# Gtkmmproc Output module # # Copyright 2001 Free Software Foundation # # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 2 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see . # package Output; use strict; use open IO => ":utf8"; use Function qw(FLAG_PARAM_OPTIONAL FLAG_PARAM_OUTPUT FLAG_PARAM_NULLPTR FLAG_PARAM_EMPTY_STRING); use DocsParser; BEGIN { @Namespace::ISA=qw(main); } # $objOutputter new() sub new { my ($m4path, $macrodirs) = @_; my $self = {}; bless $self; $$self{out} = []; $$self{source} = ""; $$self{tmpdir} = File::Spec->tmpdir(); $$self{destdir} = ""; $$self{objDefsParser} = undef; # It will be set in set_defsparser() $$self{m4path} = $m4path; $$self{m4args} = "-I"; $$self{m4args} .= join(" -I", @$macrodirs); return $self; } sub set_defsparser($$) { my ($self, $objDefsParser) = @_; $$self{objDefsParser} = $objDefsParser; #Remember it so that we can use it in our output methods. } sub m4args_append($$) { my ($self, $str) = @_; $$self{m4args} .= $str; } sub append($$) { my ($self, $str) = @_; push(@{$$self{out}}, $str); } # void output_wrap_failed($cname, $error) # Puts a comment in the header about the error during code-generation. sub output_wrap_failed($$$) { my ($self, $cname, $error) = @_; # See "MS Visual Studio" comment in gmmproc.in. my $str = sprintf("//gtkmmproc error: %s : %s", $cname, $error); print STDERR "Output.pm, $main::source, $cname : $error\n"; $self->append($str); } sub error { my $format=shift @_; printf STDERR "Output.pm, $main::source: $format",@_; } # void check_deprecation($file_deprecated, $defs_deprecated, $wrap_deprecated, # $entity_name, $entity_type, $wrapper) sub check_deprecation($$$$$$) { my ($file_deprecated, $defs_deprecated, $wrap_deprecated, $entity_name, $entity_type, $wrapper) = @_; # Don't print a warning if the whole .hg file is deprecated. return if ($file_deprecated); if ($defs_deprecated && !$wrap_deprecated) { print STDERR "Warning, $main::source: The $entity_name $entity_type" . " is deprecated in the .defs file, but not in _WRAP_$wrapper.\n"; } elsif (!$defs_deprecated && $wrap_deprecated) { print STDERR "Warning, $main::source: The $entity_name $entity_type" . " is deprecated in _WRAP_$wrapper, but not in the .defs file.\n"; } } sub ifdef($$) { my ($self, $ifdef) = @_; if ($ifdef) { $self->append("\n#ifdef $ifdef\n"); } } sub endif($$) { my ($self, $ifdef) = @_; if ($ifdef) { $self->append("\n#endif // $ifdef\n"); } } ### Convert _WRAP to a virtual # _VFUNC_H(signame,rettype,`') # _VFUNC_PH(gtkname,crettype,cargs and names) # void output_wrap_vfunc_h($filename, $line_num, $objCppfunc, $objCDefsFunc) sub output_wrap_vfunc_h($$$$$$) { my ($self, $filename, $line_num, $objCppfunc, $objCDefsFunc, $ifdef) = @_; #Old code. We removed _VFUNC_H from the .m4 file # my $str = sprintf("_VFUNC_H(%s,%s,\`%s\',%s)dnl\n", # $$objCppfunc{name}, # $$objCppfunc{rettype}, # $objCppfunc->args_types_and_names(), # $objCppfunc->get_is_const() # ); # $self->append($str); $self->ifdef($ifdef); # Prepend a Doxygen @throws directive to the declaration if the virtual # function throws an error. if($$objCDefsFunc{throw_any_errors}) { $self->append('/// @throws Glib::Error.' . "\n"); } my $cppVfuncDecl = "virtual " . $$objCppfunc{rettype} . " " . $$objCppfunc{name} . "(" . $objCppfunc->args_types_and_names() . ")"; if($objCppfunc->get_is_const()) { $cppVfuncDecl .= " const"; } $self->append(" $cppVfuncDecl;\n"); $self->endif($ifdef); #The default callback, which will call *_vfunc, which will then call the base default callback. #Declares the callback in the private *Class class and sets it in the class_init function. my $str = sprintf("_VFUNC_PH(%s,%s,\`%s\',%s)dnl\n", $$objCDefsFunc{name}, $$objCDefsFunc{rettype}, $objCDefsFunc->args_types_and_names(), $ifdef ); $self->append($str); } # _VFUNC_CC(signame,gtkname,rettype,crettype,`',`') sub output_wrap_vfunc_cc($$$$$$$$) { my ($self, $filename, $line_num, $objCppfunc, $objCFunc, $custom_vfunc, $custom_vfunc_callback, $ifdef) = @_; my $cname = $$objCFunc{name}; my $errthrow = ""; if($$objCFunc{throw_any_errors}) { $errthrow = "errthrow" } # e.g. Gtk::Button::draw_indicator: #Use a different macro for Interfaces, to generate an extra convenience method. if (!$custom_vfunc) { my $refreturn = ""; $refreturn = "refreturn" if($$objCppfunc{rettype_needs_ref}); my $returnValue = $$objCppfunc{return_value}; my ($conversions, $declarations, $initializations) = convert_args_cpp_to_c($objCppfunc, $objCFunc, 0, $line_num, $errthrow); my $no_slot_copy = ""; $no_slot_copy = "no_slot_copy" if ($$objCppfunc{no_slot_copy}); my $str = sprintf("_VFUNC_CC(%s,%s,%s,%s,\`%s\',\`%s\',%s,%s,%s,%s,%s,%s,%s,%s)dnl\n", $$objCppfunc{name}, $cname, $$objCppfunc{rettype}, $$objCFunc{rettype}, $objCppfunc->args_types_and_names(), $conversions, $objCppfunc->get_is_const(), $refreturn, $ifdef, $errthrow, $$objCppfunc{slot_type}, $$objCppfunc{slot_name}, $no_slot_copy, $returnValue); $self->append($str); } # e.g. Gtk::ButtonClass::draw_indicator(): if (!