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Wikipedia

GNU Compiler Collection

April 30, 2023

The GNU Compiler Collection (GCC) is an optimizing compiler produced by the GNU Project supporting various programming languages, hardware architectures and operating systems. The Free Software Foundation (FSF) distributes GCC as free software under the GNU General Public License (GNU GPL). GCC is a key component of the GNU toolchain and the standard compiler for most projects related to GNU and the Linux kernel. With roughly 15 million lines of code in 2019, GCC is one of the biggest free programs in existence.[4] It has played an important role in the growth of free software, as both a tool and an example.

GNU Compiler Collection
Screenshot of GCC 10.2 compiling its own source code
Original author(s)Richard Stallman
Developer(s)GNU Project
Initial releaseMarch 22, 1987; 36 years ago (1987-03-22)[1]
Stable release
13.1[2]  / 26 April 2023
Repository
  • gcc.gnu.org/git/gcc.git
Written inC, C++[3]
Operating systemCross-platform
PlatformGNU and many others
Size~15 million LOC[4]
Available inEnglish
TypeCompiler
LicenseGPLv3+ with GCC Runtime Library Exception[5]
Websitegcc.gnu.org

When it was first released in 1987 by Richard Stallman, GCC 1.0 was named the GNU C Compiler since it only handled the C programming language.[1] It was extended to compile C++ in December of that year. Front ends were later developed for Objective-C, Objective-C++, Fortran, Ada, D and Go, among others.[6] The OpenMP and OpenACC specifications are also supported in the C and C++ compilers.[7][8]

GCC has been ported to more platforms and instruction set architectures than any other compiler, and is widely deployed as a tool in the development of both free and proprietary software. GCC is also available for many embedded systems, including ARM-based and Power ISA-based chips.

As well as being the official compiler of the GNU operating system, GCC has been adopted as the standard compiler by many other modern Unix-like computer operating systems, including most Linux distributions. Most BSD family operating systems also switched to GCC shortly after its release, although since then, FreeBSD, OpenBSD and Apple macOS have moved to the Clang compiler,[9] largely due to licensing reasons.[10][11][12] GCC can also compile code for Windows, Android, iOS, Solaris, HP-UX, AIX and DOS.[13]

History

In late 1983, in an effort to bootstrap the GNU operating system, Richard Stallman asked Andrew S. Tanenbaum, the author of the Amsterdam Compiler Kit (also known as the Free University Compiler Kit) for permission to use that software for GNU. When Tanenbaum advised him that the compiler was not free, and that only the university was free, Stallman decided to work on a different compiler.[14] His initial plan was to rewrite an existing compiler from Lawrence Livermore National Laboratory from Pastel to C with some help from Len Tower and others.[15][16] Stallman wrote a new C front end for the Livermore compiler, but then realized that it required megabytes of stack space, an impossibility on a 68000 Unix system with only 64 KB, and concluded he would have to write a new compiler from scratch.[15] None of the Pastel compiler code ended up in GCC, though Stallman did use the C front end he had written.[15][17]

GCC was first released March 22, 1987, available by FTP from MIT.[18] Stallman was listed as the author but cited others for their contributions, including Tower for "parts of the parser, RTL generator, RTL definitions, and of the Vax machine description", Jack Davidson and Christopher W. Fraser for the idea of using RTL as an intermediate language, and Paul Rubin for writing most of the preprocessor.[19] Described as the "first free software hit" by Peter H. Salus, the GNU compiler arrived just at the time when Sun Microsystems was unbundling its development tools from its operating system, selling them separately at a higher combined price than the previous bundle, which led many of Sun's users to buy or download GCC instead of the vendor's tools.[20] While Stallman considered GNU Emacs as his main project, by 1990, GCC supported thirteen computer architectures, was outperforming several vendor compilers, and was used commercially by several companies.[21]

EGCS fork

As GCC was licensed under the GPL, programmers wanting to work in other directions—particularly those writing interfaces for languages other than C—were free to develop their own fork of the compiler, provided they meet the GPL's terms, including its requirements to distribute source code. Multiple forks proved inefficient and unwieldy, however, and the difficulty in getting work accepted by the official GCC project was greatly frustrating for many, as the project favored stability over new features.[22] The FSF kept such close control on what was added to the official version of GCC 2.x (developed since 1992) that GCC was used as one example of the "cathedral" development model in Eric S. Raymond's essay The Cathedral and the Bazaar.

In 1997, a group of developers formed the Experimental/Enhanced GNU Compiler System (EGCS) to merge several experimental forks into a single project.[22][17] The basis of the merger was a development snapshot of GCC (taken around the 2.7.2 and later followed up to 2.8.1 release). Mergers included g77 (Fortran), PGCC (P5 Pentium-optimized GCC),[17] many C++ improvements, and many new architectures and operating system variants.[23]

While both projects followed each other's changes closely, EGCS development proved considerably more vigorous, so much so that the FSF officially halted development on their GCC 2.x compiler, blessed EGCS as the official version of GCC, and appointed the EGCS project as the GCC maintainers in April 1999. With the release of GCC 2.95 in July 1999 the two projects were once again united.[24][17] GCC has since been maintained by a varied group of programmers from around the world under the direction of a steering committee.[25]

GCC 3 (2002) removed a front-end for CHILL due to a lack of maintenance.[26]

Before version 4.0 the Fortran front end was g77, which only supported FORTRAN 77, but later was dropped in favor of the new GNU Fortran front end that supports Fortran 95 and large parts of Fortran 2003 and Fortran 2008 as well.[27][28]

As of version 4.8, GCC is implemented in C++.[29]

Support for Cilk Plus existed from GCC 5 to GCC 7.[30][31]

