\input texinfo @c -*- Texinfo -*- @setfilename reno-1.info @ifinfo @format START-INFO-DIR-ENTRY * Reno 1: (reno). The GNU C++ Renovation Project, Phase 1. END-INFO-DIR-ENTRY @end format @end ifinfo @ifinfo Copyright @copyright{} 1992, 1993, 1994 Free Software Foundation, Inc. Permission is granted to make and distribute verbatim copies of this manual provided the copyright notice and this permission notice are preserved on all copies. @ignore Permission is granted to process this file through TeX and print the results, provided the printed document carries a copying permission notice identical to this one except for the removal of this paragraph (this paragraph not being relevant to the printed manual). @end ignore Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided also that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions. @end ifinfo @setchapternewpage odd @settitle GNU C++ Renovation Project @c @smallbook @titlepage @finalout @title GNU C++ Renovation Project @subtitle Phase 1.3 @author Brendan Kehoe, Jason Merrill, @author Mike Stump, Michael Tiemann @page Edited March, 1994 by Roland Pesch (@code{pesch@@cygnus.com}) @vskip 0pt plus 1filll Copyright @copyright{} 1992, 1993, 1994 Free Software Foundation, Inc. Permission is granted to make and distribute verbatim copies of this manual provided the copyright notice and this permission notice are preserved on all copies. @ignore Permission is granted to process this file through Tex and print the results, provided the printed document carries copying permission notice identical to this one except for the removal of this paragraph (this paragraph not being relevant to the printed manual). @end ignore Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided also that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions. @end titlepage @ifinfo @node Top @top @sc{gnu} C++ Renovation Project This file describes the goals of the @sc{gnu} C++ Renovation Project, and its accomplishments to date (as of Phase 1.3). It also discusses the remaining divergences from @sc{gnu} C++, and how the name encoding in @sc{gnu} C++ differs from the sample encoding in @cite{The Annotated C++ Reference Manual}. @c This is not a good place to introduce the acronym ARM because it's @c info-only. @menu * Introduction:: What is the GNU C++ Renovation Project? * Changes:: Summary of changes since previous GNU C++ releases. * Plans:: Plans for Reno-2. * Templates:: The template implementation. * ANSI:: GNU C++ conformance to ANSI C++. * Encoding:: Name encoding in GNU C++. @end menu @end ifinfo @node Introduction @chapter Introduction As you may remember, @sc{gnu} C++ was the first native-code C++ compiler available under Unix (December 1987). In November 1988, it was judged superior to the AT&T compiler in a Unix World review. In 1990 it won a Sun Observer ``Best-Of'' award. But now, with new requirements coming out of the @sc{ansi} C++ committee and a growing backlog of bugs, it's clear that @sc{gnu} C++ needs an overhaul. The C++ language has been under development since 1982. It has evolved significantly since its original incarnation (C with Classes), addressing many commercial needs and incorporating many lessons learned as more and more people started using ``object-oriented'' programming techniques. In 1989, the first X3J16 committee meeting was held in Washington DC; in the interest of users, C++ was going to be standardized. As C++ has become more popular, more demands have been placed on its compilers. Some compilers are up to the demands, others are not. @sc{gnu} C++ was used to prototype several features which have since been incorporated into the standard, most notably exception handling. While @sc{gnu} C++ has been an excellent experimental vehicle, it did not have the resources that AT&T, Borland, or Microsoft have at their disposal. We believe that @sc{gnu} C++ is an important compiler, providing users with many of the features that have made @sc{gnu} C so popular: fast compilation, good error messages, innovative features, and full sources that may be freely redistributed. The purpose of this overhaul, dubbed the @var{@sc{gnu} C++ Renovation Project}, is to take advantage of the functionality that @sc{gnu} C++ offers today, to strengthen its base technology, and put it in a position to remain---as other @sc{gnu} software currently is---the technical leader in the field. This release represents the latest phase of work in strengthening the compiler on a variety of points. It includes many months of work concentrated on fixing many of the more egregious bugs that presented themselves in the compiler recently. @ignore @c FIXME-- update? Nearly 85% of all bugs reported in the period of February to September of 1992 were fixed as part of the work in the first phase. @end ignore In the coming months, we hope to continue expanding and enhancing the quality and dependability of the industry's only freely redistributable C++ compiler. @node Changes @chapter Changes in Behavior in @sc{gnu} C++ The @sc{gnu} C++ compiler continues to improve and change. A major goal of our work has