperator_
, divisionOperator_
, greaterOperator_
, greaterOrEqualOperator_
,lowerOrEqualOperator_
,lowerOperator_
,componentOperator_;
qi::symbols<char, std::string> twoArgsFunction;
qi::symbols<char, std::string> oneArgsFunction;
qi::symbols<char, std::string> threeArgsFunction;
qi::symbols<char, std::string> definedParams;
};
void parse(const std::string& str)
{
std::string::const_iterator iter = str.begin(), end = str.end();
parserExpression<std::string::const_iterator,qi::space_type> parser;
Expression::expressionContainer expr;
bool result = qi::phrase_parse(iter,end,parser,qi::space, expr);
if(result && iter==end)
{
std::cout << "Success." << std::endl;
std::cout << str << " => " << expr << std::endl;
}
else
{
std::cout << "Failure." << std::endl;
}
}
int main()
{
parse("1");
parse("1+1");
parse("(1+1)");
//
parse("fun1_1((1))");
//
parse("fun2_1(1,2)");
parse("fun2_1( (fun2_1(1,1)), (2))");
//
parse("fun3_1(fun1_1(1),fun2_1(2,3),imf(1,1))");
}
output
Success.
1 => 1
Success.
imf => $imf
Success.
imf(1) => $imf(1)
Success.
(1+1) => (1+1)
Success.
fun1_1((1)) => f11(1)
Success.
fun2_1(1,2) => f21(1,2)
Success.
fun2_1( (fun2_1(1,1)), (2)) => f21(f21(1,1),2)
Success.
fun3_1(fun1_1(1),fun2_1(2,3),imf(1,1)) => f31(f11(1),f21(2,3),$imf(1,1))

Visit boost variant with extra arguments

I am trying to implement the Tseitin transformation over boolean formulas. The idea is that you transform boolean formulas in CNF, using transformation rules. For example, if the formula f = l OR r, we assign to each formula a new variable, let's say v_f, v_l and v_r, and we transform f = l OR r into (!v_f OR v_l OR v_r) AND (v_f OR !v_l) AND (v_f OR !v_r).
I use something like (v_f, v_l and v_r are replaced by p, p1 and p2. m is a variable that permits us to now what next variable we can use) :
int m = 0;
std::vector<std::vector<int> > formules;
struct op_or {};
struct op_and {};
struct op_not {};
struct op_impl {};
typedef int var;
template <typename tag> struct binop;
template <typename tag> struct unop;
typedef boost::variant<var,
boost::recursive_wrapper<unop <op_not> >,
boost::recursive_wrapper<binop<op_and> >,
boost::recursive_wrapper<binop<op_or> >,
boost::recursive_wrapper<binop<op_impl> >
> expr;
template <typename tag> struct binop
{
explicit binop(const expr& l, const expr& r) : oper1(l), oper2(r) { }
expr oper1, oper2;
};
template <typename tag> struct unop
{
explicit unop(const expr& o) : oper1(o) { }
expr oper1;
};
struct tseitin : boost::static_visitor<void>
{
tseitin() {}
void operator()(const var& v, int p = 0) {}
void operator()(const binop<op_and>& b, int p = m++) { proceed(0, b.oper1, b.oper2, p); }
void operator()(const binop<op_or>& b, int p = m++) { proceed(1, b.oper1, b.oper2, p);}
void operator()(const unop<op_not>& u, int p = m++) {}
void proceed(int nop, const expr& l, const expr& r, int p)
{
int p1 = m+1;
int p2 = m+2;
m += 2;
// Do the transformation
recurse(l, p1);
recurse(r, p2);
}
private:
template<typename T, typename U>
bool recurse(T const& v, U const& p)
{ return boost::apply_visitor(*this, v, p); }
};
And in the main, I call this transformation with : boost::apply_visitor(tseitin(), result, 0);
But I encounter errors like : error: no matching function for call to ‘apply_visitor(tseitin, expr&, int)’
boost::apply_visitor(tseitin(), result, 0);
And : error: request for member ‘apply_visitor’ in ‘visitable’, which is of non-class type ‘const int’
I don't really understand the error, do you have any ideas ?
