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<link HREF="mailto:drh@cs.princeton.edu" REV="made" TITLE="David R. Hanson">

<title>Installing lcc</title>

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<h1>Installing lcc</h1>

<p ALIGN="LEFT"><strong><a HREF="http://www.research.microsoft.com/~cwfraser/">Christopher

W. Fraser</a> and <a HREF="http://www.research.microsoft.com/~drh/">David R. Hanson</a>, <a

HREF="http://www.research.microsoft.com/">Microsoft Research</a></strong><br>

September 2002</p>

<h2>Contents</h2>

<dir>

  <li><a HREF="#intro">Introduction</a></li>

  <li><a HREF="#unix">Installation on UNIX</a></li>

  <li><a HREF="#driver">Building the Driver</a></li>

  <li><a HREF="#rcc">Building the Compiler and Accessories</a></li>

  <li><a HREF="#win32">Installation on Windows</a></li>

  <li><a HREF="#bugs">Reporting Bugs</a></li>

  <li><a HREF="#mailinglist">Keeping in Touch</a></li>

</dir>

<h2><a NAME="intro">Introduction</a></h2>

<p><a HREF="http://www.cs.princeton.edu/software/lcc/">lcc</a> is the ANSI C compiler

described in our book <cite>A Retargetable C Compiler: Design and Implementation</cite>

(Addison-Wesley, 1995, ISBN 0-8053-1670-1).</p>

<p>If you're installing lcc on a UNIX system, read the remainder of this section and

continue with the next section. If you're installing lcc on a Windows system, you should read the rest of this section, the following three sections, and the <a

HREF="#win32">Windows</a> section.</p>

<p>Extract the distribution into its own directory. All non-absolute paths below are

relative to this directory. The distribution holds the following subdirectories.</p>

<blockquote>

  <table BORDER="0" CELLPADDING="1" CELLSPACING="1" WIDTH="80%">

    <tr>

      <td><a HREF="../src"><code>src</code></a></td>

      <td></td>

      <td>source code</td>

    </tr>

    <tr>

      <td><a HREF="../etc"><code>etc</code></a></td>

      <td></td>

      <td>driver, accessories</td>

    </tr>

    <tr>

      <td><a HREF="../lib"><code>lib</code></a></td>

      <td></td>

      <td>runtime library source code</td>

    </tr>

    <tr>

      <td><a HREF="../cpp"><code>cpp</code></a></td>

      <td></td>

      <td>preprocessor source code</td>

    </tr>

    <tr>

      <td><a HREF="../lburg"><code>lburg</code></a></td>

      <td></td>

      <td>code-generator generator source code</td>

    </tr>

    <tr>

      <td><a HREF="../doc"><code>doc</code></a></td>

      <td></td>

      <td>this document, man pages</td>

    </tr>

    <tr>

      <td><code><a HREF="../include">include</a>/*/*</code></td>

      <td></td>

      <td>include files</td>

    </tr>

    <tr>

      <td><a HREF="../tst"><code>tst</code></a></td>

      <td></td>

      <td>test suite</td>

    </tr>

    <tr>

      <td><code><a HREF="../alpha">alpha</a>/*/tst</code></td>

      <td></td>

      <td>ALPHA test outputs</td>

    </tr>

    <tr>

      <td><code><a HREF="../mips">mips</a>/*/tst</code></td>

      <td></td>

      <td>MIPS test outputs</td>

    </tr>

    <tr>

      <td><code><a HREF="../sparc">sparc</a>/*/tst</code></td>

      <td></td>

      <td>SPARC test outputs</td>

    </tr>

    <tr>

      <td><code><a HREF="../x86">x86</a>/*/tst</code></td>

      <td></td>

      <td>X86 test outputs</td>

    </tr>

  </table>

</blockquote>

<p><code>doc/install.html</code> is the HTML file for this document.</p>

<p>The installation makefile is designed so that lcc can be installed from a read-only

file system or directory, which is common in networked environments, so the distribution

can be unloaded on a central file server. <strong>You will need an existing ANSI/ISO C

compiler to build and install lcc.</strong></p>

<h2><a NAME="unix">Installation on UNIX</a></h2>

<p>The compilation components (the preprocessor, include files, and compiler proper, etc.)

are installed in a single <em>build directory</em>. On multi-platform systems supported by

a central file server, it's common to store the build directory in a location specific to

the platform and to the version of lcc, and to point a symbolic link to this location. For

example,</p>

<blockquote>

  <pre>% ln -s $BUILDDIR/sparc-solaris /usr/local/lib/lcc</pre>

</blockquote>

<p>points <code>/usr/local/lib/lcc</code> to a build directory for lcc on the SPARC under Solaris. Links into <code>/usr/local/lib/lcc</code> are created for the programs <code>lcc</code>

and <code>bprint</code>. Thus, a new distribution can be installed by building it in its

own build directory and changing one symbolic link to point to that directory. If these

conventions or their equivalents are followed, the host-specific parts of the driver

program, <code>lcc</code>, can be used unmodified.</p>

<p>Installation on a UNIX system involves the following steps. Below, the build directory

is referred to as <code>BUILDDIR</code>, and the commands below are executed

from the distribution directory.<ol>

  <li>Create the build directory, using a version- and platform-specific naming convention as

    suggested above, and record the name of this directory in the <code>BUILDDIR</code>

    environment variable:<blockquote>

      <pre>% setenv BUILDDIR $BUILDDIR/sparc-solaris

% mkdir -p $BUILDDIR</pre>

    </blockquote>

    <p>Here and below, commands assume the C shell. Also, you'll need a version of <code>mkdir</code>

    that supports the <code>-p</code> option, which creates intermediate directories as

    necessary.</p>

  </li>

  <li>Copy the man pages to the repository for local man pages, e.g.,<blockquote>

      <pre>% cp doc/*.1 /usr/local/man/man1</pre>

    </blockquote>

    <p>Some users copy the man pages to the build directory and create the appropriate

    symbolic links, e.g., </p>

    <blockquote>

      <pre>% cp doc/*.1 $BUILDDIR

% ln -s $BUILDDIR/*.1 /usr/local/man/man1</pre>

    </blockquote>

  </li>

  <li>Platform-specific include files are in directories named <code>include/</code><em>target</em><code>/</code><em>os</em>.