been to continue to bring the compiler into compliance with the draft @sc{ansi} C++ standard, and with @cite{The Annotated C++ Reference Manual} (the @sc{arm}). This section outlines most of the user-noticeable changes that might be encountered during the normal course of use. @menu * Summary of Phase 1.3:: * Major changes:: * New features:: * Enhancements and bug fixes:: * Problems with debugging:: @end menu @node Summary of Phase 1.3 @section Summary of Changes in Phase 1.3 The bulk of this note discusses the cumulative effects of the @sc{gnu} C++ Renovation Project to date. The work during its most recent phase (1.3) had these major effects: @itemize @bullet @item The standard compiler driver @code{g++} is now the faster compiled version, rather than a shell script. @item Nested types work much better; notably, nesting is no longer restricted to nine levels. @item Better @sc{arm} conformance on member access control. @item The compiler now always generates default assignment operators (@samp{operator =}), copy constructors (@samp{X::X(X&)}), and default constructors (@samp{X::X()}) whenever they are required. @item The new draft @sc{ansi} standard keyword @code{mutable} is supported. @item @samp{-fansi-overloading} is the default, to comply better with the @sc{arm} (at some cost in compatibility to earlier versions of @sc{gnu} C++). @item More informative error messages. @item System include files are automatically treated as if they were wrapped in @samp{extern "C" @{ @}}. @item The new option @samp{-falt-external-templates} provides alternate template instantiation semantics. @item Operator declarations are now checked more strictly. @item You can now use template type arguments in the template parameter list. @item You can call the destructor for any type. @item The compiler source code is better organized. @item You can specify where to instantiate template definitions explicitly. @end itemize Much of the work in Phase 1.3 went to elimination of known bugs, as well as the major items above. During the span of Phase 1.3, there were also two changes associated with the compiler that, while not specifically part of the C++ Renovation project, may be of interest: @itemize @bullet @item @code{gcov}, a code coverage tool for @sc{gnu cc}, is now available from Cygnus Support. (@code{gcov} is free software, but the @sc{fsf} has not yet accepted it.) @xref{Gcov,, @code{gcov}: a Test Coverage Program, gcc.info, Using GNU CC}, for more information (in Cygnus releases of that manual). @item @sc{gnu} C++ now supports @dfn{signatures}, a language extension to provide more flexibility in abstract type definitions. @xref{C++ Signatures,, Type Abstraction using Signatures, gcc.info, Using GNU CC}. @end itemize @node Major changes @section Major Changes This release includes four wholesale rewrites of certain areas of compiler functionality: @enumerate 1 @item Argument matching. @sc{gnu} C++ is more compliant with the rules described in Chapter 13, ``Overloading'', of the @sc{arm}. This behavior is the default, though you can specify it explicitly with @samp{-fansi-overloading}. For compatibility with earlier releases of @sc{gnu} C++, specify @samp{-fno-ansi-overloading}; this makes the compiler behave as it used to with respect to argument matching and name overloading. @item Default constructors/destructors. Section 12.8 of the @sc{arm}, ``Copying Class Objects'', and Section 12.1, ``Constructors'', state that a compiler must declare such default functions if the user does not specify them. @sc{gnu} C++ now declares, and generates when necessary, the defaults for constructors and destructors you might omit. In particular, assignment operators (@samp{operator =}) behave the same way whether you define them, or whether the compiler generates them by default; taking the address of the default @samp{operator =} is now guaranteed to work. Default copy constructors (@samp{X::X(X&)}) now function correctly, rather than calling the copy assignment operator for the base class. Finally, constructors (@samp{X::X()}), as well as assignment operators and copy constructors, are now available whenever they are required. @c XXX This may be taken out eventually... @item Binary incompatibility. There are no new binary incompatibilities in Phase 1.3, but Phase 1.2 introduced two binary incompatibilities with earlier releases. First, the functionality of @samp{operator new} and @samp{operator delete} changed. Name encoding (``mangling'') of virtual table names changed as well. Libraries built with versions of the compiler earlier than Phase 1.2 must be compiled with the new compiler. (This includes the Cygnus Q2 progressive release and the FSF 2.4.5 release.) @item New @code{g++} driver. A new binary @code{g++} compiler driver replaces the shell script. The new driver executes faster. @end enumerate @node New features @section New features @itemize @bullet @item The compiler warns when a class contains only private constructors or destructors, and has no friends. At the request of some of our customers, we have added a new option, @samp{-Wctor-dtor-privacy} (on