ecency-mobile/ios/Pods/boost-for-react-native/boost/dll/detail/demangling/msvc.hpp

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// Copyright 2016 Klemens Morgenstern
//
// Distributed under the Boost Software License, Version 1.0.
// (See accompanying file LICENSE_1_0.txt
// or copy at http://www.boost.org/LICENSE_1_0.txt)
#ifndef BOOST_DLL_DETAIL_DEMANGLING_MSVC_HPP_
#define BOOST_DLL_DETAIL_DEMANGLING_MSVC_HPP_
#include <boost/dll/detail/demangling/mangled_storage_base.hpp>
#include <iterator>
#include <algorithm>
#include <boost/type_traits/is_const.hpp>
#include <boost/type_traits/is_volatile.hpp>
#include <boost/type_traits/is_lvalue_reference.hpp>
#include <boost/type_traits/is_rvalue_reference.hpp>
#include <boost/type_traits/function_traits.hpp>
#include <boost/type_traits/remove_reference.hpp>
#include <boost/spirit/home/x3.hpp>
namespace boost { namespace dll { namespace detail {
class mangled_storage_impl : public mangled_storage_base
{
template<typename T>
struct dummy {};
template<typename Return, typename ...Args>
std::vector<std::string> get_func_params(dummy<Return(Args...)>) const
{
return {get_name<Args>()...};
}
template<typename Return, typename ...Args>
std::string get_return_type(dummy<Return(Args...)>) const
{
return get_name<Return>();
}
//function to remove preceeding 'class ' or 'struct ' if the are given in this format.
inline static void trim_typename(std::string & val);
public:
using ctor_sym = std::string;
using dtor_sym = std::string;
using mangled_storage_base::mangled_storage_base;
template<typename T>
std::string get_variable(const std::string &name) const;
template<typename Func>
std::string get_function(const std::string &name) const;
template<typename Class, typename Func>
std::string get_mem_fn(const std::string &name) const;
template<typename Signature>
ctor_sym get_constructor() const;
template<typename Class>
dtor_sym get_destructor() const;
template<typename T> //overload, does not need to virtual.
std::string get_name() const
{
auto nm = mangled_storage_base::get_name<T>();
trim_typename(nm);
return nm;
}
template<typename T>
std::string get_vtable() const;
template<typename T>
std::vector<std::string> get_related() const;
};
void mangled_storage_impl::trim_typename(std::string & val)
{
//remove preceeding class or struct, because you might want to use a struct as class, et vice versa
if (val.size() >= 6)
{
using namespace std;
static constexpr char class_ [7] = "class ";
static constexpr char struct_[8] = "struct ";
if (equal(begin(class_), end(class_)-1, val.begin())) //aklright, starts with 'class '
val.erase(0, 6);
else if (val.size() >= 7)
if (equal(begin(struct_), end(struct_)-1, val.begin()))
val.erase(0, 7);
}
}
namespace parser
{
namespace x3 = spirit::x3;
auto ptr_rule_impl(std::integral_constant<std::size_t, 32>)
{
return -((-x3::space) >> "__ptr32");
}
auto ptr_rule_impl(std::integral_constant<std::size_t, 64>)
{
return -((-x3::space) >> "__ptr64");
}
auto ptr_rule() { return ptr_rule_impl(std::integral_constant<std::size_t, sizeof(std::size_t)*8>());}
auto const visibility = ("public:" | x3::lit("protected:") | "private:");
auto const virtual_ = x3::space >> "virtual";
auto const static_ = x3::space >> x3::lit("static") ;
auto const_rule_impl(true_type ) {return x3::space >> "const";};
auto const_rule_impl(false_type) {return x3::eps;};
template<typename T>
auto const_rule() {using t = is_const<typename remove_reference<T>::type>; return const_rule_impl(t());}
auto volatile_rule_impl(true_type ) {return x3::space >> "volatile";};
auto volatile_rule_impl(false_type) {return x3::eps;};
template<typename T>
auto volatile_rule() {using t = is_volatile<typename remove_reference<T>::type>; return volatile_rule_impl(t());}
auto inv_const_rule_impl(true_type ) {return "const" >> x3::space ;};
auto inv_const_rule_impl(false_type) {return x3::eps;};
template<typename T>
auto inv_const_rule() {using t = is_const<typename remove_reference<T>::type>; return inv_const_rule_impl(t());}
auto inv_volatile_rule_impl(true_type ) {return "volatile" >> x3::space;};
auto inv_volatile_rule_impl(false_type) {return x3::eps;};
template<typename T>
auto inv_volatile_rule() {using t = is_volatile<typename remove_reference<T>::type>; return inv_volatile_rule_impl(t());}
auto reference_rule_impl(false_type, false_type) {return x3::eps;}
auto reference_rule_impl(true_type, false_type) {return x3::space >>"&" ;}
auto reference_rule_impl(false_type, true_type ) {return x3::space >>"&&" ;}
template<typename T>
auto reference_rule() {using t_l = is_lvalue_reference<T>; using t_r = is_rvalue_reference<T>; return reference_rule_impl(t_l(), t_r());}
auto const class_ = ("class" | x3::lit("struct"));
//it takes a string, because it may be overloaded.