$custom_vfunc_callback) { my $refreturn_ctype = ""; $refreturn_ctype = "refreturn_ctype" if($$objCFunc{rettype_needs_ref}); my $keep_return = ""; $keep_return = "keep_return" if($$objCppfunc{keep_return}); # Get the conversions. my $conversions = convert_args_c_to_cpp($objCFunc, $objCppfunc, $line_num); my $returnValue = $$objCppfunc{return_value}; my $errReturnValue = $$objCppfunc{err_return_value}; my $exceptionHandler = $$objCppfunc{exception_handler}; my $str = sprintf("_VFUNC_PCC(%s,%s,%s,%s,\`%s\',\`%s\',\`%s\',%s,%s,%s,%s,%s,%s,%s,%s,%s,%s)dnl\n", $$objCppfunc{name}, $cname, $$objCppfunc{rettype}, $$objCFunc{rettype}, $objCFunc->args_types_and_names(), $objCFunc->args_names_only(), $conversions, ${$objCFunc->get_param_names()}[0], $refreturn_ctype, $keep_return, $ifdef, $errthrow, $$objCppfunc{slot_type}, $$objCppfunc{c_data_param_name}, $returnValue, $errReturnValue, $exceptionHandler); $self->append($str); } } ### Convert _WRAP to a signal # _SIGNAL_H(signame,rettype, `', ifdef) # _SIGNAL_PH(gtkname,crettype, cargs and names, ifdef, deprecated) # void output_wrap_default_signal_handler_h($filename, $line_num, $objCppfunc, # $objCDefsFunc, $ifdef, $deprecated, $exceptionHandler) sub output_wrap_default_signal_handler_h($$$$$$$$) { my ($self, $filename, $line_num, $objCppfunc, $objCDefsFunc, $ifdef, $deprecated, $exceptionHandler) = @_; # The default signal handler is a virtual function. # It's not hidden by deprecation, since that would break ABI. my $str = sprintf("_SIGNAL_H(%s,%s,\`%s\',%s)dnl\n", $$objCppfunc{name}, $$objCppfunc{rettype}, $objCppfunc->args_types_and_names(), $ifdef ); $self->append($str); #The default callback, which will call on_* or the base default callback. #Declares the callback in the private *Class class and sets it in the class_init function. #This is hidden by deprecation. $str = sprintf("_SIGNAL_PH(%s,%s,\`%s\',%s,%s,%s)dnl\n", $$objCDefsFunc{name}, $$objCDefsFunc{rettype}, $objCDefsFunc->args_types_and_names(), $ifdef, $deprecated, $exceptionHandler ); $self->append($str); } # _SIGNAL_CC(signame, gtkname, rettype, crettype,`',`', const, refreturn, ifdef, exceptionHandler) sub output_wrap_default_signal_handler_cc($$$$$$$$$$$) { my ($self, $filename, $line_num, $objCppfunc, $objDefsSignal, $bImplement, $bCustomCCallback, $bRefreturn, $ifdef, $deprecated, $exceptionHandler) = @_; my $cname = $$objDefsSignal{name}; # $cname = $1 if ($args[3] =~ /"(.*)"/); #TODO: What's this about? # e.g. Gtk::Button::on_clicked: if($bImplement eq 1) { my $refreturn = ""; $refreturn = "refreturn" if($bRefreturn eq 1); my ($conversions, $declarations, $initializations) = convert_args_cpp_to_c($objCppfunc, $objDefsSignal, 0, $line_num); # The default signal handler is a virtual function. # It's not hidden by deprecation, since that would break ABI. my $str = sprintf("_SIGNAL_CC(%s,%s,%s,%s,\`%s\',\`%s\',%s,%s,%s)dnl\n", $$objCppfunc{name}, $cname, $$objCppfunc{rettype}, $$objDefsSignal{rettype}, $objCppfunc->args_types_and_names(), $conversions, $$objCppfunc{const}, $refreturn, $ifdef ); $self->append($str); } # e.g. Gtk::ButtonClass::on_clicked(): #Callbacks always take the object instance as the first argument: # my $arglist_names = "object"; # my $arglist_names_extra = $objDefsSignal->args_names_only(); # if ($arglist_names_extra) # { # $arglist_names .= ", "; # $arglist_names .= $arglist_names_extra; # } if($bCustomCCallback ne 1) { my $conversions = convert_args_c_to_cpp($objDefsSignal, $objCppfunc, $line_num); #This is hidden by deprecation. my $str = sprintf("_SIGNAL_PCC(%s,%s,%s,%s,\`%s\',\`%s\',\`%s\',\`%s\',%s,%s,%s)dnl\n", $$objCppfunc{name}, $cname, $$objCppfunc{rettype}, $$objDefsSignal{rettype}, $objDefsSignal->args_types_and_names(), $objDefsSignal->args_names_only(), $conversions, ${$objDefsSignal->get_param_names()}[0], $ifdef, $deprecated, $exceptionHandler); $self->append($str); } } ### Convert _WRAP to a method # _METHOD(cppname,cname,cpprettype,crettype,arglist,cargs,const) # void output_wrap_meth($filename, $line_num, $objCppFunc, $objCDefsFunc, $cppMethodDecl, $documentation, $ifdef) sub output_wrap_meth($$$$$$$) { my ($self, $filename, $line_num, $objCppfunc, $objCDefsFunc, $cppMethodDecl, $documentation, $ifdef) = @_; my $objDefsParser = $$self{objDefsParser}; my $cpp_param_names = $$objCppfunc{param_names}; my $cpp_param_types = $$objCppfunc{param_types}; my $c_param_name_mappings = $$objCppfunc{param_mappings}; my $num_args_list = $objCppfunc->get_num_possible_args_list(); my $output_var_name; my $output_var_type; if(defined($$c_param_name_mappings{"OUT"})) { $output_var_name = $$cpp_param_names[$$c_param_name_mappings{"OUT"}]; $output_var_type = $$cpp_param_types[$$c_param_name_mappings{"OUT"}]; } for(my $arg_list = 0; $arg_list < $num_args_list; $arg_list++) { # Allow the generated .h/.cc code to have an #ifndef around it, and add # deprecation docs to the generated documentation. my $deprecated = ""; if($$objCDefsFunc{deprecated}) { $deprecated = "deprecated"; } #Declaration: if($deprecated ne "") { $self->append("\n_DEPRECATE_IFDEF_START"); } $self->ifdef($ifdef); if($arg_list == 0) { # Doxygen documentation before the method declaration: $self->output_wrap_meth_docs_only($filename, $line_num, $documentation); } else { $self->append("\n\n /// A $$objCppfunc{name}() convenience overload.\n"); } $self->append(" " . $objCppfunc->get_declaration($arg_list)); $self->endif($ifdef); if($deprecated ne "") { $self->append("\n_DEPRECATE_IFDEF_END\n"); } my $refneeded = ""; if($$objCDefsFunc{rettype_needs_ref}) { $refneeded = "refreturn" } my $errthrow = ""; if($$objCDefsFunc{throw_any_errors}) { $errthrow = "errthrow" } my $constversion = ""; #Whether it is just a const overload (so it can reuse code) if($$objCDefsFunc{constversion}) { $constversion = "constversion" } if($$objCDefsFunc{ignore_deprecations}) { $deprecated = "ignore_deprecations" } #Implementation: my $str; if ($$objCppfunc{static}) { my ($conversions, $declarations, $initializations) = convert_args_cpp_to_c($objCppfunc, $objCDefsFunc, 1, $line_num, $errthrow, $arg_list); #1 means it's static, so it has 'object'. my $no_slot_copy = ""; my $slot_type = ""; my $slot_name = ""; # A slot may be optional so if it is signaled by # convert_args_cpp_to_c() to not be included, then don't. if ($$objCppfunc{include_slot}) { $slot_type = $$objCppfunc{slot_type}; $slot_name = $$objCppfunc{slot_name}; $no_slot_copy = "no_slot_copy" if ($$objCppfunc{no_slot_copy}); } $str = sprintf("_STATIC_METHOD(%s,%s,\`%s\',%s,\`%s\',\`%s\',\`%s\',\`%s\',%s,%s,%s,%s,%s,%s,`%s',`%s',`%s',%s)dnl\n", $$objCppfunc{name}, $$objCDefsFunc{c_name}, $$objCppfunc{rettype}, $objCDefsFunc->get_return_type_for_methods(), $objCppfunc->args_types_and_names($arg_list), $declarations, $conversions, $initializations, $refneeded, $errthrow, $deprecated, $ifdef, $output_var_name, $output_var_type, $slot_type, $slot_name, $no_slot_copy, $line_num ); } else { my ($conversions, $declarations, $initializations) = convert_args_cpp_to_c($objCppfunc, $objCDefsFunc, 0, $line_num, $errthrow, $arg_list); my $no_slot_copy = ""; my $slot_type = ""; my $slot_name = ""; # A slot may be optional so if it is signaled by # convert_args_cpp_to_c() to not be included, then don't. if ($$objCppfunc{include_slot}) { $slot_type = $$objCppfunc{slot_type}; $slot_name = $$objCppfunc{slot_name}; $no_slot_copy = "no_slot_copy" if ($$objCppfunc{no_slot_copy}); } $str = sprintf("_METHOD(%s,%s,\`%s\',%s,\`%s\',\`%s\',\`%s\',\`%s\',%s,%s,%s,%s,%s,\`%s\',%s,%s,%s,`%s',`%s',`%s',%s)dnl\n", $$objCppfunc{name}, $$objCDefsFunc{c_name}, $$objCppfunc{rettype}, $objCDefsFunc->get_return_type_for_methods(), $objCppfunc->args_types_and_names($arg_list), $declarations, $conversions, $initializations, $$objCppfunc{const}, $refneeded, $errthrow, $deprecated, $constversion, $objCppfunc->args_names_only($arg_list), $ifdef, $output_var_name, $output_var_type, $slot_type, $slot_name, $no_slot_copy, $line_num ); } $self->append($str); } } ### Convert _WRAP to a method # _METHOD(cppname,cname,cpprettype,crettype,arglist,cargs,const) # void output_wrap_meth($filename, $line_num, $documentation) sub output_wrap_meth_docs_only($$$$) { my ($self, $filename, $line_num, $documentation) = @_; my $objDefsParser = $$self{objDefsParser}; # Doxygen documentation before the method declaration: $self->append("\n${documentation}"); } ### Convert _WRAP_CTOR to a ctor # _METHOD(cppname,cname,cpprettype,crettype,arglist,cargs,const) # void output_wrap_ctor($filename, $line_num, $objCppFunc, $objCDefsFunc, $cppMethodDecl) sub output_wrap_ctor($$$$$) { my ($self, $filename, $line_num, $objCppfunc, $objCDefsFunc, $cppMethodDecl) = @_; my $objDefsParser = $$self{objDefsParser}; my $num_args_list = $objCppfunc->get_num_possible_args_list(); for(my $arg_list = 0; $arg_list < $num_args_list; $arg_list++) { if ($arg_list > 0) { $self->append("\n\n /// A $$objCppfunc{name}() convenience overload.\n"); } #Ctor Declaration: $self->append(" explicit " . $objCppfunc->get_declaration($arg_list) . "\n"); my $errthrow = ""; if($$objCDefsFunc{throw_any_errors}) { $errthrow = "errthrow"; } #Implementation: my $str = sprintf("_CTOR_IMPL(%s,%s,\`%s\',\`%s\')dnl\n", $$objCppfunc{name}, $$objCDefsFunc{c_name}, $objCppfunc->args_types_and_names($arg_list), get_ctor_properties($objCppfunc, $objCDefsFunc, $line_num, $errthrow, $arg_list) ); $self->append($str); } } sub output_wrap_create($$$) { my ($self, $args_type_and_name_with_default_values, $objWrapParser) = @_; #Re-use Function in a very hacky way, to separate the argument types_and_names. my $fake_decl = "void fake_func(" . $args_type_and_name_with_default_values . ")"; my $objFunction = &Function::new($fake_decl, $objWrapParser); my $num_args_list = $objFunction->get_num_possible_args_list(); for(my $arg_list = 0; $arg_list < $num_args_list; $arg_list++) { my $args_names_only = $objFunction->args_names_only($arg_list); my $args_type_and_name_hpp = $objFunction->args_types_and_names_with_default_values($arg_list); my $args_type_and_name_cpp = $objFunction->args_types_and_names($arg_list); if ($arg_list > 0) { $self->append("\n /// A create() convenience overload."); } my $str = sprintf("_CREATE_METHOD(\`%s\',\`%s\',\`%s\')dnl\n", $args_type_and_name_hpp, , $args_type_and_name_cpp, $args_names_only); $self->append($str) } } # void output_wrap_sig_decl($filename, $line_num, $objCSignal, $objCppfunc, $signal_name, # $bCustomCCallback, $ifdef, $commentblock, $deprecated, $deprecation_docs, # $newin, $exceptionHandler, $detail_name, $bTwoSignalMethods) sub output_wrap_sig_decl($$$$$$$$$$$$$$) { my ($self, $filename, $line_num, $objCSignal, $objCppfunc, $signal_name, $bCustomCCallback, $ifdef, $commentblock, $deprecated, $deprecation_docs, $newin, $exceptionHandler, $detail_name, $bTwoSignalMethods) = @_; # _SIGNAL_PROXY(c_signal_name, c_return_type, `', # cpp_signal_name, cpp_return_type, `',`', # refdoc_comment, exceptionHandler) # Get the signal name with underscores only (to look up docs -- they are # stored that way). my $underscored_signal_name = $signal_name; $underscored_signal_name =~ s/-/_/g; # Get the existing signal documentation from the parsed docs. my $documentation = DocsParser::lookup_documentation( "$$objCSignal{class}::$underscored_signal_name", $deprecation_docs, $newin, $objCppfunc); # Create a merged Doxygen comment block for the signal from the looked up # docs (the block will also contain a prototype of the slot as an example). my $doxycomment = $objCppfunc->get_refdoc_comment($documentation, $$objCSignal{flags}); # If there was already a previous doxygen comment, we want to merge this # one with the previous so it is one big comment. If # $commentblock is not emtpy, it contains the previous doxygen comment without # opening and closing tokens (/** and */). if($commentblock ne "") { # Strip leading whitespace $doxycomment =~ s/^\s+//; # Add a level of m4 quotes. Necessary if $commentblock contains __FT__ or __BT__. # DocsParser::lookup_documentation() adds it in $documentation. $commentblock = "`" . $commentblock . "'"; # We don't have something to add, so just use $commentblock with # opening and closing tokens added. if($doxycomment eq "") { $doxycomment = ' /**' . $commentblock . "\n */"; } else { # Merge the two comments, but remove the first three characters from the # second comment (/**) that mark the beginning of