GCC has been ported to a wide variety of instruction set architectures, and is widely deployed as a tool in the development of both free and proprietary software. GCC is also available for many embedded systems, including Symbian (called gcce),[32] ARM-based, and Power ISA-based chips.[33] The compiler can target a wide variety of platforms, including video game consoles such as the PlayStation 2,[34] Cell SPE of PlayStation 3,[35] and Dreamcast.[36] It has been ported to more kinds of processors and operating systems than any other compiler.[37][self-published source?][better source needed]

Supported languages

As of May 2021, the recent 11.1 release of GCC includes front ends for C (gcc), C++ (g++), Objective-C, Fortran (gfortran), Ada (GNAT), Go (gccgo) and D (gdc, since 9.1)[38] programming languages,[39] with the OpenMP and OpenACC parallel language extensions being supported since GCC 5.1.[8][40] Versions prior to GCC 7 also supported Java (gcj), allowing compilation of Java to native machine code.[41] Modula-2 support, previously offered by third parties, will be merged into GCC 13.[42]

Regarding language version support for C++ and C, since GCC 11.1 the default target is gnu++17, a superset of C++17, and gnu11, a superset of C11, with strict standard support also available. GCC also provides experimental support for C++20 and upcoming C++23.[43]

Third-party front ends exist for many languages, such as Pascal (gpc), Modula-3, and VHDL (GHDL).[39] A few experimental branches exist to support additional languages, such as the GCC UPC compiler for Unified Parallel C[44] or Rust.[45][46][47][better source needed]

Design

 
Overview of GCC's extended compilation pipeline, including specialized programs like the preprocessor, assembler and linker.
 
GCC follows the 3-stage architecture typical of multi-language and multi-CPU compilers. All program trees are converted to a common abstract representation at the "middle end", allowing code optimization and binary code generation facilities to be shared by all languages.

GCC's external interface follows Unix conventions. Users invoke a language-specific driver program (gcc for C, g++ for C++, etc.), which interprets command arguments, calls the actual compiler, runs the assembler on the output, and then optionally runs the linker to produce a complete executable binary.

Each of the language compilers is a separate program that reads source code and outputs machine code. All have a common internal structure. A per-language front end parses the source code in that language and produces an abstract syntax tree ("tree" for short).

These are, if necessary, converted to the middle end's input representation, called GENERIC form; the middle end then gradually transforms the program towards its final form. Compiler optimizations and static code analysis techniques (such as FORTIFY_SOURCE,[48] a compiler directive that attempts to discover some buffer overflows) are applied to the code. These work on multiple representations, mostly the architecture-independent GIMPLE representation and the architecture-dependent RTL representation. Finally, machine code is produced using architecture-specific pattern matching originally based on an algorithm of Jack Davidson and Chris Fraser.

GCC was written primarily in C except for parts of the Ada front end. The distribution includes the standard libraries for Ada and C++ whose code is mostly written in those languages.[49][needs update] On some platforms, the distribution also includes a low-level runtime library, libgcc, written in a combination of machine-independent C and processor-specific machine code, designed primarily to handle arithmetic operations that the target processor cannot perform directly.[50]

GCC uses many additional tools in its build, many of which are installed by default by many Unix and Linux distributions (but which, normally, aren't present in Windows installations), including Perl,[further explanation needed] Flex, Bison, and other common tools. In addition, it currently requires three additional libraries to be present in order to build: GMP, MPC, and MPFR.[51]

In May 2010, the GCC steering committee decided to allow use of a C++ compiler to compile GCC.[52] The compiler was intended to be written mostly in C plus a subset of features from C++. In particular, this was decided so that GCC's developers could use the destructors and generics features of C++.[53]

In August 2012, the GCC steering committee announced that GCC now uses C++ as its implementation language.[54] This means that to build GCC from sources, a C++ compiler is required that understands ISO/IEC C++03 standard.

On May 18, 2020, GCC moved away from ISO/IEC C++03 standard to ISO/IEC C++11 standard (i.e. needed to compile, bootstrap, the compiler itself; by default it however compiles later versions of C++).[55]

Front ends

 
Front ends consist of preprocessing, lexical analysis, syntactic analysis (parsing) and semantic analysis. The goals of compiler front ends are to either accept or reject candidate programs according to the language grammar and semantics, identify errors and handle valid program representations to later compiler stages. This example shows the lexer and parser steps performed for a simple program written in C.

Each front end uses a parser to produce the abstract syntax tree of a given source file. Due to the syntax tree abstraction, source files of any of the different supported languages can be processed by the same back end. GCC started out using LALR parsers generated with Bison, but gradually switched to hand-written recursive-descent parsers for C++ in 2004,[56] and for C and Objective-C in 2006.[57] As of 2021 all front ends use hand-written recursive-descent parsers.

Until GCC 4.0 the tree representation of the program was not fully independent of the processor being targeted. The meaning of a tree was somewhat different for different language front ends, and front ends could provide their own tree codes. This was simplified with the introduction of GENERIC and GIMPLE, two new forms of language-independent trees that were introduced with the advent of GCC 4.0. GENERIC is more complex, based on the GCC 3.x Java front end's intermediate representation. GIMPLE is a simplified GENERIC, in which various constructs are lowered to multiple GIMPLE instructions. The C, C++, and Java front ends produce GENERIC directly in the front end. Other front ends instead have different intermediate representations after parsing and convert these to GENERIC.

In either case, the so-called "gimplifier" then converts this more complex form into the simpler SSA-based GIMPLE form that is the common language for a large number of powerful language- and architecture-independent global (function scope) optimizations.

GENERIC and GIMPLE

GENERIC is an intermediate representation language used as a "middle end" while compiling source code into executable binaries. A subset, called GIMPLE, is targeted by all the front ends of GCC.

