C-INTERCAL 0.29
About this manual
PART I: THE C-INTERCAL COMPILER
1 Installation
  1.1 Obtaining
  1.2 Unpacking
  1.3 Simple Installation
  1.4 Installation on DOS
  1.5 Uninstalling
  1.6 Reporting Bugs
  1.7 Distributing
2 Invoking ick
  2.1 Language-affecting Options
  2.2 Debug Options
  2.3 Output Options
  2.4 Optimizer Options
  2.5 Other Options
  2.6 Options to Generated Programs
  2.7 Environment Variables
3 Errors and Warnings
  3.1 Errors
  3.2 Warnings
4 The yuk debugger
PART II: THE INTERCAL LANGUAGE
5 Syntax
  5.1 Princeton and Atari Syntax
  5.2 Line Labels
  5.3 Statement Identifiers
  5.4 Execution Chance
  5.5 ONCE and AGAIN
6 Expressions
  6.1 Constants and Variables
  6.2 Grouping Rules
  6.3 Operators
    6.3.1 Mingle
    6.3.2 Select
    6.3.3 Unary Binary Logic
    6.3.4 Array Subscript
7 Statements
  7.1 Syntax Error
  7.2 Calculate
  7.3 NEXT, FORGET and RESUME
  7.4 STASH and RETRIEVE
  7.5 IGNORE and REMEMBER
  7.6 ABSTAIN and REINSTATE
  7.7 READ OUT and WRITE IN
    7.7.1 INTERCAL-72 I/O
    7.7.2 C-INTERCAL I/O
    7.7.3 CLC-INTERCAL I/O
  7.8 GIVE UP
  7.9 TRY AGAIN
  7.10 COME FROM and NEXT FROM
8 System Libraries
  8.1 syslib
  8.2 floatlib
PART III: INTERCAL DIALECTS AND EXTENSIONS
9 TriINTERCAL
10 Multithreading and Backtracking
  10.1 Multithreading using COME FROM
  10.2 Multithreading using WHILE
  10.3 Backtracking
11 Operand Overloading
12 PIC-INTERCAL
13 CREATE
14 External Calls
  14.1 External Calls to C
    14.1.1 External C Call Infrastructure
    14.1.2 ick_startup
    14.1.3 ick_linelabel
    14.1.4 ick_labeledblock
    14.1.5 ick_comefrom and ick_nextfrom
    14.1.6 ick_next
    14.1.7 ick_resume
    14.1.8 ick_forget
    14.1.9 ick_get/setone/twospot
    14.1.10 ick_create
    14.1.11 External Calls and auto
  14.2 External Calls to Funge-98
    14.2.1 Creating the Funge-98 Library
    14.2.2 The IFFI Fingerprint
  14.3 Miscellaneous External Calls
  14.4 Using External Calls
  14.5 Expansion Libraries
15 Differences to Other Compilers
PART IV: APPENDICES AND INDICES
Appendix A Character Sets
Appendix B convickt
Appendix C Optimizer Idiom Language
  C.1 OIL Basics
  C.2 OIL Syntax
  C.3 OIL Expressions
  C.4 OIL Patterns
  C.5 OIL Replacements
  C.6 OIL Loops
  C.7 OIL Tips
  C.8 OIL Example
Appendix D Copying
  D.1 GNU Free Documentation License
Index
C-INTERCAL 0.29
***************

This manual is for C-INTERCAL version 0.29.  It does not replace the old
groff manual, nor is it designed to be read in conjunction with it;
instead, it serves a different purpose, of providing information useful
to users of C-INTERCAL (unlike the other manual, it is not derived from
the original INTERCAL-72 manual).

Copyright  2007 Alex Smith.

     Permission is granted to copy, distribute and/or modify this
     document under the terms of the GNU Free Documentation License,
     Version 1.2 or any later version published by the Free Software
     Foundation; with no Invariant Sections, with no Front-Cover Texts,
     and with no Back-Cover Texts.  A copy of the license is included in
     the section entitled "GNU Free Documentation License."

About this manual
*****************

This is the Revamped Instruction Manual for C-INTERCAL (this version is
distributed with C-INTERCAL version 0.29).  It is divided into four
parts.

The first part is about the C-INTERCAL compiler 'ick', and how to use
it.  It covers installing the compiler, using the compiler, what error
and warning messages are produced by the compiler, and some information
on how to use the debugger.

The second part is about the core INTERCAL language, invented in 1972,
and some other commands since then which don't feel like they're
extensions.  (This is a pretty arbitrary distinction, but people who
write the documentation are entitled to arbitrary distinctions.  The
manual's licensed under a license that lets you change it (*note
Copying::), so if you disagree you can move the commands from section to
section yourself.)  Mostly only commands that are implemented in
C-INTERCAL are covered here (if you're interested in the other commands
implemented in other compilers, read CLC-INTERCAL's documentation).
However, a comprehensive guide to portability of these commands between
C-INTERCAL and other INTERCAL compilers is given.

The third part covers the INTERCAL extensions and dialects that are
implemented by C-INTERCAL, such as TriINTERCAL and Threaded INTERCAL.
Again, extensions and dialects not implemented have been mostly left
out.

The final part contains appendices (which were known as 'tonsils' in the
original INTERCAL manual), such as character sets used by INTERCAL,
programs other than 'ick' in the C-INTERCAL distribution, information on
how to read and update the list of optimizer idioms used by the
compiler, and the copyright.

PART I: THE C-INTERCAL COMPILER
*******************************

1 Installation
**************

The C-INTERCAL distribution is distributed in source code form; this
means that before using it, you first have to compile it.  Don't worry:
if you have the right software, it's not at all difficult.  Most
Linux-based and UNIX-based computers are likely to have the software
needed already; the software needed to compile source-distributed
packages is also readily available for free for other operating systems.
The following instructions will help you install the distribution in a
method appropriate for your system.

1.1 Obtaining
=============

C-INTERCAL distributions have been stored in many different places over
time; it can sometimes be hard to make sure that you are finding the
most recent version.  In order to make sure that you have the most
recent version, the easiest way is to look at the alt.lang.intercal
newsgroup; all releases of the C-INTERCAL compiler ought to be announced
there.  (If you are interested in what other INTERCAL compilers are
available, it may also be worth looking there.)  If you don't have
access to a newsreader, your newsreader doesn't cover that newsgroup, or
the distance between releases has been too large for your news server to
keep the message, it's likely that you can find the announcement in an
archive on the World Wide Web; at the time of writing (2007), the
archives of the newsgroup are stored by Google Groups
(http://groups.google.com), and a search for 'alt.lang.intercal' there
should tell you where to find a copy.

If you're looking for the latest version, note that the number after the
dot represents the major version number; you want to maximise this in
favour of the number before the dot, which is the bugfix level within a
major version.  (Major versions are released as version 0.whatever; if a
new version comes out that fixes bugs but adds no new features, nowadays
its number will be of the form 1.whatever, with the same major number.
This has not always been the case, though.)

1.2 Unpacking
=============

C-INTERCAL is distributed in compressed pax format; for instance, you
may find it as a '.pax.lzma' file if you have the 'unlzma' decompression
program (this is advised, as it's the smallest); '.pax.bz2' is larger
and '.pax.gz' is larger still.  Most computers can decompress files in
this format, even if they don't realise it, because pax is
forwards-compatible with tar; try renaming the extension from '.pax' to
'.tar' after decompressing to see if you have a progam that can
decompress it.  (If you're wondering why such an apparently non-standard
format is being used, this is is actually a case where C-INTERCAL is
being perfectly nonstandard by conforming to the standards; tar is no
longer specified by POSIX, and pax is its replacement.  It's just that
pax never really caught on.)

It doesn't matter where you extract the distribution file to: it's best
if you don't put it anywhere special.  If you aren't an administrator,
you should extract the file to somewhere in your home directory (Linux
or UNIX-like systems) or to your My Documents directory (recent versions
of Windows; if you're using an older version, then you _are_ an
administrator, or at least have the same privileges, and can extract it
anywhere).  Some commands that you might use to extract it:

Generic UNIX/Linux

          unlzma ick-0-29.pax.lzma
          tar xvf ick-0-29.pax
     or
          bunzip2 ick-0-29.pax.bz2
          tar xvf ick-0-29.pax
     or
          gunzip ick-0-29.pax.gz
          tar xvf ick-0-29.pax

     On most UNIX-based and Linux-based systems, 'tar' will be available
     to unpack the installation files once they've been uncompressed
     with 'gunzip'.  (I've heard that some BSD systems have 'pax' itself
     to decompress the files, although have not been able to verify
     this; some Linux distributions also have 'pax' in their package
     managers.  Both tar and pax should work fine, though.)  'gunzip' is
     also likely to be available (and 'bunzip2' and 'unlzma' are less
     likely, but use those versions if you have them to save on your
     bandwidth); if it isn't, you will need to download a copy from the
     Internet.

Using GNU tar

          tar xzvf ick-0-29.pax.gz
     or
          tar xqvf ick-0-29.pax.bz2

     If you are using the GNU version of 'tar' (which is very likely on
     Linux), you can combine the two steps into one as shown here,
     except when using the lzma-compressed version.

Using DJGPP

          djtar -x ick-0-29.pax.gz

     On a DOS system, you will have to install DJGPP anyway to be able
     to compile the distribution, and once you've done that you will be
     able to use DJGPP's decompressing and unpacking utility to extract
     the files needed to install the distribution.  (You will need to
     type this at the command line; on Windows 95 and later, try
     choosing Run... from the start menu then typing 'cmd' (or 'command'
     if that fails) in the dialog box that opens to get a command
     prompt, which you can exit by typing 'exit'.  After typing any
     command at a command line, press <RET> to tell the shell to execute
     that command.)

On Windows

     If you're running a Windows system, you could always try
     double-clicking on the ick-0-29.pax.gz file; probably renaming it
     to have the extension '.tgz' is likely to give the best results.
     It's quite possible that you'll have a program installed that's
     capable of decompressing and unpacking it.  Unfortunately, I can't
     guess what program that might be, so I can't give you any
     instructions for using it.

Whatever method you use, you should end up with a directory created
called 'ick-0.29'; this is your main installation directory where all
the processing done by the installation will be carried out.  You will
need to have that directory as the current directory during install (at
the command prompt in all the operating systems I know, you can set the
current directory by typing 'cd ick-0.29').

1.3 Simple Installation
=======================

There are scripts included in the distribution to automate the process
of installing, in various ways.  The simplest method of installing on
most operating systems (on DOS, *note Installation on DOS::) is to use
the following routine:

  1. Configure C-INTERCAL, by running 'configure'.  Although building in
     the distribution directory works, it is recommended that you build
     elsewhere; create a directory to build in (using 'mkdir' on most
     operating systems), then run 'configure' from inside that directory
     (for instance, you could do this from inside the main installation
     directory:
          mkdir build
          cd build
          ../configure
     to build in a subdirectory of the distribution called "build").
     You also specify where you want the files to be installed at this
     stage; the default of '/usr/local' is good for many people, but you
     may want to install elsewhere (in particular, if you want to test
     out C-INTERCAL without installing it, create a new directory
     somewhere you own and specify that as the place to install it, so
     the install will actually just copy the files into the right
     structure for use instead of installing them).  To specify a
     location, give the option '--prefix=LOCATION' to configure; for
     instance, 'configure --prefix=/usr' would install in /usr.

  2. Compile the source code, with the command 'make'.  The Makefile
     will be set up for your version of 'make', and to automatically
     recompile only what needs compiling (it will even recompile the
     build system if you change that).

  3. Optionally, create libraries from third-party interpreters to add
     support for more languages to the C-INTERCAL external calls system;
     see *note Creating the Funge-98 Library::.  (This step can be
     skipped; you can also do it later, but if you do so you need to run
     the next step again.)

  4. Install the executables, help files, include files, and libraries,
     using 'make install'.  (This is the only step that needs
     root/administrator permissions; so on a system that uses sudo to
     elevate permissions, for instance, write it as 'sudo make install'
     if you're installing into a directory that you can't write to as a
     non-administrative user.)  This step is optional; if you do not
     install C-INTERCAL, you can still run it by directly referencing
     the exact location of the 'ick' command.

On all systems, it's worth just trying this to see if it works.  This
requires a lot of software on your computer to work, but all of it is
standard on Linux and UNIX systems.  The first command is a shell-script
which will analyse your system and set settings accordingly; it will
explain what it's doing and what settings it detected, and create
several files in the installation directory to record its results.
(This is a configure script produced by the GNU autoconf (configure);
its autoconf source code is available in the file 'configure.ac'.)  The
second command actually compiles the source code to produce binaries;
this takes the longest of any of the steps.  You will see all the
commands that it's running as it runs them.  The third command will copy
the files it's compiled to appropriate shared locations on your system
so that anyone on the system can just use 'ick'.

There may be various factors that prevent this simple installation
method working.  On a system not based on UNIX or Linux, you may find
that you don't have some of the software required to run this (for
instance, you may be missing the shell 'sh', and don't have the shell
'bash' which can emulate it, and so can't run 'configure' that depends
on one of those shells being available) and so this method won't work
for you.  In such cases, one solution may be to install all the software
required; the GNU project has a version of all the commands required,
for instance, and there may be ports available for your operating
system.  However, the only software absolutely required is a C compiler
(C-INTERCAL was designed to work with 'gcc' and is tested mostly with
that compiler, but in theory it should work with other C compilers too,
and this is tested on occasion) and the associated software needed to
compile C files to object files and executables, combine object files
into libraries, etc.; but this requires trying to do the build by hand,
so it's generally easier just to install a UNIX-like shell and
associated tools.

Another possibility that might stop this process working is if your
version of the relevant software is incompatible with the GNU versions
that were used for testing.  For instance, I have come across
proprietary versions of 'lex' that need directives in the source file to
say in advance how much memory the lexer-generator needs to allocate.
In such cases, pay attention to the error messages you're getting;
normally they will suggest trivial modifications to the source files
that will cause the compilation to work again.

Some Linux and UNIX systems (notably Debian and Ubuntu) don't have the
required files for compilation installed by default.  To install them,
just download and install the required packages: for Ubuntu at the time
of writing, they are 'binutils', 'cpp', 'gcc', 'libc6-dev', 'make' to
compile C-INTERCAL, and if you want to modify it, you may also need
'autoconf', 'automake', 'bison', and 'flex'.  For debugging help, you
may also want 'gdb', and to recompile the documentation, you may need
'groff', 'texlive', 'texinfo', and 'tidy'.

If you're trying to do something unusual, you probably want to set some
of the settings yourself rather than letting the compilation process
guess everything.  In this case, use 'configure --help' to view the
options that you can set on 'configure'; there's a wide range of
settings that you can set available there, and one of them may be what
you want.