    Create the include directory in the build directory, and copy the include hierarchy for

    your platform to this directory, e.g.,<blockquote>

      <pre>% mkdir $BUILDDIR/include

% cp -p -R include/sparc/solaris/* $BUILDDIR/include</pre>

    </blockquote>

    <p>Again, some users create a symbolic link to the appropriate directory in the

    distribution instead of copying the include files. For example, at Princeton, the

    distributions are stored under <code>/proj/pkg/lcc</code>, so the included files are

    &quot;installed&quot; by creating one symbolic link: </p>

    <blockquote>

      <pre>% ln -s $BUILDDIR/include/sparc/solaris $BUILDDIR/include</pre>

    </blockquote>

    <p>If you're installing lcc on Linux, you <em>must</em> also plant a symbolic link named <code>gcc</code>

    to gcc's library directory, because lcc uses gcc's C preprocessor and most of gcc's header

    files:</p>

    <blockquote>

      <pre>% ln -s /usr/lib/gcc-lib/i386-redhat-linux/2.96 $BUILDDIR/gcc</pre>

    </blockquote>

    <p>The library directory shown above may be different on your Linux machine; to determine

    the correct directory, browse <code>/usr/lib/gcc-lib</code>, or execute</p>

    <blockquote>

      <pre>% cc -v tst/8q.c</pre>

    </blockquote>

    <p>and examine the diagnostic output. Make sure that <code>$BUILDDIR/gcc/cpp0</code> and <code>$BUILDDIR/gcc/include</code>

    are, respectively, gcc's C preprocessor and header files. On Linux, lcc looks for

    include files in <code>$BUILDDIR/include</code>, <code>$BUILDDIR/gcc/include</code>, and <code>/usr/include</code>,

    in that order; see <a HREF="#driver"><em>Building the Driver</em></a> and <a

    href="../etc/linux.c"><code>etc/linux.c</code></a> for details.</p>

  </li>

  <li>The <a HREF="../makefile"><code>makefile</code></a> includes the file named by the <code>CUSTOM</code>

    macro; the default is <code>custom.mk</code>, and an empty <code>custom.mk</code> is

    included in the distribution. If desired, prepare a site-specification customization file

    and define <code>CUSTOM</code> to the path of that file when invoking make in steps 5 and

    6, e.g.,<blockquote>

      <pre>make CUSTOM=<a href="http://www.cs.princeton.edu/software/lcc/pkg/solaris.mk">solaris.mk</a></pre>

    </blockquote>

    <p>You can, for example, use customization files to record site-specific values for macros

    instead of using environment variables, and to record targets for the steps in this list.</p>

  </li>

  <li>Build the host-specific driver, creating a custom host-specific part, if necessary. See <a

    HREF="#driver"><em>Building the Driver</em></a>.</li>

  <li>Build the preprocessor, compiler proper, library, and other accessories. See <a

    HREF="#rcc"><em>Building the Compiler</em></a>.</li>

  <li>Plant symbolic links to the build directory and to the installed programs, e.g.,<blockquote>

      <pre>% ln -s $BUILDDIR /usr/local/lib/lcc

% ln -s /usr/local/lib/{lcc,bprint} /usr/local/bin</pre>

    </blockquote>

    <p>Some users copy <code>bprint</code> and <code>lcc</code> into <code>/usr/local/bin</code>

    instead of creating symbolic links. The advantage of creating the links for <code>lcc</code>

    and <code>bprint</code> as shown is that, once established, they point indirectly to

    whatever <code>/usr/local/lib/lcc</code> points to; installing a new version of lcc can be done by changing <code>/usr/local/lib/lcc</code> to point to the build

    directory for the new version.</p>

  </li>

</ol>

<h2><a NAME="driver">Building the Driver</a></h2>

<p>The preprocessor, compiler, assembler, and loader are invoked by a driver program, <code>lcc</code>,

which is similar to <code>cc</code> on most systems. It's described in the man page <code>doc/lcc.1</code>.

The driver is built by combining the host-independent part, <a href="../etc/lcc.c"><code>etc/lcc.c</code></a>,

with a small host-specific part. Distributed host-specific parts are named <code>etc/</code><em>os</em><code>.c</code>,

where <em>os</em> is the name of the operating system for the host on which <code>lcc</code>

is being installed. If you're following the installations conventions described above, you

can probably use one of the host-specific parts unmodified; otherwise, pick one that is

closely related to your platform, copy it to <em>whatever</em><code>.c</code>, and edit it

as described below. You should not have to edit <code>etc/lcc.c</code>.</p>

<p>We'll use <a HREF="../etc/solaris.c"><code>etc/solaris.c</code></a> as an example in

describing how the host-specific part works. This example illustrates all the important

features. Make sure you have the environment variable <code>BUILDDIR</code> set correctly,

and build the driver with a <code>make</code> command, e.g.,</p>

<blockquote>

  <pre>% make HOSTFILE=etc/solaris.c lcc

cc -g -c -o $BUILDDIR/sparc-solaris/lcc.o etc/lcc.c

cc -g -c -o $BUILDDIR/sparc-solaris/host.o etc/solaris.c

cc -g -o $BUILDDIR/lcc $BUILDDIR/sparc-solaris/lcc.o $BUILDDIR/sparc-solaris/host.o</pre>

