ecency-mobile/ios/Pods/boost-for-react-native/boost/wave/preprocessing_hooks.hpp

820 lines
34 KiB
C++

/*=============================================================================
Boost.Wave: A Standard compliant C++ preprocessor library
http://www.boost.org/
Copyright (c) 2001-2012 Hartmut Kaiser. 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)
=============================================================================*/
#if !defined(DEFAULT_PREPROCESSING_HOOKS_HPP_INCLUDED)
#define DEFAULT_PREPROCESSING_HOOKS_HPP_INCLUDED
#include <boost/wave/wave_config.hpp>
#include <boost/wave/util/cpp_include_paths.hpp>
#include <boost/wave/cpp_exceptions.hpp>
#include <vector>
// this must occur after all of the includes and before any code appears
#ifdef BOOST_HAS_ABI_HEADERS
#include BOOST_ABI_PREFIX
#endif
///////////////////////////////////////////////////////////////////////////////
namespace boost {
namespace wave {
namespace context_policies {
///////////////////////////////////////////////////////////////////////////////
//
// The default_preprocessing_hooks class is a placeholder for all
// preprocessing hooks called from inside the preprocessing engine
//
///////////////////////////////////////////////////////////////////////////////
struct default_preprocessing_hooks
{
///////////////////////////////////////////////////////////////////////////
//
// The function 'expanding_function_like_macro' is called, whenever a
// function-like macro is to be expanded.
//
// The parameter 'macrodef' marks the position, where the macro to expand
// is defined.
//
// The parameter 'formal_args' holds the formal arguments used during the
// definition of the macro.
//
// The parameter 'definition' holds the macro definition for the macro to
// trace.
//
// The parameter 'macro_call' marks the position, where this macro invoked.
//
// The parameter 'arguments' holds the macro arguments used during the
// invocation of the macro
//
// The parameters 'seqstart' and 'seqend' point into the input token
// stream allowing to access the whole token sequence comprising the macro
// invocation (starting with the opening parenthesis and ending after the
// closing one).
//
// The return value defines whether the corresponding macro will be
// expanded (return false) or will be copied to the output (return true).
// Note: the whole argument list is copied unchanged to the output as well
// without any further processing.
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
template <typename TokenT, typename ContainerT>
void expanding_function_like_macro(
TokenT const& macrodef, std::vector<TokenT> const& formal_args,
ContainerT const& definition,
TokenT const& macrocall, std::vector<ContainerT> const& arguments)
{}
#else
// new signature
template <typename ContextT, typename TokenT, typename ContainerT, typename IteratorT>
bool
expanding_function_like_macro(ContextT const& ctx,
TokenT const& macrodef, std::vector<TokenT> const& formal_args,
ContainerT const& definition,
TokenT const& macrocall, std::vector<ContainerT> const& arguments,
IteratorT const& seqstart, IteratorT const& seqend)
{ return false; } // default is to normally expand the macro
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'expanding_object_like_macro' is called, whenever a
// object-like macro is to be expanded .
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'macro' marks the position, where the macro to expand
// is defined.
//
// The definition 'definition' holds the macro definition for the macro to
// trace.
//
// The parameter 'macrocall' marks the position, where this macro invoked.
//
// The return value defines whether the corresponding macro will be
// expanded (return false) or will be copied to the output (return true).
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
template <typename TokenT, typename ContainerT>
void expanding_object_like_macro(TokenT const& macro,
ContainerT const& definition, TokenT const& macrocall)
{}
#else
// new signature
template <typename ContextT, typename TokenT, typename ContainerT>
bool
expanding_object_like_macro(ContextT const& ctx, TokenT const& macro,
ContainerT const& definition, TokenT const& macrocall)
{ return false; } // default is to normally expand the macro
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'expanded_macro' is called, whenever the expansion of a
// macro is finished but before the rescanning process starts.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'result' contains the token sequence generated as the
// result of the macro expansion.