1.4 Installation on DOS
=======================

On DOS-based systems, it's possible to install C-INTERCAL via compiling
it using DJGPP, a free DOS development system.  (You can obtain DJGPP
via its homepage, at <http://www.delorie.com/djgpp/>.)  The process for
installing it works like this:

  1. To start with, you will need to install DJGPP and various utilities
     (especially many of the GNU utilities) that come with it.  To do
     this, see the instructions on DJGPP's website, and download and
     unpack any additional packages on this list that you did not
     install as part of those instructions (a filename by which the
     package can be found on DJGPP mirrors is given, and a version
     number with which C-INTERCAL was tested is given as part of the
     filename, but other versions are likely to work as well):

        * Unzip32 ('unzip32.exe') -- to unpack the other packages

        * DJGPP development kit ('v2/djdev203.zip') -- needed for all
          DJGPP compiles

        * CS's DPMI Provider ('v2misc/csdpmi7b.zip') -- you need some
          DPMI provider to run C-INTERCAL on a plain DOS system,
          although this is not needed on systems such as Microsoft
          Windows' emulation of DOS which already include a DPMI
          provider

        * GNU Binutils ('v2gnu/bnu219b.zip') -- needed to produce
          executables

        * gcc ('v2gnu/gcc444b.zip') -- used to compile C code

        * GNU make ('v2gnu/mak3791b.zip') -- used to resolve
          dependencies within the build system

        * GNU bash ('v2gnu/bsh204b.zip') -- used to interpret build
          scripts

        * GNU Diffutils ('v2gnu/dif20b.zip') -- used by the build
          scripts

        * GNU Fileutils ('v2gnu/fil41b.zip') -- used by the build
          scripts

        * GNU Findutils ('v2gnu/find41b.zip') -- used by the build
          scripts

        * GNU awk ('v2gnu/gwk318b.zip') -- used by the build scripts

        * GNU sed ('v2gnu/sed421b.zip') -- used by the build scripts

        * GNU Shellutils ('v2gnu/shl2011b.zip') -- used by the build
          scripts

        * GNU Textutils ('v2gnu/txt20b.zip') -- used by the build
          scripts, and sometimes by C-INTERCAL itself too

     You might want to install other packages, particularly GNU Bison
     and GNU Flex, in order to be able to rebuild certain parts of the
     compiler if you change them.  This is not necessary to simply be
     able to run C-INTERCAL without changing it, though.

  2. Test your DJGPP install to ensure it works, and make sure you have
     environment variables set up correctly.  In addition to the 'DJGPP'
     variable that points to your 'DJGPP.ENV' file, and the 'PATH'
     variable that needs to contain DJGPP's binaries directory, you also
     need to set the 'DJDIR' environment variable to point to the main
     DJGPP installation directory.

  3. Unpack a copy of C-INTERCAL in its own directory, if you haven't
     already (*note Unpacking::).

  4. Load up a 'bash' session, change to the 'buildaux' subdirectory of
     your main C-INTERCAL directory, and run the command 'build-dj.sh'.
     This will run the entire C-INTERCAL build system, and hopefully end
     up with executables you can run in the 'build' subdirectory that
     will be created in your main C-INTERCAL directory.

  5. If you wish, you can install C-INTERCAL by using the command 'make
     install' from the new 'build' subdirectory.  It will run just fine
     in-place without a need to install, though, if you prefer.

1.5 Uninstalling
================

It may happen that you decide to uninstall C-INTERCAL after installing
it; this may be useful if you want to test the installation system, or
change the location you install programs, or for some reason you don't
want it on your computer.  It's worth uninstalling just before you
install a new version of C-INTERCAL because this will save some disk
space; you cannot install two versions of C-INTERCAL at once (at least,
not in the same directory; but you can change the '--prefix' of one of
the installations to get two versions at once).

If you installed C-INTERCAL using 'make install', you can uninstall it
by using 'make uninstall' from the installation directory, assuming that
it still exists.  If you can't use that method for some reason, you can
uninstall it by deleting the files 'ick' and 'convickt' where your
computer installs binaries (with an extension like '.exe' added if
that's usual for binaries on your operating system), 'libick.a',
'libickmt.a', 'libickec.a', and 'libyuk.a' where your computer installs
libraries, and the subdirectories 'ick-0.29' in the places where your
computer installs data files and include files, and their contents.

You can go further than uninstalling.  Running 'make clean' will delete
any files created by compilation; 'make distclean' will delete those
files, and also any files created by configuring.  It's probably a wise
idea to uninstall before doing a distclean, though, as otherwise
information needed to uninstall will be deleted, as that information is
generated by 'configure'.  You can go even further and use 'make
veryclean' which will delete not only files created by configuring, but
the entire build system; doing so is not recommended unless you have
some method of rebuilding the build system from its original sources (a
script to do this is provided in repository versions of C-INTERCAL,
because the generated part of the build system is not stored in the
repository).

1.6 Reporting Bugs
==================

If you can't get C-INTERCAL to install at all, or something goes wrong
when you're using it, reporting a bug is probably a good idea.  (This is
still important even if you figure out how to fix it, and the
information isn't in the manual, because the fix can be added to the
source code if possible, or at least to the manual, to benefit future
users.)  For general help, you may want to post to the alt.lang.intercal
news group; to report a bug or submit a patch, email the person who
released the most recent C-INTERCAL version (which you can determine by
looking at that newsgroup).

If you do find a bug (either the compiler not behaving in the way you'd
expect, or if you find a way to cause E778 (*note E778::) without
modifying the source code), it helps a lot if you can submit a bug
report explaining what causes it.  If you're not sure, say that; it
helps if you give examples of input, command line options, etc. that
cause the bug.  There are several debug options (*note Debug Options::)
that you can use to help pin down a bug if you're interested in trying
to solve the problem yourself; looking at the output C code can also
help pin down a bug if the compiler gets that far.

Information that should be given in a bug report is what you expect to
happen, what actually happens, what input and command line options you
gave to the compiler, what operating system you're using, any ideas you
might have as to what the problem is, and any appropriate debug traces
(for instance, '-H' (*note -H: -H+.) output if you think the bug is in
the optimizer).  Core dumps aren't portable between systems, so don't
send those; however, if you're getting an internal error and can dump
core with '-U' (*note -U: -U+.), it helps if you can load a debugger
(such as 'gdb') on the core dump, use the debugger to produce a
backtrace, and send that backtrace.

If you figure out how to solve the bug yourself, and want to submit the
patches to help other users (this also carries the advantage that your
patches will then be maintained along with the rest of the distribution,
and that you won't have to reapply them every time you upgrade to a
newer version of C-INTERCAL), you must first agree to license your code
under the same license as the code that surrounds it (normally, that's
the GNU General Public License, but if you submit a patch to a file with
a different license, like this manual (yes, documentation patches are
useful too), you must agree to that license).  You will be credited for
the patch in the source code unless you specifically ask not to be or
you don't give your name (in both these cases, you must license the code
to the public domain so that it can be incorporated without the
attribution requirement).  Preferably, patches should be submitted in
the format created by the command 'diff -u'; this command is likely to
be available on UNIX and Linux systems and versions are also available
for DOS and Windows (including a DJGPP port of the GNU version).  If you
can't manage that, just submit your new code with enough lines of old
code around it to show where it's meant to go, and a description of
approximately where in the file it was.  Patches should be submitted by
email to the person who most recently released a version of C-INTERCAL.

If you have a suggestion for a new feature, it makes sense to first
discuss it on the alt.lang.intercal news group; other INTERCAL compiler
maintainers may also want to implement that feature.  If you have
developed code to implement that feature in C-INTERCAL, you can submit
it the same way that you would submit a patch for a bug.

1.7 Distributing
================

Due to the licensing conditions of C-INTERCAL, you are allowed to
release your own version or distribution if you want to.  In such cases,
it's recommended that you follow the following guidelines:

  1. Make sure the new version is based on the most recent existing
     version.  Looking at the alt.lang.intercal newsgroup will normally
     let you know what version is most recent.

  2. Increment the version number; if you add any new features,
     increment the major version number (after the decimal point) and
     drop the minor version number (before the decimal point) to 0, and
     otherwise increment the minor version number.  You have to update
     the version number in the following files: 'configure.ac',
     'configure', and 'doc/ick.texi'.  You also have to rename the
     installation directory to reflect the new version number.

  3. Add an entry to the 'NEWS' file explaining what's new in the
     version that you're releasing, following the same format as the
     other entries.

  4. Update the 'README' with a description of any new files you may
     have added.

  5. Remove any autosave or backup files that may be littering the
     installation directory or its subdirectories.

  6. Run 'make distcheck', which will make the distribution paxballs,
     and rename them to have the correct extensions (Automake thinks
     they're tarballs, so will use '.tar' rather than '.pax', and you
     have to fix this by hand).  'make distcheck' will also perform some
     sanity checks on the build system of the resulting paxball, which
     will help to ensure that nothing important is missing from it; and
     some regression tests on a version of C-INTERCAL built from the
     distribution tarball itself, to prove that it runs correctly and
     produces plausible output.  (A failure of the regression checks
     will not stop the build, but should stop you distributing the
     resulting compiler.)

  7. Place the new version somewhere on the Internet, and announce the
     location and the fact that a new version has been released on
     alt.lang.intercal.

2 Invoking ick
**************

All operations on INTERCAL source code available in C-INTERCAL, other
than the conversion from one character set to another, are currently
carried out by the compiler 'ick'.

The syntax is

     ick -options INPUTFILE

(Options can be given preceded by separate hyphens, or all in a row
after one hyphen, or a mixture; they're all single characters.)  By
default, this compiles one INTERCAL program given as the input file
directly to an executable without doing anything fancy; usually you will
want to give options, which are described below.

2.1 Language-affecting Options
==============================

The following command-line options to 'ick' affect what dialect of the
INTERCAL language is compiled by the compiler; you may need to set one
or more of these options if your input is not the default C-INTERCAL but
instead some other language like INTERCAL-72 or CLC-INTERCAL, or just
because you like certainty or like being different with respect to your
output.  Note that there is no command-line option corresponding to
TriINTERCAL (or the base 4-7 versions); instead, the numeric base to use
is determined by looking at the filename extension ('.i' for base 2, the
default, or '.3i' to '.7i' for the base 3-7 versions.)

'-b'
     If this option is _not_ given, there is a small chance that a
     random bug appears in the compiler, which causes the programs it
     creates to manifest a bug that causes error E774 (*note E774::).
     Giving the option means that this bug will not happen.  (You may
     wonder why this bug was preserved; it is in fact a bug that was
     carefully preserved since the days of INTERCAL-72, in this case,
     but the option to turn it off is available as a workaround.  (There
     are no plans to fix this or any of the other carefully preserved
     bugs any time soon, because that would kind of defeat the point of
     having preserved them.)  Interestingly, the INTERCAL-72 compiler
     documentation mentions a similar command-line option that is a
     workaround for the same bug.)

'-m'
     This option needs to be given to allow any multithreading or
     backtracking commands or identifiers to be used.  (Unlike with
     other language features, this is not autodetected because it's
     legal to have a program with multiple COME FROM (*note COME FROM::)
     commands aiming at the same line even when it isn't multithreaded,
     in which case the commands cause error E555 (*note E555::) when
     that line is encountered (with the usual caveats about both
     commands having to be active at the time).)  Attempts to use
     non-COME FROM multithreading or backtracking commands without this
     option produce error E405 (*note E405::).

'-e'
     This option makes it possible to link non-INTERCAL programs with
     INTERCAL programs; instead of giving INTERCAL programs only on the
     command line, give one INTERCAL program, followed by any number of
     programs in other languages that have been written to be able to
     link to INTERCAL programs.  It also allows expansion libraries to
     be specified on the command line, after the INTERCAL program
     (expansion libraries are given with no extension).  For more
     information, see *note External Calls::.  Also, both the '-a' and
     '-e' options must be set to use CREATEd operators (regardless of
     whether external calls are used or not).

'-E'
     This option causes the system library to never be linked; this
     option is only useful if your program references a line number in
     the range 1000 to 1999, contains no line numbers in that range, and
     yet still doesn't want the system library to be linked in;
     therefore, it is mostly useful with '-e' when adding in a custom
     replacement system library written in a non-INTERCAL language,
     especially the expansion library 'syslibc' (a system library
     replacement written in C).

'-t'
     This option tells the compiler to treat the source code as
     INTERCAL-72; as a result, any language constructs that are used but
     weren't available in 1972 will trigger error E111 (*note E111::).

'-a'
     This option allows the CREATE statement (*note CREATE::) to be
     used.  Note that enabling it carries a run-time penalty, as it
     means that operand overloading code has to be generated for every
     variable in the program.  (This option is not necessarily needed
     for the external call version of CREATE to work, but the external
     call version has fewer features without it.)  Note that '-e' (*note
     -e::) also needs to be set to be able to CREATE operators.

'-v'
     It is possible to write INTERCAL code sufficiently tortuous that it
     ends up assigning to a constant.  Generally speaking, this isn't
     what you wanted to do, so the compiler will kindly cause an error
     (E277; *note E277::) that stops the insanity at that point, but at
     the cost of a significant amount of performance you can give this
     option to tell the compiler to simply change the constant and keep
     on going anyway.  (Note that unlike CLC-INTERCAL, this only changes
     uses of the constant preceded by '#' in your program, not things
     like line numbers; you want Forte (http://esolangs.org/wiki/Forte)
     for that.)  This option also allows you to write arbitary
     expressions on the left of an assignment statement if you wish.

'-C'
     When this option is given, the generated programs will write the
     number 4 as 'IIII' rather than 'IV', in case you're writing a clock
     program.

'-P'
     This tells the compiler to treat the input as PIC-INTERCAL (*note
     PIC-INTERCAL::) rather than ordinary C-INTERCAL input, and generate
     PIC output code accordingly.  There are a lot of options that are
     incompatible with this, as well as many language features, due to
     the limited memory available on a PIC. If you get error E256 (*note
     E256::), you have this option given when it shouldn't be; likewise,
     if you get error E652 (*note E652::), you should be using this
     option but aren't.  (A few simple programs are
     C-INTERCAL/PIC-INTERCAL polyglots, but such programs are incapable
     of doing input or output, meaning that they aren't particularly
     useful.)

'-X'
     The C-INTERCAL and CLC-INTERCAL compilers use different notation
     for various things, sometimes to the extent where the same notation
     is legal in both cases but has a different meaning.  As this is the
     C-INTERCAL compiler, it rather guessably uses its own notation by
     default; however, the CLC-INTERCAL notation can be used as the
     default instead using this option.  (In most situations where there
     isn't an ambiguity about what something means, you can use the
     'wrong' syntax freely.)  The option causes ambiguous characters
     like '?' to be interpreted with Princeton rather than Atari
     meanings.

