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view DEPENDENCIES/generic/include/boost/wave/util/cpp_iterator.hpp @ 75:a76b96026c2d
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| author | Chris Cannam |
|---|---|
| date | Thu, 30 Oct 2014 13:25:15 +0000 |
| parents | 2665513ce2d3 |
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/*============================================================================= Boost.Wave: A Standard compliant C++ preprocessor library Definition of the preprocessor iterator 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(CPP_ITERATOR_HPP_175CA88F_7273_43FA_9039_BCF7459E1F29_INCLUDED) #define CPP_ITERATOR_HPP_175CA88F_7273_43FA_9039_BCF7459E1F29_INCLUDED #include <string> #include <vector> #include <list> #include <cstdlib> #include <cctype> #include <boost/assert.hpp> #include <boost/shared_ptr.hpp> #include <boost/filesystem/path.hpp> #include <boost/filesystem/operations.hpp> #include <boost/spirit/include/classic_multi_pass.hpp> #include <boost/spirit/include/classic_parse_tree_utils.hpp> #include <boost/wave/wave_config.hpp> #include <boost/pool/pool_alloc.hpp> #include <boost/wave/util/insert_whitespace_detection.hpp> #include <boost/wave/util/macro_helpers.hpp> #include <boost/wave/util/cpp_macromap_utils.hpp> #include <boost/wave/util/interpret_pragma.hpp> #include <boost/wave/util/transform_iterator.hpp> #include <boost/wave/util/functor_input.hpp> #include <boost/wave/util/filesystem_compatibility.hpp> #include <boost/wave/grammars/cpp_grammar_gen.hpp> #include <boost/wave/grammars/cpp_expression_grammar_gen.hpp> #if BOOST_WAVE_ENABLE_COMMANDLINE_MACROS != 0 #include <boost/wave/grammars/cpp_predef_macros_gen.hpp> #endif #include <boost/wave/whitespace_handling.hpp> #include <boost/wave/cpp_iteration_context.hpp> #include <boost/wave/cpp_exceptions.hpp> #include <boost/wave/language_support.hpp> // 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 util { /////////////////////////////////////////////////////////////////////////////// // retrieve the macro name from the parse tree template < typename ContextT, typename ParseNodeT, typename TokenT, typename PositionT > inline bool retrieve_macroname(ContextT& ctx, ParseNodeT const &node, boost::spirit::classic::parser_id id, TokenT ¯oname, PositionT& act_pos, bool update_position) { ParseNodeT const *name_node = 0; using boost::spirit::classic::find_node; if (!find_node(node, id, &name_node)) { // ill formed define statement (unexpected, should not happen) BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_define_statement, "bad parse tree (unexpected)", act_pos); return false; } typename ParseNodeT::children_t const &children = name_node->children; if (0 == children.size() || children.front().value.begin() == children.front().value.end()) { // ill formed define statement (unexpected, should not happen) BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_define_statement, "bad parse tree (unexpected)", act_pos); return false; } // retrieve the macro name macroname = *children.front().value.begin(); if (update_position) { macroname.set_position(act_pos); act_pos.set_column(act_pos.get_column() + macroname.get_value().size()); } return true; } /////////////////////////////////////////////////////////////////////////////// // retrieve the macro parameters or the macro definition from the parse tree template <typename ParseNodeT, typename ContainerT, typename PositionT> inline bool retrieve_macrodefinition( ParseNodeT const &node, boost::spirit::classic::parser_id id, ContainerT ¯odefinition, PositionT& act_pos, bool update_position) { using namespace boost::wave; typedef typename ParseNodeT::const_tree_iterator const_tree_iterator; // find macro parameters/macro definition inside the parse tree std::pair<const_tree_iterator, const_tree_iterator> nodes; using boost::spirit::classic::get_node_range; if (get_node_range(node, id, nodes)) { // copy all parameters to the supplied container typename ContainerT::iterator last_nonwhite = macrodefinition.end(); const_tree_iterator end = nodes.second; for (const_tree_iterator cit = nodes.first; cit != end; ++cit) { if ((*cit).value.begin() != (*cit).value.end()) { typename ContainerT::iterator inserted = macrodefinition.insert( macrodefinition.end(), *(*cit).value.begin()); if (!IS_CATEGORY(macrodefinition.back(), WhiteSpaceTokenType) && T_NEWLINE != token_id(macrodefinition.back()) && T_EOF != token_id(macrodefinition.back())) { last_nonwhite = inserted; } if (update_position) { (*inserted).set_position(act_pos); act_pos.set_column( act_pos.get_column() + (*inserted).get_value().size()); } } } // trim trailing whitespace (leading whitespace is trimmed by the grammar) if (last_nonwhite != macrodefinition.end()) { if (update_position) { act_pos.set_column((*last_nonwhite).get_position().get_column() + (*last_nonwhite).get_value().size()); } macrodefinition.erase(++last_nonwhite, macrodefinition.end()); } return true; } return false; } #if BOOST_WAVE_ENABLE_COMMANDLINE_MACROS != 0 /////////////////////////////////////////////////////////////////////////////// // add an additional predefined macro given by a string (MACRO(x)=definition) template <typename ContextT> bool add_macro_definition(ContextT &ctx, std::string macrostring, bool is_predefined, boost::wave::language_support language) { typedef typename ContextT::token_type token_type; typedef typename ContextT::lexer_type lexer_type; typedef typename token_type::position_type position_type; typedef boost::wave::grammars::predefined_macros_grammar_gen<lexer_type> predef_macros_type; using namespace boost::wave; using namespace std; // isspace is in std namespace for some systems // skip leading whitespace std::string::iterator begin = macrostring.begin(); std::string::iterator end = macrostring.end(); while(begin != end && isspace(*begin)) ++begin; // parse the macro definition position_type act_pos("<command line>"); boost::spirit::classic::tree_parse_info<lexer_type> hit = predef_macros_type::parse_predefined_macro( lexer_type(begin, end, position_type(), language), lexer_type()); if (!hit.match || (!hit.full && T_EOF != token_id(*hit.stop))) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_macro_definition, macrostring.c_str(), act_pos); return false; } // retrieve the macro definition from the parse tree token_type macroname; std::vector<token_type> macroparameters; typename ContextT::token_sequence_type macrodefinition; bool has_parameters = false; if (!boost::wave::util::retrieve_macroname(ctx, *hit.trees.begin(), BOOST_WAVE_PLAIN_DEFINE_ID, macroname, act_pos, true)) return false; has_parameters = boost::wave::util::retrieve_macrodefinition(*hit.trees.begin(), BOOST_WAVE_MACRO_PARAMETERS_ID, macroparameters, act_pos, true); boost::wave::util::retrieve_macrodefinition(*hit.trees.begin(), BOOST_WAVE_MACRO_DEFINITION_ID, macrodefinition, act_pos, true); // get rid of trailing T_EOF if (!macrodefinition.empty() && token_id(macrodefinition.back()) == T_EOF) macrodefinition.pop_back(); // If no macrodefinition is given, and the macro string does not end with a // '=', then the macro should be defined with the value '1' if (macrodefinition.empty() && '=' != macrostring[macrostring.size()-1]) macrodefinition.push_back(token_type(T_INTLIT, "1", act_pos)); // add the new macro to the macromap return ctx.add_macro_definition(macroname, has_parameters, macroparameters, macrodefinition, is_predefined); } #endif // BOOST_WAVE_ENABLE_COMMANDLINE_MACROS != 0 /////////////////////////////////////////////////////////////////////////////// } // namespace util /////////////////////////////////////////////////////////////////////////////// // forward declaration template <typename ContextT> class pp_iterator; namespace impl { /////////////////////////////////////////////////////////////////////////////// // // pp_iterator_functor // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> class pp_iterator_functor { public: // interface to the boost::spirit::classic::iterator_policies::functor_input policy typedef typename ContextT::token_type result_type; // eof token static result_type const eof; private: // type of a token sequence typedef typename ContextT::token_sequence_type token_sequence_type; typedef typename ContextT::lexer_type lexer_type; typedef typename result_type::string_type string_type; typedef typename result_type::position_type position_type; typedef boost::wave::grammars::cpp_grammar_gen<lexer_type, token_sequence_type> cpp_grammar_type; // iteration context related types (an iteration context represents a current // position in an included file) typedef base_iteration_context<ContextT, lexer_type> base_iteration_context_type; typedef iteration_context<ContextT, lexer_type> iteration_context_type; // parse tree related types typedef typename cpp_grammar_type::node_factory_type node_factory_type; typedef boost::spirit::classic::tree_parse_info<lexer_type, node_factory_type> tree_parse_info_type; typedef boost::spirit::classic::tree_match<lexer_type, node_factory_type> parse_tree_match_type; typedef typename parse_tree_match_type::node_t parse_node_type; // tree_node<node_val_data<> > typedef typename parse_tree_match_type::parse_node_t parse_node_value_type; // node_val_data<> typedef typename parse_tree_match_type::container_t parse_tree_type; // parse_node_type::children_t public: template <typename IteratorT> pp_iterator_functor(ContextT &ctx_, IteratorT const &first_, IteratorT const &last_, typename ContextT::position_type const &pos_) : ctx(ctx_), iter_ctx(new