the comment. $doxycomment = substr($doxycomment, 3); $doxycomment =~ s/^\s+//; $doxycomment = ' /**' . $commentblock . "\n *\n " . $doxycomment; } } my $conversions = convert_args_c_to_cpp($objCSignal, $objCppfunc, $line_num); my $str = sprintf("_SIGNAL_PROXY(%s,%s,\`%s\',%s,%s,\`%s\',\`%s\',\`%s\',%s,\`%s\',%s,%s,%s,%s)dnl\n", $signal_name, $$objCSignal{rettype}, $objCSignal->args_types_and_names_without_object(), $$objCppfunc{name}, $$objCppfunc{rettype}, $objCppfunc->args_types_only(), $conversions, $bCustomCCallback, #When this is true, it will not write the *_callback implementation for you. $deprecated, $doxycomment, $ifdef, $exceptionHandler, $detail_name, # If a detailed name is supported (signal_name::detail_name) $bTwoSignalMethods # If separate signal_xxx() methods for detailed and general name. ); $self->append($str); } # void output_wrap_enum($filename, $line_num, $cpp_type, $c_type, # $comment, $ref_subst_in, $ref_subst_out, $gtype_func, # $deprecated, $deprecation_docs, $newin, $decl_prefix) sub output_wrap_enum($$$$$$$$$$$$$) { my ($self, $filename, $line_num, $cpp_type, $c_type, $comment, $ref_subst_in, $ref_subst_out, $gtype_func, $deprecated, $deprecation_docs, $newin, $decl_prefix) = @_; my $objEnum = GtkDefs::lookup_enum($c_type); if(!$objEnum) { $self->output_wrap_failed($c_type, "enum defs lookup failed."); return; } $objEnum->beautify_values(); my $elements = $objEnum->build_element_list($ref_subst_in, $ref_subst_out, " "); add_m4_quotes(\$elements); if(!$elements) { $self->output_wrap_failed($c_type, "unknown _WRAP_ENUM() flag"); return; } my $value_suffix = "Enum"; $value_suffix = "Flags" if($$objEnum{flags}); # Get the enum documentation from the parsed docs. my $enum_docs = DocsParser::lookup_enum_documentation("$c_type", "$cpp_type", " ", $ref_subst_in, $ref_subst_out, $deprecation_docs, $newin); # Merge the passed in comment to the existing enum documentation. $comment .= "\n * " . $enum_docs if $enum_docs ne ""; my $str = sprintf("_ENUM(%s,%s,%s,\`%s\',\`%s\',\`%s\',\`%s\',\`%s\')dnl\n", $cpp_type, $c_type, $value_suffix, $elements, $gtype_func, $comment, $deprecated, $decl_prefix ); $self->append($str); } sub output_wrap_enum_docs_only($$$$$$$$$$$) { my ($self, $filename, $line_num, $module_canonical, $cpp_type, $c_type, $comment, $ref_subst_in, $ref_subst_out, $deprecation_docs, $newin, $decl_prefix) = @_; # Get the existing enum description from the parsed docs. my $enum_docs = DocsParser::lookup_enum_documentation("$c_type", "$cpp_type", " ", $ref_subst_in, $ref_subst_out, $deprecation_docs, $newin); if($enum_docs eq "") { $self->output_wrap_failed($c_type, "failed to find documentation."); return; } # Include the enum docs in the module's enum docs group. $enum_docs .= "\n *\n * \@ingroup ${module_canonical}Enums"; # Merge the passed in comment to the existing enum documentation. $comment = "/** " . $comment . "\n * " . $enum_docs . "\n */\n"; $self->append($comment); } # void output_wrap_gerror($filename, $line_num, $cpp_type, $c_type, $domain, # $class_docs, $ref_subst_in, $ref_subst_out, $gtype_func, # $deprecated, $deprecation_docs, $newin, $decl_prefix) sub output_wrap_gerror($$$$$$$$$$$$$$) { my ($self, $filename, $line_num, $cpp_type, $c_type, $domain, $class_docs, $ref_subst_in, $ref_subst_out, $gtype_func, $deprecated, $deprecation_docs, $newin, $decl_prefix) = @_; my $objDefsParser = $$self{objDefsParser}; my $objEnum = GtkDefs::lookup_enum($c_type); if(!$objEnum) { $self->output_wrap_failed($c_type, "enum defs lookup failed."); return; } # Shouldn't happen, and if it does, I'd like to know that. warn if($$objEnum{flags}); $objEnum->beautify_values(); # cut off the module prefix, e.g. GDK_ my $prefix = $domain; $prefix =~ s/^[^_]+_//; # Chop off the domain prefix, because we put the enum into the class. unshift(@$ref_subst_in, "^${prefix}_"); unshift(@$ref_subst_out, ""); my $elements = $objEnum->build_element_list($ref_subst_in, $ref_subst_out, " "); add_m4_quotes(\$elements); # Get the enum documentation from the parsed docs. my $enum_docs = DocsParser::lookup_enum_documentation("$c_type", "Code", " ", $ref_subst_in, $ref_subst_out, $deprecation_docs, $newin); # Prevent Doxygen from auto-linking to a class called Error. $enum_docs =~ s/([^%])(Error code)/$1%$2/g; # Add @newin and @deprecated to the class documentation, if appropriate. my $extra_class_docs = ""; if ($newin ne "" and !($class_docs =~ /\@newin/)) { $extra_class_docs .= "\n *\n *" if $class_docs; $extra_class_docs .= " \@newin{$newin}"; } if ($deprecation_docs ne "" and !($class_docs =~ /\@deprecated/)) { $extra_class_docs .= "\n *\n *" if $class_docs or $extra_class_docs; $extra_class_docs .= " \@deprecated $deprecation_docs"; } if ($extra_class_docs ne "") { # $class_docs has got ` and ' replaced and m4 quotes added in WrapParser:: # on_comment_doxygen() and extract_preceding_documentation(). # Fix $extra_class_docs here. $deprecation_docs can contain any characters. add_m4_quotes(\$extra_class_docs); $class_docs .= $extra_class_docs; } # Prevent Doxygen from auto-linking to a class called Exception. $class_docs =~ s/([^%])(Exception class)/$1%$2/g; my $str = sprintf("_GERROR(%s,%s,%s,\`%s\',\`%s\',\`%s\',\`%s\',\`%s\',\`%s\')dnl\n", $cpp_type, $c_type, $domain, $elements, $gtype_func, $class_docs, $enum_docs, $deprecated, $decl_prefix ); $self->append($str); } # _PROPERTY_PROXY(name, cpp_type) and _CHILD_PROPERTY_PROXY(name, cpp_type) # void output_wrap_any_property($filename, $line_num, $name, $cpp_type, $c_class, $deprecated, $deprecation_docs, $objProperty, $proxy_macro) sub output_wrap_any_property($$$$$$$$$$) { my ($self, $filename, $line_num, $name, $cpp_type, $c_class, $deprecated, $deprecation_docs, $newin, $objProperty, $proxy_macro) = @_; my $objDefsParser = $$self{objDefsParser}; # We use a suffix to specify a particular Glib::PropertyProxy* class. my $proxy_suffix = ""; # Read/Write: if ($objProperty->get_construct_only()) { # construct-only functions can be read, but not written. $proxy_suffix = "_ReadOnly"; if (!