</blockquote>

<p>Of course, the actual value of <code>BUILDDIR</code> will appear in place of

<code>$BUILDDIR</code>. The symbolic name <code>HOSTFILE</code> specifies the path to the host-specific part,

either one in the distribution or <em>whatever</em><code>.c</code>. Some versions of make

may require the <code>-e</code> option in order to read the environment.</p>

<p>Here's <code>etc/solaris.c</code>:</p>

<blockquote>

  <pre>/* Sparcs running Solaris 2.5.1 at CS Dept., Princeton University */

#include <string.h>

static char rcsid[] = "$ Id: solaris.c,v 1.10 1998/09/14 20:36:33 drh Exp $";

#ifndef LCCDIR

#define LCCDIR "/usr/local/lib/lcc/"

#endif

#ifndef SUNDIR

#define SUNDIR "/opt/SUNWspro/SC4.2/lib/"

#endif

char *suffixes[] = { ".c", ".i", ".s", ".o", ".out", 0 };

char inputs[256] = "";

char *cpp[] = { LCCDIR "cpp",

        "-D__STDC__=1", "-Dsparc", "-D__sparc__", "-Dsun", "-D__sun__", "-Dunix",

        "$1", "$2", "$3", 0 };

char *include[] = { "-I" LCCDIR "include", "-I/usr/local/include",

        "-I/usr/include", 0 };

char *com[] = { LCCDIR "rcc", "-target=sparc/solaris",

        "$1", "$2", "$3", 0 };

char *as[] = { "/usr/ccs/bin/as", "-Qy", "-s", "-o", "$3", "$1", "$2", 0 };

char *ld[] = { "/usr/ccs/bin/ld", "-o", "$3", "$1",

        SUNDIR "crti.o", SUNDIR "crt1.o",

        SUNDIR "values-xa.o", "$2", "",

        "-Y", "P," SUNDIR ":/usr/ccs/lib:/usr/lib", "-Qy",

        "-L" LCCDIR, "-llcc", "-lm", "-lc", SUNDIR "crtn.o", 0 };

extern char *concat(char *, char *);

int option(char *arg) {

        if (strncmp(arg, "-lccdir=", 8) == 0) {

                cpp[0] = concat(&arg[8], "/cpp");

                include[0] = concat("-I", concat(&arg[8], "/include"));

                ld[12] = concat("-L", &arg[8]);

                com[0] = concat(&arg[8], "/rcc");

        } else if (strcmp(arg, "-p") == 0) {

                ld[5] = SUNDIR "mcrt1.o";

                ld[10] = "P," SUNDIR "libp:/usr/ccs/lib/libp:/usr/lib/libp:"

                         SUNDIR ":/usr/ccs/lib:/usr/lib";

        } else if (strcmp(arg, "-b") == 0)

                ;

        else if (strncmp(arg, "-ld=", 4) == 0)

                ld[0] = &arg[4];

        else

                return 0;

        return 1;

}</pre>

</blockquote>

<p><code>LCCDIR</code> defaults to <code>&quot;/usr/local/lib/lcc/&quot;</code> unless

it's defined by a <code>-D</code> option as part of <code>CFLAGS</code> in the make

command, e.g.,</p>

<blockquote>

  <pre>% make HOSTFILE=etc/solaris.c CFLAGS='-DLCCDIR=\&quot;/v/lib/lcc/\&quot;' lcc</pre>

</blockquote>

<p>Note the trailing slash; <code>SUNDIR</code> is provided so you can use <code>etc/solaris.c</code>

even if you have a different version of the Sun Pro compiler suite. If you're using the

gcc compiler tools instead of the Sun Pro tools, see <a HREF="../etc/gcc-solaris.c"><code>etc/gcc-solaris.c</code></a>.</p>

<p>Most of the host-specific code is platform-specific data and templates for the commands

that invoke the preprocessor, compiler, assembler, and loader. The <code>suffixes</code>

array lists the file name suffixes for C source files, preprocessed source files, assembly

language source files, object files, and executable files. <code>suffixes</code> must be

terminated with a null pointer, as shown above. The initialization of <code>suffixes</code>

in <code><a HREF="../etc/solaris.c">etc/solaris.c</a></code> are the typical ones for UNIX

systems. Each element of <code>suffixes</code> is actually a list of suffixes, separated

by semicolons; <code><a HREF="../etc/win32.c">etc/win32.c</a></code> holds an example:</p>

<blockquote>

  <pre>char *suffixes[] = { &quot;.c;.C&quot;, &quot;.i;.I&quot;, &quot;.asm;.ASM;.s;.S&quot;, &quot;.obj;.OBJ&quot;, &quot;.exe&quot;, 0 };</pre>

</blockquote>

<p>When a list is given, the first suffix is used whenever lcc needs to generate a file

name. For example, with <code><a HREF="../etc/win32.c">etc/win32.c</a></code>, lcc emits

the generated assembly code into <code>.asm</code> files.</p>

<p>The <code>inputs</code> array holds a null-terminated string of directories separated

by colons or semicolons. These are used as the default value of <code>LCCINPUTS</code>, if

the environment variable <code>LCCINPUTS</code> is not set; see the <a HREF="lcc.pdf">man

page</a>.</p>

<p>Each command template is an array of pointers to strings terminated with a null

pointer; the strings are full path names of commands, arguments, or argument placeholders,

which are described below. Commands are executed in a child process, and templates can

contain multiple commands by separating commands with newlines. The driver runs each

command in a new process.</p>

<p>The <code>cpp</code> array gives the command for running lcc's preprocessor, <code>cpp</code>.