As you may notice, I used How to calculate boolean expression in Spirit and boost spirit tutorial to implement the operators over the transformation.
I you need the whole code, let me now.
Thanks in advance !

I don't really understand the error, do you have any ideas ?
You are calling the binary version of boost::variant::apply_visitor. But you pass it a variant and an int. An int, as the error message announces, is not visitable.
To make this work, just bind the argument:
boost::apply_visitor(boost::bind(tseitin(), _1, 0), result);
This means that the _1 placeholder will receive the variant element and the second parameter is passed through.
You will also want to carry this through in recurse:
bool recurse(T const& v, U const& p)
{ return boost::apply_visitor(boost::bind(*this, _1, p), v); }
Update
Here's the demo of the linked answer, but using extra bound arguments instead of a stateful printer functor:
struct printer : boost::static_visitor<void>
{
//
void operator()(std::ostream& os, const var& v) const { os << v; }
void operator()(std::ostream& os, const binop<op_and>& b) const { print(os, " & ", b.oper1, b.oper2); }
void operator()(std::ostream& os, const binop<op_or >& b) const { print(os, " | ", b.oper1, b.oper2); }
void print(std::ostream& os, const std::string& op, const expr& l, const expr& r) const
{
os << "(";
boost::apply_visitor(boost::bind(*this, boost::ref(os), _1), l);
os << op;
boost::apply_visitor(boost::bind(*this, boost::ref(os), _1), r);
os << ")";
}
void operator()(std::ostream& os, const unop<op_not>& u) const
{
os << "(";
os << "!";
boost::apply_visitor(boost::bind(*this, boost::ref(os), _1), u.oper1);
os << ")";
}
};
Full Code:
Live On Coliru
#include <boost/spirit/include/qi.hpp>
#include <boost/spirit/include/phoenix.hpp>
#include <boost/spirit/include/phoenix_operator.hpp>
#include <boost/variant/recursive_wrapper.hpp>
#include <boost/lexical_cast.hpp>
#include <boost/bind.hpp>
namespace qi = boost::spirit::qi;
namespace phx = boost::phoenix;
struct op_or {};
struct op_and {};
struct op_not {};
typedef std::string var;
template <typename tag> struct binop;
template <typename tag> struct unop;
typedef boost::variant<var,
boost::recursive_wrapper<unop <op_not> >,
boost::recursive_wrapper<binop<op_and> >,
boost::recursive_wrapper<binop<op_or> >
> expr;
template <typename tag> struct binop
{
explicit binop(const expr& l, const expr& r) : oper1(l), oper2(r) { }
expr oper1, oper2;
};
template <typename tag> struct unop
{
explicit unop(const expr& o) : oper1(o) { }
expr oper1;
};
struct eval : boost::static_visitor<bool>
{
eval() {}
//
bool operator()(const var& v) const
{
if (v=="T" || v=="t" || v=="true" || v=="True")
return true;
else if (v=="F" || v=="f" || v=="false" || v=="False")
return false;
return boost::lexical_cast<bool>(v);
}
bool operator()(const binop<op_and>& b) const
{
return recurse(b.oper1) && recurse(b.oper2);
}
bool operator()(const binop<op_or>& b) const
{
return recurse(b.oper1) || recurse(b.oper2);
}
bool operator()(const unop<op_not>& u) const
{
return !recurse(u.oper1);
}
private:
template<typename T>
bool recurse(T const& v) const
{ return boost::apply_visitor(*this, v); }
};