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
template <typename ContainerT>
void expanded_macro(ContainerT const& result)
{}
#else
// new signature
template <typename ContextT, typename ContainerT>
void expanded_macro(ContextT const& ctx, ContainerT const& result)
{}
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'rescanned_macro' is called, whenever the rescanning of a
// macro is finished.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'result' contains the token sequence generated as the
// result of the rescanning.
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
template <typename ContainerT>
void rescanned_macro(ContainerT const& result)
{}
#else
// new signature
template <typename ContextT, typename ContainerT>
void rescanned_macro(ContextT const& ctx, ContainerT const& result)
{}
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'locate_include_file' is called, whenever a #include
// directive was encountered. It is supposed to locate the given file and
// should return the full file name of the located file. This file name
// is expected to uniquely identify the referenced file.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'file_path' contains the (expanded) file name found after
// the #include directive. This parameter holds the string as it is
// specified in the #include directive, i.e. <file> or "file" will result
// in a parameter value 'file'.
//
// The parameter 'is_system' is set to 'true' if this call happens as a
// result of a #include '<file>' directive, it is 'false' otherwise, i.e.
// for #include "file" directives.
//
// The parameter 'current_name' is only used if a #include_next directive
// was encountered (and BOOST_WAVE_SUPPORT_INCLUDE_NEXT was defined to be
// non-zero). In this case it points to unique full name of the current
// include file (if any). Otherwise this parameter is set to NULL.
//
// The parameter 'dir_path' on return is expected to hold the directory
// part of the located file.
//
// The parameter 'native_name' on return is expected to hold the unique
// full file name of the located file.
//
// The return value defines whether the file was located successfully.
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT>
bool
locate_include_file(ContextT& ctx, std::string &file_path,
bool is_system, char const *current_name, std::string &dir_path,
std::string &native_name)
{
if (!ctx.find_include_file (file_path, dir_path, is_system, current_name))
return false; // could not locate file
namespace fs = boost::filesystem;
fs::path native_path(wave::util::create_path(file_path));
if (!fs::exists(native_path)) {
BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_include_file,
file_path.c_str(), ctx.get_main_pos());
return false;
}
// return the unique full file system path of the located file
native_name = wave::util::native_file_string(native_path);
return true; // include file has been located successfully
}
///////////////////////////////////////////////////////////////////////////
//
// The function 'found_include_directive' is called, whenever a #include
// directive was located.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'filename' contains the (expanded) file name found after
// the #include directive. This has the format '<file>', '"file"' or
// 'file'.
// The formats '<file>' or '"file"' are used for #include directives found
// in the preprocessed token stream, the format 'file' is used for files
// specified through the --force_include command line argument.
//
// The parameter 'include_next' is set to true if the found directive was
// a #include_next directive and the BOOST_WAVE_SUPPORT_INCLUDE_NEXT
// preprocessing constant was defined to something != 0.
//
// The return value defines whether the found file will be included
// (return false) or will be skipped (return true).
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
void
found_include_directive(std::string const& filename, bool include_next)
{}
#else
// new signature
template <typename ContextT>
bool
found_include_directive(ContextT const& ctx, std::string const& filename,
bool include_next)
{
return false; // ok to include this file
}
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'opened_include_file' is called, whenever a file referred
// by an #include directive was successfully located and opened.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'filename' contains the file system path of the
// opened file (this is relative to the directory of the currently
// processed file or a absolute path depending on the paths given as the
// include search paths).
//
// The include_depth parameter contains the current include file depth.
//
// The is_system_include parameter denotes whether the given file was
// found as a result of a #include <...> directive.
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
void
opened_include_file(std::string const& relname, std::string const& absname,
std::size_t include_depth, bool is_system_include)
{}
#else
// new signature
template <typename ContextT>
void
opened_include_file(ContextT const& ctx, std::string const& relname,
std::string const& absname, bool is_system_include)
{}
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'returning_from_include_file' is called, whenever an
// included file is about to be closed after it's processing is complete.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
void
returning_from_include_file()
{}
#else
// new signature
template <typename ContextT>
void
returning_from_include_file(ContextT const& ctx)
{}
#endif
#if BOOST_WAVE_SUPPORT_PRAGMA_ONCE != 0
///////////////////////////////////////////////////////////////////////////
//
// The function 'detected_include_guard' is called whenever either a
// include file is about to be added to the list of #pragma once headers.