Literal arguments specified in templates, e.g., <code>&quot;-Dsparc&quot;</code> in the <code>cpp</code>

command above, are passed to the command as given.</p>

<p>The strings <code>&quot;$1&quot;</code>, <code>&quot;$2&quot;</code>, and <code>&quot;$3&quot;</code>

in templates are placeholders for <em>lists</em> of arguments that are substituted in a

copy of the template before the command is executed. <code>$1</code> is replaced by the <em>options</em>

specified by the user; for the preprocessor, this list always contains at least <code>-D__LCC__</code>.

<code>$2</code> is replaced by the <em>input</em> files, and <code>$3</code> is replaced

by the <em>output</em> file.</p>

<p>Zero-length arguments after replacement are removed from the argument list before the

command is invoked. So, for example, if the preprocessor is invoked without an output

file, <code>&quot;$3&quot;</code> becomes <code>&quot;&quot;</code>, which is removed from

the final argument list.</p>

<p>The <code>include</code> array is a list of <code>-I</code> options that specify which

directives should be searched to satisfy include directives. These directories are

searched in the order given. The first directory should be the one to which the ANSI

header files were copied as described in <a HREF="#unix">UNIX</a> or <a HREF="#win32">Windows</a>

installation instructions. The driver adds these options to <code>cpp</code>'s arguments

when it invokes the preprocessor, except when <code>-N</code> is specified.</p>

<p><code>com</code> gives the command for invoking the compiler. This template can appear

as shown above in a custom host-specific part, but the option <code>-target=sparc/solaris</code>

should be edited to the <em>target</em><code>/</code><em>os</em> for your platform. If <code>com[1]</code>

includes the string &quot;<code>win32</code>&quot;, the driver assumes it's running on

Windows. lcc can generate code for <em>all</em> of the <em>target</em><code>/</code><em>os</em>

combinations listed in the file <code>src/bind.c</code>. The <code>-target</code> option

specifies the default combination. The driver's <code>-Wf</code> option can be used to

specify other combinations; the <a HREF="lcc.pdf">man page</a> elaborates.</p>

<p><code>as</code> gives the command for invoking the assembler. On Linux, you must be

running at least version 2.8.1 of the GNU assembler; earlier versions mis-assemble some

instructions emitted by lcc.</p>

<p><code>ld</code> gives the command for invoking the loader. For the other commands, the

list <code>$2</code> contains a single file; for <code>ld</code>, <code>$2</code> contains

all &quot;.o&quot; files and libraries, and <code>$3</code> is <code>a.out</code>, unless

the <code>-o</code> option is specified. As suggested in the code above, <code>ld</code>

must also specify the appropriate startup code and default libraries, including the lcc

library, <code>liblcc.a</code>.</p>

<p>The <code>option</code> function is described below; the minimal <code>option</code>

function just returns 0.</p>

<p>You can test <code>lcc</code> with the options <code>-v -v</code> to display the

commands that would be executed, e.g.,</p>

<blockquote>

  <pre>% $BUILDDIR/lcc -v -v foo.c baz.c mylib.a -lX11

$BUILDDIR/sparc-solaris/lcc $ Id: lcc.c,v 4.33 2001/06/28 22:19:58 drh $

foo.c:

/usr/local/lib/lcc/cpp -D__STDC__=1 -Dsparc -D__sparc__ -Dsun -D__sun__ -Dunix -D__LCC__i

/usr/local/lib/lcc/rcc -target=sparc/solaris -v /tmp/lcc4060.i /tmp/lcc4061.s

/usr/ccs/bin/as -Qy -s -o /tmp/lcc4062.o /tmp/lcc4061.s

baz.c:

/usr/local/lib/lcc/cpp -D__STDC__=1 -Dsparc -D__sparc__ -Dsun -D__sun__ -Dunix -D__LCC__i

/usr/local/lib/lcc/rcc -target=sparc/solaris -v /tmp/lcc4060.i /tmp/lcc4061.s

/usr/ccs/bin/as -Qy -s -o /tmp/lcc4063.o /tmp/lcc4061.s

/usr/ccs/bin/ld -o a.out /opt/SUNWspro/SC4.2/lib/crti.o /opt/SUNWspro/SC4.2/lib/crt1.o /o

rm /tmp/lcc4063.o /tmp/lcc4060.i /tmp/lcc4061.s /tmp/lcc4062.o</pre>

</blockquote>

<p>As the output shows, <code>lcc</code> places temporary files in <code>/tmp</code>; if

any of the environment variables <code>TMP</code>, <code>TEMP</code>, and <code>TMPDIR</code>

are set, they override this default (in the order shown) as does the <code>-tempdir=</code><em>dir</em>

option. The default can be changed by defining <code>TEMPDIR</code> in <code>CFLAGS</code>

when building the driver.</p>

<p>The <code>option</code> function is called for the options <code>-Wo</code>, <code>-g</code>,