template<typename T>
auto type_rule(const std::string & type_name)
{
using namespace std;
return -(class_ >> x3::space)>> x3::string(type_name) >>
const_rule<T>() >>
volatile_rule<T>() >>
reference_rule<T>() >>
ptr_rule();
}
template<>
auto type_rule<void>(const std::string &) { return x3::string("void"); };
auto const cdecl_ = "__cdecl" >> x3::space;
auto const stdcall = "__stdcall" >> x3::space;
#if defined(_WIN64)//seems to be necessary by msvc 14-x64
auto const thiscall = "__cdecl" >> x3::space;
#else
auto const thiscall = "__thiscall" >> x3::space;
#endif
template<typename Return, typename Arg>
auto arg_list(const mangled_storage_impl & ms, Return (*)(Arg))
{
using namespace std;
return type_rule<Arg>(ms.get_name<Arg>());
}
template<typename Return, typename First, typename Second, typename ...Args>
auto arg_list(const mangled_storage_impl & ms, Return (*)(First, Second, Args...))
{
using next_type = Return (*)(Second, Args...);
return type_rule<First>(ms.get_name<First>()) >> x3::char_(',') >> arg_list(ms, next_type());
}
template<typename Return>
auto arg_list(const mangled_storage_impl & ms, Return (*)())
{
return x3::string("void");
}
}
template<typename T> std::string mangled_storage_impl::get_variable(const std::string &name) const
{
using namespace std;
using namespace boost;
namespace x3 = spirit::x3;
using namespace parser;
auto type_name = get_name<T>();
auto matcher =
-(visibility >> static_ >> x3::space) >> //it may be a static class-member
parser::type_rule<T>(type_name) >> x3::space >>
name;
auto predicate = [&](const mangled_storage_base::entry & e)
{
if (e.demangled == name)//maybe not mangled,
return true;
auto itr = e.demangled.begin();
auto end = e.demangled.end();
auto res = x3::parse(itr, end, matcher);
return res && (itr == end);
};
auto found = std::find_if(storage_.begin(), storage_.end(), predicate);
if (found != storage_.end())
return found->mangled;
else
return "";
}
template<typename Func> std::string mangled_storage_impl::get_function(const std::string &name) const
{
namespace x3 = spirit::x3;
using namespace parser;
using func_type = Func*;
using return_type = typename function_traits<Func>::result_type;
std::string return_type_name = get_name<return_type>();
auto matcher =
-(visibility >> static_ >> x3::space) >> //it may be a static class-member, which does however not have the static attribute.