The middle stage of GCC does all of the code analysis and optimization, working independently of both the compiled language and the target architecture, starting from the GENERIC[58] representation and expanding it to register transfer language (RTL). The GENERIC representation contains only the subset of the imperative programming constructs optimized by the middle end.

In transforming the source code to GIMPLE,[59] complex expressions are split into a three-address code using temporary variables. This representation was inspired by the SIMPLE representation proposed in the McCAT compiler[60] by Laurie J. Hendren[61] for simplifying the analysis and optimization of imperative programs.

Optimization

Optimization can occur during any phase of compilation; however, the bulk of optimizations are performed after the syntax and semantic analysis of the front end and before the code generation of the back end; thus a common, though somewhat self-contradictory, name for this part of the compiler is the "middle end."

The exact set of GCC optimizations varies from release to release as it develops, but includes the standard algorithms, such as loop optimization, jump threading, common subexpression elimination, instruction scheduling, and so forth. The RTL optimizations are of less importance with the addition of global SSA-based optimizations on GIMPLE trees,[62] as RTL optimizations have a much more limited scope, and have less high-level information.

Some of these optimizations performed at this level include dead-code elimination, partial-redundancy elimination, global value numbering, sparse conditional constant propagation, and scalar replacement of aggregates. Array dependence based optimizations such as automatic vectorization and automatic parallelization are also performed. Profile-guided optimization is also possible.[63]

Back end

The GCC's back end is partly specified by preprocessor macros and functions specific to a target architecture, for instance to define its endianness, word size, and calling conventions. The front part of the back end uses these to help decide RTL generation, so although GCC's RTL is nominally processor-independent, the initial sequence of abstract instructions is already adapted to the target. At any moment, the actual RTL instructions forming the program representation have to comply with the machine description of the target architecture.

The machine description file contains RTL patterns, along with operand constraints, and code snippets to output the final assembly. The constraints indicate that a particular RTL pattern might only apply (for example) to certain hardware registers, or (for example) allow immediate operand offsets of only a limited size (e.g. 12, 16, 24, ... bit offsets, etc.). During RTL generation, the constraints for the given target architecture are checked. In order to issue a given snippet of RTL, it must match one (or more) of the RTL patterns in the machine description file, and satisfy the constraints for that pattern; otherwise, it would be impossible to convert the final RTL into machine code.

Towards the end of compilation, valid RTL is reduced to a strict form in which each instruction refers to real machine registers and a pattern from the target's machine description file. Forming strict RTL is a complicated task; an important step is register allocation, where real hardware registers are chosen to replace the initially assigned pseudo-registers. This is followed by a "reloading" phase; any pseudo-registers that were not assigned a real hardware register are 'spilled' to the stack, and RTL to perform this spilling is generated. Likewise, offsets that are too large to fit into an actual instruction must be broken up and replaced by RTL sequences that will obey the offset constraints.

In the final phase, the machine code is built by calling a small snippet of code, associated with each pattern, to generate the real instructions from the target's instruction set, using the final registers, offsets, and addresses chosen during the reload phase. The assembly-generation snippet may be just a string, in which case a simple string substitution of the registers, offsets, and/or addresses into the string is performed. The assembly-generation snippet may also be a short block of C code, performing some additional work, but ultimately returning a string containing the valid assembly code.

C++ Standard Library (libstdc++)

The GCC project includes an implementation of the C++ Standard Library called libstdc++,[64] licensed under the GPLv3 License with an exception to link closed source application when sources are built with GCC.[65] The current version is 11[when?].

Other features

Some features of GCC include:

Link-time optimization
Link-time optimization optimizes across object file boundaries to directly improve the linked binary. Link-time optimization relies on an intermediate file containing the serialization of some Gimple representation included in the object file.[citation needed] The file is generated alongside the object file during source compilation. Each source compilation generates a separate object file and link-time helper file. When the object files are linked, the compiler is executed again and uses the helper files to optimize code across the separately compiled object files.
Plugins
Plugins extend the GCC compiler directly.[66] Plugins allow a stock compiler to be tailored to specific needs by external code loaded as plugins. For example, plugins can add, replace, or even remove middle-end passes operating on Gimple representations.[67] Several GCC plugins have already been published, notably:
  • The Python plugin, which links against libpython, and allows one to invoke arbitrary Python scripts from inside the compiler. The aim is to allow GCC plugins to be written in Python.
  • The MELT plugin provides a high-level Lisp-like language to extend GCC.[68]
The support of plugins was once a contentious issue in 2007.[69]
C++ transactional memory
The C++ language has an active proposal for transactional memory. It can be enabled in GCC 6 and newer when compiling with -fgnu-tm.[7][70]
Unicode identifiers
Although the C++ language requires support for non-ASCII Unicode characters in identifiers, the feature has only been supported since GCC 10. As with the existing handling of string literals, the source file is assumed to be encoded in UTF-8. The feature is optional in C, but has been made available too since this change.[71][72]
C extensions
GNU C extends the C programming language with several non-standard-features, including nested functions[73] and typeof expressions.[74]

Architectures

 
GCC compiling Hello World on Windows

The primary supported (and best tested) processor families are 64- and 32-bit ARM, 64- and 32-bit x86_64 and x86 and 64-bit PowerPC and SPARC.[75]

GCC target processor families as of version 11.1 include:[76]

Lesser-known target processors supported in the standard release have included:

Additional processors have been supported by GCC versions maintained separately from the FSF version:

The GCJ Java compiler can target either a native machine language architecture or the Java virtual machine's Java bytecode.[79] When retargeting GCC to a new platform, bootstrapping is often used. Motorola 68000, Zilog Z80, and other processors are also targeted in the GCC versions developed for various Texas Instruments, Hewlett Packard, Sharp, and Casio programmable graphing calculators.[80]

License

GCC is licensed under the GNU General Public License version 3.[81] The GCC runtime exception permits compilation of proprietary programs (in addition to free software) with GCC. This does not impact the license terms of GCC source code.[82]

See also

References

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Further reading

  • Using the GNU Compiler Collection (GCC), Free Software Foundation, 2008.
  • GNU Compiler Collection (GCC) Internals, Free Software Foundation, 2008.
  • An Introduction to GCC, Network Theory Ltd., 2004 (Revised August 2005). ISBN 0-9541617-9-3.
  • Arthur Griffith, GCC: The Complete Reference. McGraw Hill / Osborne, 2002. ISBN 0-07-222405-3.