'-x'
     This option causes some constructs with different meanings in
     C-INTERCAL and CLC-INTERCAL to use the CLC-INTERCAL meaning rather
     than the C-INTERCAL meaning.  At present, it affects the abstention
     of a GIVE UP (*note GIVE UP::) command by line number, which is
     possible as long as this switch isn't given; reading through the
     INTERCAL-72 manual, there are a lot of things that imply that this
     probably wasn't intended to be possible, but as far as I can tell
     that manual doesn't actually _say_ anywhere that this particular
     case is disallowed, even though it rules out all other similar
     cases.  It also causes I/O on array variables to be done in
     CLC-INTERCAL's extended Baudot syntax, rather than using the Turing
     Tape method.

2.2 Debug Options
=================

Sometimes things will go wrong with your program, or with the way 'ick'
was installed.  There may even be unknown bugs in 'ick' itself (if you
find one of these, please report it).  The following options are used to
debug the whole system on various levels.

'-d'

     If you think that something has gone wrong with the parser, or you
     want to see how your program is being parsed, you can give this
     option on the command line.  All the debug output produced by the
     parser and lexical analyser will be output.

'-g'

     This option allows debugging of the final executable at the C code
     level.  Any C code generated will be left in place, and the '-g'
     option will be given to the C compiler that's used to compile the
     code, so all the information needed for a C debugger to be used on
     the executable will be present there.

'-h'
'-H'
'-hH'

     These options allow debugging of the optimiser, or produce output
     helpful for understanding how your program has been summarised.
     '-h' produces a summary of what optimiser rules were used, the
     initial expression and what it was optimised to; '-H' produces a
     more expanded view that shows each intermediate step of
     optimisation, and '-hH' shows the same output as '-H', but written
     completely using C syntax (the other options output in a strange
     mix of INTERCAL and C).

'-l'

     This option turns on generation of warnings (*note Warnings::).  To
     make sure that they aren't actually useful, or are only marginally
     useful, the warning generator is far too sensitive, and there is no
     way to decide which warnings are given and which ones aren't; you
     either get all of them or none.

'-p'

     This option causes the program to run immediately after being
     compiled, and profiles the resulting program to identify
     performance bottlenecks, etc.  The usefulness of this depends on
     the resolution of the timers on the computer and operating system;
     DOS, in particular, is really bad with timer resolution.  The
     output will be saved in a file called 'yuk.out' when the program
     finishes running.  It's legal to turn on both the profiler and the
     interactive debugger at the same time, but if you do this the
     profiler will also identify bottlenecks in the person typing in
     commands to step through the program!  The profiler will, in fact,
     identify all the timings that particular commands in the program
     take; so 'WRITE IN' instructions will often show up as taking a
     long time due to their need to wait for input.

'-w'

     This option causes the produced program to support the 'printflow'
     option fully; when this option is not given, 'printflow' will in
     most cases have partial or no support (except in multithreaded
     programs, where this option is redundant), because not all the code
     needed for it will be included in the program to save space.

'-u'

     When you are getting problems with finding files - for instance,
     the compiler can't find the skeleton file (*note E999::) or the
     system library (*note E127::) - this option will let you know, on
     standard error, where the compiler is looking for files.  This may
     hopefully help you pin down where the file-finding problems are
     coming from, and also offers the option of simply placing copies of
     the files where the compiler is looking as a last resort.

'-y'

     This is the main debugging option: it loads yuk, an interactive
     INTERCAL debugger with ability to step through the program, set
     breakpoints, view and modify variables, etc.  *Note yuk::.

'-Y'

     This options causes the command line to be displayed for all calls
     to other programs that 'ick' makes (mostly to 'gcc'); it is
     therefore useful for debugging problems with the command lines used
     when using the external calls system (*note External Calls::).

'-U'

     The internal error E778 (*note E778::) should never happen.
     However, there are all sorts of potential problems that may come
     up, and if part of the code detects something impossible, or more
     usually when the operating system detects things have got too
     insane and segfaults, normally this error will just be generated
     and that's that.  (I most often get this when I've been writing a
     new section of code and have made a mistake; hopefully, all or at
     least most of these errors are fixed before release, though.)  If
     you want more information as to what's going on, you can give the
     '-U' option, which will cause the compiler to raise an abort signal
     when an internal error happens.  This can generally be caught by a
     debugger that's being run on 'ick' itself at the time; on many
     systems, it will also cause a core dump.

2.3 Output Options
==================

These options allow you to control how far to compile (all the way to an
executable, or only to C, etc.), and where the output will be created.
Note that the output options may change depending on the other options
selected; for instance, many of the debug options will prevent the code
being compiled all the way to an executable.

'-c'

     By default, the original INTERCAL code will be compiled all the way
     to an executable, and the intermediate C and object files produced
     will be deleted.  Giving this option causes the compiler to stop
     when it has finished producing the C file, leaving the C file there
     as the final output of the compiler.  (Its filename is the same as
     the source file, but with '.c' as its extension/suffix rather than
     the source file's extension.)  Without this option, an executable
     will be produced with the extension changed to whatever's
     appropriate for the system you are on (or omitted entirely if
     that's appropriate for the system).

     This option also places verbose comments in the output C file.

'-o'

     This option causes the compiler to progress no further than
     producing the C output file, but instead of writing it to a file
     writes it directly to standard output.  This might occasionally be
     useful when using 'ick' as part of a pipe; it can also be useful to
     see how far the compiler gets with compiling code before an error
     happens, when you're trying to track down an error.

2.4 Optimizer Options
=====================

There are various command line options that can be used to tell 'ick'
whether and in what ways to optimize code.

'-f'

     This option requests the compiler to attempt to analyse the flow of
     the program and optimize accordingly; for instance, it will detect
     which commands can't possibly be 'ABSTAINED' from and refrain from
     generating code to check the abstention status of those commands.

'-F'

     This option tells the compiler to optimize the output for speed.
     This is done to crazy extremes; the compiler may take several
     hours/days analysing the program in some cases and still not come
     up with an improvement.  It turns on all the other optimizer
     options.  Note that not all systems accept this option, because it
     sometimes outputs a shell script disguised as an executable rather
     than an actual executable.

'-O'

     This option tells the compiler to apply optimizer idioms to the
     expressions in the code given, when appropriate.  The list of
     idioms is stored in the file 'src/idiotism.oil'; note that it is
     compiled into the compiler, though, so you will have to rebuild and
     reinstall the compiler if you change it.  For more information
     about changing the list of idioms, see *note Optimizer Idiom
     Language::.

2.5 Other Options
=================

Some options just can't be classified.

'-@'

     If this option is given, the compiler doesn't run at all, but
     instead prints a set of instructions for using it, explaining which
     options are available on the system you're on and which options
     conflict with which other options.

2.6 Options to Generated Programs
=================================

Once the compiler runs and produces an output executable, that
executable itself will accept a range of options that control the way it
runs.  None of these options have to be used; a default value will be
assumed if they aren't.

'+help'
'-help'

     Whether '+' or '-' is given at the start of this option, it will
     cause the program to print out what options are available and what
     state they are in.  It will then cause the program to exit via an
     internal error.

'+wimpmode'
'-wimpmode'

     If the '+' version of this is given (rather than the default '-'),
     then the program will print a message explaining that you are a
     wimp (the mode itself is known as wimpmode), and for the rest of
     execution will input in Arabic numerals ('123' rather than 'ONE TWO
     THREE') and likewise will output in Arabic numerals rather than
     Roman numerals (such as 'CXXIII').  True INTERCAL programmers
     should rarely have to use this mode.

'+traditional'
'-traditional'

     This option does not actually appear to do anything.

'+instapipe'
'-instapipe'

     This option causes standard output to be flushed whenever any
     characters are output when the '+' version is used, rather than on
     each newline (the default '-' version).  It is most useful for more
     responsive pipes when outputting binary data, and also useful for
     debugging very slow programs.

'+printflow'
'-printflow'

     The usual debugging methods don't work with multithreaded or
     backtracking programs.  This option exists to give at least a slim
     chance of working out what is going on with them.  It causes the
     program to print the line number of the command it thinks it may be
     executing next (i.e. the line number that would be printed if that
     line had an error) immediately after executing each command, and
     also an internal identifier for the thread that that command was
     in.  It also prints a trace of what parts of the multithreader are
     being activated; so for instance, it will tell you when a thread is
     being forked into multiple threads or when a choicepoint has been
     deleted.  Note that the '-w' option (*note -w::) must be given to
     gain full support for flow printing in non-multithreaded
     non-backtracking programs, because otherwise the required code to
     print this information will not be generated.

'+mystery'
'-mystery'

     This option is occasionally capable of doing something, but is
     deliberately undocumented.  Normally changing it will have no
     effect, but changing it is not recommended.

2.7 Environment Variables
=========================

Various environment variables can be set to affect the operation of
'ick'.

Variable               Meaning
--------------------------------------------------------------------------
ICKINCLUDEDIR          These four environment variables suggest
ICKLIBDIR              locations in which 'ick' should look to find
ICKSYSDIR              various files that it needs: the skeleton file,
ICKCSKELDIR            system library, C header files and libraries
                       that it needs, constant-output optimiser, and
                       the GNU General Public License (which the
                       debugger needs to be able to display on demand
                       for legal reasons).
CC                     The name of a C compiler to use (defaults to
                       'gcc'; C-INTERCAL has recently been tested only
                       with 'gcc' and 'clang').  This option has no
                       effect on DJGPP, where 'gcc' is always used.
ICKTEMP                On DJGPP, 'ick' creates temporary files to pass
TMPDIR                 options to gcc as a method of getting around the
TEMP                   limit on the length of a command line that can
TMP                    sometimes affect DOS programs.  These four
                       environment variables are tried (in this order)
                       to determine a location for the temporary file;
                       if none of them are set, the current directory
                       is used.

3 Errors and Warnings
*********************

Things may go wrong, either during the compilation or the execution of
your program.  Note that some things that would be compile-time errors
in many other languages - such as syntax errors - are in fact run-time
errors in INTERCAL.

Errors and warnings appear as an error code starting with 'ICL',
followed by a three digit number, followed by 'I' for an error or 'W'
for a warning.  However, they will be notated here as 'E000', etc., to
save space and because consistency was never a strong point of INTERCAL.
This is followed by a text description of the error, and a hint as to
the location of the error.  This is not the line on which the error
occurred, but rather the line on which the next command to be executed
is.  To add to the fun, the calculation of the next command to be
executed is done at compile-time rather than runtime, so it may be
completely wrong due to things like abstention on 'COME FROM's or
computed 'COME FROM's.  The moral of this story is that, if you really
want to know where the error is, use a debugger.  Note also that if the
error happens at compile-time, there is no guarantee that the line
number given makes any sense at all.  Some errors don't give next line
numbers, mostly those for which it doesn't make logical sense, such as
E633 (*note E633::).  After this is a suggestion to correct (or
reconsider) the source code and to resubnit it.  (This typo has been
carefully preserved for over a decade.)

3.1 Errors
==========

This is a list of the error messages that might be produced during the
compilation or execution of an INTERCAL program.

E000

     This is an unusual error; it's what's printed when a syntax error
     is encounted at runtime, in a situation in which it would be
     executed.  (An 'ABSTAIN'ed syntax error, for instance, would not be
     executed; this is one of the mechanisms available for writing
     comments.)  The text of the error message is simply the statement
     that couldn't be decoded.

E017
          DO YOU EXPECT ME TO FIGURE THIS OUT?

     This error occurs when there is an attempt to use a constant with a
     value outside the onespot range; it's a compile-time error.

E079
          PROGRAMMER IS INSUFFICIENTLY POLITE

     The balance between various statement identifiers is important.  If
     less than approximately one fifth of the statement identifiers used
     are the polite versions containing 'PLEASE', that causes this error
     at compile time.

E099
          PROGRAMMER IS OVERLY POLITE

     Of course, the same problem can happen in the other direction; this
     error is caused at compile time if more than about one third of the
     statement identifiers are the polite form.

E111
          COMMUNIST PLOT DETECTED, COMPILER IS SUICIDING

     This error happens when you give the '-t' option (*note -t::) but
     you use a language construct that wasn't available in INTERCAL-72.
     If this happens, then either there's a mistake in the program that
     prevents it being INTERCAL-72 or you shouldn't be compiling it as
     INTERCAL-72 in the first place.

E123
          PROGRAM HAS DISAPPEARED INTO THE BLACK LAGOON

     There is a hard limit of 80 'NEXT's at a time; this is to
     discourage excessive use of 'NEXTING' for things like recursion.
     (Recursive programs are entirely legal; you simply have to figure
     out how to do it with computed 'COME FROM' instead.  (For the
     record, it is possible.  (Using lots of nested brackets when
     talking about recursion is great (yay!).)))  Another problem with
     writing the source code that can cause this error is a failure to
     properly 'FORGET' the entry on the 'NEXT' stack created when trying
     to simulate a goto.

E127
          SAYING 'ABRACADABRA' WITHOUT A MAGIC WAND WON'T DO YOU ANY
          GOOD
     Your program asked to include a system library (by specifying a
     line number in a magic range without including a line with that
     number), but due to installation problems the compiler couldn't
     find the system library to include.  You could try using the '-u'
     (*note -u::) option to see where the compiler's looking; that may
     give you an idea of where you need to copy the system library so
     that the compilation will work.  This error happens at compile time
     and doesn't give a next command line number.

E129
          PROGRAM HAS GOTTEN LOST

     This error happens at compile time when the compiler can't figure
     out where a 'NEXT' command is actually aiming (normally due to a
     typo in either the line label given or the line label on the line
     aimed for).  The logic behind this error means that the next line
     to be executed is unknown (after all, that's the whole point of the
     error) and is therefore not given.  The '-e' command-line option
     (*note -e::) makes this error into a run-time error, because it
     allows 'NEXT' commands to dynamically change targets at runtime, as
     well as line labels to dynamically change values, and thus the
     error is impossible to detect at compile time.

E139
          I WASN'T PLANNING TO GO THERE ANYWAY

     This error happens at compile time when an 'ABSTAIN' or 'REINSTATE'
     references a non-existent target line.  This generally happens for
     much the same reasons as E129 (*note E129::).

E182
          YOU MUST LIKE THIS LABEL A LOT!

     At present, it's impossible to have more than one line with the
     same line number.  That would make 'NEXT' act too much like 'COME
     FROM' in reverse to be interesting.  This error happens at compile
     time.  (For inconsistency, it is possible to have multiple lines
     with the same number as long as at most one of them is in an
     INTERCAL program (the others have to be in programs in other
     languages included via the external calls system).  The resulting
     behaviour is entirely inconsistent with the rest of the language,
     though, for what I hope are obvious reasons.)

E197
          SO!  65535 LABELS AREN'T ENOUGH FOR YOU?

     Legal values for line labels are 1 to 65535 (certain subranges are
     reserved for system and expansion libraries).  This error comes up
     if you use nonpositive or twospot values for a line label.