base_iteration_context_type(ctx, lexer_type(first_, last_, pos_, boost::wave::enable_prefer_pp_numbers(ctx.get_language())), lexer_type(), pos_.get_file().c_str() )), seen_newline(true), skipped_newline(false), must_emit_line_directive(false), act_pos(ctx_.get_main_pos()), whitespace(boost::wave::need_insert_whitespace(ctx.get_language())) { act_pos.set_file(pos_.get_file()); #if BOOST_WAVE_SUPPORT_PRAGMA_ONCE != 0 ctx_.set_current_filename(pos_.get_file().c_str()); #endif iter_ctx->emitted_lines = (unsigned int)(-1); // force #line directive } // get the next preprocessed token result_type const &operator()(); // get the last recognized token (for error processing etc.) result_type const ¤t_token() const { return act_token; } protected: friend class pp_iterator<ContextT>; bool on_include_helper(char const *t, char const *s, bool is_system, bool include_next); protected: result_type const &get_next_token(); result_type const &pp_token(); template <typename IteratorT> bool extract_identifier(IteratorT &it); template <typename IteratorT> bool ensure_is_last_on_line(IteratorT& it, bool call_hook = true); template <typename IteratorT> bool skip_to_eol_with_check(IteratorT &it, bool call_hook = true); bool pp_directive(); template <typename IteratorT> bool handle_pp_directive(IteratorT &it); bool dispatch_directive(tree_parse_info_type const &hit, result_type const& found_directive, token_sequence_type const& found_eoltokens); void replace_undefined_identifiers(token_sequence_type &expanded); void on_include(string_type const &s, bool is_system, bool include_next); void on_include(typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end, bool include_next); void on_define(parse_node_type const &node); void on_undefine(lexer_type const &it); void on_ifdef(result_type const& found_directive, lexer_type const &it); // typename parse_tree_type::const_iterator const &end); void on_ifndef(result_type const& found_directive, lexer_type const& it); // typename parse_tree_type::const_iterator const &end); void on_else(); void on_endif(); void on_illformed(typename result_type::string_type s); void on_line(typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end); void on_if(result_type const& found_directive, typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end); void on_elif(result_type const& found_directive, typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end); void on_error(typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end); #if BOOST_WAVE_SUPPORT_WARNING_DIRECTIVE != 0 void on_warning(typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end); #endif bool on_pragma(typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end); bool emit_line_directive(); bool returned_from_include(); bool interpret_pragma(token_sequence_type const &pragma_body, token_sequence_type &result); private: ContextT &ctx; // context, this iterator is associated with boost::shared_ptr<base_iteration_context_type> iter_ctx; bool seen_newline; // needed for recognizing begin of line bool skipped_newline; // a newline has been skipped since last one bool must_emit_line_directive; // must emit a line directive result_type act_token; // current token typename result_type::position_type &act_pos; // current fileposition (references the macromap) token_sequence_type unput_queue; // tokens to be preprocessed again token_sequence_type pending_queue; // tokens already preprocessed // detect whether to insert additional whitespace in between two adjacent // tokens, which otherwise would form a different token type, if // re-tokenized boost::wave::util::insert_whitespace_detection whitespace; }; /////////////////////////////////////////////////////////////////////////////// // eof token template <typename ContextT> typename pp_iterator_functor<ContextT>::result_type const pp_iterator_functor<ContextT>::eof; /////////////////////////////////////////////////////////////////////////////// // // returned_from_include() // // Tests if it is necessary to pop the include file context (eof inside // a file was reached). If yes, it pops this context. Preprocessing will // continue with the next outer file scope. // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline bool pp_iterator_functor<ContextT>::returned_from_include() { if (iter_ctx->first == iter_ctx->last && ctx.get_iteration_depth() > 0) { // call the include policy trace function #if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0 ctx.get_hooks().returning_from_include_file(); #else ctx.get_hooks().returning_from_include_file(ctx.derived()); #endif // restore the previous iteration context after finishing the preprocessing // of the included file BOOST_WAVE_STRINGTYPE oldfile = iter_ctx->real_filename; position_type old_pos (act_pos); // if this file has include guards handle it as if it had a #pragma once #if BOOST_WAVE_SUPPORT_PRAGMA_ONCE != 0 if (need_include_guard_detection(ctx.get_language())) { std::string guard_name; if (iter_ctx->first.has_include_guards(guard_name)) ctx.add_pragma_once_header(ctx.get_current_filename(), guard_name); } #endif iter_ctx = ctx.pop_iteration_context(); must_emit_line_directive = true; iter_ctx->emitted_lines = (unsigned int)(-1); // force #line directive seen_newline = true; // restore current file position act_pos.set_file(iter_ctx->filename); act_pos.set_line(iter_ctx->line); act_pos.set_column(0); // restore the actual current file and directory #if BOOST_WAVE_SUPPORT_PRAGMA_ONCE != 0 namespace fs = boost::filesystem; fs::path rfp(wave::util::create_path(iter_ctx->real_filename.c_str())); std::string real_filename(rfp.string()); ctx.set_current_filename(real_filename.c_str()); #endif ctx.set_current_directory(iter_ctx->real_filename.c_str()); ctx.set_current_relative_filename(iter_ctx->real_relative_filename.c_str()); // ensure the integrity of the #if/#endif stack // report unbalanced #if/#endif now to make it possible to recover properly if (iter_ctx->if_block_depth != ctx.get_if_block_depth()) { using boost::wave::util::impl::escape_lit; BOOST_WAVE_STRINGTYPE msg(escape_lit(oldfile)); BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, unbalanced_if_endif, msg.c_str(), old_pos); } return true; } return false; } /////////////////////////////////////////////////////////////////////////////// // // operator()(): get the next preprocessed token // // throws a preprocess_exception, if appropriate // /////////////////////////////////////////////////////////////////////////////// namespace impl { // It may be necessary to emit a #line directive either // - when comments need to be preserved: if the current token is not a // whitespace, except comments // - when comments are to be skipped: if the current token is not a // whitespace token. template <typename ContextT> bool consider_emitting_line_directive(ContextT const& ctx, token_id id) { if (need_preserve_comments(ctx.get_language())) { if (!IS_CATEGORY(id, EOLTokenType) && !IS_CATEGORY(id, EOFTokenType)) { return true; } } if (!IS_CATEGORY(id, WhiteSpaceTokenType) && !IS_CATEGORY(id, EOLTokenType) && !IS_CATEGORY(id, EOFTokenType)) { return true; } return false; } } template <typename ContextT> inline typename pp_iterator_functor<ContextT>::result_type const & pp_iterator_functor<ContextT>::operator()() { using namespace boost::wave; // make sure the cwd has been initialized ctx.init_context(); // loop over skip able whitespace until something significant is found bool was_seen_newline = seen_newline; bool was_skipped_newline = skipped_newline; token_id id = T_UNKNOWN; try { // catch lexer exceptions do { if (skipped_newline) { was_skipped_newline = true; skipped_newline = false; } // get_next_token assigns result to act_token member get_next_token(); // if comments shouldn't be preserved replace them with newlines id = token_id(act_token); if (!need_preserve_comments(ctx.get_language()) && (T_CPPCOMMENT == id || context_policies::util::ccomment_has_newline(act_token))) { act_token.set_token_id(id = T_NEWLINE); act_token.set_value("\n"); } if (IS_CATEGORY(id, EOLTokenType)) seen_newline = true; } while (ctx.get_hooks().may_skip_whitespace(ctx.derived(), act_token, skipped_newline)); } catch (boost::wave::cpplexer::lexing_exception const& e) { // dispatch any lexer exceptions to the context hook function ctx.get_hooks().throw_exception(ctx.derived(), e); return act_token; } // restore the accumulated skipped_newline state for next invocation if (was_skipped_newline) skipped_newline = true; // if there were skipped any newlines, we must emit a #line directive if ((must_emit_line_directive || (was_seen_newline && skipped_newline)) && impl::consider_emitting_line_directive(ctx, id)) { // must emit a #line directive if (need_emit_line_directives(ctx.get_language()) && emit_line_directive()) { skipped_newline = false; ctx.get_hooks().may_skip_whitespace(ctx.derived(), act_token, skipped_newline); // feed ws eater FSM id = token_id(act_token); } } // cleanup of certain tokens required seen_newline = false; switch (static_cast<unsigned int>(id)) { case T_NONREPLACABLE_IDENTIFIER: act_token.set_token_id(id = T_IDENTIFIER); break; case T_GENERATEDNEWLINE: // was generated by emit_line_directive() act_token.set_token_id(id = T_NEWLINE); ++iter_ctx->emitted_lines; seen_newline = true; break; case T_NEWLINE: case T_CPPCOMMENT: seen_newline = true; ++iter_ctx->emitted_lines; break; #if BOOST_WAVE_SUPPORT_CPP0X != 0 case T_RAWSTRINGLIT: iter_ctx->emitted_lines += context_policies::util::rawstring_count_newlines(act_token); break; #endif case T_CCOMMENT: // will come here only if whitespace is preserved iter_ctx->emitted_lines += context_policies::util::ccomment_count_newlines(act_token); break; case T_PP_NUMBER: // re-tokenize the