struct printer : boost::static_visitor<void>
{
//
void operator()(std::ostream& os, const var& v) const { os << v; }
void operator()(std::ostream& os, const binop<op_and>& b) const { print(os, " & ", b.oper1, b.oper2); }
void operator()(std::ostream& os, const binop<op_or >& b) const { print(os, " | ", b.oper1, b.oper2); }
void print(std::ostream& os, const std::string& op, const expr& l, const expr& r) const
{
os << "(";
boost::apply_visitor(boost::bind(*this, boost::ref(os), _1), l);
os << op;
boost::apply_visitor(boost::bind(*this, boost::ref(os), _1), r);
os << ")";
}
void operator()(std::ostream& os, const unop<op_not>& u) const
{
os << "(";
os << "!";
boost::apply_visitor(boost::bind(*this, boost::ref(os), _1), u.oper1);
os << ")";
}
};
bool evaluate(const expr& e)
{ return boost::apply_visitor(eval(), e); }
std::ostream& operator<<(std::ostream& os, const expr& e)
{ boost::apply_visitor(boost::bind(printer(), boost::ref(os), _1), e); return os; }
template <typename It, typename Skipper = qi::space_type>
struct parser : qi::grammar<It, expr(), Skipper>
{
parser() : parser::base_type(expr_)
{
using namespace qi;
expr_ = or_.alias();
or_ = (and_ >> '|' >> or_ ) [ _val = phx::construct<binop<op_or > >(qi::_1, qi::_2) ] | and_ [ _val = qi::_1 ];
and_ = (not_ >> '&' >> and_) [ _val = phx::construct<binop<op_and> >(qi::_1, qi::_2) ] | not_ [ _val = qi::_1 ];
not_ = ('!' > simple ) [ _val = phx::construct<unop <op_not> >(qi::_1) ] | simple [ _val = qi::_1 ];
simple = (('(' > expr_ > ')') | var_);
var_ = qi::lexeme[ +(alpha|digit) ];
BOOST_SPIRIT_DEBUG_NODE(expr_);
BOOST_SPIRIT_DEBUG_NODE(or_);
BOOST_SPIRIT_DEBUG_NODE(and_);
BOOST_SPIRIT_DEBUG_NODE(not_);
BOOST_SPIRIT_DEBUG_NODE(simple);
BOOST_SPIRIT_DEBUG_NODE(var_);
}
private:
qi::rule<It, var() , Skipper> var_;
qi::rule<It, expr(), Skipper> not_, and_, or_, simple, expr_;
};
int main()
{
const std::string inputs[] = {
std::string("true & false;"),
std::string("true & !false;"),
std::string("!true & false;"),
std::string("true | false;"),
std::string("true | !false;"),
std::string("!true | false;"),
std::string("T&F;"),
std::string("T&!F;"),
std::string("!T&F;"),
std::string("T|F;"),
std::string("T|!F;"),
std::string("!T|F;"),
std::string("") // marker
};
for (const std::string *i = inputs; !i->empty(); ++i)
{
typedef std::string::const_iterator It;
It f(i->begin()), l(i->end());
parser<It> p;
try
{
expr result;
bool ok = qi::phrase_parse(f,l,p > ';',qi::space,result);
if (!ok)
std::cerr << "invalid input\n";
else
{
std::cout << "result:\t" << result << "\n";
std::cout << "evaluated:\t" << evaluate(result) << "\n";
}
} catch (const qi::expectation_failure<It>& e)
{
std::cerr << "expectation_failure at '" << std::string(e.first, e.last) << "'\n";
}
if (f!=l) std::cerr << "unparsed: '" << std::string(f,l) << "'\n";
}
return 0;
}

How do i change the grammar from this example to parse "AND ( (OR (a b c)) (NOT (d)))

Boolean expression (grammar) parser in c++
I'm trying to modify the grammar from the above example provided by "sehe" to parse the following expression. "AND ( (OR (a b c)) (NOT (d)))".
There are three operators AND/OR/NOT, NOT is unary but AND and OR can act on multiple operands.