// That means this header file will not be opened and parsed again even
// if it is specified in a later #include directive.
// This function is called as the result of a detected include guard
// scheme.
//
// The implemented heuristics for include guards detects two forms of
// include guards:
//
// #ifndef INCLUDE_GUARD_MACRO
// #define INCLUDE_GUARD_MACRO
// ...
// #endif
//
// or
//
// if !defined(INCLUDE_GUARD_MACRO)
// #define INCLUDE_GUARD_MACRO
// ...
// #endif
//
// note, that the parenthesis are optional (i.e. !defined INCLUDE_GUARD_MACRO
// will work as well). The code allows for any whitespace, newline and single
// '#' tokens before the #if/#ifndef and after the final #endif.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'filename' contains the file system path of the
// opened file (this is relative to the directory of the currently
// processed file or a absolute path depending on the paths given as the
// include search paths).
//
// The parameter contains the name of the detected include guard.
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT>
void
detected_include_guard(ContextT const& ctx, std::string const& filename,
std::string const& include_guard)
{}
///////////////////////////////////////////////////////////////////////////
//
// The function 'detected_pragma_once' is called whenever either a
// include file is about to be added to the list of #pragma once headers.
// That means this header file will not be opened and parsed again even
// if it is specified in a later #include directive.
// This function is called as the result of a detected directive
// #pragma once.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter pragma_token refers to the token "#pragma" triggering
// this preprocessing hook.
//
// The parameter 'filename' contains the file system path of the
// opened file (this is relative to the directory of the currently
// processed file or a absolute path depending on the paths given as the
// include search paths).
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT, typename TokenT>
void
detected_pragma_once(ContextT const& ctx, TokenT const& pragma_token,
std::string const& filename)
{}
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'interpret_pragma' is called, whenever a '#pragma command'
// directive is found which isn't known to the core Wave library, where
// 'command' is the value defined as the BOOST_WAVE_PRAGMA_KEYWORD constant
// which defaults to "wave".
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'pending' may be used to push tokens back into the input
// stream, which are to be used as the replacement text for the whole
// #pragma directive.
//
// The parameter 'option' contains the name of the interpreted pragma.
//
// The parameter 'values' holds the values of the parameter provided to
// the pragma operator.
//
// The parameter 'act_token' contains the actual #pragma token, which may
// be used for error output.
//
// If the return value is 'false', the whole #pragma directive is
// interpreted as unknown and a corresponding error message is issued. A
// return value of 'true' signs a successful interpretation of the given
// #pragma.
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT, typename ContainerT>
bool
interpret_pragma(ContextT const& ctx, ContainerT &pending,
typename ContextT::token_type const& option, ContainerT const& values,
typename ContextT::token_type const& act_token)
{
return false;
}
///////////////////////////////////////////////////////////////////////////
//
// The function 'emit_line_directive' is called whenever a #line directive
// has to be emitted into the generated output.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'pending' may be used to push tokens back into the input
// stream, which are to be used instead of the default output generated
// for the #line directive.
//
// The parameter 'act_token' contains the actual #pragma token, which may
// be used for error output. The line number stored in this token can be
// used as the line number emitted as part of the #line directive.
//
// If the return value is 'false', a default #line directive is emitted
// by the library. A return value of 'true' will inhibit any further
// actions, the tokens contained in 'pending' will be copied verbatim
// to the output.
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT, typename ContainerT>
bool
emit_line_directive(ContextT const& ctx, ContainerT &pending,
typename ContextT::token_type const& act_token)
{
return false;
}
///////////////////////////////////////////////////////////////////////////
//
// The function 'defined_macro' is called, whenever a macro was defined
// successfully.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'name' is a reference to the token holding the macro name.
//
// The parameter 'is_functionlike' is set to true, whenever the newly
// defined macro is defined as a function like macro.