External links

 
Wikimedia Commons has media related to GCC.
 
Wikibooks has a book on the topic of: GNU C Compiler Internals

Official

  • Official website  
  • GCC Release Timeline
  • GCC Development Plan

Other

  • Collection of GCC 4.0.2 architecture and internals documents at I.I.T. Bombay
  • Kerner, Sean Michael (March 2, 2006). "New GCC Heavy on Optimization". internetnews.com
  • Kerner, Sean Michael (April 22, 2005). . internetnews.com. Archived from the original on September 17, 2006. Retrieved October 21, 2006
  • , by Diego Novillo, Red Hat Magazine, December 2004
  • A 2003 paper on GENERIC and GIMPLE
  • , an essay covering GCC development for the 1990s, with 30 monthly reports for in the "Inside Cygnus Engineering" section near the end
  • EGCS 1.0 announcement
  • EGCS 1.0 features list
  • Fear of Forking, an essay by Rick Moen recording seven well-known forks, including the GCC/EGCS one

April 30, 2023
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This article relies excessively on references to primary sources Please improve this article by adding secondary or tertiary sources Find sources GNU Compiler Collection news newspapers books scholar JSTOR January 2022 Learn how and when to remove this template message The GNU Compiler Collection GCC is an optimizing compiler produced by the GNU Project supporting various programming languages hardware architectures and operating systems The Free Software Foundation FSF distributes GCC as free software under the GNU General Public License GNU GPL GCC is a key component of the GNU toolchain and the standard compiler for most projects related to GNU and the Linux kernel With roughly 15 million lines of code in 2019 GCC is one of the biggest free programs in existence 4 It has played an important role in the growth of free software as both a tool and an example GNU Compiler CollectionScreenshot of GCC 10 2 compiling its own source codeOriginal author s Richard StallmanDeveloper s GNU ProjectInitial releaseMarch 22 1987 36 years ago 1987 03 22 1 Stable release13 1 2 26 April 2023Repositorygcc wbr gnu wbr org wbr git wbr gcc wbr gitWritten inC C 3 Operating systemCross platformPlatformGNU and many othersSize 15 million LOC 4 Available inEnglishTypeCompilerLicenseGPLv3 with GCC Runtime Library Exception 5 Websitegcc wbr gnu wbr orgWhen it was first released in 1987 by Richard Stallman GCC 1 0 was named the GNU C Compiler since it only handled the C programming language 1 It was extended to compile C in December of that year Front ends were later developed for Objective C Objective C Fortran Ada D and Go among others 6 The OpenMP and OpenACC specifications are also supported in the C and C compilers 7 8 GCC has been ported to more platforms and instruction set architectures than any other compiler and is widely deployed as a tool in the development of both free and proprietary software GCC is also available for many embedded systems including ARM based and Power ISA based chips As well as being the official compiler of the GNU operating system GCC has been adopted as the standard compiler by many other modern Unix like computer operating systems including most Linux distributions Most BSD family operating systems also switched to GCC shortly after its release although since then FreeBSD OpenBSD and Apple macOS have moved to the Clang compiler 9 largely due to licensing reasons 10 11 12 GCC can also compile code for Windows Android iOS Solaris HP UX AIX and DOS 13 Contents 1 History 1 1 EGCS fork 2 Supported languages 3 Design 3 1 Front ends 3 2 GENERIC and GIMPLE 3 3 Optimization 3 4 Back end 3 5 C Standard Library libstdc 3 6 Other features 4 Architectures 5 License 6 See also 7 References 8 Further reading 9 External links 9 1 Official 9 2 OtherHistory EditIn late 1983 in an effort to bootstrap the GNU operating system Richard Stallman asked Andrew S Tanenbaum the author of the Amsterdam Compiler Kit also known as the Free University Compiler Kit for permission to use that software for GNU When Tanenbaum advised him that the compiler was not free and that only the university was free Stallman decided to work on a different compiler 14 His initial plan was to rewrite an existing compiler from Lawrence Livermore National Laboratory from Pastel to C with some help from Len Tower and others 15 16 Stallman wrote a new C front end for the Livermore compiler but then realized that it required megabytes of stack space an impossibility on a 68000 Unix system with only 64 KB and concluded he would have to write a new compiler from scratch 15 None of the Pastel compiler code ended up in GCC though Stallman did use the C front end he had written 15 17 GCC was first released March 22 1987 available by FTP from MIT 18 Stallman was listed as the author but cited others for their contributions including Tower for parts of the parser RTL generator RTL definitions and of the Vax machine description Jack Davidson and Christopher W Fraser for the idea of using RTL as an intermediate language and Paul Rubin for writing most of the preprocessor 19 Described as the first free software hit by Peter H Salus the GNU compiler arrived just at the time when Sun Microsystems was unbundling its development tools from its operating system selling them separately at a higher combined price than the previous bundle which led many of Sun s users to buy or download GCC instead of the vendor s tools 20 While Stallman considered GNU Emacs as his main project by 1990 GCC supported thirteen computer architectures was outperforming several vendor compilers and was used commercially by several companies 21 EGCS fork Edit As GCC was licensed under the GPL programmers wanting to work in other directions particularly those writing interfaces for languages other than C were free to develop their own fork of the compiler provided they meet the GPL s terms including its requirements to distribute source code Multiple forks proved inefficient and unwieldy however and the difficulty in getting work accepted by the official GCC project was greatly frustrating for many as the project favored stability over new features 22 The FSF kept such close control on what was added to the official version of GCC 2 x developed since 1992 that GCC was used as one example of the cathedral development