<code>-p</code>, <code>-pg</code>, and <code>-b</code> because these compiler options

might also affect the loader's arguments. For these options, the driver calls <code>option(arg)</code>

to give the host-specific code an opportunity to edit the <code>ld</code> command, if

necessary. <code>option</code> can change <code>ld</code>, if necessary, and return 1 to

announce its acceptance of the option. If the option is unsupported, <code>option</code>

should return 0.</p>

<p>For example, in response to <code>-g</code>, the <code>option</code> function shown

above accepts the option but does nothing else, because the <code>ld</code> and <code>as</code>

commands don't need to be modified on the SPARC. <code>-g</code> will also be added to the

compiler's options by the host-independent part of the driver. The <code>-p</code> causes <code>option</code>

to change the name of the startup code and changed the list of libraries. The <code>-b</code>

option turns on <code>lcc</code>'s per-expression profiling, the code for which is in <code>liblcc.a</code>,

so <code>option</code> need no nothing.</p>

<p>On SPARCs, the driver also recognizes <code>-Bstatic</code> and <code>-Bdynamic</code>

as linker options. The driver recognizes but ignores &quot;<code>-target</code> <em>name</em>&quot;

option.</p>

<p>The option <code>-Wo</code><em>arg</em> causes the driver to pass <em>arg</em> to <code>option</code>.

Such options have no other effect; this mechanism is provided to support system-specific

options that affect the commands executed by the driver. As illustrated above,

host-specific parts should support the <code>-Wo-lccdir=</code><em>dir</em> option, which

causes lcc's compilation components to be found in <em>dir</em>, because this option is

used by the test scripts, and because the driver simulates a <code>-Wo-lccdir</code>

option with the value of the environment variable <code>LCCDIR</code>, if it's defined.

The code above rebuilds the paths to the include files, preprocessor, compiler, and

library by calling <code>concat</code>, which is defined in <code>etc/lcc.c</code>.</p>

<h2><a NAME="rcc">Building the Compiler and Accessories</a></h2>

<p>To build the rest of compilation components make sure <code>BUILDDIR</code> is set

appropriately and type &quot;<code>make all</code>&quot;. This command builds <code>librcc.a</code>

(the compiler's private library), <code>rcc</code> (the compiler proper), <code>lburg</code>

(the code-generator generator), <code>cpp</code> (the preprocessor), <code>liblcc.a</code>

(the runtime library), and <code>bprint</code> (the profile printer), all in <code>BUILDDIR</code>.

There may be warnings, but there should be no errors. If you're using an ANSI/ISO compiler

other than <code>cc</code>, specify its name with the <code>CC=</code> option, e.g.,

&quot;<code>make CC=gcc all</code>&quot;. If you're running on a DEC ALPHA, use &quot;<code>make

CC='cc -std1' all</code>&quot;; the <code>-std1</code> option is essential on

the ALPHA.</p>

<p>Once <code>rcc</code> is built with the host C compiler, run the test suite to verify

that <code>rcc</code> is working correctly. If any of the steps below fail, contact us

(see <a HREF="#bugs"><em>Reporting Bugs</em></a>). The commands in the makefile run the

shell script <code>src/run.sh</code> on each C program in the test suite, <code>tst/*.c</code>.

It uses the driver, <code>$BUILDDIR/lcc</code>, so you must have the driver in the build

directory before testing <code>rcc</code>. The <em>target</em><code>/</code><em>os</em>

combination is read from the variable <code>TARGET</code>, which must be specified when

invoking <code>make</code>:</p>

<blockquote>

  <pre>% make TARGET=sparc/solaris test

mkdir -p $BUILDDIR/sparc-solaris/sparc/solaris/tst

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/8q.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/array.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/cf.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/cq.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/cvt.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/fields.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/front.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/incr.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/init.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/limits.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/paranoia.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/sort.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/spill.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/stdarg.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/struct.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/switch.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/wf1.s:

$BUILDDIR/sparc-solaris/rcc -target=sparc/solaris $BUILDDIR/sparc-solaris/sparc/solaris/tst/yacc.s:</pre>

</blockquote>

<p>Each line in the output above is of the form</p>

<blockquote>

  <p><code>$BUILDDIR/rcc -target=</code><em>target</em><code>/</code><em>os</em><code> $BUILDDIR/</code><em>target</em><code>/</code><em>os</em><code>/</code><em>X</em><code>.s:</code></p>

</blockquote>

<p>where <em>X</em> is the base name of the C program <em>X</em><code>.c</code> in the

test suite. The actual value of <code>BUILDDIR</code> will, of course, appear in

place of <code>$BUILDDIR</code>. This output identifies the compiler and the target, e.g., &quot;<code>$BUILDDIR/rcc</code>

is generating code for a <code>sparc</code> running the <code>solaris</code> operating

system.&quot;</p>

<p>For each program in the test suite, <code>src/run.sh</code> compiles the program, drops

the generated assembly language code in <code>BUILDDIR</code>/<em>target</em><code>/</code><em>os</em>,

and uses <code>diff</code> to compare the generated assembly code with the expected code

(the code expected for <code>tst/8q.c</code> on the SPARC under Solaris is in <code>sparc/solaris/tst/8q.sbk</code>,

etc.). If there are differences, the script executes the generated code with the input

given in <code>tst</code> (the input for <code>tst/8q.c</code> is in <code>tst/8q.0</code>,

etc.) and compares the output with the expected output (the expected output from <code>tst/8q.c</code>

on the SPARC under Solaris is in <code>sparc/solaris/tst/8q.1bk</code>, etc.). The script

also compares the diagnostics from the compiler with the expected diagnostics.</p>

<p>On some systems, there may be a few differences between the generated code and the

expected code. These differences occur because the expected code is generated by cross

compilation and the least significant bits of some floating-point constants differ from

those bits in constants generated on your system. On Linux, there may be differences

because of differences in the header files between our system and yours. There should be

no differences in the output from executing the test programs.</p>

<p>Next, run the &quot;triple test&quot;, which builds <code>rcc</code> using itself:</p>

<blockquote>

  <pre>% make triple

$BUILDDIR/sparc-solaris/lcc -A -d0.6 -Wo-lccdir=$(BUILDDIR) -Isrc -I$(BUILDDIR) -o $BUILDDIR/sparc-solaris/1rcc -B$BUILDDIR/sparc-solaris/ src/alloc.c ...

src/alloc.c:

...