pp-number { token_sequence_type rescanned; std::string pp_number( util::to_string<std::string>(act_token.get_value())); lexer_type it = lexer_type(pp_number.begin(), pp_number.end(), act_token.get_position(), ctx.get_language()); lexer_type end = lexer_type(); for (/**/; it != end && T_EOF != token_id(*it); ++it) rescanned.push_back(*it); pending_queue.splice(pending_queue.begin(), rescanned); act_token = pending_queue.front(); id = token_id(act_token); pending_queue.pop_front(); } break; case T_EOF: seen_newline = true; break; default: // make sure whitespace at line begin keeps seen_newline status if (IS_CATEGORY(id, WhiteSpaceTokenType)) seen_newline = was_seen_newline; break; } if (whitespace.must_insert(id, act_token.get_value())) { // must insert some whitespace into the output stream to avoid adjacent // tokens, which would form different (and wrong) tokens whitespace.shift_tokens(T_SPACE); pending_queue.push_front(act_token); // push this token back return act_token = result_type(T_SPACE, typename result_type::string_type(" "), act_token.get_position()); } whitespace.shift_tokens(id); return ctx.get_hooks().generated_token(ctx.derived(), act_token); } /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline typename pp_iterator_functor<ContextT>::result_type const & pp_iterator_functor<ContextT>::get_next_token() { using namespace boost::wave; // if there is something in the unput_queue, then return the next token from // there (all tokens in the queue are preprocessed already) if (!pending_queue.empty() || !unput_queue.empty()) return pp_token(); // return next token // test for EOF, if there is a pending input context, pop it back and continue // parsing with it bool returned_from_include_file = returned_from_include(); // try to generate the next token if (iter_ctx->first != iter_ctx->last) { do { // If there are pending tokens in the queue, we'll have to return // these. This may happen from a #pragma directive, which got replaced // by some token sequence. if (!pending_queue.empty()) { util::on_exit::pop_front<token_sequence_type> pop_front_token(pending_queue); return act_token = pending_queue.front(); } // adjust the current position (line and column) bool was_seen_newline = seen_newline || returned_from_include_file; // fetch the current token act_token = *iter_ctx->first; act_pos = act_token.get_position(); // act accordingly on the current token token_id id = token_id(act_token); if (T_EOF == id) { // returned from an include file, continue with the next token whitespace.shift_tokens(T_EOF); ++iter_ctx->first; // now make sure this line has a newline if ((!seen_newline || act_pos.get_column() > 1) && !need_single_line(ctx.get_language())) { // warn, if this file does not end with a newline BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, last_line_not_terminated, "", act_pos); } continue; // if this is the main file, the while loop breaks } else if (T_NEWLINE == id || T_CPPCOMMENT == id) { // a newline is to be returned ASAP, a C++ comment too // (the C++ comment token includes the trailing newline) seen_newline = true; ++iter_ctx->first; if (!ctx.get_if_block_status()) { // skip this token because of the disabled #if block whitespace.shift_tokens(id); // whitespace controller util::impl::call_skipped_token_hook(ctx, act_token); continue; } return act_token; } seen_newline = false; if (was_seen_newline && pp_directive()) { // a pp directive was found // pending_queue.push_back(result_type(T_NEWLINE, "\n", act_pos)); // seen_newline = true; // must_emit_line_directive = true; // loop to the next token to analyze // simply fall through, since the iterator was already adjusted // correctly } else if (ctx.get_if_block_status()) { // preprocess this token, eat up more, if appropriate, return // the next preprocessed token return pp_token(); } else { // compilation condition is false: if the current token is a // newline, account for it, otherwise discard the actual token and // try the next one if (T_NEWLINE == token_id(act_token)) { seen_newline = true; must_emit_line_directive = true; } // next token util::impl::call_skipped_token_hook(ctx, act_token); ++iter_ctx->first; } } while ((iter_ctx->first != iter_ctx->last) || (returned_from_include_file = returned_from_include())); // overall eof reached if (ctx.get_if_block_depth() > 0 && !need_single_line(ctx.get_language())) { // missing endif directive(s) BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, missing_matching_endif, "", act_pos); } } else { act_token = eof; // this is the last token } // whitespace.shift_tokens(T_EOF); // whitespace controller return act_token; // return eof token } /////////////////////////////////////////////////////////////////////////////// // // emit_line_directive(): emits a line directive from the act_token data // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline bool pp_iterator_functor<ContextT>::emit_line_directive() { using namespace boost::wave; typename ContextT::position_type pos = act_token.get_position(); // if (must_emit_line_directive && // iter_ctx->emitted_lines+1 == act_pos.get_line() && // iter_ctx->filename == act_pos.get_file()) // { // must_emit_line_directive = false; // return false; // } if (must_emit_line_directive || iter_ctx->emitted_lines+1 != act_pos.get_line()) { // unput the current token pending_queue.push_front(act_token); pos.set_line(act_pos.get_line()); if (iter_ctx->emitted_lines+2 == act_pos.get_line() && act_pos.get_line() != 1) { // prefer to output a single newline instead of the #line directive // whitespace.shift_tokens(T_NEWLINE); act_token = result_type(T_NEWLINE, "\n", pos); } else { // account for the newline emitted here act_pos.set_line(act_pos.get_line()-1); iter_ctx->emitted_lines = act_pos.get_line()-1; token_sequence_type pending; if (!ctx.get_hooks().emit_line_directive(ctx, pending, act_token)) { unsigned int column = 6; // the hook did not generate anything, emit default #line pos.set_column(1); pending.push_back(result_type(T_PP_LINE, "#line", pos)); pos.set_column(column); // account for '#line' pending.push_back(result_type(T_SPACE, " ", pos)); // 21 is the max required size for a 64 bit integer represented as a // string char buffer[22]; using namespace std; // for some systems sprintf is in namespace std sprintf (buffer, "%ld", pos.get_line()); pos.set_column(++column); // account for ' ' pending.push_back(result_type(T_INTLIT, buffer, pos)); pos.set_column(column += (unsigned int)strlen(buffer)); // account for <number> pending.push_back(result_type(T_SPACE, " ", pos)); pos.set_column(++column); // account for ' ' std::string file("\""); boost::filesystem::path filename( wave::util::create_path(act_pos.get_file().c_str())); using wave::util::impl::escape_lit; file += escape_lit(wave::util::native_file_string(filename)) + "\""; pending.push_back(result_type(T_STRINGLIT, file.c_str(), pos)); pos.set_column(column += (unsigned int)file.size()); // account for filename pending.push_back(result_type(T_GENERATEDNEWLINE, "\n", pos)); } // if there is some replacement text, insert it into the pending queue if (!pending.empty()) { pending_queue.splice(pending_queue.begin(), pending); act_token = pending_queue.front(); pending_queue.pop_front(); } } must_emit_line_directive = false; // we are now in sync return true; } must_emit_line_directive = false; // we are now in sync return false; } /////////////////////////////////////////////////////////////////////////////// // // pptoken(): return the next preprocessed token // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline typename pp_iterator_functor<ContextT>::result_type const & pp_iterator_functor<ContextT>::pp_token() { using namespace boost::wave; token_id id = token_id(*iter_ctx->first); // eat all T_PLACEHOLDER tokens, eventually slipped through out of the // macro engine do { if (!pending_queue.empty()) { // if there are pending tokens in the queue, return the first one act_token = pending_queue.front(); pending_queue.pop_front(); act_pos = act_token.get_position(); } else if (!unput_queue.empty() || T_IDENTIFIER == id || IS_CATEGORY(id, KeywordTokenType) || IS_EXTCATEGORY(id, OperatorTokenType|AltExtTokenType) || IS_CATEGORY(id, BoolLiteralTokenType)) { // call the lexer, preprocess the required number of tokens, put them // into the unput queue act_token = ctx.expand_tokensequence(iter_ctx->first, iter_ctx->last, pending_queue, unput_queue, skipped_newline); } else { // simply return the next token act_token = *iter_ctx->first; ++iter_ctx->first; } id = token_id(act_token); } while (T_PLACEHOLDER == id); return act_token; } /////////////////////////////////////////////////////////////////////////////// // // pp_directive(): recognize a preprocessor directive // /////////////////////////////////////////////////////////////////////////////// namespace impl { // call 'found_directive' preprocessing hook template <typename ContextT> bool call_found_directive_hook(ContextT& ctx, typename ContextT::token_type const& found_directive) { #if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0 ctx.get_hooks().found_directive(found_directive); #else if (ctx.get_hooks().found_directive(ctx.derived(), found_directive)) return true; // skip this directive and return newline only #endif return false; } // // call 'skipped_token' preprocessing hook // template <typename ContextT> // void call_skipped_token_hook(ContextT& ctx, // typename ContextT::token_type const& skipped) // { // #if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0 // ctx.get_hooks().skipped_token(skipped); // #else // ctx.get_hooks().skipped_token(ctx.derived(), skipped); // #endif // } template <typename ContextT, typename IteratorT> bool next_token_is_pp_directive(ContextT &ctx, IteratorT &it, IteratorT const &end) { using namespace boost::wave; token_id id = T_UNKNOWN; for (/**/; it != end; ++it) { id = token_id(*it); if (!IS_CATEGORY(id, WhiteSpaceTokenType)) break; // skip leading whitespace if (IS_CATEGORY(id, EOLTokenType) || IS_CATEGORY(id, EOFTokenType)) break; // do not enter a new line if (T_CPPCOMMENT == id || context_policies::util::ccomment_has_newline(*it)) { break; } // this token gets skipped util::impl::call_skipped_token_hook(ctx, *it); } BOOST_ASSERT(it == end || id != T_UNKNOWN); return it != end && IS_CATEGORY(id, PPTokenType); } // verify that there isn't anything significant left on the line template <typename ContextT, typename IteratorT> bool pp_is_last_on_line(ContextT &ctx, IteratorT &it, IteratorT const &end, bool call_hook = true) { using namespace boost::wave; // this token gets skipped if (call_hook) util::impl::call_skipped_token_hook(ctx, *it); for (++it; it != end; ++it) { token_id id = token_id(*it); if (T_CPPCOMMENT == id || T_NEWLINE == id || context_policies::util::ccomment_has_newline(*it)) { if (call_hook) util::impl::call_skipped_token_hook(ctx, *it); ++it; // skip eol/C/C++ comment return true; // no more significant tokens on this line } if (!IS_CATEGORY(id, WhiteSpaceTokenType)) break; // this token gets skipped if (call_hook) util::impl::call_skipped_token_hook(ctx, *it); } return false; } /////////////////////////////////////////////////////////////////////////// template <typename ContextT, typename IteratorT> bool skip_to_eol(ContextT &ctx, IteratorT &it, IteratorT const &end, bool call_hook = true) { using namespace boost::wave; for (/**/; it != end; ++it) { token_id id = token_id(*it); if (T_CPPCOMMENT == id || T_NEWLINE == id || context_policies::util::ccomment_has_newline(*it)) { // always call hook for eol util::impl::call_skipped_token_hook(ctx, *it); ++it; // skip eol/C/C++ comment return true; // found eol } if (call_hook) util::impl::call_skipped_token_hook(ctx, *it); } return false; } /////////////////////////////////////////////////////////////////////////// template <typename ContextT, typename ContainerT> inline void remove_leading_whitespace(ContextT &ctx, ContainerT& c, bool call_hook = true) { typename ContainerT::iterator it = c.begin(); while (IS_CATEGORY(*it, WhiteSpaceTokenType)) { typename ContainerT::iterator save = it++; if (call_hook) util::impl::call_skipped_token_hook(ctx, *save); c.erase(save); } } } /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> template <typename IteratorT> inline bool pp_iterator_functor<ContextT>::extract_identifier(IteratorT &it) { token_id id = util::impl::skip_whitespace(it, iter_ctx->last); if (T_IDENTIFIER == id || IS_CATEGORY(id, KeywordTokenType) || IS_EXTCATEGORY(id, OperatorTokenType|AltExtTokenType) || IS_CATEGORY(id, BoolLiteralTokenType)) { IteratorT save = it; if (impl::pp_is_last_on_line(ctx, save, iter_ctx->last, false)) return true; } // report the ill formed directive impl::skip_to_eol(ctx, it, iter_ctx->last); string_type str(util::impl::as_string<string_type>(iter_ctx->first, it)); seen_newline = true; iter_ctx->first = it; on_illformed(str); return false; } /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> template <typename IteratorT> inline bool pp_iterator_functor<ContextT>::ensure_is_last_on_line(IteratorT& it, bool call_hook) { if (!impl::pp_is_last_on_line(ctx, it, iter_ctx->last, call_hook)) { // enable error recovery (start over with the next line) impl::skip_to_eol(ctx, it, iter_ctx->last); string_type str(util::impl::as_string<string_type>( iter_ctx->first, it)); seen_newline = true; iter_ctx->first = it; // report an invalid directive on_illformed(str); return false; } if (it == iter_ctx->last && !need_single_line(ctx.get_language())) { // The line doesn't end with an eol but eof token. seen_newline = true; // allow to resume after warning iter_ctx->first = it; // Trigger a warning that the last line was not terminated with a // newline. BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, last_line_not_terminated, "", act_pos); return false; } return true; } template <typename ContextT> template <typename IteratorT> inline bool pp_iterator_functor<ContextT>::skip_to_eol_with_check(IteratorT &it, bool call_hook) { typename ContextT::string_type value ((*it).get_value()); if (!impl::skip_to_eol(ctx, it, iter_ctx->last, call_hook) && !need_single_line(ctx.get_language())) { // The line doesn't end with an eol but eof token. seen_newline = true; // allow to resume after warning iter_ctx->first = it; // Trigger a warning, that the last line was not terminated with a // newline. BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, last_line_not_terminated, "", act_pos); return false; } // normal line ending reached, adjust iterator and flag seen_newline = true; iter_ctx->first = it; return true; } /////////////////////////////////////////////////////////////////////////////// // handle_pp_directive: handle certain pp_directives template <typename ContextT> template <typename IteratorT> inline bool pp_iterator_functor<ContextT>::handle_pp_directive(IteratorT &it) { token_id id = token_id(*it); bool can_exit = true; bool call_hook_in_skip = true; if (!ctx.get_if_block_status()) { if (IS_EXTCATEGORY(*it, PPConditionalTokenType)) { // simulate the if block hierarchy switch (static_cast<unsigned int>(id)) { case T_PP_IFDEF: // #ifdef case T_PP_IFNDEF: // #ifndef case T_PP_IF: // #if ctx.enter_if_block(false); break; case T_PP_ELIF: // #elif if (!ctx.get_enclosing_if_block_status()) { if (!ctx.enter_elif_block(false)) { // #else without matching #if BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, missing_matching_if, "#elif", act_pos); return true; // do not analyze this directive any further } } else { can_exit = false; // #elif is not always safe to skip } break; case T_PP_ELSE: // #else case T_PP_ENDIF: // #endif { // handle this directive if (T_PP_ELSE == token_id(*it)) on_else(); else on_endif(); // make sure, there are no (non-whitespace) tokens left on // this line ensure_is_last_on_line(it); // we skipped to the end of this line already seen_newline = true; iter_ctx->first = it; } return true; default: // #something else on_illformed((*it).get_value()); break; } } else { util::impl::call_skipped_token_hook(ctx, *it); ++it; } } else { // try to handle the simple pp directives without parsing result_type directive = *it; bool include_next = false; switch (static_cast<unsigned int>(id)) { case T_PP_QHEADER: // #include "..." #if BOOST_WAVE_SUPPORT_INCLUDE_NEXT != 0 case T_PP_QHEADER_NEXT: #endif include_next = (T_PP_QHEADER_NEXT == id) ? true : false; if (!impl::call_found_directive_hook(ctx, *it)) { string_type dir((*it).get_value()); // make sure, there are no (non-whitespace) tokens left on // this line if (ensure_is_last_on_line(it)) { seen_newline = true; iter_ctx->first = it; on_include (dir, false, include_next); } return true; } break; case T_PP_HHEADER: // #include <...> #if BOOST_WAVE_SUPPORT_INCLUDE_NEXT != 0 case T_PP_HHEADER_NEXT: #endif include_next = (T_PP_HHEADER_NEXT == id) ? true : false; if (!impl::call_found_directive_hook(ctx, *it)) { string_type dir((*it).get_value()); // make sure, there are no (non-whitespace) tokens left on // this line if (ensure_is_last_on_line(it)) { seen_newline = true; iter_ctx->first = it; on_include (dir, true, include_next); } return true; } break; case T_PP_ELSE: // #else case T_PP_ENDIF: // #endif if (!impl::call_found_directive_hook(ctx, *it)) { // handle this directive if (T_PP_ELSE == token_id(*it)) on_else(); else on_endif(); // make sure, there are no (non-whitespace) tokens left on // this line ensure_is_last_on_line(it); // we skipped to the end of this line already seen_newline = true; iter_ctx->first = it; return true; } break; // extract everything on this line as arguments // case T_PP_IF: // #if // case T_PP_ELIF: // #elif // case T_PP_ERROR: // #error // case T_PP_WARNING: // #warning // case T_PP_PRAGMA: // #pragma // case T_PP_LINE: // #line // break; // extract first non-whitespace token as argument case T_PP_UNDEF: // #undef if (!impl::call_found_directive_hook(ctx, *it) && extract_identifier(it)) { on_undefine(it); } call_hook_in_skip = false; break; case T_PP_IFDEF: // #ifdef if (!impl::call_found_directive_hook(ctx, *it) && extract_identifier(it)) { on_ifdef(directive, it); } call_hook_in_skip = false; break; case T_PP_IFNDEF: // #ifndef if (!impl::call_found_directive_hook(ctx, *it) && extract_identifier(it)) { on_ifndef(directive, it); } call_hook_in_skip = false; break; #if BOOST_WAVE_SUPPORT_MS_EXTENSIONS != 0 // case T_MSEXT_PP_REGION: // #region ... // break; // // case T_MSEXT_PP_ENDREGION: // #endregion // break; #endif default: can_exit = false; break; } } // start over with the next line, if only possible if (can_exit) { skip_to_eol_with_check(it, call_hook_in_skip); return true; // may be safely ignored } return false; // do not ignore this pp directive } /////////////////////////////////////////////////////////////////////////////// // pp_directive(): recognize a preprocessor directive template <typename ContextT> inline bool pp_iterator_functor<ContextT>::pp_directive() { using namespace cpplexer; // test, if the next non-whitespace token is a pp directive lexer_type it = iter_ctx->first; if (!impl::next_token_is_pp_directive(ctx, it, iter_ctx->last)) { // skip null pp directive (no need to do it via the parser) if (it != iter_ctx->last && T_POUND == BASE_TOKEN(token_id(*it))) { if (impl::pp_is_last_on_line(ctx, it, iter_ctx->last)) { // start over with the next line seen_newline = true; iter_ctx->first = it; return true; } else if (ctx.get_if_block_status()) { // report invalid pp directive impl::skip_to_eol(ctx, it, iter_ctx->last); seen_newline = true; string_type str(boost::wave::util::impl::as_string<string_type>( iter_ctx->first, it)); token_sequence_type faulty_line; for (/**/; iter_ctx->first != it; ++iter_ctx->first) faulty_line.push_back(*iter_ctx->first); token_sequence_type pending; if (ctx.get_hooks().found_unknown_directive(ctx, faulty_line, pending)) { // if there is some replacement text, insert it into the pending queue if (!pending.empty()) pending_queue.splice(pending_queue.begin(), pending); return true; } // default behavior is to throw an exception on_illformed(str); } } // this line does not contain a pp directive, so simply return return false; } // found eof if (it == iter_ctx->last) return false; // ignore/handle all pp directives not related to conditional compilation while // if block status is false if (handle_pp_directive(it)) { // we may skip pp directives only if the current if block status is // false or if it was a #include directive we could handle directly return true; // the pp directive has been handled/skipped } // found a pp directive, so try to identify it, start with the pp_token bool found_eof = false; result_type found_directive; token_sequence_type found_eoltokens; tree_parse_info_type hit = cpp_grammar_type::parse_cpp_grammar( it, iter_ctx->last, act_pos, found_eof, found_directive, found_eoltokens); if (hit.match) { // position the iterator past the matched sequence to allow // resynchronization, if an error occurs iter_ctx->first = hit.stop; seen_newline = true; must_emit_line_directive = true; // found a valid pp directive, dispatch to the correct function to handle // the found pp directive bool result = dispatch_directive (hit, found_directive, found_eoltokens); if (found_eof && !need_single_line(ctx.get_language())) { // The line was terminated with an end of file token. // So trigger a warning, that the last line was not terminated with a // newline. BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, last_line_not_terminated, "", act_pos); } return result; } else if (token_id(found_directive) != T_EOF) { // recognized invalid directive impl::skip_to_eol(ctx, it, iter_ctx->last); seen_newline = true; string_type str(boost::wave::util::impl::as_string<string_type>( iter_ctx->first, it)); iter_ctx->first = it; // report the ill formed directive on_illformed(str); } return false; } /////////////////////////////////////////////////////////////////////////////// // // dispatch_directive(): dispatch a recognized preprocessor directive // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline bool pp_iterator_functor<ContextT>::dispatch_directive( tree_parse_info_type const &hit, result_type const& found_directive, token_sequence_type const& found_eoltokens) { using namespace cpplexer; typedef typename parse_tree_type::const_iterator const_child_iterator_t; // this iterator points to the root node of the parse tree const_child_iterator_t begin = hit.trees.begin(); // decide, which preprocessor directive was found parse_tree_type const &root = (*begin).children; parse_node_value_type const &nodeval = get_first_leaf(*root.begin()).value; //long node_id = nodeval.id().to_long(); const_child_iterator_t begin_child_it = (*root.begin()).children.begin(); const_child_iterator_t end_child_it = (*root.begin()).children.end(); token_id id = token_id(found_directive); // call preprocessing hook if (impl::call_found_directive_hook(ctx, found_directive)) return true; // skip this directive and return newline only switch (static_cast<unsigned int>(id)) { // case T_PP_QHEADER: // #include "..." // #if BOOST_WAVE_SUPPORT_INCLUDE_NEXT != 0 // case T_PP_QHEADER_NEXT: // #include_next "..." // #endif // on_include ((*nodeval.begin()).get_value(), false, // T_PP_QHEADER_NEXT == id); // break; // case T_PP_HHEADER: // #include <...> // #if BOOST_WAVE_SUPPORT_INCLUDE_NEXT != 0 // case T_PP_HHEADER_NEXT: // #include_next <...> // #endif // on_include ((*nodeval.begin()).get_value(), true, // T_PP_HHEADER_NEXT == id); // break; case T_PP_INCLUDE: // #include ... #if BOOST_WAVE_SUPPORT_INCLUDE_NEXT != 0 case T_PP_INCLUDE_NEXT: // #include_next ... #endif on_include (begin_child_it, end_child_it, T_PP_INCLUDE_NEXT == id); break; case T_PP_DEFINE: // #define on_define (*begin); break; // case T_PP_UNDEF: // #undef // on_undefine(*nodeval.begin()); // break; // // case T_PP_IFDEF: // #ifdef // on_ifdef(found_directive, begin_child_it, end_child_it); // break; // // case T_PP_IFNDEF: // #ifndef // on_ifndef(found_directive, begin_child_it, end_child_it); // break; case T_PP_IF: // #if on_if(found_directive, begin_child_it, end_child_it); break; case T_PP_ELIF: // #elif on_elif(found_directive, begin_child_it, end_child_it); break; // case T_PP_ELSE: // #else // on_else(); // break; // case T_PP_ENDIF: // #endif // on_endif(); // break; case T_PP_LINE: // #line on_line(begin_child_it, end_child_it); break; case T_PP_ERROR: // #error on_error(begin_child_it, end_child_it); break; #if BOOST_WAVE_SUPPORT_WARNING_DIRECTIVE != 0 case T_PP_WARNING: // #warning on_warning(begin_child_it, end_child_it); break; #endif case T_PP_PRAGMA: // #pragma return on_pragma(begin_child_it, end_child_it); #if BOOST_WAVE_SUPPORT_MS_EXTENSIONS != 0 case T_MSEXT_PP_REGION: case T_MSEXT_PP_ENDREGION: break; // ignore these #endif default: // #something else on_illformed((*nodeval.begin()).get_value()); // if we end up here, we have been instructed to ignore the error, so // we simply copy the whole construct to the output { token_sequence_type expanded; get_token_value<result_type, parse_node_type> get_value; std::copy(make_ref_transform_iterator(begin_child_it, get_value), make_ref_transform_iterator(end_child_it, get_value), std::inserter(expanded, expanded.end())); pending_queue.splice(pending_queue.begin(), expanded); } break; } // properly skip trailing newline for all directives typename token_sequence_type::const_iterator eol = found_eoltokens.begin(); impl::skip_to_eol(ctx, eol, found_eoltokens.end()); return true; // return newline only } /////////////////////////////////////////////////////////////////////////////// // // on_include: handle #include <...> or #include "..." directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_include (string_type const &s, bool is_system, bool include_next) { BOOST_ASSERT(ctx.get_if_block_status()); // strip quotes first, extract filename typename string_type::size_type pos_end = s.find_last_of(is_system ? '>' : '\"'); if (string_type::npos == pos_end) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_include_statement, s.c_str(), act_pos); return; } typename string_type::size_type pos_begin = s.find_last_of(is_system ? '<' : '\"', pos_end-1); if (string_type::npos == pos_begin) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_include_statement, s.c_str(), act_pos); return; } std::string file_token(s.substr(pos_begin, pos_end-pos_begin+1).c_str()); std::string file_path(s.substr(pos_begin+1, pos_end-pos_begin-1).c_str()); // finally include the file on_include_helper(file_token.c_str(), file_path.c_str(), is_system, include_next); } template <typename ContextT> inline bool pp_iterator_functor<ContextT>::on_include_helper (char const *f, char const *s, bool is_system, bool include_next) { namespace fs = boost::filesystem; // try to locate the given file, searching through the include path lists std::string file_path(s); std::string dir_path; #if BOOST_WAVE_SUPPORT_INCLUDE_NEXT != 0 char const *current_name = include_next ? iter_ctx->real_filename.c_str() : 0; #else char const *current_name = 0; // never try to match current file name #endif // call the 'found_include_directive' hook function #if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0 ctx.get_hooks().found_include_directive(f, include_next); #else if (ctx.get_hooks().found_include_directive(ctx.derived(), f, include_next)) return true; // client returned false: skip file to include #endif file_path = util::impl::unescape_lit(file_path); std::string native_path_str; if (!ctx.get_hooks().locate_include_file(ctx, file_path, is_system, current_name, dir_path, native_path_str)) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_include_file, file_path.c_str(), act_pos); return false; } // test, if this file is known through a #pragma once directive #if BOOST_WAVE_SUPPORT_PRAGMA_ONCE != 0 if (!ctx.has_pragma_once(native_path_str)) #endif { // the new include file determines the actual current directory ctx.set_current_directory(native_path_str.c_str()); // preprocess the opened file boost::shared_ptr<base_iteration_context_type> new_iter_ctx ( new iteration_context_type(ctx, native_path_str.c_str(), act_pos, boost::wave::enable_prefer_pp_numbers(ctx.get_language()), is_system ? base_iteration_context_type::system_header : base_iteration_context_type::user_header)); // call the include policy trace function #if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0 ctx.get_hooks().opened_include_file(dir_path, file_path, ctx.get_iteration_depth(), is_system); #else ctx.get_hooks().opened_include_file(ctx.derived(), dir_path, file_path, is_system); #endif // store current file position iter_ctx->real_relative_filename = ctx.get_current_relative_filename().c_str(); iter_ctx->filename = act_pos.get_file(); iter_ctx->line = act_pos.get_line(); iter_ctx->if_block_depth = ctx.get_if_block_depth(); iter_ctx->emitted_lines = (unsigned int)(-1); // force #line directive // push