model in Eric S Raymond s essay The Cathedral and the Bazaar In 1997 a group of developers formed the Experimental Enhanced GNU Compiler System EGCS to merge several experimental forks into a single project 22 17 The basis of the merger was a development snapshot of GCC taken around the 2 7 2 and later followed up to 2 8 1 release Mergers included g77 Fortran PGCC P5 Pentium optimized GCC 17 many C improvements and many new architectures and operating system variants 23 While both projects followed each other s changes closely EGCS development proved considerably more vigorous so much so that the FSF officially halted development on their GCC 2 x compiler blessed EGCS as the official version of GCC and appointed the EGCS project as the GCC maintainers in April 1999 With the release of GCC 2 95 in July 1999 the two projects were once again united 24 17 GCC has since been maintained by a varied group of programmers from around the world under the direction of a steering committee 25 GCC 3 2002 removed a front end for CHILL due to a lack of maintenance 26 Before version 4 0 the Fortran front end was g77 which only supported FORTRAN 77 but later was dropped in favor of the new GNU Fortran front end that supports Fortran 95 and large parts of Fortran 2003 and Fortran 2008 as well 27 28 As of version 4 8 GCC is implemented in C 29 Support for Cilk Plus existed from GCC 5 to GCC 7 30 31 GCC has been ported to a wide variety of instruction set architectures and is widely deployed as a tool in the development of both free and proprietary software GCC is also available for many embedded systems including Symbian called gcce 32 ARM based and Power ISA based chips 33 The compiler can target a wide variety of platforms including video game consoles such as the PlayStation 2 34 Cell SPE of PlayStation 3 35 and Dreamcast 36 It has been ported to more kinds of processors and operating systems than any other compiler 37 self published source better source needed Supported languages EditAs of May 2021 update the recent 11 1 release of GCC includes front ends for C gcc C g Objective C Fortran a href Gfortran html class mw redirect title Gfortran gfortran a Ada GNAT Go gccgo and D gdc since 9 1 38 programming languages 39 with the OpenMP and OpenACC parallel language extensions being supported since GCC 5 1 8 40 Versions prior to GCC 7 also supported Java a href GNU Compiler for Java html title GNU Compiler for Java gcj a allowing compilation of Java to native machine code 41 Modula 2 support previously offered by third parties will be merged into GCC 13 42 Regarding language version support for C and C since GCC 11 1 the default target is gnu 17 a superset of C 17 and gnu11 a superset of C11 with strict standard support also available GCC also provides experimental support for C 20 and upcoming C 23 43 Third party front ends exist for many languages such as Pascal a href GNU Pascal html title GNU Pascal gpc a Modula 3 and VHDL GHDL 39 A few experimental branches exist to support additional languages such as the GCC UPC compiler for Unified Parallel C 44 or Rust 45 46 47 better source needed Design Edit Overview of GCC s extended compilation pipeline including specialized programs like the preprocessor assembler and linker GCC follows the 3 stage architecture typical of multi language and multi CPU compilers All program trees are converted to a common abstract representation at the middle end allowing code optimization and binary code generation facilities to be shared by all languages GCC s external interface follows Unix conventions Users invoke a language specific driver program gcc for C g for C etc which interprets command arguments calls the actual compiler runs the assembler on the output and then optionally runs the linker to produce a complete executable binary Each of the language compilers is a separate program that reads source code and outputs machine code All have a common internal structure A per language front end parses the source code in that language and produces an abstract syntax tree tree for short These are if necessary converted to the middle end s input representation called GENERIC form the middle end then gradually transforms the program towards its final form Compiler optimizations and static code analysis techniques such as FORTIFY SOURCE 48 a compiler directive that attempts to discover some buffer overflows are applied to the code These work on multiple representations mostly the architecture independent GIMPLE representation and the architecture dependent RTL representation Finally machine code is produced using architecture specific pattern matching originally based on an algorithm of Jack Davidson and Chris Fraser GCC was written primarily in C except for parts of the Ada front end The distribution includes the standard libraries for Ada and C whose code is mostly written in those languages 49 needs update On some platforms the distribution also includes a low level runtime library libgcc written in a combination of machine independent C and processor specific machine code designed primarily to handle arithmetic operations that the target processor cannot perform directly 50 GCC uses many additional tools in its build many of which are installed by default by many Unix and Linux distributions but which normally aren t present in Windows installations including Perl further explanation needed Flex Bison and other common tools In addition it currently requires three additional libraries to be present in order to build GMP MPC and MPFR 51 In May 2010 the GCC steering committee decided to allow use of a C compiler to compile GCC 52 The compiler was intended to be written mostly in C plus a subset of features from C In particular this was decided so that GCC s developers could use the destructors and generics features of C 53 In August 2012 the GCC steering committee announced that GCC now uses C as its implementation language 54 This means that to build GCC from sources a C compiler is required that understands ISO IEC C 03 standard On May 18 2020 GCC moved away from ISO IEC C 03 standard to ISO IEC C 11 standard i e needed to compile bootstrap the compiler itself by default it however compiles later versions of C 55 Front ends Edit Front ends consist of preprocessing lexical analysis