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<!--{
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"Title": "Setting up and using gccgo"
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}-->
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<p>
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This document explains how to use <code>gccgo</code>, a compiler for
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the Go language. The <code>gccgo</code> compiler is a new frontend
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for <code>gcc</code>, the widely used GNU compiler. Although the
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frontend itself is under a BSD-style license, <code>gccgo</code> is
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normally used as part of <code>gcc</code> and is then covered by
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the <a href="http://www.gnu.org/licenses/gpl.html">GNU General Public
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License</a>.
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</p>
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<p>
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Note that <code>gccgo</code> is not the <code>6g</code> compiler; see
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the <a href="install.html">Installing Go</a> instructions for that
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compiler.
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</p>
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<h2 id="Source_code">Source code</h2>
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<p>
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The <code>gccgo</code> source code is accessible via Subversion. The
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<code>gcc</code> web site
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has <a href="http://gcc.gnu.org/svn.html">instructions for getting the
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<code>gcc</code> source code</a>. The <code>gccgo</code> source code
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is a branch of the main <code>gcc</code> code
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repository: <code>svn://gcc.gnu.org/svn/gcc/branches/gccgo</code>.
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</p>
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<p>
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Note that although <code>gcc.gnu.org</code> is the most convenient way
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to get the source code for the compiler, that is not where the master
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sources live. If you want to contribute changes to the gccgo
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compiler, see <a href="gccgo_contribute.html">Contributing to
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gccgo</a>.
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</p>
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<h2 id="Building">Building</h2>
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<p>
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Building <code>gccgo</code> is just like building <code>gcc</code>
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with one or two additional options. See
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the <a href="http://gcc.gnu.org/install/">instructions on the gcc web
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site</a>. When you run <code>configure</code>, add the
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option <code>--enable-languages=c,c++,go</code> (along with other
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languages you may want to build). If you are targeting a 32-bit x86,
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then you will want to build <code>gccgo</code> to default to
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supporting locked compare and exchange instructions; do this by also
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using the <code>configure</code> option <code>--with-arch=i586</code>
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(or a newer architecture, depending on where you need your programs to
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run).
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</p>
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<p>
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On x86 GNU/Linux systems the <code>gccgo</code> compiler is able to
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use a small discontiguous stack for goroutines. This permits programs
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to run many more goroutines, since each goroutine can use a relatively
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small stack. Doing this requires using a development version of
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the <code>gold</code> linker. The easiest way to do this is to build
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the GNU binutils, using <code>--enable-gold=default</code> when you run
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the <code>configure</code> script, and to
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use <code>--with-ld=GOLD_BINARY</code> when you
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configure <code>gccgo</code>. A typical sequence would look like
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this (you can replace <code>/opt/gold</code> with any directory to
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which you have write access):
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</p>
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<pre>
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cvs -z 9 -d :pserver:anoncvs@sourceware.org:/cvs/src login
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[password is "anoncvs"]
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cvs -z 9 -d :pserver:anoncvs@sourceware.org:/cvs/src co binutils
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mkdir binutils-objdir
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cd binutils-objdir
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../src/configure --enable-gold=default --prefix=/opt/gold
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make
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make install
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</pre>
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<p>
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A number of prerequisites are required to build <code>gcc</code>, as
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described on the <a href="http://gcc.gnu.org/">gcc web site</a>. If
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those are all available, then a typical build and install sequence
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would look like this (only use the <code>--with-ld</code> option if
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you built and installed the gold linker as described above):
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</p>
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<pre>
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svn checkout svn://gcc.gnu.org/svn/gcc/branches/gccgo gccgo
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mkdir objdir
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cd objdir
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../gccgo/configure --enable-languages=c,c++,go --with-ld=/opt/gold/bin/ld
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make
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make install
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</pre>
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<h2 id="Using_gccgo">Using gccgo</h2>
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<p>
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The <code>gccgo</code> compiler works like other gcc frontends.
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<p>
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To compile a file:
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<pre>
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gccgo -c file.go
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</pre>
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<p>
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That produces <code>file.o</code>. To link files together to form an
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executable:
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<pre>
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gccgo -o file file.o
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</pre>
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<p>
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To run the resulting file, you will need to tell the program where to
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find the compiled Go packages. This can be done either by setting
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<code>LD_LIBRARY_PATH</code> in your environment:
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<pre>
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LD_LIBRARY_PATH=/usr/lib/gcc/MACHINE/VERSION
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</pre>
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<p>
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or by passing a <code>-Wl,-R</code> option when you link:
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<pre>
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gccgo -o file file.o -Wl,-R,/usr/lib/gcc/MACHINE/VERSION
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</pre>
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<p>
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or you can use the <code>-static-libgo</code> link-time option to link
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statically against libgo, or you can do a fully static link (static
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linking is the default for the <code>6l</code> Go linker). On most
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systems, a static link will look something like:
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<pre>
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gccgo -o file file.o -static -L /usr/lib/nptl -lgobegin -lgo -lpthread
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</pre>
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<p>
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You may get a warning about not creating an <code>.eh_frame_hdr</code>
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section; this has nothing to do with Go, and may be ignored. In the
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future the requirement of explicitly specifying
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<code>-L /usr/lib/nptl -lgobegin -lgo -lpthread</code>
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may be removed.