$BUILDDIR/sparc-solaris/lcc -A -d0.6 -Wo-lccdir=$(BUILDDIR) -Isrc -I$(BUILDDIR) -o $BUILDDIR/sparc-solaris/2rcc -B$BUILDDIR/sparc-solaris/1 src/alloc.c ...

src/alloc.c:

...

strip $BUILDDIR/sparc-solaris/[12]rcc

dd if=$BUILDDIR/sparc-solaris/1rcc of=$BUILDDIR/sparc-solaris/rcc1 bs=512 skip=1

1270+1 records in

1270+1 records out

dd if=$BUILDDIR/sparc-solaris/2rcc of=$BUILDDIR/sparc-solaris/rcc2 bs=512 skip=1

1270+1 records in

1270+1 records out

if cmp $BUILDDIR/sparc-solaris/rcc[12]; then \

        mv $BUILDDIR/sparc-solaris/2rcc $BUILDDIR/sparc-solaris/rcc; \

        rm -f $BUILDDIR/sparc-solaris/1rcc $BUILDDIR/sparc-solaris/rcc[12]; fi</pre>

</blockquote>

<p>This command builds <code>rcc</code> twice; once using the <code>rcc</code> built by <code>cc</code>

and again using the <code>rcc</code> built by <code>lcc</code>. The resulting binaries are

compared. They should be identical, as shown at the end of the output above. If they

aren't, our compiler is generating incorrect code; <a HREF="#bugs">contact</a> us.</p>

<p>The final version of <code>rcc</code> should also pass the test suite; that is, the

output from</p>

<blockquote>

  <pre>% make TARGET=sparc/solaris test</pre>

</blockquote>

<p>should be identical to that from the previous <code>make test</code>.</p>

<p>The command &quot;<code>make clean</code>&quot; cleans up, but does not remove <code>rcc</code>,

etc., and &quot;<code>make clobber</code>&quot; cleans up and removes <code>lcc</code>, <code>rcc</code>,

and the other accessories. Test directories under <code>BUILDDIR</code> are <em>not</em>

removed; you'll need to remove these by hand, e.g.,</p>

<blockquote>

  <pre>% rm -fr $BUILDDIR/sparc</pre>

</blockquote>

<p>The code generators for the other targets can be tested by specifying the desired <em>target</em><code>/</code><em>os</em>

and setting an environment variable that controls what <code>src/run.sh</code> does. For

example, to test the MIPS code generator, type</p>

<blockquote>

  <pre>% setenv REMOTEHOST noexecute

% make TARGET=mips/irix test</pre>

</blockquote>

<p>As above, <code>src/run.sh</code> compares the MIPS code generated with what's

expected. There should be no differences. Setting <code>REMOTEHOST</code> to <code>noexecute</code>

suppresses the assembly and execution of the generated code. If you set <code>REMOTEHOST</code>

to the name of a MIPS machine to which you can <code>rlogin</code>, <code>src/run.sh</code>

will <code>rcp</code> the generated code to that machine and execute it there, if

necessary. See <code>src/run.sh</code> for the details.</p>

<p>You can use lcc as a cross compiler. The options <code>-S</code> and <code>-Wf-target=</code><em>target/os</em>

generate assembly code for the specified target, which is any of those listed in the file <code>src/bind.c</code>.

For example, </p>

<blockquote>

  <pre>% lcc -Wf-target=mips/irix -S tst/8q.c</pre>

</blockquote>

<p>generates MIPS code for <code>tst/8q.c</code> in <code>8q.s</code>.</p>

<p>lcc can also generate code for a &quot;symbolic&quot; target. This target is used

routinely in front-end development, and its output is a printable representation of the

input program, e.g., the dags constructed by the front end are printed, and other

interface functions print their arguments. You can specify this target with the option <code>-Wf-target=symbolic</code>.

For example,</p>

<blockquote>

  <pre>% lcc -Wf-target=symbolic -S tst/8q.c</pre>

</blockquote>

<p>generates symbolic output for <code>tst/8q.c</code> in <code>8q.s</code>. Adding <code>-Wf-html</code>

causes the symbolic target to emit HTML instead of plain text. Finally, the option <code>-Wf-target=null</code>

specifies the "null" target for which lcc emits nothing and thus only checks the

syntax and semantics of its input files.</p>

<h2><a NAME="win32">Installation on Windows</a></h2>

<p>On Windows, lcc is designed to work with Microsoft's Visual

C++ (VC), version 5.0 and above, and Microsoft's Assembler, MASM. It uses the VC header files,

libraries, and command-line tools, and it uses MASM to assemble the code it generates.

You must use MASM 6.11d or later,

because earlier  releases generate incorrect COFF object files. MASM

6.15 is available as part of the free

<a href="http://msdn.microsoft.com/vstudio/downloads/ppack/default.asp">Visual

C++ 6.0 Processor Pack</a>.</p>

<p>Building the distribution components from the ground up requires Microsoft's Visual

C/C++ compiler, Microsoft's make, <code>nmake</code>, and the standard Windows command

interpreter. <a HREF="../makefile.nt"><code>makefile.nt</code></a> is written to use only <code>nmake</code>.