$objProperty->get_readable()) { $self->output_wrap_failed($name, "attempt to wrap write-only and construct-only property."); return; } } elsif (!$objProperty->get_readable()) { $proxy_suffix = "_WriteOnly"; } elsif (!$objProperty->get_writable()) { $proxy_suffix = "_ReadOnly"; } # Convert - to _ so we can use it in C++ method and variable names: my $name_underscored = $name; $name_underscored =~ tr/-/_/; # Get the existing property documentation, if any, from the parsed docs. my $documentation = DocsParser::lookup_documentation( "$$objProperty{class}:$name_underscored", $deprecation_docs, $newin); if ($documentation ne "") { # Remove leading "/**" and trailing "*/". They will be added by the m4 macro. $documentation =~ s/^\s*\/\*\*\s*//; $documentation =~ s/\s*\*\/\s*$//; } if ($documentation =~ /^`?[*\s]* (?: \@newin\{[\d,]+\} |[Ss]ince[:\h]+\d+\.\d+ |\@deprecated\s |[Dd]eprecated[:\s] )/x) { # The documentation begins with a "@newin", "Since", "@deprecated" or # "Deprecated" line. Get documentation also from the Property object, # but don't add another @newin or @deprecated. my $objdoc = $objProperty->get_docs("", ""); if ($objdoc ne "") { $documentation = "$objdoc\n *\n * $documentation"; } } elsif ($documentation eq "") { # Try to get the (usually short) documentation from the Property object. $documentation = $objProperty->get_docs($deprecation_docs, $newin); } # Default value, if available: my $default_value = $objProperty->get_default_value(); if (defined($default_value)) { DocsParser::convert_value_to_cpp(\$default_value); # Add double quotes around a string value. if ($objProperty->get_type() eq "GParamString") { $default_value = "\"" . $default_value . "\""; } $default_value = "Default value: $default_value"; add_m4_quotes(\$default_value); if ($documentation ne "") { $documentation .= "\n *\n * "; } $documentation .= $default_value; } #Declaration: if($deprecated ne "") { $self->append("\n_DEPRECATE_IFDEF_START\n"); } my $str = sprintf("$proxy_macro(%s,%s,%s,%s,%s,`%s')dnl\n", $name, $name_underscored, $cpp_type, $proxy_suffix, $deprecated, $documentation ); $self->append($str); $self->append("\n"); # If the property is not already read-only, and the property can be read, # then add a second const accessor for a read-only propertyproxy: if( ($proxy_suffix ne "_ReadOnly") && ($objProperty->get_readable()) ) { my $str = sprintf("$proxy_macro(%s,%s,%s,%s,%s,`%s')dnl\n", $name, $name_underscored, $cpp_type, "_ReadOnly", $deprecated, $documentation ); $self->append($str); } if($deprecated ne "") { $self->append("\n_DEPRECATE_IFDEF_END"); } } # _PROPERTY_PROXY(name, cpp_type) # void output_wrap_property($filename, $line_num, $name, $cpp_type, $file_deprecated, # $deprecated, $deprecation_docs) sub output_wrap_property($$$$$$$$$$) { my ($self, $filename, $line_num, $name, $cpp_type, $c_class, $file_deprecated, $deprecated, $deprecation_docs, $newin) = @_; my $objProperty = GtkDefs::lookup_property($c_class, $name); if($objProperty eq 0) #If the lookup failed: { $self->output_wrap_failed($name, "property defs lookup failed."); } else { Output::check_deprecation($file_deprecated, $objProperty->get_deprecated(), $deprecated, $name, "property", "PROPERTY"); $self->output_wrap_any_property($filename, $line_num, $name, $cpp_type, $c_class, $deprecated, $deprecation_docs, $newin, $objProperty, "_PROPERTY_PROXY"); } } # _CHILD_PROPERTY_PROXY(name, cpp_type) # void output_wrap_child_property($filename, $line_num, $name, $cpp_type, $file_deprecated, # $deprecated, $deprecation_docs) sub output_wrap_child_property($$$$$$$$$$) { my ($self, $filename, $line_num, $name, $cpp_type, $c_class, $file_deprecated, $deprecated, $deprecation_docs, $newin) = @_; my $objChildProperty = GtkDefs::lookup_child_property($c_class, $name); if($objChildProperty eq 0) #If the lookup failed: { $self->output_wrap_failed($name, "child property defs lookup failed."); } else { Output::check_deprecation($file_deprecated, $objChildProperty->get_deprecated(), $deprecated, $name, "child property", "CHILD_PROPERTY"); $self->output_wrap_any_property($filename, $line_num, $name, $cpp_type, $c_class, $deprecated, $deprecation_docs, $newin, $objChildProperty, "_CHILD_PROPERTY_PROXY"); } } sub add_m4_quotes($) { my ($text) = @_; # __BT__ and __FT__ are M4 macros defined in the base.m4 file that produce # a "`" and a "'" resp. without M4 errors. my %m4_quotes = ( "`" => "'__BT__`", "'" => "'__FT__`", ); $$text =~ s/([`'])/$m4_quotes{$1}/g; $$text = "`" . $$text . "'"; } # void output_temp_g1($module, $glibmm_version) e.g. output_temp_g1(gtkmm, 2.38.0) sub output_temp_g1($$$) { my ($self, $module, $glibmm_version) = @_; # Write out *.g1 temporary file open(FILE, '>', "$$self{tmpdir}/gtkmmproc_$$.g1"); # $$ is the Process ID print FILE "include(base.m4)dnl\n"; my $module_canonical = Util::string_canonical($module); #In case there is a / character in the module. print FILE "_START($$self{source},$module,$module_canonical,$glibmm_version)dnl\n"; print FILE join("", @{$$self{out}}); print FILE "_END()\n"; close(FILE); } sub make_g2_from_g1($) { my ($self) = @_; # Execute m4 to get *.g2 file: system("$$self{m4path} $$self{m4args} \"$$self{tmpdir}/gtkmmproc_$$.g1\" > \"$$self{tmpdir}/gtkmmproc_$$.g2\""); return ($? >> 8); } # void write_sections_to_files() # This is where we snip the /tmp/gtkmmproc*.g2 file into sections (,h, .cc, _private.h) sub write_sections_to_files() { my ($self) = @_; my $fname_h = "$$self{destdir}/$$self{source}.h"; my $fname_ph = "$$self{destdir}/private/$$self{source}_p.h"; my $fname_cc = "$$self{destdir}/$$self{source}.cc"; open(INPUT, '<', "$$self{tmpdir}/gtkmmproc_$$.g2"); # $$ is the process ID. # open temporary file for each section open(OUTPUT_H, '>', "$fname_h.tmp"); open(OUTPUT_PH, '>', "$fname_ph.tmp"); open(OUTPUT_CC, '>', "$fname_cc.tmp"); my $oldfh = select(OUTPUT_H); my $blank = 0; while() { # section switching if(/^#S 0/) { select(OUTPUT_H); next; } if(/^#S 1/) { select(OUTPUT_PH); next; } if(/^#S 2/) { select(OUTPUT_CC); next; } # get rid of bogus blank lines if(/^\s*$/) { ++$blank; } else { $blank = 0; } next if($blank > 2); print $_; } select($oldfh); close(INPUT); close(OUTPUT_H); close(OUTPUT_PH); close(OUTPUT_CC); foreach($fname_h, $fname_ph, $fname_cc) { # overwrite the source file only if it has actually changed # Win32 does fail at this, so we do the two steps separately: #system("cmp -s '$_.tmp' '$_' || cp '$_.tmp' '$_'" ; rm -f '$_.tmp'); system("cmp -s '$_.tmp' '$_' || cp '$_.tmp' '$_'"); system("rm -f '$_.tmp'"); } } sub remove_temp_files($) { my ($self) = @_; system("rm -f \"$$self{tmpdir}/gtkmmproc_$$.g1\""); system("rm -f \"$$self{tmpdir}/gtkmmproc_$$.g2\""); } # procedure for generating CONVERT macros, C declarations (for C output # variables), and INITIALIZE macros (to set the corresponding C++ parameters # from the C output parameters) for the specified argument list # (string, string, string) convert_args_cpp_to_c($objCppfunc, $objCDefsFunc, $static, $wrap_line_number,$automatic_error, $index = 0) # The return is an array of 3 strings: The _CONVERT macros, the C declarations # and the _INITIALIZE macros. # The optional index specifies which arg list out of the possible combination # of arguments based on whether any arguments are optional. index = 0 ==> all # the arguments. sub convert_args_cpp_to_c($$$$$) { my ($objCppfunc, $objCDefsFunc, $static, $wrap_line_number, $automatic_error, $index) = @_; $automatic_error = "" unless defined $automatic_error; $index = 0 unless defined $index; my $cpp_param_names = $$objCppfunc{param_names}; my $cpp_param_types = $$objCppfunc{param_types}; my $cpp_param_flags = $$objCppfunc{param_flags}; my $c_param_name_mappings = $$objCppfunc{param_mappings}; my $c_param_types = $$objCDefsFunc{param_types}; my $c_param_names = $$objCDefsFunc{param_names}; my @conversions = (); my @declarations = (); my @initializations = (); my $num_c_args_expected = scalar(@{$c_param_types}); if( !($static) ) { $num_c_args_expected--; } #The cpp method will need an Object* paramater at the start. my $num_cpp_args = scalar(@{$cpp_param_types}); my $has_output_param = 0; my $output_param_index; # See if there is an output parameter. If so, temporarily decrement the # number of C++ arguments so that the possible GError addition works and # note the existence. if(defined($$c_param_name_mappings{"OUT"})) { $num_cpp_args--; $has_output_param = 1; $output_param_index = $$c_param_name_mappings{"OUT"}; } else { # Check for possible void return mismatch (warn if the option was # specified to gmmproc at the command line). if($main::return_mismatches && $$objCppfunc{rettype} eq "void" && $$objCDefsFunc{rettype} ne "void") { Output::error( "void return of $$objCppfunc{name}() does not match the " . "$$objCDefsFunc{rettype} return type.\n"); } } # add implicit last error parameter; if ( $automatic_error ne "" && $num_cpp_args == ($num_c_args_expected - 1) && ${$c_param_types}[-1] eq "GError**" ) { $num_cpp_args++; $cpp_param_names = [@{$cpp_param_names},"gerror"]; $cpp_param_types = [@{$cpp_param_types},"GError*&"]; $cpp_param_flags = [@{$cpp_param_flags}, 0]; # Map from the C gerror param name to the newly added C++ param index. # The correct C++ index to map to (from the C name) depends on if there # is an output parameter since it will be readded. my $cpp_index = $num_cpp_args - 1; $cpp_index++ if($has_output_param); $$c_param_name_mappings{$$c_param_names[$num_c_args_expected]} = $cpp_index; } # If the method has a slot temporarily decrement the C arg count when # comparing the C++ and C argument count because the C function would # have a final 'gpointer data' parameter. $num_c_args_expected-- if ($$objCppfunc{slot_name}); if ( $num_cpp_args != $num_c_args_expected ) { Output::error( "convert_args_cpp_to_c(): Incorrect number of arguments. (%d != %d)\n", $num_cpp_args, $num_c_args_expected ); $objCppfunc->dump(); $objCDefsFunc->dump(); return ("", "", ""); } # Reincrement the expected C argument count if there is a slot. $num_c_args_expected++ if ($$objCppfunc{slot_name}); # If there is an output parameter it must be processed so re-increment (now) # the number of C++ arguments. $num_cpp_args++ if($has_output_param); if ($index == 0) { # Check if the C param names in %$c_param_name_mappings exist. foreach my $mapped_c_param_name (keys %$c_param_name_mappings) { next if $mapped_c_param_name eq "" || $mapped_c_param_name eq "OUT"; if (!grep($_ eq $mapped_c_param_name, @$c_param_names)) { Output::error("convert_args_cpp_to_c(): There is no C argument called \"$mapped_c_param_name\"\n"); $objCDefsFunc->dump(); return ("", "", ""); } } } # Get the desired argument list combination. my $possible_arg_list = $$objCppfunc{possible_args_list}[$index]; # Tells if slot code should be included or not based on if a slot # parameter is optional. $$objCppfunc{include_slot} = 0; # Loop through the parameters: my $i; my $cpp_param_max = $num_cpp_args; # if( !($static) ) { $cpp_param_max++; } for ($i = 0; $i < $cpp_param_max; $i++) { # Skip the output parameter because it is handled in output_wrap_meth(). next if($has_output_param && $i == $output_param_index); #index of C parameter: my $iCParam = $i; if( !