Thanks

The changed grammar is actually a lot simpler because it sidesteps the issue of operator precedence. This is the 'lisp' approach to grammars :)
Nevertheless, since you asked, I give you, the changed parser to parse your modified grammar:
struct op_or {};
struct op_and {};
struct op_xor {};
struct op_not {};
typedef std::string var;
template <typename tag> struct combination_op;
template <typename tag> struct unop;
typedef boost::variant<var,
boost::recursive_wrapper<unop <op_not> >,
boost::recursive_wrapper<combination_op<op_and> >,
boost::recursive_wrapper<combination_op<op_xor> >,
boost::recursive_wrapper<combination_op<op_or> >
> expr;
template <typename tag> struct combination_op
{
typedef std::vector<expr> operands_t;
combination_op() = default;
combination_op(operands_t const& operands) : operands(operands) { }
operands_t operands;
};
template <typename tag> struct unop
{
unop() = default;
unop(const expr& o) : operand(o) { }
expr operand;
};
//////////////////////////////////////////////////
// Parser grammar
template <typename It, typename Skipper = qi::space_type>
struct parser : qi::grammar<It, expr(), Skipper>
{
parser() : parser::base_type(expr_)
{
using namespace qi;
or_ = no_case [ "OR" ] > '(' > expr_list > ')';
xor_ = no_case [ "XOR" ] > '(' > expr_list > ')';
and_ = no_case [ "AND" ] > '(' > expr_list > ')';
not_ = no_case [ "NOT" ] > '(' > expr_ > ')';
var_ = qi::lexeme[ +alpha ];
expr_list = +expr_;
expr_ = xor_ | and_ | or_ | not_ | var_;
on_error<fail> ( expr_, std::cout
<< phx::val("Error! Expecting ") << _4 << phx::val(" here: \"")
<< phx::construct<std::string>(_3, _2) << phx::val("\"\n"));
}
private:
template <typename Attr> using Rule = qi::rule<It, Attr(), Skipper>;
Rule<var> var_;
Rule<unop<op_not>> not_;
Rule<combination_op<op_and>> and_;
Rule<combination_op<op_xor>> xor_;
Rule<combination_op<op_or>> or_;
Rule<std::vector<expr>> expr_list;
Rule<expr> expr_;
};
If you wanted evaluation too:
//////////////////////////////////////////////////
// Evaluation
struct eval : boost::static_visitor<bool>
{
eval() {}
//
bool operator()(const var& v) const
{
if (v=="T" || v=="t" || v=="true" || v=="True")
return true;
else if (v=="F" || v=="f" || v=="false" || v=="False")
return false;
return boost::lexical_cast<bool>(v);
}
bool operator()(const combination_op<op_and>& b) const
{
return std::accumulate(begin(b.operands), end(b.operands), true,
[this](bool a, expr const& b) { return a && recurse(b); });
}
bool operator()(const combination_op<op_xor>& b) const
{
return std::accumulate(begin(b.operands), end(b.operands), false,
[this](bool a, expr const& b) { return a != recurse(b); });
}
bool operator()(const combination_op<op_or>& b) const
{
return std::accumulate(begin(b.operands), end(b.operands), false,
[this](bool a, expr const& b) { return a || recurse(b); });
}
bool operator()(const unop<op_not>& u) const
{
return !recurse(u.operand);
}
private:
template<typename T>
bool recurse(T const& v) const
{ return boost::apply_visitor(*this, v); }
};
bool evaluate(const expr& e)
{
return boost::apply_visitor(eval(), e);
}
And you can print the evaluation results using
std::cout << "eval: " << evaluate(result) << "\n";
Output:
tree: XOR (AND (true NOT (T)) OR (AND (T T) AND (F T)))
eval: 1
(Note: The tree is printed using the mirroring karma grammar, see "full code sample" below).