As on UNIX systems, the compilation components are installed in a single <em>build

directory</em>, and the top-level programs, <code>lcc.exe</code> and <code>bprint.exe</code>,

are installed in a directory on the PATH. If the conventions used below are followed, the

Windows-specific parts of the driver program, <code>lcc.exe</code>, can be used

unmodified.</p>

<p>Building from the source distribution on a Windows system involves the following steps.

Below, the build directory is referred to as <code>BUILDDIR</code>, and the distribution

is in <code>\dist\lcc</code>.

<ol>

  <li>Create the build directory, perhaps using a version- and platform-specific naming

    convention as suggested in <a HREF="#unix"><em>Installation on UNIX</em></a>, and record

    the name of this directory in the <code>BUILDDIR</code> environment variable:<blockquote>

      <pre>C:\dist\lcc&gt;set BUILDDIR=\progra~1\lcc\<i>version</i>\bin

C:\dist\lcc&gt;mkdir %BUILDDIR%</pre>

    </blockquote>

    <p>The default build, or installation, directory is <code>\Program Files\lcc\</code><i>version</i><code>\bin</code>,

    where <i>version</i> is the version number, e.g., 4.2, but the <code>nmake</code> commands require that you use the corresponding 8.3 file name, <code>progra~1</code>,

    instead of <code>Program Files</code>.</p>

  </li>

  <li><a HREF="../etc/win32.c"><code>etc\win32.c</code></a> is the Windows-specific part of

    the driver. It assumes that environment variable <code>include</code> gives the locations

    of the VC header files and that the linker (<code>link.exe</code>) and the assembler (<code>ml.exe</code>)

    are on the PATH. It also assumes that the macro <code>LCCDIR</code> gives the build

    directory. If necessary, revise a copy of <a HREF="../etc/win32.c"><code>etc\win32.c</code></a>

    to reflect the conventions on your computer (see <a HREF="#driver"><em>Building the Driver</em></a>),

    then build the driver, specifying the default temporary directory, if necessary:<blockquote>

      <pre>C:\dist\lcc&gt;nmake -f makefile.nt HOSTFILE=etc/win32.c lcc

...

        cl -nologo -Zi -MLd -Fd%BUILDDIR%\ -c -Fo%BUILDDIR%\lcc.obj etc/lcc.c

lcc.c

        cl -nologo -Zi -MLd -Fd%BUILDDIR%\ -c -Fo%BUILDDIR%\host.obj etc/win32.c

win32.c

        cl -nologo -Zi -MLd -Fd%BUILDDIR%\ -Fe%BUILDDIR%\lcc.exe %BUILDDIR%\lcc.obj %BUILDDIR%\host.obj</pre>

    </blockquote>

    <p>If you make a copy of <code>etc\win32.c</code>, specify the path of the copy as the

    value of <code>HOSTFILE</code>. For example, if you copy <code>etc\win32.c</code> to <code>BUILDDIR</code>

    and edit it, use the command</p>

    <blockquote>

      <pre>C:\dist\lcc&gt;nmake -f makefile.nt HOSTFILE=%BUILDDIR%\win32.c lcc</pre>

    </blockquote>

  </li>

  <li>Build the preprocessor, compiler proper, library, and other accessories (see <a

    HREF="#rcc"><em>Building the Compiler</em></a>):<blockquote>

      <pre>C:\dist\lcc&gt;nmake -f makefile.nt all</pre>

    </blockquote>

    <p>This command uses the VC command-line tools <code>cl</code> and <code>lib</code> to

    build <code>bprint.exe</code>, <code>cpp.exe</code>, <code>lburg.exe</code>, <code>liblcc.lib</code>,

    <code>librcc.lib</code>, and <code>rcc.exe</code>, all in <code>BUILDDIR</code>. There may

    be some warnings, but there should be no warnings.</p>

  </li>

  <li>Create a test directory and run the test suite:<blockquote>

      <pre>C:\dist\lcc&gt;mkdir %BUILDDIR%\x86\win32\tst

C:\dist\lcc&gt;nmake -f makefile.nt test</pre>

    </blockquote>

    <p>This command compiles each program in <a HREF="../tst">tst</a>, compares the generated

    assembly code and diagnostics with the expected assembly code and diagnostics, executes

    the program, and compares the output with the expected output (using <code>fc</code>). For

    example, when the nmake command compiles <a HREF="../tst/8q.c"><code>tst\8q.c</code></a>,

    it leaves the generated assembly code and diagnostic output in <code>%BUILDDIR%\x86\win32\tst\8q.s</code>

    and <code>%BUILDDIR%\x86\win32\tst\8q.2</code>, and it compares them with the expected

    results in <code>x86\win32\tst\8q.sbk</code>. It builds the executable program in <code>%BUILDDIR%\x86\win32\tst\8q.exe</code>,

    runs it, and redirects the output to <code>%BUILDDIR%\x86\win32\tst\8q.1</code>, which it

    compares with <code>x86\win32\tst\8q.1bk</code>. The output from this step is voluminous,

    but there should be no differences and no errors.</p>

  </li>

  <li>Run the &quot;triple&quot; test, which compiles <code>rcc</code> with itself and

    verifies the results:<blockquote>

      <pre>C:\dist\lcc&gt;nmake -f makefile.nt triple

...