syntactic analysis parsing and semantic analysis The goals of compiler front ends are to either accept or reject candidate programs according to the language grammar and semantics identify errors and handle valid program representations to later compiler stages This example shows the lexer and parser steps performed for a simple program written in C Each front end uses a parser to produce the abstract syntax tree of a given source file Due to the syntax tree abstraction source files of any of the different supported languages can be processed by the same back end GCC started out using LALR parsers generated with Bison but gradually switched to hand written recursive descent parsers for C in 2004 56 and for C and Objective C in 2006 57 As of 2021 all front ends use hand written recursive descent parsers Until GCC 4 0 the tree representation of the program was not fully independent of the processor being targeted The meaning of a tree was somewhat different for different language front ends and front ends could provide their own tree codes This was simplified with the introduction of GENERIC and GIMPLE two new forms of language independent trees that were introduced with the advent of GCC 4 0 GENERIC is more complex based on the GCC 3 x Java front end s intermediate representation GIMPLE is a simplified GENERIC in which various constructs are lowered to multiple GIMPLE instructions The C C and Java front ends produce GENERIC directly in the front end Other front ends instead have different intermediate representations after parsing and convert these to GENERIC In either case the so called gimplifier then converts this more complex form into the simpler SSA based GIMPLE form that is the common language for a large number of powerful language and architecture independent global function scope optimizations GENERIC and GIMPLE Edit GENERIC is an intermediate representation language used as a middle end while compiling source code into executable binaries A subset called GIMPLE is targeted by all the front ends of GCC The middle stage of GCC does all of the code analysis and optimization working independently of both the compiled language and the target architecture starting from the GENERIC 58 representation and expanding it to register transfer language RTL The GENERIC representation contains only the subset of the imperative programming constructs optimized by the middle end In transforming the source code to GIMPLE 59 complex expressions are split into a three address code using temporary variables This representation was inspired by the SIMPLE representation proposed in the McCAT compiler 60 by Laurie J Hendren 61 for simplifying the analysis and optimization of imperative programs Optimization Edit Optimization can occur during any phase of compilation however the bulk of optimizations are performed after the syntax and semantic analysis of the front end and before the code generation of the back end thus a common though somewhat self contradictory name for this part of the compiler is the middle end The exact set of GCC optimizations varies from release to release as it develops but includes the standard algorithms such as loop optimization jump threading common subexpression elimination instruction scheduling and so forth The RTL optimizations are of less importance with the addition of global SSA based optimizations on GIMPLE trees 62 as RTL optimizations have a much more limited scope and have less high level information Some of these optimizations performed at this level include dead code elimination partial redundancy elimination global value numbering sparse conditional constant propagation and scalar replacement of aggregates Array dependence based optimizations such as automatic vectorization and automatic parallelization are also performed Profile guided optimization is also possible 63 Back end Edit This section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed May 2020 Learn how and when to remove this template message The GCC s back end is partly specified by preprocessor macros and functions specific to a target architecture for instance to define its endianness word size and calling conventions The front part of the back end uses these to help decide RTL generation so although GCC s RTL is nominally processor independent the initial sequence of abstract instructions is already adapted to the target At any moment the actual RTL instructions forming the program representation have to comply with the machine description of the target architecture The machine description file contains RTL patterns along with operand constraints and code snippets to output the final assembly The constraints indicate that a particular RTL pattern might only apply for example to certain hardware registers or for example allow immediate operand offsets of only a limited size e g 12 16 24 bit offsets etc During RTL generation the constraints for the given target architecture are checked In order to issue a given snippet of RTL it must match one or more of the RTL patterns in the machine description file and satisfy the constraints for that pattern otherwise it would be impossible to convert the final RTL into machine code Towards the end of compilation valid RTL is reduced to a strict form in which each instruction refers to real machine registers and a pattern from the target s machine description file Forming strict RTL is a complicated task an important step is register allocation where real hardware registers are chosen to replace the initially assigned pseudo registers This is followed by a reloading phase any pseudo registers that were not assigned a real hardware register are spilled to the stack and RTL to perform this spilling is generated Likewise offsets that are too large to fit into an actual instruction must be broken up and replaced by RTL sequences that will obey the offset constraints In the final phase the machine code is built by calling a small snippet of code associated with each pattern to generate the real instructions from the target s instruction set using the final registers offsets and addresses chosen during the reload phase The assembly generation snippet may be just a string in which case a simple string substitution of the registers offsets and or addresses into the string is