the old iteration context onto the stack and continue with the new ctx.push_iteration_context(act_pos, iter_ctx); iter_ctx = new_iter_ctx; seen_newline = true; // fake a newline to trigger pp_directive must_emit_line_directive = true; act_pos.set_file(iter_ctx->filename); // initialize file position #if BOOST_WAVE_SUPPORT_PRAGMA_ONCE != 0 fs::path rfp(wave::util::create_path(iter_ctx->real_filename.c_str())); std::string real_filename(rfp.string()); ctx.set_current_filename(real_filename.c_str()); #endif ctx.set_current_relative_filename(dir_path.c_str()); iter_ctx->real_relative_filename = dir_path.c_str(); act_pos.set_line(iter_ctx->line); act_pos.set_column(0); } return true; } /////////////////////////////////////////////////////////////////////////////// // // on_include(): handle #include ... directives // /////////////////////////////////////////////////////////////////////////////// namespace impl { // trim all whitespace from the beginning and the end of the given string template <typename StringT> inline StringT trim_whitespace(StringT const &s) { typedef typename StringT::size_type size_type; size_type first = s.find_first_not_of(" \t\v\f"); if (StringT::npos == first) return StringT(); size_type last = s.find_last_not_of(" \t\v\f"); return s.substr(first, last-first+1); } } template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_include( typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end, bool include_next) { BOOST_ASSERT(ctx.get_if_block_status()); // preprocess the given token sequence (the body of the #include directive) get_token_value<result_type, parse_node_type> get_value; token_sequence_type expanded; token_sequence_type toexpand; std::copy(make_ref_transform_iterator(begin, get_value), make_ref_transform_iterator(end, get_value), std::inserter(toexpand, toexpand.end())); typename token_sequence_type::iterator begin2 = toexpand.begin(); ctx.expand_whole_tokensequence(begin2, toexpand.end(), expanded, false); // now, include the file string_type s (impl::trim_whitespace(boost::wave::util::impl::as_string(expanded))); bool is_system = '<' == s[0] && '>' == s[s.size()-1]; if (!is_system && !('\"' == s[0] && '\"' == s[s.size()-1])) { // should resolve into something like <...> or "..." BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_include_statement, s.c_str(), act_pos); return; } on_include(s, is_system, include_next); } /////////////////////////////////////////////////////////////////////////////// // // on_define(): handle #define directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_define (parse_node_type const &node) { BOOST_ASSERT(ctx.get_if_block_status()); // retrieve the macro definition from the parse tree result_type macroname; std::vector<result_type> macroparameters; token_sequence_type macrodefinition; bool has_parameters = false; position_type pos(act_token.get_position()); if (!boost::wave::util::retrieve_macroname(ctx, node, BOOST_WAVE_PLAIN_DEFINE_ID, macroname, pos, false)) return; has_parameters = boost::wave::util::retrieve_macrodefinition(node, BOOST_WAVE_MACRO_PARAMETERS_ID, macroparameters, pos, false); boost::wave::util::retrieve_macrodefinition(node, BOOST_WAVE_MACRO_DEFINITION_ID, macrodefinition, pos, false); if (has_parameters) { #if BOOST_WAVE_SUPPORT_VARIADICS_PLACEMARKERS != 0 if (boost::wave::need_variadics(ctx.get_language())) { // test whether ellipsis are given, and if yes, if these are placed as the // last argument, test if __VA_ARGS__ is used as a macro parameter name using namespace cpplexer; typedef typename std::vector<result_type>::iterator parameter_iterator_t; bool seen_ellipses = false; parameter_iterator_t end = macroparameters.end(); for (parameter_iterator_t pit = macroparameters.begin(); pit != end; ++pit) { if (seen_ellipses) { // ellipses are not the last given formal argument BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_define_statement, macroname.get_value().c_str(), (*pit).get_position()); return; } if (T_ELLIPSIS == token_id(*pit)) seen_ellipses = true; // can't use __VA_ARGS__ as a argument name if ("__VA_ARGS__" == (*pit).get_value()) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_define_statement_va_args, macroname.get_value().c_str(), (*pit).get_position()); return; } } // if there wasn't an ellipsis, then there shouldn't be a __VA_ARGS__ // placeholder in the definition too [C99 Standard 6.10.3.5] if (!seen_ellipses) { typedef typename token_sequence_type::iterator definition_iterator_t; bool seen_va_args = false; definition_iterator_t pend = macrodefinition.end(); for (definition_iterator_t dit = macrodefinition.begin(); dit != pend; ++dit) { if (T_IDENTIFIER == token_id(*dit) && "__VA_ARGS__" == (*dit).get_value()) { seen_va_args = true; } } if (seen_va_args) { // must not have seen __VA_ARGS__ placeholder BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_define_statement_va_args, macroname.get_value().c_str(), act_token.get_position()); return; } } } else #endif // BOOST_WAVE_SUPPORT_VARIADICS_PLACEMARKERS != 0 { // test, that there is no T_ELLIPSES given using namespace cpplexer; typedef typename std::vector<result_type>::iterator parameter_iterator_t; parameter_iterator_t end = macroparameters.end(); for (parameter_iterator_t pit = macroparameters.begin(); pit != end; ++pit) { if (T_ELLIPSIS == token_id(*pit)) { // if variadics are disabled, no ellipses should be given BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, bad_define_statement, macroname.get_value().c_str(), (*pit).get_position()); return; } } } } // add the new macro to the macromap ctx.add_macro_definition(macroname, has_parameters, macroparameters, macrodefinition); } /////////////////////////////////////////////////////////////////////////////// // // on_undefine(): handle #undef directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_undefine (lexer_type const &it) { BOOST_ASSERT(ctx.get_if_block_status()); // retrieve the macro name to undefine from the parse tree ctx.remove_macro_definition((*it).get_value()); // throws for predefined macros } /////////////////////////////////////////////////////////////////////////////// // // on_ifdef(): handle #ifdef directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_ifdef( result_type const& found_directive, lexer_type const &it) // typename parse_tree_type::const_iterator const &it) // typename parse_tree_type::const_iterator const &end) { // get_token_value<result_type, parse_node_type> get_value; // token_sequence_type toexpand; // // std::copy(make_ref_transform_iterator((*begin).children.begin(), get_value), // make_ref_transform_iterator((*begin).children.end(), get_value), // std::inserter(toexpand, toexpand.end())); bool is_defined = false; token_sequence_type directive; directive.insert(directive.end(), *it); #if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0 is_defined = ctx.is_defined_macro((*it).get_value()); // toexpand.begin(), toexpand.end()); ctx.get_hooks().evaluated_conditional_expression(directive, is_defined); #else do { is_defined = ctx.is_defined_macro((*it).get_value()); // toexpand.begin(), toexpand.end()); } while (ctx.get_hooks().evaluated_conditional_expression(ctx.derived(), found_directive, directive, is_defined)); #endif ctx.enter_if_block(is_defined); } /////////////////////////////////////////////////////////////////////////////// // // on_ifndef(): handle #ifndef directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_ifndef( result_type const& found_directive, lexer_type const &it) // typename parse_tree_type::const_iterator const &it) // typename parse_tree_type::const_iterator const &end) { // get_token_value<result_type, parse_node_type> get_value; // token_sequence_type toexpand; // // std::copy(make_ref_transform_iterator((*begin).children.begin(), get_value), // make_ref_transform_iterator((*begin).children.end(), get_value), // std::inserter(toexpand, toexpand.end())); bool is_defined = false; token_sequence_type directive; directive.insert(directive.end(), *it); #if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0 is_defined = ctx.is_defined_macro((*it).get_value()); // toexpand.begin(), toexpand.end()); ctx.get_hooks().evaluated_conditional_expression(directive, is_defined); #else do { is_defined = ctx.is_defined_macro((*it).get_value()); // toexpand.begin(), toexpand.end()); } while (ctx.get_hooks().evaluated_conditional_expression(ctx.derived(), found_directive, directive, is_defined)); #endif ctx.enter_if_block(!is_defined); } /////////////////////////////////////////////////////////////////////////////// // // on_else(): handle #else directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_else() { if (!ctx.enter_else_block()) { // #else without matching #if BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, missing_matching_if, "#else", act_pos); } } /////////////////////////////////////////////////////////////////////////////// // // on_endif(): handle #endif directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_endif() { if (!ctx.exit_if_block()) { // #endif without matching #if BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, missing_matching_if, "#endif", act_pos); } } /////////////////////////////////////////////////////////////////////////////// // replace all remaining (== undefined) identifiers with an integer literal '0' template <typename ContextT> inline void pp_iterator_functor<ContextT>::replace_undefined_identifiers( token_sequence_type &expanded) { typename token_sequence_type::iterator exp_end = expanded.end(); for (typename token_sequence_type::iterator exp_it = expanded.begin(); exp_it != exp_end; ++exp_it) { using