E200
          NOTHING VENTURED, NOTHING GAINED

     You used a variable that isn't actually in your program.  Failing
     that (which, contrary to previous versions of this manual, is
     indeed possible in the present version of C-INTERCAL, although I'm
     not telling how; a hint: what mechanism in C-INTERCAL allows for a
     computed variable number?), you specified an illegal number for a
     variable (legal numbers are positive and onespot).  This error
     happens at compile time, at least for illegal variable numbers.

E222
          BUMMER, DUDE!

     In INTERCAL, you're allowed to 'STASH' as much as you like; this
     makes the language Turing-complete and allows for unlimited
     recursion when combined with computed 'COME FROM' in the right way.
     Unfortunately, real computers aren't so idealised; if you manage to
     write a program so memory-intensive that the computer runs out of
     memory to store stashes, it causes this error at runtime.  To fix
     this error, you either have to simplify the program or upgrade your
     computer's memory, and even then that will only help to some
     extent.

E240
          ERROR HANDLER PRINTED SNIDE REMARK

     Arrays have to be large enough to hold at least one element; you
     tried to dimension an array which isn't large enough to hold any
     data.  This error happens at run time.

E241
          VARIABLES MAY NOT BE STORED IN WEST HYPERSPACE

     This error happens at run time when the subscripts given to an
     array are inconsistent with the way the array was dimensioned,
     either because there were the wrong number of subscripts or because
     a subscript was too large to fit in the array.  It can also happen
     when a multidimensional array is given to a command, such as 'WRITE
     IN', that expects it to be monodimensional.

E252
          I'VE FORGOTTEN WHAT I WAS ABOUT TO SAY

     This run-time error message is caused by the compiler running out
     of memory whilst trying to do I/O; at present, it can only happen
     during CLC-INTERCAL-style I/O.

E256
          THAT'S TOO HARD FOR MY TINY BRAIN

     Some commands simply aren't available in PIC-INTERCAL.  I mean,
     PICs generally have less than a kilobyte of memory; you're not
     going to be able to use some of the more confusing language
     features with that sort of resource limitation.  The solution is to
     replace the affected command, or to not give the '-P' option (*note
     -P: -P+.) if you didn't mean to compile as PIC-INTERCAL in the
     first place.

E275
          DON'T BYTE OFF MORE THAN YOU CAN CHEW

     This error happens when there is an attempt to store a twospot
     value in a onespot variable.  The actual size of the value is what
     matters when counting its spots; so you can store the output of a
     mingle in a onespot variable if it happens to be less than or equal
     to 65535, for instance.  (This is not necessarily the case in
     versions of INTERCAL other than C-INTERCAL, though, so you have to
     be careful with portability when doing this.)

E277
          YOU CAN ONLY DISTORT THE LAWS OF MATHEMATICS SO FAR

     Reverse assignments are not always mathematically possible.  Also,
     sometimes they require changing the value of a constant; this is
     only legal if you specifically specified that it was legal by using
     the '-v' option.  In the case of an impossible reverse assignment
     (including a situation in which operand overloading causes a
     reverse assignment to happen), this error happens at runtime.

     This error can also come up when a scalar variable is overloaded to
     an array (which doesn't make sense, but could happen if someone
     exploited bugs in the CREATE statement (*note CREATE::)), and an
     attempt is made to read or assign to that variable.  (Subscripting
     a scalar variable is a syntax error, so there is no use for doing
     such an overload anyway.)

E281
          THAT MUCH QUOTATION AMOUNTS TO PLAGIARISM

     There is a limit of 3200 on the number of nested spark/ears groups
     allowed.  If you somehow manage to exceed that limit, that will
     cause this error.  Try breaking the expression up into smaller
     expressions.  (The limit is trivial to increase by changing
     'SENESTMAX' in 'ick.h'; if you ever actually come across a program
     that hits the limit but wasn't designed to, just email the
     maintainer to request a higher limit.)

E333
          YOU CAN'T HAVE EVERYTHING, WHERE WOULD YOU PUT IT?

     Your program references so many variables that the compiler
     couldn't cope.  This error is unlikely to ever happen; if it does,
     try reducing the number of variables you use by combining some into
     arrays.  This is a compile-time error.

E345
          THAT'S TOO COMPLEX FOR ME TO GRASP

     This is another compile-time error that's unlikely to ever happen;
     this one signifies the compiler itself running out of memory trying
     to compile your program.  The only solutions to this are to
     simplify your program, or to make more memory available to the
     compiler.

E404
          I'M ALL OUT OF CHOICES!

     Your program asked that a choicepoint be backtracked to or removed,
     but there aren't any choicepoints at the moment.  This runtime
     error usually indicates a logic mistake in your program.  In
     backtracking programs translated from other backtracking languages,
     this indicates that the program has failed.

E405
          PROGRAM REJECTED FOR MENTAL HEALTH REASONS

     Your program used a construct that only makes sense when
     multithreading or backtracking ('WHILE', 'MAYBE', 'GO BACK', or 'GO
     AHEAD'), but you didn't specify the '-m' option (*note -m::).  If
     you meant to write a multithreaded or backtracking program, just
     give that option; if you didn't, be careful what words you use in
     comments!  This error happens at compile-time.

E436
          THROW STICK BEFORE RETRIEVING!

     In order to 'RETRIEVE' a variable, it has to be 'STASH'ed first; if
     it isn't, then this error happens at runtime.

E444
          IT CAME FROM BEYOND SPACE

     A 'COME FROM' aiming at a line label -- as opposed to a computed
     'COME FROM', which is allowed to be pointing at a nonexistent line
     -- must point to a valid line label.  The same applies to 'NEXT
     FROM'.  This error happens at compile time if a nonexistent line
     label is found in one of these contexts.

E533
          YOU WANT MAYBE WE SHOULD IMPLEMENT 64-BIT VARIABLES?

     This error is like E275 (*note E275::), but applies when an attempt
     is made at runtime to store a threespot value (or even a fourspot
     or morespot value) in a twospot variable, or a threespot or greater
     value is produced as an intermediate during a calculation (for
     instance by a mingle operation).  No values above twospot are
     allowed at any point during an INTERCAL program; if you want to
     process higher numbers, you have to figure out a different way of
     storing them.

E553
          BETTER LATE THAN NEVER

     Oops!  The compiler just noticed that it had a buffer overflow.
     (Normally programs catch buffer overflows before they happen;
     C-INTERCAL catches them just afterwards instead.)  This only
     happens on systems which don't have a modern C standard library.
     Try using shorter or fewer filenames on the command line, to reduce
     the risk of such an overflow.

E555
          FLOW DIAGRAM IS EXCESSIVELY CONNECTED

     Aiming two 'COME FROM's at the same line only makes sense in a
     multithreaded program.  In a non-multithread program, doing that
     will cause this error at compile time (if neither 'COME FROM' is
     computed) or at run time (if the command that has just finished
     running is simultaneously the target of two or more 'COME FROM's).
     This either indicates an error in your program or that you've
     forgotten to use the '-m' option (*note -m::) if you are actually
     trying to split the program into two threads.

E562
          I DO NOT COMPUTE

     The program asked for input, but for some reason it wasn't
     available.  (This is a runtime error, obviously.)  The error may
     happen because the input is being piped in from a command or file
     which has reached end-of-file, or because the user typed
     '<CTRL>-<D>' (UNIX/Linux) or '<CTRL>-<Z>' (DOS/Windows) while the
     program was trying to 'WRITE IN' some data.

E579
          WHAT BASE AND/OR LANGUAGE INCLUDES STRING?

     When reading spelt-out-digit input, the input didn't seem to be a
     valid digit in English, Sanskrit, Basque, Tagalog, Classical
     Nahuatl, Georgian, Kwakiutl, Volapk, or Latin.  This seems to have
     languages covered pretty well; what on earth were you using, or did
     you just make a spelling mistake?

E621
          ERROR TYPE 621 ENCOUNTERED

     The compiler encountered error E621 (*note E621::).  This happens
     at runtime when the program requests that no entries are removed
     from the 'NEXT' stack (which is possible), but that the last entry
     removed should be jumped to (which given the circumstances isn't,
     because no entries were removed).

E632
          THE NEXT STACK RUPTURES. ALL DIE. OH, THE EMBARRASSMENT!

     When an attempt is made to 'RESUME' past the end of the 'NEXT'
     stack, the program ends; however, this cause the program to end in
     a manner other than via 'GIVE UP' or 'DON'T TRY AGAIN', so an error
     message must be printed, and this is that error message.

E633
          PROGRAM FELL OFF THE EDGE

     You can't just let execution run off the end of the program.  At
     least, that is, if it doesn't end with 'TRY AGAIN'.  An attempt to
     do that causes this error at runtime.  Note that if your program
     references the system library, then it counts as being appended to
     your program and so the program will run into the first line of the
     system library rather than cause this error.  As it happens, the
     first line of the system library is a syntax error, so doing this
     will cause E000 (*note E000::) with the error text 'PLEASE KNOCK
     BEFORE ENTERING'.  There isn't a next statement to be executed with
     E633, so the next statement won't be given in the error message.

E652
          HOW DARE YOU INSULT ME!

     The 'PIN' command doesn't make much sense for anything bigger than
     a PIC; using it in a non-PIC program causes this error at
     compile-time.  Try using the normal input and output mechanisms
     instead.  This error may also be a clue that you are trying to
     compile a PIC-INTERCAL program without giving the '-P' option
     (*note -P: -P+.).

E666
          COMPILER HAS INDIGESTION

     There isn't a limit on the length of an input program other than
     your computer's memory; if your computer does run out of memory
     during compilation, it causes this error.  This error can also be
     caused if too many input files are specified on the command line;
     if you suspect this is the problem, split the compilation into
     separate compilations if you can, or otherwise you may be able to
     concatenate together your input files into larger but fewer files.
     Yet another potential cause of this error is if a line in an input
     program is too long; sensible line-wrapping techniques are
     encouraged.

E774
          RANDOM COMPILER BUG

     No compiler is perfect; sometimes errors just happen at random.  In
     this case, the random error is E774.  If you don't like the idea
     that your program may be shot down by a random compiler bug, or you
     are doing something important, you can use the '-b' option (*note
     -b::) to prevent this bug happening.  (You may wonder why this bug
     is in there at all if it's so easily prevented.  The answer is that
     such a bug was present in the original INTERCAL-72 compiler, which
     also had an option to turn the bug off.  It's also a reward for
     people who actually read the manual.)

E777
          A SOURCE IS A SOURCE, OF COURSE, OF COURSE

     You specified a file to compile on the command line, but the
     compiler couldn't find or couldn't open it.  This is almost
     certainly because you made a typo specifying the file.

E778
          UNEXPLAINED COMPILER BUG

     This should never come up, either at compile time or at run time.
     It could come up at either when an internal check by the compiler
     or the runtime libraries realises that something has gone badly
     wrong; mistakes happen, and in such cases the mistake will have
     been detected.  (If this happens at compile time you can use the
     '-U' option (*note -U: -U+.) to cause the compiler to send an abort
     signal - which normally causes a core dump - when the error
     happens, to help debug what's causing it.)  More often, this error
     comes up when the operating system has noticed something
     impossible, like an attempt to free allocated memory twice or to
     write to a null pointer, and tells the compiler an error has
     occured, in which case the same response of putting up this error
     happens.  The point is that in all cases this error indicates a bug
     in the compiler (even if it happens at run time); in such cases, it
     would be very helpful if you figure out what caused it and send a
     bug report (*note Reporting Bugs::).

E810
          ARE ONE-CHARACTER COMMANDS TOO SHORT FOR YOU?

     This is a debug-time error caused when you give too much input to
     the debugger when all it wanted was to know what you wanted to do
     next.

E811
          PROGRAM IS TOO BADLY BROKEN TO RUN

     There's a limit to how many breakpoints you can have in a program;
     you've broken the limit and therefore broken the debugger.  This is
     a debug-time error.

E888
          I HAVE NO FILE AND I MUST SCREAM

     The output file couldn't be written, maybe because the disk is full
     or because there's already a read-only file with the same name.
     This is a compile-time error.

E899
          HELLO? CAN ANYONE GIVE ME A HAND HERE?

     This error occurs at compile-time if a file type was requested for
     which the required libraries are unavailable.  (Support for Funge
     does not ship with the compiler; instead, you need to generate the
     library yourself from the cfunge sources.  For more information,
     see *note Creating the Funge-98 Library::.)

E990
          FLAG ETIQUETTE FAILURE BAD SCOUT NO BISCUIT

     This error occurs at runtime if an INTERCAL program was passed an
     unknown option flag.

E991
          YOU HAVE TOO MUCH ROPE TO HANG YOURSELF

     There is no limit on the number of threads or choicepoints that you
     can have in a multithreaded or backtracking program (in a program
     that isn't multithreaded or backtracking, these are obviously
     limited to 1 and 0 respectively).  However, your computer may not
     be able to cope; if it runs out of memory in the multithreader, it
     will cause this error at runtime.

E993
          I GAVE UP LONG AGO

     'TRY AGAIN' has to be the last command in a program, if it's there
     at all; you can't even follow it by comments, not even if you know
     in advance that they won't be 'REINSTATE'd.  This error happens at
     compile time if a command is found after a 'TRY AGAIN'.

E994
          NOCTURNAL EMISSION, PLEASE LAUNDER SHEETS IMMEDIATELY

     This error should never happen, and if it does indicates a compiler
     bug.  It means the emitter function in the code degenerator has
     encountered an unknown opcode.  Please send a copy of the program
     that triggered it to the INTERCAL maintainers.

E995
          DO YOU REALLY EXPECT ME TO HAVE IMPLEMENTED THAT?

     Some parts of the code haven't been written yet.  There ought to be
     no way to cause those to actually run; however, if you do somehow
     find a way to cause them to run, they will cause this error at
     compile time.

E997
          ILLEGAL POSSESSION OF A CONTROLLED UNARY OPERATOR

     Some operators (such as whirlpool ('@') and sharkfin ('^')) only
     make sense in TriINTERCAL programs, and some have a minimum base in
     which they make sense.  This error happens at compile-time if you
     try to use an operator that conflicts with the base you're in (such
     as using TriINTERCAL operators in an INTERCAL program in the
     default base 2).

E998
          EXCUSE ME, YOU MUST HAVE ME CONFUSED WITH SOME OTHER COMPILER

     This error occurs just before compile-time if a file is encountered
     on the command line that C-INTERCAL doesn't recognise.  (If this
     error occurs due to a '.a', '.b98', '.c', '.c99', or '.c11' file,
     then you forgot to enable the external calls system using '-e'
     (*note -e::).)

E999
          NO SKELETON IN MY CLOSET, WOE IS ME!

     The skeleton file 'ick-wrap.c' or 'pickwrap.c' is needed to be able
     to compile INTERCAL to C. If the compiler can't find it, it will
     give this error message.  This indicates a problem with the way the
     compiler has been installed; try using the '-u' option (*note -u::)
     to find out where it's looking (you may be able to place a copy of
     the skeleton file in one of those places).