by default), and its negation, @samp{-Wno-ctor-dtor-privacy}, to control the emission of this warning. If, for example, you are working towards making your code compile warning-free, you can use @w{@samp{-Wall -Wno-ctor-dtor-privacy}} to find the most common warnings. @item There is now a mechanism which controls exactly when templates are expanded, so that you can reduce memory usage and program size and also instantiate them exactly once. You can control this mechanism with the option @samp{-fexternal-templates} and its corresponding negation @samp{-fno-external-templates}. Without this feature, space consumed by template instantiations can grow unacceptably in large-scale projects with many different source files. The default is @samp{-fno-external-templates}. You do not need to use the @samp{-fexternal-templates} option when compiling a file that does not define and instantiate templates used in other files, even if those files @emph{are} compiled with @samp{-fexternal-templates}. The only side effect is an increase in object size for each file that was compiled without @samp{-fexternal-templates}. When your code is compiled with @samp{-fexternal-templates}, all template instantiations are external; this requires that the templates be under the control of @samp{#pragma interface} and @samp{#pragma implementation}. All instantiations that will be needed should be in the implementation file; you can do this with a @code{typedef} that references the instantiation needed. Conversely, when you compile using the option @samp{-fno-external-templates}, all template instantiations are explicitly internal. @samp{-fexternal-templates} also allows you to finally separate class template function definitions from their declarations, thus speeding up compilation times for every file that includes the template declaration. Now you can have tens or even hundreds of lines in template declarations, and thousands or tens of thousands of lines in template definitions, with the definitions only going through the compiler once instead of once for each source file. It is important to note that you must remember to externally instantiate @emph{all} templates that are used from template declarations in interface files. If you forget to do this, unresolved externals will occur. In the example below, the object file generated (@file{example.o}) will contain the global instantiation for @samp{Stack}. If other types of @samp{Stack} are needed, they can be added to @file{example.cc} or placed in a new file, in the same spirit as @file{example.cc}. @code{foo.h}: @smallexample @group #pragma interface "foo.h" template class Stack @{ static int statc; static T statc2; Stack() @{ @} virtual ~Stack() @{ @} int bar(); @}; @end group @end smallexample @code{example.cc}: @smallexample @group #pragma implementation "foo.h" #include "foo.h" typedef Stack t; int Stack::statc; int Stack::statc2; int Stack::bar() @{ @} @end group @end smallexample Note that using @samp{-fexternal-templates} does not reduce memory usage from completely different instantiations (@samp{Stack} vs. @samp{Stack}), but only collapses different occurrences of @samp{Stack} so that only one @samp{Stack} is generated. @samp{-falt-external-templates} selects a slight variation in the semantics described above (incidentally, you need not specify both options; @samp{-falt-external-templates} implies @samp{-fexternal-templates}). With @samp{-fexternal-templates}, the compiler emits a definition in the implementation file that includes the header definition, @emph{even if} instantiation is triggered from a @emph{different} implementation file (e.g. with a template that uses another template). With @samp{-falt-external-templates}, the definition always goes in the implementation file that triggers instantiation. For instance, with these two header files--- @example @exdent @file{a.h}: #pragma interface template class A @{ @dots{} @}; @exdent @file{b.h}: #pragma interface class B @{ @dots{} @}; void f (A); @end example Under @samp{-fexternal-templates}, the definition of @samp{A} ends up in the implementation file that includes @file{a.h}. Under @samp{-falt-external-templates}, the same definition ends up in the implementation file that includes @file{b.h}. @item You can control explicitly where a template is instantiated, without having to @emph{use} the template to get an instantiation. To instantiate a class template explicitly, write @samp{template class @var{name}}, where @var{paramvals} is a list of values for the template parameters. For example, you might write @example template class A @end example Similarly, to instantiate a function template explicitly, write @samp{template @var{fnsign}} where @var{fnsign} is the particular function signature you need. For example, you might write @example template void foo (int, int) @end example This syntax for explicit template instantiation agrees with recent extensions to the draft @sc{ansi} standard. @item The compiler's actions on @sc{ansi}-related warnings and errors have been further enhanced. The @samp{-pedantic-errors} option produces