BONUS MATERIAL:
You may have noticed that the grammar has gotten very symmetrical around the corners. This is precisely because the precedence issue has vanished. Therefore, it might make sense to simplify the grammar further: simplified.cpp
Full Code Sample
Also on github: straight_forward.cpp
#include <boost/spirit/include/qi.hpp>
#include <boost/spirit/include/phoenix.hpp>
#include <boost/spirit/include/karma.hpp>
#include <boost/variant/recursive_wrapper.hpp>
#include <boost/lexical_cast.hpp>
namespace qi = boost::spirit::qi;
namespace karma = boost::spirit::karma;
namespace phx = boost::phoenix;
struct op_or {};
struct op_and {};
struct op_xor {};
struct op_not {};
typedef std::string var;
template <typename tag> struct combination_op;
template <typename tag> struct unop;
typedef boost::variant<var,
boost::recursive_wrapper<unop <op_not> >,
boost::recursive_wrapper<combination_op<op_and> >,
boost::recursive_wrapper<combination_op<op_xor> >,
boost::recursive_wrapper<combination_op<op_or> >
> expr;
template <typename tag> struct combination_op
{
typedef std::vector<expr> operands_t;
combination_op() = default;
combination_op(operands_t const& operands) : operands(operands) { }
operands_t operands;
};
template <typename tag> struct unop
{
unop() = default;
unop(const expr& o) : operand(o) { }
expr operand;
};
//////////////////////////////////////////////////
// Evaluation
struct eval : boost::static_visitor<bool>
{
eval() {}
//
bool operator()(const var& v) const
{
if (v=="T" || v=="t" || v=="true" || v=="True")
return true;
else if (v=="F" || v=="f" || v=="false" || v=="False")
return false;
return boost::lexical_cast<bool>(v);
}
bool operator()(const combination_op<op_and>& b) const
{
return std::accumulate(begin(b.operands), end(b.operands), true,
[this](bool a, expr const& b) { return a && recurse(b); });
}
bool operator()(const combination_op<op_xor>& b) const
{
return std::accumulate(begin(b.operands), end(b.operands), false,
[this](bool a, expr const& b) { return a != recurse(b); });
}
bool operator()(const combination_op<op_or>& b) const
{
return std::accumulate(begin(b.operands), end(b.operands), false,
[this](bool a, expr const& b) { return a || recurse(b); });
}
bool operator()(const unop<op_not>& u) const
{
return !recurse(u.operand);
}
private:
template<typename T>
bool recurse(T const& v) const
{ return boost::apply_visitor(*this, v); }
};
bool evaluate(const expr& e)
{
return boost::apply_visitor(eval(), e);
}
//////////////////////////////////////////////////
// Parser grammar
template <typename It, typename Skipper = qi::space_type>
struct parser : qi::grammar<It, expr(), Skipper>
{
parser() : parser::base_type(expr_)
{
using namespace qi;
or_ = no_case [ "OR" ] > '(' > expr_list > ')';
xor_ = no_case [ "XOR" ] > '(' > expr_list > ')';
and_ = no_case [ "AND" ] > '(' > expr_list > ')';
not_ = no_case [ "NOT" ] > '(' > expr_ > ')';
var_ = qi::lexeme[ +alpha ];
expr_list = +expr_;
expr_ = xor_ | and_ | or_ | not_ | var_;
on_error<fail> ( expr_, std::cout
<< phx::val("Error! Expecting ") << _4 << phx::val(" here: \"")
<< phx::construct<std::string>(_3, _2) << phx::val("\"\n"));
}
private:
template <typename Attr> using Rule = qi::rule<It, Attr(), Skipper>;
Rule<var> var_;
Rule<unop<op_not>> not_;
Rule<combination_op<op_and>> and_;
Rule<combination_op<op_xor>> xor_;
Rule<combination_op<op_or>> or_;
Rule<std::vector<expr>> expr_list;