3.2 Warnings
============

This is a list of the warnings stored in the warning database.  Warnings
only come up when the '-l' option (*note -l::) is given; even then, some
of the warnings are not currently implemented and therefore will never
come up.

W016
          DON'T TYPE THAT SO HASTILY

     The positional precedence rules for unary operators are somewhat
     complicated, and it's easy to make a mistake.  This warning is
     meant to detect such mistakes, but is not currently implemented.

W018
          THAT WAS MEANT TO BE A JOKE

     If an INTERCAL expression has been translated from another language
     such as C, the optimiser is generally capable of translating it
     back into something similar to the original, at least in base 2.
     When after optimisation there are still INTERCAL operators left in
     an expression, then this warning is produced.  (Therefore, it's
     likely to come up quite a lot if optimisation isn't used!)  The
     system library produces some of these warnings (you can tell if a
     warning has come up in the system library because you'll get a line
     number after the end of your program).

W112
          THAT RELIES ON THE NEW WORLD ORDER

     This warning comes up whenever the compiler recognises that you've
     added some code that didn't exist in INTERCAL-72.  This allows you
     to check whether your code is valid INTERCAL-72 (although '-t'
     (*note -t::) is more useful for that); it also warns you that code
     might not be portable (because INTERCAL-72 is implemented by most
     INTERCAL compilers, but more recent language features may not be).

W128
          SYSLIB IS OPTIMIZED FOR OBUSCATION

     There is an idiom used in the system library that does a
     right-shift by selecting alternate bits from a twospot number and
     then mingling them the other way round.  A rightshift can much more
     easily be done with a single rightshift, so this is a silly way to
     do it, and this warning warns that this idiom was used.  However,
     the present optimizer is incapable of recognising whether this
     problem exists or not, so the warning is not currently implemented.

W276
          YOU CAN'T EXPECT ME TO CHECK BACK THAT FAR

     It's an error to assign a twospot value (a value over 65535) to a
     onespot variable, or to use it as an argument to a mingle.  If the
     optimizer can't guarantee at compile time that there won't be an
     overflow, it issues this warning.  (Note that this doesn't
     necessarily mean there's a problem -- for instance, the system
     library generates some of these warnings -- only that the optimiser
     couldn't work out for sure that there wasn't a problem.)

W239
          WARNING HANDLER PRINTED SNIDE REMARK

     Your code looks like it's trying to assign 0 to an array, giving it
     no dimension; this is an error.  This warning is produced at
     compile time if it looks like a line in your code will cause this
     error, but it isn't necessarily an error because that line of code
     might never be executed.

W278
          FROM A CONTRADICTION, ANYTHING FOLLOWS

     It's sometimes impossible to reverse an assignment (a reverse
     assignment can happen if the '-v' option (*note -v::) is used and
     an expression is placed on the left of an assignment, or in operand
     overloading); if the compiler detects that a reversal failure is
     inevitable, it will cause this warning.  Note that this doesn't
     always cause an error, because the relevant code might never be
     executed.

W450
          THE DOCUMENTOR IS NOT ALWAYS RIGHT

     There is no way to get this warning to come up; it isn't even
     written anywhere in C-INTERCAL's source code, is not implemented by
     anything, and there are no circumstances in which it is even meant
     to come up.  It is therefore not at all obvious why it is
     documented.

W534
          KEEP LOOKING AT THE TOP BIT

     C-INTERCAL uses a slightly different typing mechanism to some other
     INTERCAL compilers; types are calculated at compile time rather
     than run time.  This only makes a difference in some cases
     involving unary operators.  It's impossible to detect at compile
     time for certain whether such a case has come up or not, but if the
     compiler or optimizer thinks that such a case might have come up,
     it will issue this warning.

W622
          WARNING TYPE 622 ENCOUNTERED

     Your code looks like it's trying to resume by 0; this is an error.
     This warning is produced at compile time if it looks like a line in
     your code will cause this error, but it isn't necessarily an error
     because that line of code might never be executed.

4 The yuk debugger
******************

The C-INTERCAL distribution contains a runtime debugger called 'yuk'.
Unlike most other debuggers, it is stored as object code rather than as
an executable, and it is compiled into the code rather than operating on
it.  To debug code, add '-y' (*note -y::) to the command line of 'ick'
when invoking it; that tells it to compile the debugger into the code
and then execute the resulting combination.  (The resulting hybrid
debugger/input executable is deleted afterwards; this is to prevent it
being run by mistake, and to prevent spreading the debugger's licence
onto the code it was compiled with.)

yuk can also be used as a profiler using the '-p' option (*note -p::);
this produces a file 'yuk.out' containing information on how much time
was spent running each command in your program, and does not prompt for
debugger commands.

Note that some command line arguments are incompatible with the
debugger, such as '-m' and '-f'.  In particular, this means that
multithreaded programs and programs that use backtracking cannot be
debugged using this method; the '+printflow' option (*note +printflow::)
to a compiled program may or may not be useful for debugging
multithreaded programs.

When the debugger starts, it will print a copyright message and a
message on how to access online help; then you can enter commands to
run/debug the program.  The debugger will show a command prompt, 'yuk007
', to let you know you can input a command.

Here are the commands available.  Commands are single characters
followed by newlines, or followed by a line number (in decimal) and a
newline or a variable name (a '.', ',', ':' or ';' followed by a number
in decimal; note that some commands only allow onespot and twospot
variables as arguments).

Command     Description
--------------------------------------------------------------------------
aLINE       All non-abstained commands on line LINE become abstained
            from once.
bLINE       A breakpoint is set on line LINE.  The breakpoint causes
            execution with 'c' to stop when it is reached.
c           The program is run until it ends (which also ends the
            debugger) or a breakpoint is reached.
dLINE       Any breakpoint that may be on line LINE is removed.
eLINE       An explanation of the main expression in each command on
            line LINE is printed to the screen.  The explanation is in
            the same format as the format produced by '-h' (*note -h::)
            and shows what the optimiser optimised the expression to
            (or the original expression if the optimiser wasn't used).
fLINE       Removes the effect of the 'm' command on line LINE.
gLINE       Causes the current command to be the first command on LINE
            (if not on that line already) or the next command on LINE,
            as if that line was 'NEXT'ed to and then that 'NEXT' stack
            item was forgotten.
h           Lists 10 lines either side of the current line; if there
            aren't 10 lines to one or the other side of the current
            line, instead more lines will be shown on the other side to
            compensate, if available.
iVAR        Causes variable VAR to become 'IGNORE'd, making it
            read-only.
jVAR        Causes variable VAR to become 'REMEMBER'ed, making it no
            longer read-only.
k           Continues executing commands until the 'NEXT' stack is the
            same size or smaller than it was before.  In other words,
            if the current command is not a 'NEXT' and doesn't have a
            'NEXT FROM' aiming at it, one command is executed; but if a
            'NEXT' does happen, execution will continue until that
            'NEXT' returns or is forgotten.  A breakpoint or the end of
            the program also end this.
lLINE       Lists 10 lines of source code either side of line LINE, the
            same way as with 'h', but using a line stated in the
            command rather than the current line.
mLINE       Produces a message onscreen every time a command on line
            LINE is executed, but without interrupting the program.
n           Show the 'NEXT' stack on the screen.
o           Continue executing commands until the 'NEXT' stack is
            smaller than it was before.  If you are using 'NEXT's like
            procedures, then this effectively means that the procedure
            will run until it returns.  A breakpoint or the end of the
            program also end this.
p           Displays the value of all onespot and twospot variables.
q           Aborts the current program and exits the debugger.
rLINE       Reinstates once all abstained commands on line LINE.
s           Executes one command.
t           Continues execution until the end of the program or a
            breakpoint: each command that executes is displayed while
            this command is running.
uLINE       Continues execution of the program until just before a
            command on line LINE is run (or a breakpoint or the end of
            the program).
vVAR        Adds a 'view' on variable VAR (which must be onespot or
            twospot), causing its value to be displayed on the screen
            whenever a command is printed on screen (for instance,
            because the command has just been stepped past, or due to
            the 'm' or 't' commands).
w           Displays the current line and current command onscreen.
xVAR        Removes any view and any action that may be associated with
            it on variable VAR (which must be onespot or twospot).
yVAR        Adds a view on variable VAR; also causes a break, as if a
            breakpoint was reached, whenever the value of that variable
            changes.
zVAR        Adds a view on variable VAR; also causes a break, as if a
            breakpoint was reached, whenever that variable's value
            becomes 0.
VAR         A onespot or twospot variable written by itself prints out
            the value of that variable.
<VAR        'WRITEs IN' a new value for variable VAR.  Note that input
            must be in the normal 'ONE TWO THREE' format; input in any
            other format will cause error E579 (*note E579::) and as
            that is a fatal error, the debugger and program it's
            debugging will end.
*           Displays the license conditions under which 'ick' is
            distributed.
?           Displays a summary of what each command does.  ('@' does
            the same thing.)

While the code is executing (for instance, during a 'c', 'k', 'o', 't'
or 'u' command), it's possible to interrupt it with '<CTRL>-<C>' (on
UNIX/Linux) or '<CTRL>-<BREAK>' (on Windows/DOS); this will cause the
current command to finish running and the debugger prompt to come back
up.

PART II: THE INTERCAL LANGUAGE
******************************

5 Syntax
********

INTERCAL programs consist of a list of statements.  Execution of a
program starts with its first statement; generally speaking each
statement runs after the previous statement, although many situations
can change this.

Whitespace is generally insignificant in INTERCAL programs; it cannot be
added in the middle of a keyword (unless the keyword contains whitespace
itself) or inside a decimal number, but it can be added more or less
anywhere else, and it can be removed from anywhere in the program as
well.

An INTERCAL statement consists of an optional line label, a statement
identifier, an optional execution chance, the statement itself (*note
Statements::), and optionally 'ONCE' or 'AGAIN'.

5.1 Princeton and Atari Syntax
==============================

The history of INTERCAL is plagued with multiple syntaxes and character
sets.  The result has settled down with two versions of the syntax; the
original Princeton syntax, and the Atari syntax (which is more suited to
the operating systems of today).

Princeton syntax
----------------

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
some versions     version 0.18+     all versions      no

The original INTERCAL-72 compiler was the Princeton compiler, which
introduced what has become known as the Princeton syntax for INTERCAL;
this is the syntax used in the original manual, for instance, and can be
considered to be the 'original' or 'official' INTERCAL syntax.  It is
notable for containing various characters not found in some character
sets; for instance, it writes the operator for mingle as a cent sign
(known as 'change').  The other operator that often causes problems is
the bookworm operator 'V', backspace, '-', which is used for
exclusive-or; the backspace can cause problems on some systems (which
was probably the original intention).  This syntax is also the default
syntax in the CLC-INTERCAL compiler, which is the de facto standard for
expanding the Princeton syntax to modern INTERCAL features that are not
found in INTERCAL-72; however, it does not appear to have been used as
the default syntax in any other compilers.  Nowadays, there are other
ways to write the required characters than using backspace; for
instance, the cent sign appears in Latin-1 and UTF-8, and there are
various characters that approximate bookworms (for instance,
CLC-INTERCAL uses the Latin-1 yen symbol for this, which just to make
things confusing, refers to a mingle in modern Atari syntax).

Atari syntax
------------

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
some versions     yes               version 0.05+     yes

The other main syntax is the Atari syntax, so called because it was
originally described in notes about an "Atari implementation" added to
the paper INTERCAL-72 manual when it was softcopied in 1982.  These
notes describe a never-completed compiler implementation for 6502 by
Mike Albaugh and Karlina Ott; it was meant to use the Atari 800
cartrtidge and screen editor, but that portion was never written.  The
syntax was designed to work better on ASCII-based systems, by avoiding
the change character (although it can still be written as 'c',
backspace, '/', which the Atari compiler documentation claims that the
Princeton compiler supported) in favour of a 'big money' character
('$'), and using the 'what' ('?') as an alternative character for
exclusive-or.  This is the syntax that C-INTERCAL and J-INTERCAL have
always used, and is the one most commonly used for communicating
INTERCAL programs on Usenet and other similar fora (where ASCII is one
of the most reliable-to-send character sets).  It is also the syntax
used for examples in this manual, for much the same reason.  The Atari
syntax for constructs more modern than INTERCAL-72 is normally taken to
be that used by the C-INTERCAL compiler, because it is the only
Atari-syntax-based compiler that contains non-INTERCAL-72 constructs
that actually need their own notation.

5.2 Line Labels
===============

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

The first part of an INTERCAL statement is a line label that specifies
what its line number is.  This is optional; it's legal to have a
statement without a line number, although that prevents other commands
referring to it by number.  Line numbers must be constants, and unique
within the program.  However, they do not have to be in order; unlike
some other languages with line numbers, a line with a higher number can
come earlier in the program than a line with a lower number, and the
numbers don't affect the order in which commands are executed.

A line label is a integer expressed in decimal within a wax/wane pair
('(' and ')').  For instance, this is a valid line label:

     (1000)

Note that line numbers from 1000 to 1999 are used by the system library,
so using them within your own programs may produce unexpected errors if
the system library is included.  Apart from this, line numbers from 1 to
65535 are allowed.

It has become reasonably customary for people writing INTERCAL libraries
to pick a range of 1000 line numbers (for instance, 3000 to 3999) and
stick to that range for all line numbers used in the program (apart from
when calling the system library), so if you want to write an INTERCAL
library, it may be a good idea to look at the existing libraries (in the
'pit/lib' directory in the C-INTERCAL distribution) and choose a range
of numbers that nobody else has used.  If you aren't writing a library,
it may be a good idea to avoid such number ranges (that is, use only
line numbers below 1000 or very high numbers that are unlikely to be
used by libraries in the future), so that you can easily add libraries
to your program without renumbering in the future.

5.3 Statement Identifiers
=========================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

After the line label (if a statement has one) comes the statement
identifier, which marks where the statement starts.  Either the label or
the statement identifier, whichever one comes first, marks where the
preceding statement finishes.

The main statement identifier is 'DO'.  It also has two synonyms,
'PLEASE' and 'PLEASE DO'; these synonyms are the 'polite' forms of
statement identifiers.  Although the three identifiers have the same
meaning, using either polite or non-polite identifiers too much can
cause an error; the correct proportion is approximately 3 non-polite
identifiers for every polite identifier used.  None of these identifiers
actually does anything else apart from marking where the statement
starts; they leave the statements in the default 'reinstated' state.

Adding 'NOT' or 'N'T' to the end of any of these identifiers, to create
a statement identifier such as 'DO NOT' or 'PLEASE DON'T', also creates
a valid statement identifier.  These differ in meanings from the
previous set of identifiers, though; they cause the statement they
precede to not be executed by default; that is, the command will be
skipped during execution (this is known as the 'abstained' state).  This
applies even if the command in question is in fact a syntax error, thus
causing this to be a useful method of writing comments.  One common
idiom is to write code like this:

     PLEASE NOTE: This is a comment.