 Assembling: C:/TEMP/lcc2001.asm

        fc /b %BUILDDIR%\1rcc.exe %BUILDDIR%\2rcc.exe

Comparing files %BUILDDIR%\1rcc.exe and %BUILDDIR%\2RCC.EXE

00000088: B4 D5</pre>

    </blockquote>

    <p>This command builds <code>rcc</code> twice; once using the <code>rcc</code> built by VC

    and again using the <code>rcc</code> built by <code>lcc</code>. The resulting binaries are

    compared using <code>fc</code>. They should be identical, except for one or two bytes of

    timestamp data, as shown at the end of the output above (which will be

    different on your system). If <code>1rcc.exe</code> and <code>2rcc.exe</code> aren't

    identical, our compiler is

    generating incorrect code; <a HREF="#bugs">contact</a> us.</p>

  </li>

  <li>Copy <code>lcc.exe</code> and <code>bprint.exe</code> to a directory on your PATH, e.g.,<blockquote>

      <pre>C:\dist\lcc&gt;copy %BUILDDIR%\lcc.exe \bin

        1 file(s) copied.

C:\dist\lcc>copy %BUILDDIR%\bprint.exe \bin

        1 file(s) copied.</pre>

    </blockquote>

  </li>

  <li>Finally, clean up:<blockquote>

      <pre>C:\dist\lcc&gt;nmake -f makefile.nt clean</pre>

    </blockquote>

    <p>This command removes the derived files in <code>BUILDDIR</code>, but does not remove <code>rcc.exe</code>,

    etc.; &quot;<code>nmake -f makefile.nt clobber</code>&quot; cleans up and removes all

    executables and libraries. Test directories under <code>BUILDDIR</code> are <em>not</em>

    removed; you'll need to remove these by hand, e.g.,</p>

    <blockquote>

      <pre>C:\dist\lcc&gt;rmdir %BUILDDIR%\x86 /s

%BUILDDIR%\x86, Are you sure (Y/N)? y</pre>

    </blockquote>

  </li>

</ol>

<h2><a NAME="bugs">Reporting Bugs</a></h2>

<p>lcc is a large, complex program. We find and repair errors routinely. If you think that

you've found a error, follow the steps below, which are adapted from the instructions in

Chapter 1 of <cite>A Retargetable C Compiler: Design and Implementation</cite>.

<ol>

  <li>If you don't have a source file that displays the error, create one. Most errors are

    exposed when programmers try to compile a program they think is valid, so you probably

    have a demonstration program already.</li>

  <li>Preprocess the source file and capture the preprocessor output. Discard the original

    code.</li>

  <li>Prune your source code until it can be pruned no more without sending the error into

    hiding. We prune most error demonstrations to fewer than five lines.</li>

  <li>Confirm that the source file displays the error with the <em>distributed</em> version of

    lcc. If you've changed lcc and the error appears only in your version, then you'll have to

    chase the error yourself, even if it turns out to be our fault, because we can't work on

    your code.</li>

  <li>Annotate your code with comments that explain why you think that lcc is

  wrong. If lcc dies with an assertion failure, please tell us where it died. If

  lcc crashes, please report the last part of the call chain if you can. If lcc

  is rejecting a program you think is valid, please tell us why you think it's

  valid, and include supporting page numbers in the ANSI Standard or the

    appropriate section in <cite>C: A Reference Manual</cite>, 4th edition by S. B. Harbison

    and G. L. Steele, Jr. (Prentice Hall, 1995). If lcc silently generates incorrect code for

    some construct, please include the corrupt assembly code in the comments and flag the

    incorrect instructions if you can.</li>

  <li>Confirm that your error hasn't been fixed already. The latest version of lcc is always

    available for anonymous <code>ftp</code> from <code>ftp.cs.princeton.edu</code> in <a

    HREF="ftp://ftp.cs.princeton.edu/pub/lcc"><code>pub/lcc</code></a>. A <a

    HREF="ftp://ftp.cs.princeton.edu/pub/lcc/README"><code>README</code></a> file there gives

    acquisition details, and the <a HREF="../LOG"><code>LOG</code></a> file reports what errors

    were fixed and when they were fixed. If you report a error that's been fixed, you might

    get a canned reply.</li>

  <li>Post your program to the newsgroup <a href="news:comp.compilers.lcc"><code>comp.compilers.lcc</code></a>

  using a USENET newsreader like those at <a href="http://www.dejanews.com/">http://www.dejanews.com/</a>

  and <a href="http://groups.google.com/">http://groups.google.com/</a>.

    Please post only valid C programs; put all remarks in C comments so that we can process

    reports semi automatically.</li>

</ol>

<h2><a NAME="mailinglist">Keeping in Touch</a></h2>

<p>The USENET newsgroup <a href="news:comp.compilers.lcc">comp.compilers.lcc</a> is an

unmoderated newsgroup that serves as a forum for all topics related to the installation,

use, and development of lcc. You can post messages to comp.compilers.lcc using any USENET

newsreader or by visiting <a href="http://www.dejanews.com/">http://www.dejanews.com/</a>,

which also includes an archive of recent postings.</p>

<hr>

<address>

  <a HREF="http://www.research.microsoft.com/~cwfraser/">Chris Fraser</a> / <a

  HREF="mailto:cwfraser@microsoft.com">cwfraser@microsoft.com</a><br>

  <a HREF="http://www.research.microsoft.com/~drh/">David Hanson</a> / <a

  HREF="mailto:drh@microsoft.com">drh@microsoft.com</a><br>

  $Revision: 1.45 $ $Date: 2002/09/04 18:33:24 $

</address>

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