namespace boost::wave; token_id id = token_id(*exp_it); if (IS_CATEGORY(id, IdentifierTokenType) || IS_CATEGORY(id, KeywordTokenType)) { (*exp_it).set_token_id(T_INTLIT); (*exp_it).set_value("0"); } } } /////////////////////////////////////////////////////////////////////////////// // // on_if(): handle #if directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_if( result_type const& found_directive, typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end) { // preprocess the given sequence into the provided list get_token_value<result_type, parse_node_type> get_value; token_sequence_type toexpand; std::copy(make_ref_transform_iterator(begin, get_value), make_ref_transform_iterator(end, get_value), std::inserter(toexpand, toexpand.end())); impl::remove_leading_whitespace(ctx, toexpand); bool if_status = false; grammars::value_error status = grammars::error_noerror; token_sequence_type expanded; do { expanded.clear(); typename token_sequence_type::iterator begin2 = toexpand.begin(); ctx.expand_whole_tokensequence(begin2, toexpand.end(), expanded); // replace all remaining (== undefined) identifiers with an integer literal '0' replace_undefined_identifiers(expanded); #if BOOST_WAVE_DUMP_CONDITIONAL_EXPRESSIONS != 0 { string_type outstr(boost::wave::util::impl::as_string(toexpand)); outstr += "(" + boost::wave::util::impl::as_string(expanded) + ")"; BOOST_WAVE_DUMP_CONDITIONAL_EXPRESSIONS_OUT << "#if " << outstr << std::endl; } #endif try { // parse the expression and enter the #if block if_status = grammars::expression_grammar_gen<result_type>:: evaluate(expanded.begin(), expanded.end(), act_pos, ctx.get_if_block_status(), status); } catch (boost::wave::preprocess_exception const& e) { // any errors occurred have to be dispatched to the context hooks ctx.get_hooks().throw_exception(ctx.derived(), e); break; } #if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0 ctx.get_hooks().evaluated_conditional_expression(toexpand, if_status); } while (false); #else } while (ctx.get_hooks().evaluated_conditional_expression(ctx.derived(), found_directive, toexpand, if_status) && status == grammars::error_noerror); #endif ctx.enter_if_block(if_status); if (grammars::error_noerror != status) { // division or other error by zero occurred string_type expression = util::impl::as_string(expanded); if (0 == expression.size()) expression = "<empty expression>"; if (grammars::error_division_by_zero & status) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, division_by_zero, expression.c_str(), act_pos); } else if (grammars::error_integer_overflow & status) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, integer_overflow, expression.c_str(), act_pos); } else if (grammars::error_character_overflow & status) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, character_literal_out_of_range, expression.c_str(), act_pos); } } } /////////////////////////////////////////////////////////////////////////////// // // on_elif(): handle #elif directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_elif( result_type const& found_directive, typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end) { // preprocess the given sequence into the provided list get_token_value<result_type, parse_node_type> get_value; token_sequence_type toexpand; std::copy(make_ref_transform_iterator(begin, get_value), make_ref_transform_iterator(end, get_value), std::inserter(toexpand, toexpand.end())); impl::remove_leading_whitespace(ctx, toexpand); // check current if block status if (ctx.get_if_block_some_part_status()) { if (!ctx.enter_elif_block(false)) { // #else without matching #if BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, missing_matching_if, "#elif", act_pos); // fall through... } // skip all the expression and the trailing whitespace typename token_sequence_type::iterator begin2 = toexpand.begin(); impl::skip_to_eol(ctx, begin2, toexpand.end()); return; // one of previous #if/#elif was true, so don't enter this #elif } // preprocess the given sequence into the provided list bool if_status = false; grammars::value_error status = grammars::error_noerror; token_sequence_type expanded; do { expanded.clear(); typename token_sequence_type::iterator begin2 = toexpand.begin(); ctx.expand_whole_tokensequence(begin2, toexpand.end(), expanded); // replace all remaining (== undefined) identifiers with an integer literal '0' replace_undefined_identifiers(expanded); #if BOOST_WAVE_DUMP_CONDITIONAL_EXPRESSIONS != 0 { string_type outstr(boost::wave::util::impl::as_string(toexpand)); outstr += "(" + boost::wave::util::impl::as_string(expanded) + ")"; BOOST_WAVE_DUMP_CONDITIONAL_EXPRESSIONS_OUT << "#elif " << outstr << std::endl; } #endif try { // parse the expression and enter the #elif block if_status = grammars::expression_grammar_gen<result_type>:: evaluate(expanded.begin(), expanded.end(), act_pos, ctx.get_if_block_status(), status); } catch (boost::wave::preprocess_exception const& e) { // any errors occurred have to be dispatched to the context hooks ctx.get_hooks().throw_exception(ctx.derived(), e); } #if BOOST_WAVE_USE_DEPRECIATED_PREPROCESSING_HOOKS != 0 ctx.get_hooks().evaluated_conditional_expression(toexpand, if_status); } while (false); #else } while (ctx.get_hooks().evaluated_conditional_expression(ctx.derived(), found_directive, toexpand, if_status) && status == grammars::error_noerror); #endif if (!ctx.enter_elif_block(if_status)) { // #elif without matching #if BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, missing_matching_if, "#elif", act_pos); return; } if (grammars::error_noerror != status) { // division or other error by zero occurred string_type expression = util::impl::as_string(expanded); if (0 == expression.size()) expression = "<empty expression>"; if (grammars::error_division_by_zero & status) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, division_by_zero, expression.c_str(), act_pos); } else if (grammars::error_integer_overflow & status) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, integer_overflow, expression.c_str(), act_pos); } else if (grammars::error_character_overflow & status) { BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, character_literal_out_of_range, expression.c_str(), act_pos); } } } /////////////////////////////////////////////////////////////////////////////// // // on_illformed(): handles the illegal directive // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_illformed( typename result_type::string_type s) { BOOST_ASSERT(ctx.get_if_block_status()); // some messages have more than one newline at the end typename string_type::size_type p = s.find_last_not_of('\n'); if (string_type::npos != p) s = s.substr(0, p+1); // throw the exception BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, ill_formed_directive, s.c_str(), act_pos); } /////////////////////////////////////////////////////////////////////////////// // // on_line(): handle #line directives // /////////////////////////////////////////////////////////////////////////////// namespace impl { template <typename IteratorT, typename StringT> bool retrieve_line_info (IteratorT first, IteratorT const &last, unsigned int &line, StringT &file, boost::wave::preprocess_exception::error_code& error) { using namespace boost::wave; token_id id = token_id(*first); if (T_PP_NUMBER == id || T_INTLIT == id) { // extract line number using namespace std; // some systems have atoi in namespace std line = (unsigned int)atoi((*first).get_value().c_str()); if (0 == line) error = preprocess_exception::bad_line_number; // re-extract line number with spirit to diagnose overflow using namespace boost::spirit::classic; if (!parse((*first).get_value().c_str(), int_p).full) error = preprocess_exception::bad_line_number; // extract file name (if it is given) while (++first != last && IS_CATEGORY(*first, WhiteSpaceTokenType)) /**/; // skip whitespace if (first != last) { if (T_STRINGLIT != token_id(*first)) { error = preprocess_exception::bad_line_filename; return false; } StringT const &file_lit = (*first).get_value(); if ('L' == file_lit[0]) { error = preprocess_exception::bad_line_filename; return false; // shouldn't be a wide character string } file = file_lit.substr(1, file_lit.size()-2); // test if there is other junk on this line while (++first != last && IS_CATEGORY(*first, WhiteSpaceTokenType)) /**/; // skip whitespace } return first == last; } error = preprocess_exception::bad_line_statement; return false; } } template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_line( typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end) { BOOST_ASSERT(ctx.get_if_block_status()); // Try to extract the line number and file name from the given token list // directly. If that fails, preprocess the whole token sequence and try again // to extract this information. token_sequence_type expanded; get_token_value<result_type, parse_node_type> get_value; typedef typename ref_transform_iterator_generator< get_token_value<result_type, parse_node_type>, typename parse_tree_type::const_iterator >::type const_tree_iterator_t; const_tree_iterator_t first = make_ref_transform_iterator(begin, get_value); const_tree_iterator_t last = make_ref_transform_iterator(end, get_value); // try to interpret the #line body as a number followed by an optional // string literal unsigned int line = 0; preprocess_exception::error_code error = preprocess_exception::no_error; string_type file_name; token_sequence_type toexpand; std::copy(first, last, std::inserter(toexpand, toexpand.end())); if (!impl::retrieve_line_info(first, last, line, file_name, error)) { // preprocess the body of this #line