Rule<expr> expr_;
};
//////////////////////////////////////////////////
// Output generator
template <typename It>
struct generator : karma::grammar<It, expr()>
{
generator() : generator::base_type(expr_)
{
using namespace karma;
or_ = lit("OR ") << '(' << expr_list[ _1 = phx::bind(&combination_op<op_or >::operands, _val) ] << ')';
xor_ = lit("XOR ") << '(' << expr_list[ _1 = phx::bind(&combination_op<op_xor>::operands, _val) ] << ')';
and_ = lit("AND ") << '(' << expr_list[ _1 = phx::bind(&combination_op<op_and>::operands, _val) ] << ')';
not_ = lit("NOT ") << '(' << expr_ [ _1 = phx::bind(&unop<op_not> ::operand, _val) ] << ')';
var_ = karma::string;
expr_list = expr_ % ' ';
expr_ = var_ | not_ | xor_ | and_ | or_ | not_;
}
private:
template <typename Attr> using Rule = karma::rule<It, Attr()>;
Rule<var> var_;
Rule<unop<op_not>> not_;
Rule<combination_op<op_and>> and_;
Rule<combination_op<op_xor>> xor_;
Rule<combination_op<op_or>> or_;
Rule<std::vector<expr>> expr_list;
Rule<expr> expr_;
};
int main()
{
const std::string input("xor (and (true not(T)) or (and (T T) and (F T)));");
auto f(std::begin(input)), l(std::end(input));
const static parser<decltype(f)> p;
expr result;
bool ok = qi::phrase_parse(f,l,p > ';',qi::space,result);
if (!ok)
std::cout << "invalid input\n";
else
{
const static generator<boost::spirit::ostream_iterator> g;
std::cout << "tree: " << karma::format(g, result) << "\n";
std::cout << "eval: " << evaluate(result) << "\n";
}
if (f!=l) std::cout << "unparsed: '" << std::string(f,l) << "'\n";
}

How to calculate boolean expression in Spirit

I found a really good example about boolean translator,
* Boolean expression (grammar) parser in c++
What I am thinking now is to do a further step, translate (!T|F)&T into F or 0, so it is very convenient for calculating a very long boolean expression.
Is there some examples about this using spirit? What I have done is making a calculator first, and then let it calculate '(T+!F*T)', which equal to (T||!F&&T)but when I type (), there is an error. How to modify it? Thanks a lot!
#include <iostream>
#include <stack>
#include <boost/lexical_cast.hpp>
#include <boost/config/warning_disable.hpp>
#include <boost/spirit/include/qi.hpp>
#include <boost/spirit/include/phoenix.hpp>
using namespace std;
namespace phoenix = boost::phoenix;
namespace qi = boost::spirit::qi;
namespace ascii = boost::spirit::ascii;
struct calculator
{
bool interpret(const string& s);
void do_neg();
void do_add();
void do_sub();
void do_mul();
void do_div();
void do_number(const char* first, const char* last);
int val() const;
private:
stack<int> values_;
int *pn1_, n2_;
void pop_1();
void pop_2();
};
template <typename Iterator>
struct calc_grammar : qi::grammar<Iterator, ascii::space_type>
{
calc_grammar(calculator& calc)
: calc_grammar::base_type(add_sub_expr)
, calc_(calc)
{
using namespace qi;
using boost::iterator_range;
#define LAZY_FUN0(f) phoenix::bind(&calculator::f, calc_)
#define LAZY_FUN2(f) phoenix::bind(&calculator::f, calc_, phoenix::bind(&iterator_range<Iterator>::begin, qi::_1), phoenix::bind(&iterator_range<Iterator>::end, qi::_1))
add_sub_expr =
(
-lit('+') >> mul_div_expr |
(lit('-') >> mul_div_expr)[LAZY_FUN0(do_neg)]
) >>
*(
lit('+') >> mul_div_expr[LAZY_FUN0(do_add)] |
lit('-') >> mul_div_expr[LAZY_FUN0(do_sub)]
) >> eoi;
mul_div_expr =
basic_expr >>
*(
lit('*') >> basic_expr[LAZY_FUN0(do_mul)] |