The statement identifier ('PLEASE NOT') is the only part of this
statement that is valid INTERCAL; however, because the statement
identifier is in the negated form that contains 'NOT', the syntax error
won't be executed, and therefore this is a valid statement.  (In
INTERCAL, syntax errors happen at runtime, so a program containing a
statement like 'DOUBT THIS WILL WORK' will still compile, and will not
end due to the syntax error unless that statement is actually executed.
*Note E000::.)

The 'ABSTAIN' and 'REINSTATE' statements can override the 'NOT' or
otherwise on a statement identifier; see *note ABSTAIN::.

In backtracking programs, 'MAYBE' is also a valid statement identifier;
see *note MAYBE::.  It comes before the other keywords in the statement
identifier, and an implicit 'DO' is added if there wasn't one already in
the statement identifier (so 'MAYBE', 'MAYBE DO', 'MAYBE DON'T', 'MAYBE
PLEASE', and so on are all valid statement identifiers).

5.4 Execution Chance
====================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      version 0.02+     all versions

It's possible to specify that a command should be run only a certain
proportion of the time, at random.  This is a rarely used feature of
INTERCAL, although it is the only way to introduce randomness into a
program.  (The C-INTERCAL compiler approximates this with
pseudorandomness.)  An execution chance specification comes immediately
after the statement identifier, but before the rest of the statement,
and consists of a double-oh-seven ('%') followed by an integer from 1 to
99 inclusive, written in decimal; this gives the percentage chance of
the statement running.  The execution chance only acts to prevent a
statement running when it otherwise would have run; it cannot cause a
statement that would otherwise not have run to run.  For instance, the
statement 'DO %40 WRITE OUT #1' has a 40% chance of writing out 'I', but
the statement 'DON'T %40 WRITE OUT #1' has no chance of writing out 'I'
or anything else, because the 'N'T' prevents it running and the
double-oh-seven cannot override that.

5.5 ONCE and AGAIN
==================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.25+     no                no

The last part of a statement is an optional 'ONCE' or 'AGAIN'.  'ONCE'
specifies that the statement is self-abstaining or self-reinstating
(this will be explained below); 'AGAIN' specifies that the statement
should behave like it has already self-reinstated or self-abstained.
Whether the behaviour is self-abstention or self-reinstatement depends
on whether the statement was initially abstained or not; a 'ONCE' on an
initially reinstated statement or 'AGAIN' on an initially abstained
statement indicates a self-abstention, and a 'ONCE' on an initially
abstained statement or 'AGAIN' on an initially reinstated statement
indicates a self-reinstatement.

The first time a self-abstaining statement is encountered, it is
executed as normal, but the statement is then abstained from and
therefore will not run in future.  Likewise, the first time a
self-reinstating statement is encountered, it is not executed (as is
normal for an abstained statement), but then becomes reinstated and will
run in future.  In each of these cases, the 'ONCE' effectively changes
to an 'AGAIN'; the 'ONCE' only happens once, as might be expected.

'REINSTATING' a currently abstained self-abstaining statement or
'ABSTAINING' (that is, with the 'ABSTAIN' or 'REINSTATE' commands) a
currently reinstated self-reinstating statement causes the 'AGAIN' on
the statement to change back into a 'ONCE', so the statement will again
self-abstain or self-reinstate.  Likewise, 'REINSTATING' a currently
abstained self-reinstating statement or 'ABSTAINING' a currently
reinstated self-abstaining statement causes its 'ONCE' to turn into an
'AGAIN'.

Historical note: 'ONCE' was devised by Malcom Ryan as a method of
allowing synchronisation between threads in a multithreaded program
('ONCE' is atomic with the statement it modifies, that is, there is no
chance that threads will change between the statement and the 'ONCE').
'AGAIN' was added to Malcom Ryan's Threaded Intercal standard on the
suggestion of Kyle Dean, as a method of adding extra flexibility (and to
allow the 'ONCE's to happen multiple times, which is needed to implement
some multithreaded algorithms).

6 Expressions
*************

Many INTERCAL statements take expressions as arguments.  Expressions are
made up out of operands and operators between them.  Note that there is
no operator precedence in INTERCAL; different compilers resolve
ambiguities different ways, and some versions of some compilers
(including the original INTERCAL-72 compiler) will cause error messages
on compiling or executing an ambiguous expression, so it's safest to
fully group each expression.

6.1 Constants and Variables
===========================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

The basic operands in INTERCAL are constants and variables.  These
together make up what in other languages are known as 'lvalues', that
is, operands to which values can be assigned.  (Constants can also be
lvalues in INTERCAL, but by default C-INTERCAL turns this off because it
carries an efficiency penalty and can be confusing; this can be turned
on with the '-v' option (*note -v::).)

Constants can have any integer value from 0 to 65535 inclusive; higher
values (up to 4294967295) can be generated in programs, but cannot be
specified literally as constants.  (The usual way to work around this
limitation is to interleave two constants together; see *note Mingle::.)
A constant is written as a mesh ('#') followed by a number in decimal.
At the start of the program, all constants have the same value as the
number that identifies them; for instance, '#100' has 100 as its value,
and it's strongly advised not to change the value of a constant during
the execution of a program.

There are four types of variable: 16-bit and 32-bit unsigned integers,
and arrays of 16-bit and 32-bit unsigned integers.  These are
represented with a spot, twospot, tail, and hybrid ('.', ':', ',', and
';') respectively.  For this reason, integers within the range 0 to
65535 inclusive are known as 'onespot numbers', and integers within the
range 0 to 4294967295 inclusive are known as 'twospot numbers';
variables with those ranges are known as onespot and twospot variables.
(Note that arrays did not work in C-INTERCAL before version 0.7.)

Variables are represented with a character representing their data type,
followed by an integer from 1 to 65535 inclusive, written in decimal.
Non-array variables don't need to be declared before they are used; they
automatically exist in any program that uses them.  For instance, '.1'
and '.001' are the same variable, onespot number 1.  Array variables
need to be dimensioned before they are used, by assigning dimensions to
them; see *note Calculate::.

6.2 Grouping Rules
==================

Because there are no operator precedences in INTERCAL, there are various
solutions to specifying what precedences actually are.

The portable solution

     All known versions of INTERCAL accept the INTERCAL-72 grouping
     rules.  These state that it's possible to specify that an operator
     takes precedence by grouping it inside sparks (''') or rabbit-ears
     ('"'), the same way as wax/wane pairs (parentheses) are used in
     other programming languages.  INTERCAL-72 and earlier C-INTERCAL
     versions demanded that expressions were grouped fully like this,
     and this practice is still recommended because it leads to portable
     programs and is easier to understand.  Whether sparks or
     rabbit-ears (often called just 'ears' for short) are used normally
     doesn't matter, and programmers can use one or the other for
     clarity or for aesthetic appeal.  (One common technique is to use
     just sparks at the outermost level of grouping, just ears at the
     next level, just sparks at the next level, and so on; but
     expressions like '''#1~#2'~"#3~#4"'~#5' are completely unambiguous,
     at least to the compiler.)

     There are, however, some complicated situations involving array
     subscripting where it is necessary to use sparks and ears at
     alternate levels, if you want to write a portable program.  This
     limitation is in C-INTERCAL to simplify the parsing process;
     INTERCAL-72 has the same limitation, probably for the same reason.
     Compare these two statements:

          DO .1 <- ,3SUB",2SUB.1".2
          DO .1 <- ,3SUB",2SUB.1".2~.3"".4

     The problem is that in the first statement, the ears close a group,
     and in the second statement, the ears open a group, and it's
     impossible to tell the difference without unlimited lookahead in
     the expression.  Therefore, in similar situations (to be precise,
     in situations where a group is opened inside an array subscript),
     it's necessary to use the other grouping character to the one that
     opened the current group if you want a portable program.

     One final comment about sparks and rabbit-ears; if the next
     character in the program is a spot, as often happens because
     onespot variables are common choices for operands, a spark and the
     following spot can be combined into a wow ('!').  Unfortunately,
     the rabbit-ear/spot combination has no one-character equivalent in
     any of the character sets that C-INTERCAL accepts as input (UTF-8,
     Latin-1, and ASCII-7) as none of these contain the rabbit
     character, although the Hollerith input format that CLC-INTERCAL
     can use does.

Positional precedences: CLC-INTERCAL rules

     The precedence rules used by CLC-INTERCAL for grouping when full
     grouping isn't used are simple to explain: the largest part of the
     input that looks like an expression is taken to be that expression.
     The main practical upshot of this is that binary operators
     right-associate; that is, '.1~.2~.3' is equivalent to '.1~'.2~.3''.
     C-INTERCAL versions 0.26 and later also right-associate binary
     operators so as to produce the same results as CLC-INTERCAL rules
     in this situation, but as nobody has yet tried to work out what the
     other implications of CLC-INTERCAL rules are they are not emulated
     in C-INTERCAL, except possibly by chance.

Prefix and infix unary operators

     In INTERCAL-72 and versions of C-INTERCAL before 0.26, unary
     operators were always in the 'infix' position.  (If you're confused
     about how you can have an infix unary operator: they go one
     character inside a group that they apply to, or one character after
     the start of a constant or variable representation; so for
     instance, to portably apply the unary operator '&' to the variable
     ':1', write ':&1', and to portably apply it to the expression
     ''.1~.2'', write ''&.1~.2''.)  CLC-INTERCAL, and versions of
     C-INTERCAL from 0.26 onwards, allow the 'prefix' position of a
     unary operator, which is just before whatever it applies to (as in
     '&:1').  This leads to ambiguities as to whether an operator is
     prefix or infix.  The portable solution is, of course, to use only
     infix operators and fully group everything, but when writing for
     recent versions of C-INTERCAL, it's possible to rely on its
     grouping rule, which is: unary operators are interpreted as infix
     where possible, but at most one infix operator is allowed to apply
     to each variable, constant, or group, and infix operators can't
     apply to anything else.  So for instance, the C-INTERCAL
     ''&&&.1~.2'' is equivalent to the portable ''&"&.&1"~.2'' (or the
     more readable version of this, '"&'"&.&1"~.2'"', which is also
     portable).  If these rules are counter-intuitive to you, remember
     that this is INTERCAL we're talking about; note also that this rule
     is unique to C-INTERCAL, at least at the time of writing, and in
     particular CLC-INTERCAL is likely to interpret this expression
     differently.

6.3 Operators
=============

Operators are used to operate on operands, to produce more complicated
expressions that actually calculate something rather than just fetch
information from memory.  There are two types of operators, unary and
binary operators, which operate on one and two arguments respectively.
Binary operators are always written between their two operands; to
portably write a unary operator, it should be in the 'infix' position,
one character after the start of its operand; see *note Prefix and infix
unary operators:: for the full details of how to write unary operators
portably, and how else you can use them if you aren't aiming for
portability.  This section only describes INTERCAL-72 operators; many
INTERCAL extensions add their own operators.

6.3.1 Mingle
------------

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

Mingle, or interleave, is one of the two binary operators in
INTERCAL-72.  However, different INTERCAL compilers represent it in
different ways, so it is impossible to write a mingle in a program
completely portably, because it differs between Princeton and Atari
syntax, and worse, the sequence of character codes needed to represent
it in each syntax has varied from compiler to compiler.

The original INTERCAL-72 compiler (the Princeton compiler) used the
'change' (cent) character for a mingle, represented as 'c', backspace,
'/'.  (By the way, this is still the most portable way to write a
mingle; both C-INTERCAL and CLC-INTERCAL accept it, at least if a
lowercase 'c' is used, the Atari compiler was to accept it, and its
documentation claimed that the Princeton compiler also accepted it;
CLC-INTERCAL also accepts a capital 'C' before the backspace and '/',
and allows '|' rather than '/'.)  The uncompleted Atari compiler
intended to use a 'big money' character ('$') as the mingle character;
this character is also the only one accepted for mingle by the
J-INTERCAL compiler.  C-INTERCAL originally also used the '$' character
for mingle, and this character is the one most commonly seen in existing
C-INTERCAL programs, and most often used when giving examples of
INTERCAL on Usenet, because it exists in the ASCII-7 character set, and
because it doesn't contain control characters.  From version 0.18 of
C-INTERCAL onwards, various other units of currency (change, quid, and
zlotnik if Latin-1 is used as the input, and euro if Latin-9 is used as
the input) are accepted; from version 0.20 onwards, in addition to the
Latin-1 characters, all the currency symbols in Unicode are accepted if
UTF-8 is used as the input format.  CLC-INTERCAL has always used the
change character (either the Latin-1 version or the version that
contains a backspace) for mingle.  In this manual, mingle will be
represented as '$', but it's important to bear in mind that this
character is not the most portable choice.

The mingle operator should be applied to two operands or expressions.
To be portable, the operands must both be onespot expressions, that is
expressions which have a 16-bit result; C-INTERCAL relaxes this rule
slightly and only requires that the result be in the onespot range.
(This is because the data type of a select operator's value is meant to
be determined at runtime; C-INTERCAL determines all data types at
compile time, so has to guess a 32-bit result for a select with a 32-bit
type as its right operand even when the result might actually turn out
to be of a 16-bit type, and so this behaviour prevents an error when a
select operation returns a value with a 16-bit data type and is used as
an argument to a mingle.)  The result is a 32-bit value (that is, it is
of a 32-bit data type, even if its value fits into the onespot range),
which consists of bits alternated from the two arguments; to be precise,
its most significant bit is the most significant bit of its first
argument, its second most significant bit is the most significant bit of
its second argument, its third most significant bit is the second most
significant bit of its first argument, and so on until its least
significant bit, which is the least significant bit of its second
argument.

One of the most common uses of interleaving is to create a constant with
a value greater than 65535; for instance, 65536 is '#0$#256'.  It is
also commonly used in expressions that need to produce 32-bit results;
except in some simple cases, this is usually coded by calculating
separately the odd-numbered and even-numbered bits of the result, and
mingling them together at the end.  It is also used in expressions that
need to left-shift values or perform similar value-increasing
operations, as none of the other operators can easily do this; and
mingle results are commonly used as the argument to unary binary logic
operators, because this causes them to behave more like the binary logic
operators found in some other languages.

6.3.2 Select
------------

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

The select operator is one of the two binary operators in INTERCAL-72;
unlike mingle, every known implementation of INTERCAL ever has used the
sqiggle character ('~') as the representation of the select operator,
meaning that writing it portably is easy.