performed The assembly generation snippet may also be a short block of C code performing some additional work but ultimately returning a string containing the valid assembly code C Standard Library libstdc Edit The GCC project includes an implementation of the C Standard Library called libstdc 64 licensed under the GPLv3 License with an exception to link closed source application when sources are built with GCC 65 The current version is 11 when Other features Edit Some features of GCC include Link time optimization Link time optimization optimizes across object file boundaries to directly improve the linked binary Link time optimization relies on an intermediate file containing the serialization of some Gimple representation included in the object file citation needed The file is generated alongside the object file during source compilation Each source compilation generates a separate object file and link time helper file When the object files are linked the compiler is executed again and uses the helper files to optimize code across the separately compiled object files Plugins Plugins extend the GCC compiler directly 66 Plugins allow a stock compiler to be tailored to specific needs by external code loaded as plugins For example plugins can add replace or even remove middle end passes operating on Gimple representations 67 Several GCC plugins have already been published notably The Python plugin which links against libpython and allows one to invoke arbitrary Python scripts from inside the compiler The aim is to allow GCC plugins to be written in Python The MELT plugin provides a high level Lisp like language to extend GCC 68 The support of plugins was once a contentious issue in 2007 69 C transactional memory The C language has an active proposal for transactional memory It can be enabled in GCC 6 and newer when compiling with fgnu tm 7 70 Unicode identifiers Although the C language requires support for non ASCII Unicode characters in identifiers the feature has only been supported since GCC 10 As with the existing handling of string literals the source file is assumed to be encoded in UTF 8 The feature is optional in C but has been made available too since this change 71 72 C extensions GNU C extends the C programming language with several non standard features including nested functions 73 and typeof expressions 74 Architectures Edit GCC compiling Hello World on Windows The primary supported and best tested processor families are 64 and 32 bit ARM 64 and 32 bit x86 64 and x86 and 64 bit PowerPC and SPARC 75 GCC target processor families as of version 11 1 include 76 AArch64 Alpha ARM AVR Blackfin eBPF Epiphany GCC 4 8 H8 300 HC12 IA 32 x86 IA 64 Intel Itanium MIPS Motorola 68000 MSP430 Nvidia GPU Nvidia PTX PA RISC PDP 11 PowerPC R8C M16C M32C RISC V SPARC SuperH System 390 zSeries VAX x86 64 Lesser known target processors supported in the standard release have included 68HC11 A29K C6x CR16 D30V DSP16xx ETRAX CRIS FR 30 FR V IBM ROMP Intel i960 IP2000 M32R MCORE MIL STD 1750A MMIX MN10200 MN10300 Motorola 88000 NS32K RL78 Stormy16 V850 Xtensa Additional processors have been supported by GCC versions maintained separately from the FSF version Cortus APS3 ARC AVR32 C166 and C167 D10V EISC eSi RISC Hexagon 77 LatticeMico32 LatticeMico8 MeP MicroBlaze Motorola 6809 MSP430 NEC SX architecture 78 Nios II and Nios OpenRISC PDP 10 PIC24 dsPIC PIC32 Propeller Saturn HP48XGCC System 370 TIGCC m68k variant TMS9900 TriCore Z8000 ZPU The GCJ Java compiler can target either a native machine language architecture or the Java virtual machine s Java bytecode 79 When retargeting GCC to a new platform bootstrapping is often used Motorola 68000 Zilog Z80 and other processors are also targeted in the GCC versions developed for various Texas Instruments Hewlett Packard Sharp and Casio programmable graphing calculators 80 License EditGCC is licensed under the GNU General Public License version 3 81 The GCC runtime exception permits compilation of proprietary programs in addition to free software with GCC This does not impact the license terms of GCC source code 82 See also Edit Free and open source software portal Computer programming portalList of compilers MinGW LLVM ClangReferences Edit a b GCC Releases GNU Project Retrieved July 24 2020 GCC 13 1 Released April 26 2023 Retrieved April 26 2023 GCC Coding Conventions GNU Project gcc gnu org Retrieved February 7 2022 a b Victor Rodriguez October 1 2019 Cutting Edge Toolchain Latest Features in GCC GLIBC youtube com Linux Foundation Archived from the original on November 7 2021 Retrieved January 19 2021 GCC Runtime Library Exception Retrieved July 24 2020 Programming Languages Supported by GCC GNU Project Retrieved June 23 2014 a b GCC 6 Release Series Changes New Features and Fixes GNU Project gcc gnu org a b OpenACC GCC Wiki gcc gnu org The LLVM Compiler Infrastructure Project llvm org Apple s GPLv3 purge meta ath0 com Retrieved January 12 2021 Linnemann Reid June 20 2012 Why Clang Retrieved January 12 2021 August 29 2007 FreeBSD Foundation Newsletter August 29 2007 October 11 2007 Archived from the original on October 11 2007 Retrieved January 12 2021 Installing GCC Binaries GNU Project Free Software Foundation FSF gcc gnu org Retrieved January 12 2021 von Hagen William 2006 The Definitive Guide to GCC Definitive Guides 2nd ed Apress p XXVII ISBN 978 1 4302 0219 6 So he wrote to VUCK s author asking if GNU could use it Evidently VUCK s developer was uncooperative responding that the university was free but that the compiler was not a b c Stallman Richard September 20 2011 About the GNU Project The GNU Project Retrieved October 9 2011 Puzo Jerome E ed February 1986 Gnu s Zoo GNU s Bulletin Free Software Foundation 1 1 Retrieved August 11 2007 a b c d von Hagen William 2006 The Definitive Guide to GCC Definitive Guides 2nd ed Apress p XXVII ISBN 978 1 4302 0219 6 Richard M Stallman forwarded by Leonard H Tower Jr March 22 1987 GNU C compiler beta test release Newsgroup comp lang c Retrieved October 9 2011 Stallman Richard M June 22 2001 First published 1988 Contributors to GNU CC Using and Porting the GNU Compiler Collection GCC Free Software Foundation Inc p 7 retrieved June 18 2015 Salus Peter H 2005 Chapter 10 SUN and gcc The Daemon the Gnu and the Penguin Groklaw Garfinkel