lit('/') >> basic_expr[LAZY_FUN0(do_div)]
);
basic_expr =
raw[number][LAZY_FUN2(do_number)] |
lit('(') >> add_sub_expr >> lit(')');
number = lexeme[+digit];
}
qi::rule<Iterator, ascii::space_type> add_sub_expr, mul_div_expr, basic_expr, number;
calculator& calc_;
};
bool calculator::interpret(const string& s)
{
calc_grammar<const char*> g(*this);
const char* p = s.c_str();
return qi::phrase_parse(p, p + s.length(), g, ascii::space);
}
void calculator::pop_1()
{
pn1_ = &values_.top();
}
void calculator::pop_2()
{
n2_ = values_.top();
values_.pop();
pop_1();
}
void calculator::do_number(const char* first, const char* last)
{
string str(first, last);
int n = boost::lexical_cast<int>(str);
values_.push(n);
}
void calculator::do_neg()
{
pop_1();
*pn1_ = -*pn1_;
}
void calculator::do_add()
{
pop_2();
*pn1_ += n2_;
}
void calculator::do_sub()
{
pop_2();
*pn1_ -= n2_;
}
void calculator::do_mul()
{
pop_2();
*pn1_ *= n2_;
}
void calculator::do_div()
{
pop_2();
*pn1_ /= n2_;
}
int calculator::val() const
{
assert(values_.size() == 1);
return values_.top();
}
int main()
{
for(;;){
cout << ">>> ";
string s;
getline(cin, s);
if(s.empty()) break;
calculator calc;
if(calc.interpret(s))
cout << calc.val() << endl;
else
cout << "syntax error" << endl;
}
return 0;
}

Here goes a quick and dirty demo based on my old Boolean Parser answer. This is a visitor that evaluates the AST you pass it:
struct eval : boost::static_visitor<bool>
{
eval() {}
//
bool operator()(const var& v) const
{
if (v=="T" || v=="t" || v=="true" || v=="True")
return true;
else if (v=="F" || v=="f" || v=="false" || v=="False")
return false;
return boost::lexical_cast<bool>(v);
}
bool operator()(const binop<op_and>& b) const
{
return recurse(b.oper1) && recurse(b.oper2);
}
bool operator()(const binop<op_or>& b) const
{
return recurse(b.oper1) || recurse(b.oper2);
}
bool operator()(const unop<op_not>& u) const
{
return !recurse(u.oper1);
}
private:
template<typename T>
bool recurse(T const& v) const
{ return boost::apply_visitor(*this, v); }
};
bool evaluate(const expr& e)
{ return boost::apply_visitor(eval(), e); }
I hope I can find some time later to explain. Note that _var is a misnomer now, since you wanted to treat all operands as literals. Also note that the evaluation of a literal is a bit ... quick and dirty right now :)
Full Code
Live On Coliru
#include <boost/spirit/include/qi.hpp>
#include <boost/spirit/include/phoenix.hpp>
#include <boost/spirit/include/phoenix_operator.hpp>
#include <boost/variant/recursive_wrapper.hpp>
#include <boost/lexical_cast.hpp>
namespace qi = boost::spirit::qi;
namespace phx = boost::phoenix;
struct op_or {};
struct op_and {};
struct op_not {};
typedef std::string var;
template <typename tag> struct binop;
template <typename tag> struct unop;
typedef boost::variant<var,
boost::recursive_wrapper<unop <op_not> >,
boost::recursive_wrapper<binop<op_and> >,
boost::recursive_wrapper<binop<op_or> >
> expr;
template <typename tag> struct binop
{
explicit binop(const expr& l, const expr& r) : oper1(l), oper2(r) { }
expr oper1, oper2;
};
template <typename tag> struct unop
{
explicit unop(const expr& o) : oper1(o) { }
expr oper1;
};
struct eval : boost::static_visitor<bool>
{
eval() {}
//
bool operator()(const var& v) const
{
if (v=="T" || v=="t" || v=="true" || v=="True")
return true;
else if (v=="F" || v=="f" || v=="false" || v=="False")
return false;
return boost::lexical_cast<bool>(v);
}