The select operator takes two arguments, which can be of either datatype
(that is, 16- or 32-bit).  It returns a value made by selecting certain
bits of its first operand indicated by the second operand, and
right-justifying them.  What it does is that it ignores all the bits of
the first operand where the second operand has a 0 as the corresponding
bit, that is, deletes them from a copy of the operand's value; the bits
that are left are squashed together towards the least-significant end of
the number, and the result is filled with 0s to make it up to 16 or 32
bits.  (In INTERCAL-72 the minimum multiple of 16 bits possible that the
result fits into is chosen, although if :1 has the value 131061 (in hex,
1FFFF) the expression '#21~:1' produces a 32-bit result because 17 bits
were selected, even though many of the leading bits were zeros; in
C-INTERCAL the data type of the result is the same as of the right
operand of the select, so that it can be determined at compile time, and
so using a unary binary logic operator on the result of select when the
right operand has a 32-bit type is nonportable and not recommended.)  As
an example, '#21~:1' produces 21 as its result if :1 has the value
131061, 10 as its result if :1 has the value 30 (1E in hex; the least
significant bit of 21 is removed because it corresponds to a 0 in :1),
and 7 as its result if :1 has the value 21 (because three bits in 21 are
set, and those three bits from 21 are therefore selected by 21).

Select is used for right-shifts, to select every second bit from a
number (either to produce what will eventually become an argument to
mingle, or to interpret the result of a unary binary logic operator, or
occasionally both), to test if a number is zero or not (by selecting it
from itself and selecting 1 from the result), in some cases as a limited
version of bitwise-and (that only works if the right operand is 1 less
than a power of 2), and for many other purposes.

6.3.3 Unary Binary Logic
------------------------

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

There are three unary operators in INTERCAL-72, each of which carries
out a binary logic operation on adjacent bits of the number.  The
operators are and, or, and exclusive or; and and or are represented by
an ampersand ('&') and book ('V') respectively, and exclusive or has the
same notational problems as mingle, as it differs between Princeton and
Atari syntax.  It was represented by a bookworm, written 'V', backspace,
'-', in the Princeton INTERCAL-72 implementation, and this is still the
most portable way to write it (C-INTERCAL and CLC-INTERCAL accept it).
The Atari implementation of INTERCAL-72 wrote it with a what ('?'), and
this is the representation originally used by C-INTERCAL (and still
accepted), the only representation accepted by J-INTERCAL, the one most
commonly used on Usenet, and the one used in this manual (although
again, it's worth pointing out that this isn't portable).  CLC-INTERCAL
approximates a bookworm with the yen character, which being a currency
character is one of the possible representations for mingle in
C-INTERCAL; C-INTERCAL uses the rather confusing method of interpreting
a yen character as exclusive-or if input in Latin-1 but as mingle if
input in UTF-8.  (This usually does the right thing, because
CLC-INTERCAL doesn't support UTF-8.)  In the same way, CLC-INTERCAL has
a C-INTERCAL compatibility option to allow the use of '?' for
exclusive-or.

The operators take each pair of consecutive bits in their arguments
(that is, the least significant with the second least significant, the
second least significant with the third least significant, the third
least significant with the fourth least significant, and so on, with the
pair consisting of the most significant and least significant being used
to calculate the most significant bit of the result), and perform an
appropriate logic operation on them; and sets a bit of the result if and
only if both bits in the pair were set, or sets each bit corresponding
to each pair where either bit was set, and exclusive or sets if and only
if the bits in the pair had different values (that is, one was set, but
not both).  So for instance, '#&26' is 16 (26 is 1A in hexadecimal or
11010 in binary); '#V26' is 31 (11111 in binary), and '#?26' is 23
(10111 in binary).

The most commonly seen use for these operators is to carry out bitwise
ands, ors, and exclusive ors between two different 16-bit expressions,
by mingling them together, applying a unary binary logic operator, and
selecting every second bit of the result; such code often results due to
people thinking in terms of some other language when writing INTERCAL,
but is still often useful.  (Historically, the first idiom added to the
optimizer, apart from constant folding, was the mingle/unary/select
sequence.)  There are more imaginative uses; one impressive example is
the exclusive or in the test for greater-than from the original
INTERCAL-72 system library:

     DO :5 <- "'?":1~'#65535$#0'"$":2~'#65535$#0'"'
          ~'#0$#65535'"$"'?":1~'#0$#65535'"$":2~'#0$
          #65535'"'~'#0$#65535'"
     DO .5 <- '?"'&"':2~:5'~'"'?"'?":5~:5"~"#65535~
          #65535"'~'#65535$#0'"$#32768'~'#0$#65535'"
          $"'?":5~:5"~"#65535$#65535"'~'#0$#65535'"'
          "$"':5~:5'~#1"'~#1"$#2'~#3

The first statement works out the value of :1 bitwise exclusive or :2;
the second statement then works out whether the most significant set bit
in :5 (that is, the most significant bit that differs between :1 and :2)
corresponds to a set bit in :2 or not.  In case that's a bit too
confusing to read, here's the corresponding optimizer idiom (in OIL):

     ((_1~:2)~((?32(:2~:2))^#2147483648))->(_1>(:2^_1))

(Here, the ^ refers to a bitwise exclusive or, an operation found in OIL
but not in INTERCAL, which is why the INTERCAL version is so much
longer.)  The INTERCAL version also has some extra code to check for
equality and to produce 1 or 2 as the output rather than 0 or 1.

6.3.4 Array Subscript
---------------------

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               version 0.7+      all versions      all versions

In order to access the elements of an array, either to read or write the
array, it is necessary to use the array subscript operator 'SUB'.  Note
that an array element is not a variable, so it is not accepted as an
acceptable argument to statements like 'IGNORE'; however, it can be
assigned to.

The syntax for an array element is the array, followed by the keyword
'SUB', followed by an expression for the element number in the array.
In the case of a multidimensional array, more than one expression is
given after the keyword 'SUB' to give the location of the element in
each of the array's dimensions.  The first element in an array or array
dimension is numbered 1.

For instance, this is a legal (but not particularly useful) INTERCAL
program with no syntax errors that shows some of the syntaxes possible
with array subscripting:

     PLEASE ,1 <- #2
     DO .1 <- #2
     DO ,1 SUB .1 <- #1
     DO ,1 SUB #1 <- ,1 SUB #2
     PLEASE ;1 <- #2 BY #2
     DO ;1 SUB #1 #2 <- ,1 SUB ,1 SUB .1
     DO READ OUT ;1SUB#1.1
     DO GIVE UP

Grouping can get complicated when nested array subscripting is used,
particularly with multiple subscripts.  It is the programmer's job to
write an unambiguous statement, and also obey the extra grouping rules
that apply to array subscripts; see *note Grouping Rules::.

7 Statements
************

There is a wide range of statements available to INTERCAL programs; some
identifiably belong to a particular variant or dialect (such as
Backtracking INTERCAL), but others can be considered to be part of the
'core language'.  The statements listed here are those that the
C-INTERCAL compiler will accept with no compiler switches to turn on
particular dialect options.  Note that many statements have slightly
different effects in different implementations of INTERCAL; known
incompatibilities are listed here, but it's important to check your
program on multiple compilers when attempting to write a portable
program.

7.1 Syntax Error
================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               version 0.15+     all versions      all versions

One of the more commonly-used commands in INTERCAL is the syntax error.
A properly-written syntax error looks nothing like any known INTERCAL
command; a syntax error that looks vaguely like a command but isn't may
confuse C-INTERCAL before version 0.28, and possibly other compilers,
into bailing out at compile time in some situations (this is known as a
'serious syntax error'), and so is not portable.  For other syntax
errors, though, the semantics are easily explained: there is a run-time
error whenever the syntax error is actually executed, and the line
containing the syntax error is used as the error message.

One purpose of this is to allow your programs to produce their own
custom errors at run time; however, it's very important to make sure
that they start and end in the right place, by manipulating where
statement identifiers appear.  Here's a correct example from the system
library:

     DOUBLE OR SINGLE PRECISION ARITHMETIC OVERFLOW

This is a valid INTERCAL command, that produces an error when run (note
the 'DO' at the start).  An even more common use is to produce an
initially abstained syntax error by using an appropriate statement
identifier, for instance

     PLEASE NOTE THAT THIS IS A COMMENT

This would produce an error if reinstated somehow, but assuming that
this isn't done, this is a line of code that does nothing, which is
therefore equivalent to a comment in other programming languages.  (The
initial abstention is achieved with the statement identifier 'PLEASE
NOT'; the extra 'E' causes the command to be a syntax error, and this
particular construction is idiomatic.)

Referring to the set of all syntax errors in a program (or the set of
all commands of any other given type) is achieved with a special keyword
known as a 'gerund'; gerund support for syntax errors is resonably
recent, and only exists in CLC-INTERCAL (version 1.-94.-3 and later,
with 'COMMENT', 'COMMENTS', or 'COMMENTING'), and C-INTERCAL ('COMMENT'
in version 0.26 and later, and also 'COMMENTS' and 'COMMENTING' in
version 0.27 and later).  Therefore, it is not portable to refer to the
set of all syntax errors by gerund; using a line label is a more
portable way to refer to an individual syntax-error command.

7.2 Calculate
=============

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

At present, the only INTERCAL command that contains no keywords (apart
from the statement identifier and possibly 'ONCE' or 'AGAIN') is what is
known as the 'calculate' command.  It is used to assign values to
variables, array elements, and arrays; assigning a value to an array
changes the number of elements that that array can hold, and causes the
values of all elements previously in that array to be lost.  The syntax
of a calculate command is as follows:

     DO .1 <- ':2~:3'~#55

That is, the command is written as a variable or array element, then the
'<-' operator (known as an 'angle-worm' and pronounced 'gets'), then an
expression to assign to it.  In the special case when an array is being
dimensioned by assigning a value to it, the expression can contain the
keyword 'BY' to cause the array to become multidimensional; so for a 3
by 4 by 5 array, it would be possible to write

     DO ,1 <- #3 BY #4 BY #5

The calculate command always evaluates the expression, even if for some
reason the assignment can't be done (for instance, if the variable being
assigned to is read-only); this is important if the expression has
side-effects (for instance, giving an overflow error).  If the variable
does happen to be read-only, there is not an error; the expression being
assigned to it is just evaluated, with the resulting value being
discarded.

The gerund to refer to calculations is 'CALCULATING'; however, if you
are planning to use this, note that a bug in older versions of
C-INTERCAL means that assignments to arrays are not affected by this
gerund before version 0.27.

CLC-INTERCAL from 1.-94.-4 onwards, and C-INTERCAL from 0.26 onwards,
allow arbitrary expressions on the left hand side of an assignment
(C-INTERCAL only if the '-v' option is used); for more information on
how such 'reverse assignments' work, see *note Operand Overloading::.

7.3 NEXT, FORGET and RESUME
===========================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      see text          all versions

The only flow-control commands in INTERCAL-72 were 'NEXT', 'RESUME', and
'FORGET'; together these manipulate a stack of locations in the program
known as the 'NEXT stack'.  Although all INTERCAL compilers have
implemented these, from CLC-INTERCAL version 0.05 onwards CLC-INTERCAL
has considered them obsolete, and therefore a special command-line
switch needs to be used to enable them.  (They are still the most
portable flow-control commands currently available, though, precisely
because INTERCAL-72 implements nothing else.)  Note that there is a
strict limit of 80 locations on the NEXT stack, enforced by all known
INTERCAL compilers; this helps to enforce good programming style, by
discouraging NEXT-stack leaks (which are otherwise quite easy to write).

Here are examples to show the syntax of these three statements:

     DO (1000) NEXT
     DO FORGET '.1~.1'~#1
     DO RESUME .5

The 'NEXT' command takes a line label as its argument (unlike most other
INTERCAL commands, it comes after its argument rather than before); both
'FORGET' and 'RESUME' take expressions.  (CLC-INTERCAL from version 0.05
onwards also allows an expression in 'NEXT', rather than a label, to
give a computed 'NEXT', but this behaviour was not implemented in other
compilers, and is deprecated in CLC-INTERCAL along with noncomputed
'NEXT'; if computed 'NEXT' is ever implemented in C-INTERCAL, it will
likely likewise be deprecated upon introduction).  (Update: it was
implemented in C-INTERCAL version 0.28, but only as part of the external
calls system, so it cannot be used in ordinary programs; a sample
expansion library gives in-program access to a limited form of computed
'NEXT', but should probably not be used.)  Running a 'NEXT' causes the
program control to transfer to the command whose line label is
referenced, and also saves the location in the program immediately after
the 'NEXT' command on the top of the NEXT stack.

In order to remove items from the 'NEXT' stack, to prevent it filling up
(which is what happens with a naive attempt to use the 'NEXT' command as
an equivalent to what some other languages call GOTO), it is possible to
use the 'FORGET' or 'RESUME' commands.  They each remove a number of
items from the NEXT stack equal to their argument; 'RESUME' also
transfers control flow to the last location removed from the 'NEXT'
stack this way.  Trying to remove no items, or more items than there are
in the stack, does not cause an error when 'FORGET' is used (no items or
all the items are removed respectively); however, both of these cases
are errors in a 'RESUME' statement.

Traditionally, boolean values in INTERCAL programs have been stored
using #1 and #2 as the two logic levels.  This is because the easiest
way to implement an if-like construct in INTERCAL-72 is by 'NEXTING',
then 'NEXTING' again, then 'RESUMING' either by 1 or 2 according to an
expression, and then if the expression evaluated to 1 'FORGETTING' the
remaining NEXT stack entry.  By the way, the previous sentence also
explained what the appropriate gerunds are for 'NEXT', 'RESUME', and
'FORGET'.

7.4 STASH and RETRIEVE
======================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

The NEXT stack is not the only stack available in an INTERCAL program;
each variable used in the program also has its own stack, which holds
values of the same type as the variable.  The 'STASH' command pushes a
variable's value onto that variable's stack; 'RETRIEVE' can be used in
the same way to pop the top element of a variable's stack to replace
that variable's value.  The syntax is the same as most other INTERCAL
commands, with the word 'STASH' or 'RETRIEVE' followed by the variable
or variables to stash or retrieve:

     DO STASH .1 + ;2
     DO RETRIEVE ,3

Note that it is possible to stash or retrieve multiple variables at
once, by listing their names separated by intersections ('+'); it's even
possible to stash or retrieve a variable twice in the same statement.

It is not entirely clear how 'RETRIEVE' interacts with 'IGNORE' in
historical INTERCAL-72 compilers; the three modern INTERCAL compilers
all use different rules for the interaction (and the C-INTERCAL
maintainers recommend that if anyone decides to write their own
compiler, they choose yet another different rule so that looking at the
interaction (the so-called 'ignorret test') can be used as a method of
determining which compiler is running):

   * C-INTERCAL treats a retrieval just like an assignment.  That is, a
     read-only variable will not be changed by a retrieval, and will
     remain read-only, but the side-effect of popping that variable's
     stash will still happen.

   * J-INTERCAL ignores the read-only status of a variable when
     retrieving it from a stash; the value of the variable changes
     despite being read-only.  The variable remains read-only; the
     'RETRIEVE' simply allows a change to its value despite the
     read-only status.