parser::type_rule<return_type>(return_type_name) >> x3::space >>
cdecl_ >> //cdecl declaration for methods. stdcall cannot be
name >> x3::lit('(') >> parser::arg_list(*this, func_type()) >> x3::lit(')') >> parser::ptr_rule();
auto predicate = [&](const mangled_storage_base::entry & e)
{
if (e.demangled == name)//maybe not mangled,
return true;
auto itr = e.demangled.begin();
auto end = e.demangled.end();
auto res = x3::parse(itr, end, matcher);
return res && (itr == end);
};
auto found = std::find_if(storage_.begin(), storage_.end(), predicate);
if (found != storage_.end())
return found->mangled;
else
return "";
}
template<typename Class, typename Func>
std::string mangled_storage_impl::get_mem_fn(const std::string &name) const
{
namespace x3 = spirit::x3;
using namespace parser;
using func_type = Func*;
using return_type = typename function_traits<Func>::result_type;
auto return_type_name = get_name<return_type>();
auto cname = get_name<Class>();
auto matcher =
visibility >> -virtual_ >> x3::space >>
parser::type_rule<return_type>(return_type_name) >> x3::space >>
thiscall >> //cdecl declaration for methods. stdcall cannot be
cname >> "::" >> name >>
x3::lit('(') >> parser::arg_list(*this, func_type()) >> x3::lit(')') >>
inv_const_rule<Class>() >> inv_volatile_rule<Class>() >> parser::ptr_rule();
auto predicate = [&](const mangled_storage_base::entry & e)
{
auto itr = e.demangled.begin();
auto end = e.demangled.end();
auto res = x3::parse(itr, end, matcher);
return res && (itr == end);
};
auto found = std::find_if(storage_.begin(), storage_.end(), predicate);
if (found != storage_.end())
return found->mangled;
else
return "";
}
template<typename Signature>
auto mangled_storage_impl::get_constructor() const -> ctor_sym
{
namespace x3 = spirit::x3;
using namespace parser;
using func_type = Signature*;
std::string ctor_name; // = class_name + "::" + name;
std::string unscoped_cname; //the unscoped class-name
{
auto class_name = get_return_type(dummy<Signature>());
auto pos = class_name.rfind("::");
if (pos == std::string::npos)
{
ctor_name = class_name+ "::" + class_name ;
unscoped_cname = class_name;
}
else
{
unscoped_cname = class_name.substr(pos+2) ;
ctor_name = class_name+ "::" + unscoped_cname;
}
}
auto matcher =
visibility >> x3::space >>
thiscall >> //cdecl declaration for methods. stdcall cannot be
ctor_name >>
x3::lit('(') >> parser::arg_list(*this, func_type()) >> x3::lit(')') >> parser::ptr_rule();
auto predicate = [&](const mangled_storage_base::entry & e)
{
auto itr = e.demangled.begin();
auto end = e.demangled.end();
auto res = x3::parse(itr, end, matcher);
return res && (itr == end);
};
auto f = std::find_if(storage_.begin(), storage_.end(), predicate);
if (f != storage_.end())
return f->mangled;
else
return "";
}
template<typename Class>
auto mangled_storage_impl::get_destructor() const -> dtor_sym
{
namespace x3 = spirit::x3;
using namespace parser;
std::string dtor_name; // = class_name + "::" + name;
std::string unscoped_cname; //the unscoped class-name
{
auto class_name = get_name<Class>();
auto pos = class_name.rfind("::");
if (pos == std::string::npos)
{
dtor_name = class_name+ "::~" + class_name + "(void)";
unscoped_cname = class_name;
}
else
{
unscoped_cname = class_name.substr(pos+2) ;
dtor_name = class_name+ "::~" + unscoped_cname + "(void)";
}
}
auto matcher =
visibility >> -virtual_ >> x3::space >>
thiscall >> //cdecl declaration for methods. stdcall cannot be
dtor_name >> parser::ptr_rule();
auto predicate = [&](const mangled_storage_base::entry & e)
{
auto itr = e.demangled.begin();
auto end = e.demangled.end();
auto res = x3::parse(itr, end, matcher);
return res && (itr == end);
};
auto found = std::find_if(storage_.begin(), storage_.end(), predicate);
if (found != storage_.end())
return found->mangled;
else
return "";
}
template<typename T>
std::string mangled_storage_impl::get_vtable() const
{
std::string id = "const " + get_name<T>() + "::`vftable'";
auto predicate = [&](const mangled_storage_base::entry & e)
{
return e.demangled == id;
};
auto found = std::find_if(storage_.begin(), storage_.end(), predicate);
if (found != storage_.end())
return found->mangled;
else
return "";
}
template<typename T>
std::vector<std::string> mangled_storage_impl::get_related() const
{
std::vector<std::string> ret;
auto name = get_name<T>();
for (auto & c : storage_)
{
if (c.demangled.find(name) != std::string::npos)
ret.push_back(c.demangled);
}
return ret;
}
}}}
#endif /* BOOST_DLL_DETAIL_DEMANGLING_MSVC_HPP_ */