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<h2 id="Options">Options</h2>
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<p>
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The <code>gccgo</code> compiler supports all <code>gcc</code> options
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that are language independent, notably the <code>-O</code>
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and <code>-g</code> options.
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<p>
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The <code>-fgo-prefix=PREFIX</code> option may be used to set a unique
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prefix for the package being compiled. This option is intended for
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use with large programs that contain many packages, in order to allow
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multiple packages to use the same identifier as the package name.
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The <code>PREFIX</code> may be any string; a good choice for the
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string is the directory where the package will be installed.
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<p>
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The <code>-fno-require-return-statement</code> option may be used to
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disable the compiler error about functions missing return statements.
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Note that there is no way to disable this error in <code>6g</code>.
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<p>
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The <code>-I</code> and <code>-L</code> options, which are synonyms
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for the compiler, may be used to set the search path for finding
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imports.
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<h2 id="Imports">Imports</h2>
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<p>
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When you compile a file which exports something, the export
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information will be stored directly in the object file. When
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you import a package, you must tell <code>gccgo</code> how to
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find the file.
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<p>
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When you import the package <var>FILE</var> with <code>gccgo</code>,
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it will look for the import data in the following files, and use the
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first one that it finds.
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<ul>
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<li><code><var>FILE</var>.gox</code>
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<li><code><var>FILE</var>.o</code>
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<li><code>lib<var>FILE</var>.so</code>
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<li><code>lib<var>FILE</var>.a</code>
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</ul>
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<p>
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<code><var>FILE</var>.gox</code>, when used, will typically contain
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nothing but export data. This can be generated from
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<code><var>FILE</var>.o</code> via
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<pre>
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objcopy -j .go_export FILE.o FILE.gox
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</pre>
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<p>
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The <code>gccgo</code> compiler will look in the current
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directory for import files. In more complex scenarios you
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may pass the <code>-I</code> or <code>-L</code> option to
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<code>gccgo</code>. Both options take directories to search. The
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<code>-L</code> option is also passed to the linker.
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The <code>gccgo</code> compiler does not currently (2009-11-06) record
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the file name of imported packages in the object file. You must
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arrange for the imported data to be linked into the program.
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<pre>
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gccgo -c mypackage.go # Exports mypackage
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gccgo -c main.go # Imports mypackage
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gccgo -o main main.o mypackage.o # Explicitly links with mypackage.o
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</pre>
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<h2 id="Unimplemented">Unimplemented</h2>
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<p>
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Some Go features are not yet implemented in <code>gccgo</code>. As of
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2010-08-23, the following are not implemented:
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<ul>
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<li>goroutines are implemented as NPTL threads. If you can not use
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the gold linker as described above, they are created with a fixed
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stack size, and the number of goroutines that may be created at
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one time is limited.
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</ul>
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<h2 id="Debugging">Debugging</h2>
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<p>
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If you use the <code>-g</code> option when you compile, you can run
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<code>gdb</code> on your executable. The debugger doesn't (yet)
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know anything about Go. However, you can set breakpoints, single-step,
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etc. You can print variables, but they will be printed as though they
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had C/C++ types. For numeric types this doesn't matter. Go strings
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will show up as pointers to structures; to see the value
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<code>print *stringvar</code>. In general Go strings, maps, channels
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and interfaces are always represented as C pointers.
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<h2 id="C_Interoperability">C Interoperability</h2>
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<p>
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When using <code>gccgo</code> there is limited interoperability with C,
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or with C++ code compiled using <code>extern "C"</code>.
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<h3 id="Types">Types</h3>
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<p>
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Basic types map directly: an <code>int</code> in Go is an <code>int</code>
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in C, etc. Go <code>byte</code> is equivalent to C <code>unsigned char</code>.
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Pointers in Go are pointers in C. A Go <code>struct</code> is the same as C
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<code>struct</code> with the same fields and types.
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<p>
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The Go <code>string</code> type is currently defined as a two-element
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structure (this is <b style="color: red;">subject to change</b>):
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<pre>
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struct __go_string {
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const unsigned char *__data;
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int __length;
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};
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</pre>
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<p>
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You can't pass arrays between C and Go. However, a pointer to an
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array in Go is equivalent to a C pointer to the
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equivalent of the element type.
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For example, Go <code>*[10]int</code> is equivalent to C <code>int*</code>,
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assuming that the C pointer does point to 10 elements.