Simson L August 6 1990 Get ready for GNU software Computerworld p 102 a b Henkel Wallace David August 15 1997 A new compiler project to merge the existing GCC forks retrieved May 25 2012 The Short History of GCC development www softpanorama org Retrieved January 24 2021 History GCC Wiki gcc gnu org Retrieved September 28 2020 GCC steering committee GNU Project gcc gnu org PATCH Remove chill gcc gnu org Retrieved July 29 2010 Chart of Fortran 2003 Features supported by GNU Fortran GNU Retrieved June 25 2009 Chart of Fortran 2008 Features supported by GNU Fortran GNU Retrieved June 25 2009 GCC 4 8 Release Series Changes New Features and Fixes GNU Project gcc gnu org GCC 5 Release Series Changes New Features and Fixes gcc gnu org GCC 8 Release Series Changes New Features and Fixes gcc gnu org Symbian GCC Improvement Project Retrieved November 8 2007 Linux Board Support Packages Archived from the original on June 7 2011 Retrieved January 24 2021 setting up gcc as a cross compiler ps2stuff June 8 2002 Archived from the original on December 11 2008 Retrieved December 12 2008 CompileFarm GCC Wiki gcc gnu org sh4 g guide Archived from the original on December 20 2002 Retrieved December 12 2008 Linux Information Project LINFO Retrieved April 27 2010 The GCC has been ported to i e modified to run on more than 60 platforms which is more than for any other compiler The D Language Front End Finally Merged Into GCC 9 Phoronix phoronix com Retrieved January 19 2021 a b GCC Front Ends gnu org Retrieved November 25 2011 GCC 5 Release Series Changes New Features and Fixes GNU Project gcc gnu org GCC 7 Release Series gnu org Retrieved March 20 2018 Proven Liam December 16 2022 GCC 13 to support Modula 2 Follow up to Pascal lives on in FOSS form Retrieved December 19 2022 C Standards Support in GCC Retrieved May 17 2021 GCC UPC GCC Unified Parallel C Intrepid Technology Inc February 20 2006 Retrieved March 11 2009 GCC Front End For Rust Retrieved January 6 2023 GCC Front End for Rust Github GitHub January 5 2023 Retrieved January 6 2023 Spengler Brad January 12 2021 Open Source Security Inc Announces Funding of GCC Front End for Rust Security Features Compile Time Buffer Checks FORTIFY SOURCE fedoraproject org Retrieved March 11 2009 languages used to make GCC Archived from the original on May 27 2008 Retrieved September 14 2008 GCC Internals GCC org Retrieved March 1 2010 Prerequisites for GCC GNU Project gcc gnu org Retrieved September 5 2021 GCC allows C to some degree The H June 1 2010 Re Efforts to attract more users lists gnu org GCC 4 8 Release Series Changes New Features and Fixes Retrieved October 4 2013 bootstrap Update requirement to C 11 GitHub Retrieved May 18 2020 GCC 3 4 Release Series Changes New Features and Fixes GNU Project gcc gnu org GCC 4 1 Release Series Changes New Features and Fixes GNU Project gcc gnu org GENERIC GNU Compiler Collection GCC Internals gcc gnu org GIMPLE GNU Compiler Collection GCC Internals gcc gnu org McCAT Archived from the original on August 12 2004 Retrieved September 14 2017 a href Template Cite web html title Template Cite web cite web a CS1 maint bot original URL status unknown link Laurie Hendren s Home Page www sable mcgill ca Novillo Diego December 2004 From Source to Binary The Inner Workings of GCC Red Hat Magazine Archived from the original on April 1 2009 Installing GCC Building GNU Project gcc gnu org The GNU C Library GNU Project Retrieved February 21 2021 License GNU Project Retrieved February 21 2021 Plugins GCC online documentation Retrieved July 8 2013 Starynkevitch Basile GCC plugins thru the MELT example PDF Archived PDF from the original on April 13 2014 Retrieved April 10 2014 About GCC MELT Archived from the original on July 4 2013 Retrieved July 8 2013 GCC unplugged LWN net lwn net TransactionalMemory GCC Wiki gcc gnu org Lewis Hyatt PATCH wwwdocs Document support for extended identifiers added to GCC gcc gnu org Retrieved March 27 2020 Recommendations for extended identifier characters for C and C www open std org Retrieved March 27 2020 C Extensions Using the GNU Compiler Collection GCC gcc gnu org Retrieved January 12 2022 Typeof Using the GNU Compiler Collection GCC gcc gnu org Retrieved January 12 2022 GCC 12 Release Criteria gcc gnu org October 26 2022 Retrieved January 27 2023 Option Summary Using the GNU Compiler Collection GCC gcc gnu org Retrieved August 21 2020 Hexagon Project Wiki Archived from the original on March 23 2012 Retrieved May 19 2011 Google Code Archive Long term storage for Google Code Project Hosting code google com The GNU Compiler for the Java Programming Language Archived from the original on May 9 2007 Retrieved April 22 2010 graphing calculators programming Using the GNU Compiler Collection gnu org Retrieved November 5 2019 GCC Runtime Exception FSF Retrieved April 10 2014 Further reading EditUsing the GNU Compiler Collection GCC Free Software Foundation 2008 GNU Compiler Collection GCC Internals Free Software Foundation 2008 An Introduction to GCC Network Theory Ltd 2004 Revised August 2005 ISBN 0 9541617 9 3 Arthur Griffith GCC The Complete Reference McGraw Hill Osborne 2002 ISBN 0 07 222405 3 External links Edit Wikimedia Commons has media related to GCC Wikibooks has a book on the topic of GNU C Compiler Internals Official Edit Official website GCC Release Timeline GCC Development PlanOther Edit Collection of GCC 4 0 2 architecture and internals documents at I I T Bombay Kerner Sean Michael March 2 2006 New GCC Heavy on Optimization internetnews com Kerner Sean Michael April 22 2005 Open Source GCC 4 0 Older Faster internetnews com Archived from the original on September 17 2006 Retrieved October 21 2006 From Source to Binary The Inner Workings of GCC by Diego Novillo Red Hat Magazine December 2004 A 2003 paper on GENERIC and GIMPLE Marketing Cygnus Support an essay covering GCC development for the 1990s with 30 monthly reports for in the Inside Cygnus Engineering section near the end EGCS 1 0 announcement EGCS 1 0 features list Fear of Forking an essay by Rick Moen recording seven well known forks including the GCC EGCS one Retrieved from https en wikipedia org w index php title GNU Compiler Collection amp oldid 1139629193, wikipedia, wiki, book, books, library,

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