error messages in a number of new situations: using @code{return} in a non-@code{void} function (one returning a value); declaring a local variable that shadows a parameter (e.g., the function takes an argument @samp{a}, and has a local variable @samp{a}); and use of the @samp{asm} keyword. Finally, the compiler by default now issues a warning when converting from an @code{int} to an enumerated type. This is likely to cause many new warnings in code that hadn't triggered them before. For example, when you compile this code, @smallexample @group enum boolean @{ false, true @}; void f () @{ boolean x; x = 1; //@i{assigning an @code{int} to an @code{enum} now triggers a warning} @} @end group @end smallexample @noindent you should see the warning ``@code{anachronistic conversion from integer type to enumeral type `boolean'}''. Instead of assigning the value 1, assign the original enumerated value @samp{true}. @end itemize @node Enhancements and bug fixes @section Enhancements and bug fixes @itemize @bullet @cindex nested types in template parameters @item You can now use nested types in a template parameter list, even if the nested type is defined within the same class that attempts to use the template. For example, given a template @code{list}, the following now works: @smallexample struct glyph @{ @dots{} struct stroke @{ @dots{} @}; list l; @dots{} @} @end smallexample @cindex function pointers vs template parameters @item Function pointers now work in template parameter lists. For example, you might want to instantiate a parameterized @code{list} class in terms of a pointer to a function like this: @smallexample list fnlist; @end smallexample @item @c FIXME! Really no limit? Jason said "deeper than 9" now OK... Nested types are now handled correctly. In particular, there is no longer a limit to how deeply you can nest type definitions. @item @sc{gnu} C++ now conforms to the specifications in Chapter 11 of the @sc{arm}, ``Member Access Control''. @item The @sc{ansi} C++ committee has introduced a new keyword @code{mutable}. @sc{gnu} C++ supports it. Use @code{mutable} to specify that some particular members of a @code{const} class are @emph{not} constant. For example, you can use this to include a cache in a data structure that otherwise represents a read-only database. @item Error messages now explicitly specify the declaration, type, or expression that contains an error. @item To avoid copying and editing all system include files during @sc{gnu} C++ installation, the compiler now automatically recognizes system include files as C language definitions, as if they were wrapped in @samp{extern "C" @{ @dots{} @}}. @item The compiler checks operator declarations more strictly. For example, you may no longer declare an @samp{operator +} with three arguments. @item You can now use template type arguments in the same template parameter list where the type argument is specified (as well as in the template body). For example, you may write @example template class A @{ @dots{} @}; @end example @item Destructors are now available for all types, even built-in ones; for example, you can call @samp{int::~int}. (Destructors for types like @code{int} do not actually do anything, but their existence provides a level of generality that permits smooth template expansion in more cases.) @item Enumerated types declared inside a class are now handled correctly. @item An argument list for a function may not use an initializer list for its default value. For example, @w{@samp{void foo ( T x = @{ 1, 2 @} )}} is not permitted. @item A significant amount of work went into improving the ability of the compiler to act accurately on multiple inheritance and virtual functions. Virtual function dispatch has been enhanced as well. @item The warning concerning a virtual inheritance environment with a non-virtual destructor has been disabled, since it is not clear that such a warning is warranted. @item Until exception handling is fully implemented in the Reno-2 release, use of the identifiers @samp{catch}, @samp{throw}, or @samp{try} results in the warning: @smallexample t.C:1: warning: `catch', `throw', and `try' are all C++ reserved words @end smallexample @item When giving a warning or error concerning initialization of a member in a class, the compiler gives the name of the member if it has one. @item Detecting friendship between classes is more accurately checked. @item The syntaxes of @w{@samp{#pragma implementation "file.h"}} and @samp{#pragma interface} are now more strictly controlled. The compiler notices (and warns) when any text follows @file{file.h} in the implementation pragma, or follows the word @samp{interface}. Any such text is otherwise ignored. @item Trying to declare a template on a variable or type is now considered an error, not an unimplemented feature. @item When an error occurs involving a template, the compiler attempts to tell you at which point of instantiation the error occurred, in addition to noting the line in the template declaration which had the actual error. @item The symbol names for function templates in the resulting