bool operator()(const binop<op_and>& b) const
{
return recurse(b.oper1) && recurse(b.oper2);
}
bool operator()(const binop<op_or>& b) const
{
return recurse(b.oper1) || recurse(b.oper2);
}
bool operator()(const unop<op_not>& u) const
{
return !recurse(u.oper1);
}
private:
template<typename T>
bool recurse(T const& v) const
{ return boost::apply_visitor(*this, v); }
};
struct printer : boost::static_visitor<void>
{
printer(std::ostream& os) : _os(os) {}
std::ostream& _os;
//
void operator()(const var& v) const { _os << v; }
void operator()(const binop<op_and>& b) const { print(" & ", b.oper1, b.oper2); }
void operator()(const binop<op_or >& b) const { print(" | ", b.oper1, b.oper2); }
void print(const std::string& op, const expr& l, const expr& r) const
{
_os << "(";
boost::apply_visitor(*this, l);
_os << op;
boost::apply_visitor(*this, r);
_os << ")";
}
void operator()(const unop<op_not>& u) const
{
_os << "(";
_os << "!";
boost::apply_visitor(*this, u.oper1);
_os << ")";
}
};
bool evaluate(const expr& e)
{ return boost::apply_visitor(eval(), e); }
std::ostream& operator<<(std::ostream& os, const expr& e)
{ boost::apply_visitor(printer(os), e); return os; }
template <typename It, typename Skipper = qi::space_type>
struct parser : qi::grammar<It, expr(), Skipper>
{
parser() : parser::base_type(expr_)
{
using namespace qi;
expr_ = or_.alias();
or_ = (and_ >> '|' >> or_ ) [ _val = phx::construct<binop<op_or > >(_1, _2) ] | and_ [ _val = _1 ];
and_ = (not_ >> '&' >> and_) [ _val = phx::construct<binop<op_and> >(_1, _2) ] | not_ [ _val = _1 ];
not_ = ('!' > simple ) [ _val = phx::construct<unop <op_not> >(_1) ] | simple [ _val = _1 ];
simple = (('(' > expr_ > ')') | var_);
var_ = qi::lexeme[ +(alpha|digit) ];
BOOST_SPIRIT_DEBUG_NODE(expr_);
BOOST_SPIRIT_DEBUG_NODE(or_);
BOOST_SPIRIT_DEBUG_NODE(and_);
BOOST_SPIRIT_DEBUG_NODE(not_);
BOOST_SPIRIT_DEBUG_NODE(simple);
BOOST_SPIRIT_DEBUG_NODE(var_);
}
private:
qi::rule<It, var() , Skipper> var_;
qi::rule<It, expr(), Skipper> not_, and_, or_, simple, expr_;
};
int main()
{
const std::string inputs[] = {
std::string("true & false;"),
std::string("true & !false;"),
std::string("!true & false;"),
std::string("true | false;"),
std::string("true | !false;"),
std::string("!true | false;"),
std::string("T&F;"),
std::string("T&!F;"),
std::string("!T&F;"),
std::string("T|F;"),
std::string("T|!F;"),
std::string("!T|F;"),
std::string("") // marker
};
for (const std::string *i = inputs; !i->empty(); ++i)
{
typedef std::string::const_iterator It;
It f(i->begin()), l(i->end());
parser<It> p;
try
{
expr result;
bool ok = qi::phrase_parse(f,l,p > ';',qi::space,result);
if (!ok)
std::cerr << "invalid input\n";
else
{
std::cout << "result:\t" << result << "\n";
std::cout << "evaluated:\t" << evaluate(result) << "\n";
}
} catch (const qi::expectation_failure<It>& e)
{
std::cerr << "expectation_failure at '" << std::string(e.first, e.last) << "'\n";
}
if (f!=l) std::cerr << "unparsed: '" << std::string(f,l) << "'\n";
}
return 0;
}
Output:
result: (true & false)
evaluated: 0
result: (true & (!false))
evaluated: 1
result: ((!true) & false)
evaluated: 0
result: (true | false)
evaluated: 1
result: (true | (!false))
evaluated: 1
result: ((!true) | false)
evaluated: 0
result: (T & F)
evaluated: 0
result: (T & (!F))
evaluated: 1
result: ((!T) & F)
evaluated: 0
result: (T | F)
evaluated: 1
result: (T | (!F))
evaluated: 1
result: ((!T) | F)
evaluated: 0