//
// The parameter 'parameters' holds the parameter tokens for the macro
// definition. If the macro has no parameters or if it is a object like
// macro, then this container is empty.
//
// The parameter 'definition' contains the token sequence given as the
// replacement sequence (definition part) of the newly defined macro.
//
// The parameter 'is_predefined' is set to true for all macros predefined
// during the initialization phase of the library.
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
template <typename TokenT, typename ParametersT, typename DefinitionT>
void
defined_macro(TokenT const& macro_name, bool is_functionlike,
ParametersT const& parameters, DefinitionT const& definition,
bool is_predefined)
{}
#else
// new signature
template <
typename ContextT, typename TokenT, typename ParametersT,
typename DefinitionT
>
void
defined_macro(ContextT const& ctx, TokenT const& macro_name,
bool is_functionlike, ParametersT const& parameters,
DefinitionT const& definition, bool is_predefined)
{}
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'undefined_macro' is called, whenever a macro definition
// was removed successfully.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'name' holds the name of the macro, which definition was
// removed.
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
template <typename TokenT>
void
undefined_macro(TokenT const& macro_name)
{}
#else
// new signature
template <typename ContextT, typename TokenT>
void
undefined_macro(ContextT const& ctx, TokenT const& macro_name)
{}
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'found_directive' is called, whenever a preprocessor
// directive was encountered, but before the corresponding action is
// executed.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'directive' is a reference to the token holding the
// preprocessing directive.
//
// The return value defines whether the given expression has to be
// to be executed in a normal way (return 'false'), or if it has to be
// skipped altogether (return 'true'), which means it gets replaced in the
// output by a single newline.
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
template <typename TokenT>
void
found_directive(TokenT const& directive)
{}
#else
// new signature
template <typename ContextT, typename TokenT>
bool
found_directive(ContextT const& ctx, TokenT const& directive)
{ return false; } // by default we never skip any directives
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'found_unknown_directive' is called, whenever an unknown
// preprocessor directive was encountered.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'line' holds the tokens of the entire source line
// containing the unknown directive.
//
// The parameter 'pending' may be used to push tokens back into the input
// stream, which are to be used as the replacement text for the whole
// line containing the unknown directive.
//
// The return value defines whether the given expression has been
// properly interpreted by the hook function or not. If this function
// returns 'false', the library will raise an 'ill_formed_directive'
// preprocess_exception. Otherwise the tokens pushed back into 'pending'
// are passed on to the user program.
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT, typename ContainerT>
bool
found_unknown_directive(ContextT const& ctx, ContainerT const& line,
ContainerT& pending)
{ return false; } // by default we never interpret unknown directives
///////////////////////////////////////////////////////////////////////////
//
// The function 'evaluated_conditional_expression' is called, whenever a
// conditional preprocessing expression was evaluated (the expression
// given to a #if, #elif, #ifdef or #ifndef directive)
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'directive' is a reference to the token holding the
// corresponding preprocessing directive.
//
// The parameter 'expression' holds the non-expanded token sequence
// comprising the evaluated expression.
//
// The parameter expression_value contains the result of the evaluation of
// the expression in the current preprocessing context.
//
// The return value defines whether the given expression has to be
// evaluated again, allowing to decide which of the conditional branches
// should be expanded. You need to return 'true' from this hook function
// to force the expression to be re-evaluated.
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
template <typename ContainerT>
void
evaluated_conditional_expression(ContainerT const& expression,
bool expression_value)
{}
#else
// new signature
template <typename ContextT, typename TokenT, typename ContainerT>
bool
evaluated_conditional_expression(ContextT const& ctx,
TokenT const& directive, ContainerT const& expression,
bool expression_value)
{ return false; } // ok to continue, do not re-evaluate expression
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'skipped_token' is called, whenever a token is about to be
// skipped due to a false preprocessor condition (code fragments to be
// skipped inside the not evaluated conditional #if/#else/#endif branches).
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'token' refers to the token to be skipped.