message typename token_sequence_type::iterator begin2 = toexpand.begin(); ctx.expand_whole_tokensequence(begin2, toexpand.end(), expanded, false); error = preprocess_exception::no_error; if (!impl::retrieve_line_info(expanded.begin(), expanded.end(), line, file_name, error)) { typename ContextT::string_type msg( boost::wave::util::impl::as_string(expanded)); BOOST_WAVE_THROW_VAR_CTX(ctx, preprocess_exception, error, msg.c_str(), act_pos); return; } // call the corresponding pp hook function ctx.get_hooks().found_line_directive(ctx.derived(), expanded, line, file_name.c_str()); } else { // call the corresponding pp hook function ctx.get_hooks().found_line_directive(ctx.derived(), toexpand, line, file_name.c_str()); } // the queues should be empty at this point BOOST_ASSERT(unput_queue.empty()); BOOST_ASSERT(pending_queue.empty()); // make sure error recovery starts on the next line must_emit_line_directive = true; // diagnose possible error in detected line directive if (error != preprocess_exception::no_error) { typename ContextT::string_type msg( boost::wave::util::impl::as_string(expanded)); BOOST_WAVE_THROW_VAR_CTX(ctx, preprocess_exception, error, msg.c_str(), act_pos); return; } // set new line number/filename only if ok if (!file_name.empty()) { // reuse current file name using boost::wave::util::impl::unescape_lit; act_pos.set_file(unescape_lit(file_name).c_str()); } act_pos.set_line(line); iter_ctx->first.set_position(act_pos); } /////////////////////////////////////////////////////////////////////////////// // // on_error(): handle #error directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_error( typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end) { BOOST_ASSERT(ctx.get_if_block_status()); // preprocess the given sequence into the provided list token_sequence_type expanded; get_token_value<result_type, parse_node_type> get_value; typename ref_transform_iterator_generator< get_token_value<result_type, parse_node_type>, typename parse_tree_type::const_iterator >::type first = make_ref_transform_iterator(begin, get_value); #if BOOST_WAVE_PREPROCESS_ERROR_MESSAGE_BODY != 0 // preprocess the body of this #error message token_sequence_type toexpand; std::copy(first, make_ref_transform_iterator(end, get_value), std::inserter(toexpand, toexpand.end())); typename token_sequence_type::iterator begin2 = toexpand.begin(); ctx.expand_whole_tokensequence(begin2, toexpand.end(), expanded, false); if (!ctx.get_hooks().found_error_directive(ctx.derived(), toexpand)) #else // simply copy the body of this #error message to the issued diagnostic // message std::copy(first, make_ref_transform_iterator(end, get_value), std::inserter(expanded, expanded.end())); if (!ctx.get_hooks().found_error_directive(ctx.derived(), expanded)) #endif { // report the corresponding error BOOST_WAVE_STRINGTYPE msg(boost::wave::util::impl::as_string(expanded)); BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, error_directive, msg.c_str(), act_pos); } } #if BOOST_WAVE_SUPPORT_WARNING_DIRECTIVE != 0 /////////////////////////////////////////////////////////////////////////////// // // on_warning(): handle #warning directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline void pp_iterator_functor<ContextT>::on_warning( typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end) { BOOST_ASSERT(ctx.get_if_block_status()); // preprocess the given sequence into the provided list token_sequence_type expanded; get_token_value<result_type, parse_node_type> get_value; typename ref_transform_iterator_generator< get_token_value<result_type, parse_node_type>, typename parse_tree_type::const_iterator >::type first = make_ref_transform_iterator(begin, get_value); #if BOOST_WAVE_PREPROCESS_ERROR_MESSAGE_BODY != 0 // preprocess the body of this #warning message token_sequence_type toexpand; std::copy(first, make_ref_transform_iterator(end, get_value), std::inserter(toexpand, toexpand.end())); typename token_sequence_type::iterator begin2 = toexpand.begin(); ctx.expand_whole_tokensequence(begin2, toexpand.end(), expanded, false); if (!ctx.get_hooks().found_warning_directive(ctx.derived(), toexpand)) #else // simply copy the body of this #warning message to the issued diagnostic // message std::copy(first, make_ref_transform_iterator(end, get_value), std::inserter(expanded, expanded.end())); if (!ctx.get_hooks().found_warning_directive(ctx.derived(), expanded)) #endif { // report the corresponding error BOOST_WAVE_STRINGTYPE msg(boost::wave::util::impl::as_string(expanded)); BOOST_WAVE_THROW_CTX(ctx, preprocess_exception, warning_directive, msg.c_str(), act_pos); } } #endif // BOOST_WAVE_SUPPORT_WARNING_DIRECTIVE != 0 /////////////////////////////////////////////////////////////////////////////// // // on_pragma(): handle #pragma directives // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> inline bool pp_iterator_functor<ContextT>::on_pragma( typename parse_tree_type::const_iterator const &begin, typename parse_tree_type::const_iterator const &end) { using namespace boost::wave; BOOST_ASSERT(ctx.get_if_block_status()); // Look at the pragma token sequence and decide, if the first token is STDC // (see C99 standard [6.10.6.2]), if it is, the sequence must _not_ be // preprocessed. token_sequence_type expanded; get_token_value<result_type, parse_node_type> get_value; typedef typename ref_transform_iterator_generator< get_token_value<result_type, parse_node_type>, typename parse_tree_type::const_iterator >::type const_tree_iterator_t; const_tree_iterator_t first = make_ref_transform_iterator(begin, get_value); const_tree_iterator_t last = make_ref_transform_iterator(end, get_value); expanded.push_back(result_type(T_PP_PRAGMA, "#pragma", act_token.get_position())); expanded.push_back(result_type(T_SPACE, " ", act_token.get_position())); while (++first != last && IS_CATEGORY(*first, WhiteSpaceTokenType)) expanded.push_back(*first); // skip whitespace if (first != last) { if (T_IDENTIFIER == token_id(*first) && boost::wave::need_c99(ctx.get_language()) && (*first).get_value() == "STDC") { // do _not_ preprocess the token sequence std::copy(first, last, std::inserter(expanded, expanded.end())); } else { #if BOOST_WAVE_PREPROCESS_PRAGMA_BODY != 0 // preprocess the given tokensequence token_sequence_type toexpand; std::copy(first, last, std::inserter(toexpand, toexpand.end())); typename token_sequence_type::iterator begin2 = toexpand.begin(); ctx.expand_whole_tokensequence(begin2, toexpand.end(), expanded, false); #else // do _not_ preprocess the token sequence std::copy(first, last, std::inserter(expanded, expanded.end())); #endif } } expanded.push_back(result_type(T_NEWLINE, "\n", act_token.get_position())); // the queues should be empty at this point BOOST_ASSERT(unput_queue.empty()); BOOST_ASSERT(pending_queue.empty()); // try to interpret the expanded #pragma body token_sequence_type pending; if (interpret_pragma(expanded, pending)) { // if there is some replacement text, insert it into the pending queue if (!pending.empty()) pending_queue.splice(pending_queue.begin(), pending); return true; // this #pragma was successfully recognized } #if BOOST_WAVE_EMIT_PRAGMA_DIRECTIVES != 0 // Move the resulting token sequence into the pending_queue, so it will be // returned to the caller. if (boost::wave::need_emit_pragma_directives(ctx.get_language())) { pending_queue.splice(pending_queue.begin(), expanded); return false; // return the whole #pragma directive } #endif return true; // skip the #pragma at all } template <typename ContextT> inline bool pp_iterator_functor<ContextT>::interpret_pragma( token_sequence_type const &pragma_body, token_sequence_type &result) { using namespace cpplexer; typename token_sequence_type::const_iterator end = pragma_body.end(); typename token_sequence_type::const_iterator it = pragma_body.begin(); for (++it; it != end && IS_CATEGORY(*it, WhiteSpaceTokenType); ++it) /**/; // skip whitespace if (it == end) // eof reached return false; return boost::wave::util::interpret_pragma( ctx.derived(), act_token, it, end, result); } /////////////////////////////////////////////////////////////////////////////// } // namespace impl /////////////////////////////////////////////////////////////////////////////// // // pp_iterator // // The boost::wave::pp_iterator template is the iterator, through which // the resulting preprocessed input stream is accessible. // /////////////////////////////////////////////////////////////////////////////// template <typename ContextT> class pp_iterator : public boost::spirit::classic::multi_pass< boost::wave::impl::pp_iterator_functor<ContextT>, boost::wave::util::functor_input > { public: typedef boost::wave::impl::pp_iterator_functor<ContextT> input_policy_type; private: typedef boost::spirit::classic::multi_pass<input_policy_type, boost::wave::util::functor_input> base_type; typedef pp_iterator<ContextT> self_type; typedef boost::wave::util::functor_input functor_input_type; public: pp_iterator() {} template <typename IteratorT> pp_iterator(ContextT &ctx, IteratorT const &first, IteratorT const &last, typename ContextT::position_type const &pos) : base_type(input_policy_type(ctx, first, last, pos)) {} bool force_include(char const *path_, bool is_last) { bool result = this->get_functor().on_include_helper(path_, path_, false, false); if (is_last) { this->functor_input_type:: template inner<input_policy_type>::advance_input(); } return result; } }; /////////////////////////////////////////////////////////////////////////////// } // 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(CPP_ITERATOR_HPP_175CA88F_7273_43FA_9039_BCF7459E1F29_INCLUDED)