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<p>
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A slice in Go is a structure. The current definition is
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(this is <b style="color: red;">subject to change</b>):
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<pre>
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struct __go_slice {
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void *__values;
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int __count;
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int __capacity;
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};
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</pre>
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<p>
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The type of a Go function with no receiver is equivalent to a C function
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whose parameter types are equivalent. When a Go function returns more
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than one value, the C function returns a struct. For example, these
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functions have equivalent types:
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<pre>
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func GoFunction(int) (int, float64)
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struct { int i; float64 f; } CFunction(int)
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</pre>
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<p>
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A pointer to a Go function is equivalent to a pointer to a C function
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when the functions have equivalent types.
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<p>
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Go <code>interface</code>, <code>channel</code>, and <code>map</code>
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types have no corresponding C type (<code>interface</code> is a
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two-element struct and <code>channel</code> and <code>map</code> are
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pointers to structs in C, but the structs are deliberately undocumented). C
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<code>enum</code> types correspond to some integer type, but precisely
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which one is difficult to predict in general; use a cast. C <code>union</code>
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types have no corresponding Go type. C <code>struct</code> types containing
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bitfields have no corresponding Go type. C++ <code>class</code> types have
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no corresponding Go type.
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<p>
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Memory allocation is completely different between C and Go, as Go uses
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garbage collection. The exact guidelines in this area are undetermined,
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but it is likely that it will be permitted to pass a pointer to allocated
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memory from C to Go. The responsibility of eventually freeing the pointer
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will remain with C side, and of course if the C side frees the pointer
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while the Go side still has a copy the program will fail. When passing a
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pointer from Go to C, the Go function must retain a visible copy of it in
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some Go variable. Otherwise the Go garbage collector may delete the
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pointer while the C function is still using it.
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<h3 id="Function_names">Function names</h3>
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<p>
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Go code can call C functions directly using a Go extension implemented
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in <code>gccgo</code>: a function declaration may be followed by
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<code>__asm__("NAME")</code>. For example, here is how the C function
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<code>open</code> can be declared in Go:
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<pre>
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func c_open(name *byte, mode int, perm int) int __asm__ ("open");
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</pre>
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<p>
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The C function naturally expects a nul terminated string, which in
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Go is equivalent to a pointer to an array (not a slice!) of
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<code>byte</code> with a terminating zero byte. So a sample call
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from Go would look like (after importing the <code>os</code> package):
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<pre>
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var name = [4]byte{'f', 'o', 'o', 0};
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i := c_open(&name[0], os.O_RDONLY, 0);
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</pre>
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<p>
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(this serves as an example only, to open a file in Go please use Go's
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<code>os.Open</code> function instead).
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<p>
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The name of Go functions accessed from C is subject to change. At present
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the name of a Go function that does not have a receiver is
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<code>prefix.package.Functionname</code>. The prefix is set by
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the <code>-fgo-prefix</code> option used when the package is compiled;
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if the option is not used, the default is simply <code>go</code>.
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To call the function from C you must set the name using
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a <code>gcc</code> extension similar to the <code>gccgo</code>
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extension.
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<pre>
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extern int go_function(int) __asm__ ("myprefix.mypackage.Function");
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</pre>
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<h3 id="Automatic_generation_of_Go_declarations_from_C_source_code">
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Automatic generation of Go declarations from C source code</h3>
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<p>
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The Go version of <code>gcc</code> supports automatically generating
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Go declarations from C code. The facility is rather awkward at present,
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and a better mechanism is under development.
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<p>
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Compile your C code as usual, but replace <code>-c</code> with
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<code>-S -ggo</code>. The result will be an assembler file
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with a <code>.s</code> extension. This assembler file will contain
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comments beginning with #GO. Those comments are declarations in the Go
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language for the C types, variables and functions declared in the C code.
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C types which can not be represented in Go will contain the string INVALID.
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Unsupported macro definitions will be recorded as <code>unknowndefine</code>,
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and uses of <code>#undef</code> will be recorded as <code>undef</code>.
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So it is very approximately possible to get Go code by running
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<pre>
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gcc -S -ggo foo.c
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grep '#GO' foo.s | grep -v INVALID | grep -v unknowndefine | grep -v undef > foo.go
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</pre>
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<p>
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This procedure is full of unstated caveats and restrictions and we make no
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guarantee that it will not change in the future. It is more useful as a
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starting point for real Go code than as a regular procedure.
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<h2 id="RTEMS_Port">RTEMS Port</h2>
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<p>
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The <code>gccgo</code> compiler has been ported to <a href="http://www.rtems.com/">
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<code>RTEMS</code></a>. <code>RTEMS</code> is a real-time executive
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that provides a high performance environment for embedded applications
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on a range of processors and embedded hardware. The current <code>gccgo</code>
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port is for x86. The goal is to extend the port to most of the
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<a href="http://www.rtems.org/wiki/index.php/SupportedCPUs">
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architectures supported by <code>RTEMS</code></a>. For more information on the port,
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as well as instructions on how to install it, please see this
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<a href="http://www.rtems.com/wiki/index.php/GCCGoRTEMS"><code>RTEMS</code> Wiki page</a>.
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