assembly file are now encoded according to the arguments, rather than just being emitted as, for example, two definitions of a function @samp{foo}. @item Template member functions that are declared @code{static} no longer receive a @code{this} pointer. @item Case labels are no longer allowed to have commas to make up their expressions. @item Warnings concerning the shift count of a left or right shift now tell you if it was a @samp{left} or @samp{right} shift. @item The compiler now warns when a decimal constant is so large that it becomes @code{unsigned}. @item Union initializers which are raw constructors are now handled properly. @item The compiler no longer gives incorrect errors when initializing a union with an empty initializer list. @item Anonymous unions are now correctly used when nested inside a class. @item Anonymous unions declared as static class members are now handled properly. @item The compiler now notices when a field in a class is declared both as a type and a non-type. @item The compiler now warns when a user-defined function shadows a built-in function, rather than emitting an error. @item A conflict between two function declarations now produces an error regardless of their language context. @item Duplicate definitions of variables with @samp{extern "C"} linkage are no longer considered in error. (Note in C++ linkage---the default---you may not have more than one definition of a variable.) @item Referencing a label that is not defined in any function is now an error. @item The syntax for pointers to methods has been improved; there are still some minor bugs, but a number of cases should now be accepted by the compiler. @item In error messages, arguments are now numbered starting at 1, instead of 0. Therefore, in the function @samp{void foo (int a, int b)}, the argument @samp{a} is argument 1, and @samp{b} is argument 2. There is no longer an argument 0. @item The tag for an enumerator, rather than its value, used as a default argument is now shown in all error messages. For example, @w{@samp{void foo (enum x (= true))}} is shown instead of @w{@samp{void foo (enum x (= 1))}}. @item The @samp{__asm__} keyword is now accepted by the C++ front-end. @item Expressions of the form @samp{foo->~Class()} are now handled properly. @item The compiler now gives better warnings for situations which result in integer overflows (e.g., in storage sizes, enumerators, unary expressions, etc). @item @code{unsigned} bitfields are now promoted to @code{signed int} if the field isn't as wide as an @code{int}. @item Declaration and usage of prefix and postfix @samp{operator ++} and @samp{operator --} are now handled correctly. For example, @smallexample @group class foo @{ public: operator ++ (); operator ++ (int); operator -- (); operator -- (int); @}; void f (foo *f) @{ f++; // @i{call @code{f->operator++(int)}} ++f; // @i{call @code{f->operator++()}} f--; // @i{call @code{f->operator++(int)}} --f; // @i{call @code{f->operator++()}} @} @end group @end smallexample @item In accordance with @sc{arm} section 10.1.1, ambiguities and dominance are now handled properly. The rules described in section 10.1.1 are now fully implemented. @end itemize @node Problems with debugging @section Problems with debugging Two problems remain with regard to debugging: @itemize @bullet @item Debugging of anonymous structures on the IBM RS/6000 host is incorrect. @item Symbol table size is overly large due to redundant symbol information; this can make @code{gdb} coredump under certain circumstances. This problem is not host-specific. @end itemize @node Plans @chapter Plans for Reno-2 The overall goal for the second phase of the @sc{gnu} C++ Renovation Project is to bring @sc{gnu} C++ to a new level of reliability, quality, and competitiveness. As particular elements of this strategy, we intend to: @enumerate 0 @item Fully implement @sc{ansi} exception handling. @item With the exception handling, add Runtime Type Identification (@sc{rtti}), if the @sc{ansi} committee adopts it into the standard. @item Bring the compiler into closer compliance with the @sc{arm} and the draft @sc{ansi} standard, and document what points in the @sc{arm} we do not yet comply, or agree, with. @item Add further support for the @sc{dwarf} debugging format. @item Finish the work to make the compiler compliant with @sc{arm} Section 12.6.2, initializing base classes in declaration order, rather than in the order that you specify them in a @var{mem-initializer} list. @item Perform a full coverage analysis on the compiler, and weed out unused code, for a gain in performance and a reduction in the size of the compiler. @item Further improve the multiple inheritance implementation in the compiler to make it cleaner and more complete. @end enumerate @noindent As always, we encourage you to make suggestions and ask questions about @sc{gnu} C++ as a whole, so we can be sure that the end of this project will bring a compiler that everyone will find essential for C++ and will meet the needs of the world's C++ community. @include templates.texi @include gpcompare.texi @contents @bye