//
///////////////////////////////////////////////////////////////////////////
#if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0
// old signature
template <typename TokenT>
void
skipped_token(TokenT const& token)
{}
#else
// new signature
template <typename ContextT, typename TokenT>
void
skipped_token(ContextT const& ctx, TokenT const& token)
{}
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'generated_token' will be called by the library whenever a
// token is about to be returned from the library.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 't' is the token about to be returned from the library.
// This function may alter the token, but in this case it must be
// implemented with a corresponding signature:
//
// TokenT const&
// generated_token(ContextT const& ctx, TokenT& t);
//
// which makes it possible to modify the token in place.
//
// The default behavior is to return the token passed as the parameter
// without modification.
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT, typename TokenT>
TokenT const&
generated_token(ContextT const& ctx, TokenT const& t)
{ return t; }
///////////////////////////////////////////////////////////////////////////
//
// The function 'may_skip_whitespace' will be called by the
// library, whenever it must be tested whether a specific token refers to
// whitespace and this whitespace has to be skipped.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The 'token' parameter holds a reference to the current token. The policy
// is free to change this token if needed.
//
// The 'skipped_newline' parameter holds a reference to a boolean value
// which should be set to true by the policy function whenever a newline
// is going to be skipped.
//
// If the return value is true, the given token is skipped and the
// preprocessing continues to the next token. If the return value is
// false, the given token is returned to the calling application.
//
// ATTENTION!
// Caution has to be used, because by returning true the policy function
// is able to force skipping even significant tokens, not only whitespace.
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT, typename TokenT>
bool
may_skip_whitespace(ContextT const& ctx, TokenT& token, bool& skipped_newline)
{ return false; }
#if BOOST_WAVE_SUPPORT_WARNING_DIRECTIVE != 0
///////////////////////////////////////////////////////////////////////////
//
// The function 'found_warning_directive' will be called by the library
// whenever a #warning directive is found.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'message' references the argument token sequence of the
// encountered #warning directive.
//
// If the return value is false, the library throws a preprocessor
// exception of the type 'warning_directive', if the return value is true
// the execution continues as if no #warning directive has been found.
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT, typename ContainerT>
bool
found_warning_directive(ContextT const& ctx, ContainerT const& message)
{ return false; }
#endif
///////////////////////////////////////////////////////////////////////////
//
// The function 'found_error_directive' will be called by the library
// whenever a #error directive is found.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'message' references the argument token sequence of the
// encountered #error directive.
//
// If the return value is false, the library throws a preprocessor
// exception of the type 'error_directive', if the return value is true
// the execution continues as if no #error directive has been found.
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT, typename ContainerT>
bool
found_error_directive(ContextT const& ctx, ContainerT const& message)
{ return false; }
///////////////////////////////////////////////////////////////////////////
//
// The function 'found_line_directive' will be called by the library
// whenever a #line directive is found.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'arguments' references the argument token sequence of the
// encountered #line directive.
//
// The parameter 'line' contains the recognized line number from the #line
// directive.
//
// The parameter 'filename' references the recognized file name from the
// #line directive (if there was one given).
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT, typename ContainerT>
void
found_line_directive(ContextT const& ctx, ContainerT const& arguments,
unsigned int line, std::string const& filename)
{}
///////////////////////////////////////////////////////////////////////////
//
// The function 'throw_exception' will be called by the library whenever a
// preprocessing exception occurs.
//
// The parameter 'ctx' is a reference to the context object used for
// instantiating the preprocessing iterators by the user.
//
// The parameter 'e' is the exception object containing detailed error
// information.
//
// The default behavior is to call the function boost::throw_exception.
//
///////////////////////////////////////////////////////////////////////////
template <typename ContextT, typename ExceptionT>
void
throw_exception(ContextT const& ctx, ExceptionT const& e)
{
boost::throw_exception(e);
}
};
///////////////////////////////////////////////////////////////////////////////
} // namespace context_policies
} // namespace wave
} // namespace boost
// the suffix header occurs after all of the code
#ifdef BOOST_HAS_ABI_HEADERS
#include BOOST_ABI_SUFFIX
#endif
#endif // !defined(DEFAULT_PREPROCESSING_HOOKS_HPP_INCLUDED)