($static) ) { $iCParam++; } # Account for a possible C++ output param in the C++ arg list. $iCParam-- if($has_output_param && $i > $output_param_index); my $c_param_name = $$c_param_names[$iCParam]; my $cpp_param_index = $i; $cpp_param_index = $$c_param_name_mappings{$c_param_name} if(defined($$c_param_name_mappings{$c_param_name})); my $cppParamType = $$cpp_param_types[$cpp_param_index]; $cppParamType =~ s/ &/&/g; #Remove space between type and & $cppParamType =~ s/ \*/*/g; #Remove space between type and * my $cppParamName = $$cpp_param_names[$cpp_param_index]; my $cParamType = $$c_param_types[$iCParam]; if(!($possible_arg_list =~ /\b$cpp_param_index\b/)) { # If the C++ index is not found in the list of desired parameters, pass # nullptr to the C func unless the param is not optional (applies to a # possibly added GError parameter). if ($$cpp_param_flags[$cpp_param_index] & FLAG_PARAM_OPTIONAL) { push(@conversions, "nullptr"); next; } } if ($$cpp_param_flags[$cpp_param_index] & FLAG_PARAM_OUTPUT) { # Get a generic name for the C output parameter name. my $cOutputParamName = "g_" . $$c_param_names[$iCParam]; my $cOutputParamType = $cParamType; # Remove a possible final '*' from the output parameter type because it # will be passed by C reference (&name). $cOutputParamType =~ s/\*$//; # Only initialize pointers to nullptr. Otherwise, use the default # constructor of the type. my $initialization = ""; if($cOutputParamType =~ /\*$/) { $initialization = " = nullptr"; } else { $initialization = " = $cOutputParamType()"; } push(@declarations, " $cOutputParamType $cOutputParamName$initialization;"); push(@conversions, "&" . $cOutputParamName); push(@initializations, sprintf("_INITIALIZE(\`%s\',%s,%s,%s,%s);", $cppParamType, $cOutputParamType, $cppParamName, $cOutputParamName, $wrap_line_number)); next; } # If dealing with a slot. if ($$objCppfunc{slot_name} eq $cppParamName) { if ($$objCppfunc{slot_callback}) { # The conversion for the slot is the address of the callback. push(@conversions, "&" . $$objCppfunc{slot_callback}); } else { Output::error( "convert_args_cpp_to_c(): Missing a slot callback. " . "Specify it with the 'slot_callback' option.\n",); $objCppfunc->dump(); $objCDefsFunc->dump(); return ("", "", ""); } # Get the slot type without the const and the & and store it so # it can be passed to the m4 _*METHOD macros. $cppParamType =~ /^const\s+(.*)&/; $$objCppfunc{slot_type} = $1; # Signal that the slot code should be included. $$objCppfunc{include_slot} = 1; next; } if ($cppParamType ne $cParamType) #If a type conversion is needed. { my $std_conversion = sprintf("_CONVERT(%s,%s,%s,%s)", $cppParamType, $cParamType, $cppParamName, $wrap_line_number); # Shall an empty string be translated to a nullptr or to a pointer to # an empty string? The default is "pointer to an empty string" for # mandatory parameters, nullptr for optional parameters. if (($$cpp_param_flags[$cpp_param_index] & FLAG_PARAM_NULLPTR) || (($$cpp_param_flags[$cpp_param_index] & (FLAG_PARAM_OPTIONAL | FLAG_PARAM_EMPTY_STRING)) == FLAG_PARAM_OPTIONAL && # OPTIONAL and not EMPTY_STRING $cppParamType =~ /^(const\s+)?(std::string|Glib::ustring)&?/)) { push(@conversions, "$cppParamName.empty() ? nullptr : " . $std_conversion); } else { push(@conversions, $std_conversion); } } else { push(@conversions, $cppParamName); } } # Append the final slot copy parameter to the C function if the method # has a slot. The m4 macros assume that that parameter name is # "slot_copy". The m4 macros will either copy the slot to the # "slot_copy" variable or set it to the address of the slot itself if # the slot should not be copied. if ($$objCppfunc{slot_name}) { if ($$objCppfunc{include_slot}) { push(@conversions, "slot_copy"); } else { push(@conversions, "nullptr") } } return ( join(", ", @conversions), join("\n", @declarations), join("\n ", @initializations) ); } # procedure for generating CONVERT macros # Ignores the first C 'self' argument. # $string convert_args_c_to_cpp($objCDefsFunc, $objCppFunc, $wrap_line_number) sub convert_args_c_to_cpp($$$) { my ($objCDefsFunc, $objCppfunc, $wrap_line_number) = @_; my $cpp_param_names = $$objCppfunc{param_names}; my $cpp_param_types = $$objCppfunc{param_types}; my $c_param_types = $$objCDefsFunc{param_types}; my $c_param_names = $$objCDefsFunc{param_names}; # This variable stores the C++ parameter mappings from the C++ # index to the C param name if the mappings exist. my %cpp_index_param_mappings; # Fill the index to param names mappings from the c param names to index # mappings variable above. @cpp_index_param_mappings{values %{$$objCppfunc{param_mappings}}} = keys %{$$objCppfunc{param_mappings}}; my @result; my $num_c_args = scalar(@{$c_param_types}); # If the the function has been marked as a function that throws errors # (Glib::Error) don't count the last GError** argument. $num_c_args-- if($$objCDefsFunc{throw_any_errors}); my $num_cpp_args = scalar(@{$cpp_param_types}); # If the method has a slot temporarily increment the C++ arg count when # comparing the C++ and C argument count because the C function would # have a final 'gpointer data' parameter and the C++ method would not. $num_cpp_args++ if ($$objCppfunc{slot_name}); if ( ($num_cpp_args + 1) != $num_c_args ) { Output::error( "convert_args_c_to_cpp(): Incorrect number of arguments. (%d != %d)\n", $num_cpp_args + 1, $num_c_args); $objCppfunc->dump(); $objCDefsFunc->dump(); return ""; } # Re-decrement the expected C++ argument count if there is a slot. $num_cpp_args-- if ($$objCppfunc{slot_name}); # Loop through the C++ parameters: my $i; my $cpp_param_max = $num_cpp_args; my $num_c_args = scalar(@{$c_param_names}); for ($i = 0; $i < $cpp_param_max; $i++) { my $cParamName = ""; my $c_index = 0; if (defined $cpp_index_param_mappings{$i}) { # If a mapping exists from the current index to a C param name, # use that C param for the conversion. $cParamName = $cpp_index_param_mappings{$i}; # Get the C index based on the C param name. ++$c_index until $c_index >= $num_c_args || $$c_param_names[$c_index] eq $cParamName; if ($c_index >= $num_c_args) { Output::error("convert_args_c_to_cpp(): There is no C argument called \"$cParamName\"\n"); $objCDefsFunc->dump(); return ""; } } else { # If no mapping exists, the C index is the C++ index + 1 (to skip # The 'self' argument of the C function). $c_index = $i + 1; $cParamName = $$c_param_names[$c_index]; } my $cParamType = $$c_param_types[$c_index]; my $cppParamName = $$cpp_param_names[$i]; my $cppParamType = $$cpp_param_types[$i]; $cppParamType =~ s/ &/&/g; #Remove space between type and &. $cppParamType =~ s/ \*/*/g; #Remove space between type and * if ($$objCppfunc{slot_name}) { # If the current parameter is the slot parameter insert the # derefenced name of the variable containing the slot which is # assumed to be '*slot'. The m4 macro is responsible for ensuring # that the variable is declared and the slot in the 'user_data' C # param is placed in the variable. if ($$objCppfunc{slot_name} eq $cppParamName) { push(@result, "*slot"); # Get the slot type without the const and the '&' and store it so # it can be passed to the m4 macro. $cppParamType =~ /^const\s+(.*)&/; # If the type does not contain # any '::' then assume that it is in the library standard namespace # by prepending '__NAMESPACE__::' to it which the m4 macros will # translate to the library namespace. my $plainCppParamType = $1; $plainCppParamType = "__NAMESPACE__::" . $plainCppParamType if (!($plainCppParamType =~ /::/)); $$objCppfunc{slot_type} = $plainCppParamType; # Store the name of the C data parameter so it can be passed # to the m4 macro so it can extract the slot. $$objCppfunc{c_data_param_name} = $$c_param_names[$num_c_args - 1]; next; } } if ($cParamType ne $cppParamType) #If a type conversion is needed. { push(@result, sprintf("_CONVERT(%s,%s,%s,%s)\n", $cParamType, $cppParamType, $cParamName, $wrap_line_number) ); } else { push(@result, $cParamName); } } return join(", ",@result); } # generates the XXX in g_object_new(get_type(), XXX): A list of property names # and values. Uses the cpp arg name as the property name. # # - The optional index specifies which arg list out of the possible combination # of arguments based on whether any arguments are optional. index = 0 ==> all # the arguments. # # - The errthrow parameter tells if the C new function has a final GError** # parameter. That parameter is ignored since it will not form part of the # property list. # # $string get_ctor_properties($objCppfunc, $objCDefsFunc, $wrap_line_number, $errthrow, $index = 0) sub get_ctor_properties($$$$$$) { my ($objCppfunc, $objCDefsFunc, $wrap_line_number, $errthrow, $index) = @_; $index = 0 unless defined $index; my $cpp_param_names = $$objCppfunc{param_names}; my $cpp_param_types = $$objCppfunc{param_types}; my $cpp_param_flags = $$objCppfunc{param_flags}; my $c_param_name_mappings = $$objCppfunc{param_mappings}; my $c_param_types = $$objCDefsFunc{param_types}; my $c_param_names = $$objCDefsFunc{param_names}; my @result; my $num_args = scalar(@{$c_param_types}); # If the C function has a final GError** parameter, ignore it. $num_args-- if ($errthrow eq "errthrow"); my $num_cpp_args = scalar(@{$cpp_param_types}); if ( $num_cpp_args != $num_args ) { Output::error("get_ctor_properties(): Incorrect number of arguments. (%d != %d)\n", $num_cpp_args, $num_args ); return ""; } if ($index == 0) { # Check if the C param names in %$c_param_name_mappings exist. foreach my $mapped_c_param_name (keys %$c_param_name_mappings) { next if $mapped_c_param_name eq ""; if (!grep($_ eq $mapped_c_param_name, @$c_param_names)) { Output::error("get_ctor_properties(): There is no C argument called \"$mapped_c_param_name\"\n"); $objCDefsFunc->dump(); return ("", "", ""); } } } # Get the desired argument list combination. my $possible_arg_list = $$objCppfunc{possible_args_list}[$index]; # Loop through the parameters: my $i = 0; for ($i = 0; $i < $num_args; $i++) { my $c_param_name = $$c_param_names[$i]; my $cpp_param_index = $i; $cpp_param_index = $$c_param_name_mappings{$c_param_name} if(defined($$c_param_name_mappings{$c_param_name})); my $cppParamType = $$cpp_param_types[$cpp_param_index]; $cppParamType =~ s/ &/&/g; #Remove space between type and & $cppParamType =~ s/ \*/*/g; #Remove space between type and * my $cppParamName = $$cpp_param_names[$cpp_param_index]; my $cParamType = $$c_param_types[$i]; # Property name: push(@result, "\"" . $cppParamName . "\""); if(!($possible_arg_list =~ /\b$cpp_param_index\b/)) { # If the C++ index is not found in the list of desired parameters, pass # nullptr to the C func unless the param is not optional. if ($$cpp_param_flags[$cpp_param_index] & FLAG_PARAM_OPTIONAL) { push(@result, "nullptr"); next; } } # C property value: if ($cppParamType ne $cParamType) #If a type conversion is needed. { push(@result, sprintf("_CONVERT(%s,%s,%s,%s)", $cppParamType, $cParamType, $cppParamName, $wrap_line_number) ); } else { push(@result, $cppParamName); } } return join(", ", @result); } ### Convert _WRAP to a corba method # _CORBA_METHOD(retype, method_name,args, arg_names_only) - implemented in libbonobomm. # void output_wrap_corba_method($filename, $line_num, $objCppFunc) sub output_wrap_corba_method($$$$) { my ($self, $filename, $line_num, $objCppfunc) = @_; my $str = sprintf("_CORBA_METHOD(%s,%s,\`%s\',\`%s\')dnl\n", $$objCppfunc{rettype}, $$objCppfunc{name}, $objCppfunc->args_types_and_names(), $objCppfunc->args_names_only() ); $self->append($str); } sub output_implements_interface($$) { my ($self, $interface, $ifdef) = @_; my $str = sprintf("_IMPLEMENTS_INTERFACE_CC(%s, %s)dnl\n", $interface, $ifdef); $self->append($str); } 1; # indicate proper module load.