   * CLC-INTERCAL is the most complicated; it stores read-only status or
     otherwise in the stash, along with the variable's value.  This
     means that if a variable was stashed when read-only, retrieving it
     will retrieve its value and set it to read-only regardless of its
     previous read-only status; likewise, if a variable was stashed when
     read-write, retrieving it will retrieve its value and set it to
     read-write even if it was previously read-only.

The appropriate gerunds for 'STASH' and 'RETRIEVE' are 'STASHING' and
'RETRIEVING' respectively.

7.5 IGNORE and REMEMBER
=======================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

Variables in INTERCAL can be either read-write or read-only.  At the
start of a program, all variables are read-write, but this status can be
changed dynamically during execution of a program using the 'IGNORE' and
'REMEMBER' statements (whose gerunds are 'IGNORING' and 'REMEMBERING'
respectively).  The syntax is the same as for 'STASH' and 'RETRIEVE':
the command's name followed by an intersection-separated list of
variables.  For instance:

     DO IGNORE .4
     DO REMEMBER ,4 + ;5

Using the 'IGNORE' statement sets a variable to be read-only (or does
nothing if it's read-only already); 'REMEMBER' sets it to be read-write.
Any attempt to assign to a read-only variable silently fails.  One place
that this is used is in the system library; instead of not assigning to
a variable in certain control flow paths, it instead sets it to be
read-only so that subsequent assignments don't change its value (and
sets it to be read-write at the end, which succeeds even if it was never
set read-only in the first place); the advantage of this is that it
doesn't need to remember what flow path it's on except in the variable's
ignorance status.

The interaction between 'IGNORE' and 'RETRIEVE' was never defined very
clearly, and is in fact different in C-INTERCAL, CLC-INTERCAL and
J-INTERCAL; for more details, see *note RETRIEVE::.

7.6 ABSTAIN and REINSTATE
=========================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

The statement identifier of a statement determines whether it's in an
abstained or reinstated state at the start of a program; these states
determine whether the statement runs at all when it's encountered.  It
is, however, possible to change this state dynamically during a
program's execution, and the statements to do this are rather
appropriately named 'ABSTAIN' and 'REINSTATE'.  There are two forms of
each, one which takes a single line label (which must be constant in
most compilers, but can instead be an expression in recent CLC-INTERCAL
versions), and one which takes an intersection-delimited list of
gerunds.  They look like this:

     DO ABSTAIN FROM ABSTAINING + REINSTATING
     DO ABSTAIN FROM (10)
     DO REINSTATE CALCULATING
     DO REINSTATE (22)

(This also illustrates the gerunds used for these commands; note that
'ABSTAINING' from 'REINSTATING' is generally a bad idea!)  The line
referenced, or every command represented by any gerund referenced, are
reinstated or abstained as appropriate (effectively changing the DO to
DON'T (or PLEASE to PLEASE DON'T, etc.), or vice versa).  Using these
forms of 'ABSTAIN' and/or 'REINSTATE' won't abstain from a command
that's already abstained, or reinstate a command that's already
reinstated.

There is a strange set of restrictions on 'ABSTAIN' and 'REINSTATE' that
has existed since INTERCAL-72; historically such restrictions have not
always been implemented, or have not been implemented properly.  They
together define an unusual interaction of 'ABSTAIN' and 'GIVE UP' (note,
for instance, that there isn't a gerund for 'GIVE UP').  The wording
used in the INTERCAL-72 manual is:

     [...]  the statement DO ABSTAIN FROM GIVING UP is not accepted,
     even though DON'T GIVE UP is.  [...]  DO REINSTATE GIVING UP is
     invalid, and attempting to REINSTATE a GIVE UP statement by line
     label will have no effect.  Note that this insures that DON'T GIVE
     UP will always be a "do-nothing" statement.

This restriction was not implemented at all in the only CLC-INTERCAL
version before 0.02 (i.e. version 0.01), or in C-INTERCAL versions
before 1.26.  The restriction was implemented in C-INTERCAL version 1.26
and CLC-INTERCAL versions 0.02 and later as "'GIVE UP' cannot be
'REINSTATED' or 'ABSTAINED FROM'"; however, this is not strictly the
same as the definition used by INTERCAL-72 (C-INTERCAL still uses this
definition in CLC-INTERCAL compatibility mode).  The J-INTERCAL
implementation of this restriction is to make 'REINSTATING' or
'ABSTAINING' from a line label that refers to a 'GIVE UP' statement a
compile-time error, but this does not fit the INTERCAL-72 definition
either.  The definition adopted with version 0.27 and later of
C-INTERCAL, which is hopefully correct, is to allow abstaining from a
'GIVE UP' statement by line number but to rule out the other three cases
(reinstating by line number silently fails, reinstating or abstaining by
gerund is impossible because there is no gerund).

As well as CLC-INTERCAL's extension to abstain/reinstate by computed
line number, there is also (since version 0.25) a C-INTERCAL-specific
extension to 'ABSTAIN', also known as 'computed abstain', but with a
different syntax and different semantics.  It's written like an ordinary
'ABSTAIN', but with an expression between the words 'ABSTAIN' and
'FROM', for instance:

     DO ABSTAIN #1 FROM (1000)
     DO ABSTAIN .2 FROM WRITING IN

Unlike non-computed 'ABSTAIN', this form allows a command to be
abstained from even if it's already been abstained from; so if the first
example command is run and line (1000) is already abstained, it becomes
'double-abstained'.  The number of times the statement is abstained from
is equal to the number of times it was already abstained from, plus the
expression (whereas with non-computed abstain, it ends up abstained once
if it wasn't abstained at all, and otherwise stays at the same
abstention status).  Reinstating a statement always de-abstains it
exactly once; so double-abstaining from a statement, for instance, means
it needs to be reinstated twice before it will actually execute.

There are many uses for 'ABSTAIN' (both the computed and non-computed
versions) and 'REINSTATE', especially when interacting with 'ONCE' and
'AGAIN' (*note ONCE and AGAIN::); the computed version, in particular,
is a major part of a particular concise way to write conditionals and
certain kinds of loops.  They also play an important role in
multithreaded programs.

7.7 READ OUT and WRITE IN
=========================

The 'READ OUT' and 'WRITE IN' commands are the output and input commands
in INTERCAL; they allow communication between the program and its user.
There was a numeric I/O mechanism implemented in INTERCAL-72, and it (or
trivial variants) have been likewise implemented in all more modern
variants.  However, it had some obvious deficiences (such as not being
able to read its own output) which meant that other methods of I/O were
implemented in C-INTERCAL and CLC-INTERCAL.

The syntax of 'READ OUT' and 'WRITE IN' is the same in all cases: the
name of the command followed by an intersection-separated list of items;
the form of each item, the compiler you are using, and its command line
arguments together determine what sort of I/O is used, which can be
different for different elements in the list.

7.7.1 INTERCAL-72 I/O
---------------------

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      see text          all versions

INTERCAL-72 had its own versions of I/O commands; these commands are
available in all modern INTERCAL compilers as well (but CLC-INTERCAL
implements output slightly differently).  To distinguish INTERCAL-72
input and output from the other more modern types of I/O, the 'READ OUT'
and 'WRITE IN' commands must take one of the following values: a onespot
or twospot variable, a single element of a tail or hybrid array, or (in
the case of 'READ OUT') a constant, meaning that these are some examples
of the possible forms:

     READ OUT .1
     READ OUT ;2 SUB .3:4
     READ OUT #3
     WRITE IN :4
     WRITE IN ,5 SUB #6

The statements do what you would expect; 'READ OUT' outputs its argument
to the user, and 'WRITE IN' inputs a number from the user and assigns it
to the variable or array element referenced.  (If the variable, or the
array that contains the array element, happens to be read-only, the
input or output still happens but in the case of 'WRITE IN' silently
skips the assignment, instead throwing away the input.)  The formats
used for input and output are, however, different from each other and
from the formats used by most mainstream languages.

Input is achieved by writing a number in decimal, one digit at a time,
with each digit written out as a word; so to input the number 12345, a
user would have to type 'ONE TWO THREE FOUR FIVE' as input (if they were
using English, the most portable choice of language).  In INTERCAL-72
only English is accepted as a language, but other compilers accept other
languages in addition.  C-INTERCAL from version 0.10 onwards accepts
English, Sanskrit, Basque, Tagalog, Classical Nahuatl, Georgian, and
Kwakiutl; also Volapk from version 0.11 onwards, and Latin from version
0.20 onwards.  J-INTERCAL accepts the same languages, except with
Esperanto instead of Latin; from version 0.05 of CLC-INTERCAL onwards,
the same list of languages as C-INTERCAL is supported (apart from Latin,
which was added in version 1.-94.-8), plus Scottish Gaelic.

The format that output can be read in is a modified form of Roman
numerals, known as 'butchered' Roman numerals.  INTERCAL-72, C-INTERCAL
and J-INTERCAL do this the same way; CLC-INTERCAL is somewhat different.
The characters 'I', 'V', 'X', 'L', 'C', 'D', and 'M' mean 1, 5, 10, 50,
100, 500 and 1000 respectively, placing a lower-valued letter after a
higher-valued letter adds them, and placing a lower-valued letter before
a higher-valued letter subtracts it from the value; so 'XI' is 11 and
'IX' is 9, for instance.  In INTERCAL-72, C-INTERCAL, and J-INTERCAL, a
bar over a numeral multiplies its value by 1000, and writing a letter in
lowercase multiplies its value by 1000000; however, CLC-INTERCAL uses
lowercase to represent multiplication by 1000 and for multiplication by
1000000 writes a backslash before the relevant numeral.

7.7.2 C-INTERCAL I/O
--------------------

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.07+     version 0.05+     no

C-INTERCAL's method of character-based (rather than numeric) input and
output is known as the Turing Tape method; it is a binary
(character-set-agnostic) input/output mechanism.  To specify that
C-INTERCAL-style I/O is being used, an array must be used as the
argument to 'READ OUT' or 'WRITE IN'; as the syntax is the same as for
CLC-INTERCAL's I/O, command-line arguments and the capabilities of the
version of the compiler being used serve to distinguish the two
mechanisms.

The character-based input writes as many characters into a tail or
hybrid array as will fit, one character in each element.  The number
that's written into the array is not the character code, though, but the
difference between the character code and the previous character code,
modulo 256.  (To be precise, the code is the new character minus the
previous character, or 256 minus (the previous character minus the new
character) if the previous character had a higher character code; the
'previous character' is the previous character from the input, not the
previous character written into the array.)  End-of-file causes 256 to
be written into the array.  The concept is that of a circular tape
containing all the characters, where the program measures how many
spaces it needs to move along the tape to reach the next character.  The
'previous character' starts at 0, but is preserved throughout the entire
program, even from one 'WRITE IN' to the next.

Character-based output uses a similar model, but conceptually the output
device moves on the inside of the tape, rather than on the outside.
Therefore, the character that is actually output is the bit-reversal of
the difference between the last character output before it was
bit-reversed and the number found in the array (subtracting in that
order, and adding 256 if the result is negative).  (Rather than trying
to parse the previous sentence, you may find it easier to look either at
the source code to the compiler if you have it (the relevant part is
binout in 'src/cesspool.c') or at some example C-INTERCAL programs that
do text-based I/O.)

7.7.3 CLC-INTERCAL I/O
----------------------

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                see text          all versions      no

There are also two CLC-INTERCAL-specific I/O mechanisms.  These are
Baudot-based text I/O (which is also implemented from C-INTERCAL version
0.27 onwards), and CLC-INTERCAL generalised binary I/O (not implemented
in C-INTERCAL).

Baudot text-based I/O is specified by using a tail array as an argument
to 'WRITE IN' or 'READ OUT'.  (A tail array can also be used to specify
C-INTERCAL-style Turing Tape I/O. In order to determine which is used:
both C-INTERCAL and CLC-INTERCAL use their own sort of I/O unless a
command-line argument instructs them to use the other.)  In the case of
'WRITE IN', one line of input is requested from the user (C-INTERCAL
requires this to be input in Latin-1, and will then automatically
convert it; CLC-INTERCAL gives the option of various character sets for
this input as command-line options); the final newline is removed from
this line, then it is converted to extended Baudot and stored in the
tail array specified (causing an error if the array is too small).
Because Baudot is only a 5-bit character set, each element is padded to
16 bits; CLC-INTERCAL pads with zeros, C-INTERCAL pads with random bits.
Trying to input at end-of-file will act as if the input were a blank
line.  'READ OUT' is the reverse; it interprets the array as extended
Baudot and converts it to an appropriate character set (Latin-1 for
C-INTERCAL, or whatever was specified on the command line for
CLC-INTERCAL), which is output to the user, followed by a newline.  Note
that the Baudot is often longer than the corresponding character in
other character sets due to the need to insert shift codes; for
information on the extended Baudot character set, *note Character
Sets::.

Generalised binary I/O is specified using a hybrid array as an argument
to 'WRITE IN' or 'READ OUT'.  Input works by reading in a number of
bytes equal to the length of the array (without trying to interpret them
or translating them to a different character set), prepending a byte
with 172 to the start, padding each byte to 16 bits with random data,
then replacing each pair of consecutive bytes (that is, the first and
second, the second and third, the third and fourth, and so on) with (the
first element selected from the second element) mingled with (the
complement of the first element selected from the complement of the
second element).  Output is the exact opposite of this process.
End-of-file reads a 0, which is padded with 0s rather than random data;
if a non-end-of-file 0 comes in from the data, its padding will contain
at least one 1.  Any all-bits-0-even-the-padding being read out will be
skipped.

7.8 GIVE UP
===========

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      all versions      all versions

The 'GIVE UP' command causes the program to end (or, in a multithreaded
program, causes the current thread to end).  It is written simply as
'GIVE UP'.  There is not much else to say about it, except to mention
that it is the only way to end the program without an error unless the
last line of the program is 'TRY AGAIN', and that it has an unusual
interaction with 'ABSTAIN'; for details of this, see *note ABSTAIN::.
(Going past the last command in the program is an error.)

There is no gerund for 'GIVE UP'; in particular, 'GIVING UP' is a syntax
error.

7.9 TRY AGAIN
=============

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.25+     no                no

The 'TRY AGAIN' command is a very simple command with many limitations;
its effect is to place the entire program in a loop.  If it exists, it
must be the very last command in the program (it cannot even be followed
by syntax errors), and it causes execution of the program to go back to
the first command.  If the 'TRY AGAIN' command is abstained or for some
other reason doesn't execute when reached, it exits the program without
the error that would usually be caused by going past the last line of
code.

The gerund for 'TRY AGAIN' is 'TRYING AGAIN'.

7.10 COME FROM and NEXT FROM
============================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                see text          see text          see text

The 'COME FROM' statement (incidentally also invented in 1972, but not
in connection with INTERCAL) is the main control-flow command in
CLC-INTERCAL (which deprecates 'NEXT'), and one of two main control flow
structures in other modern INTERCAL compilers.  It takes either a label
or an expression as its argument; these forms are noncomputed 'COME
FROM' and computed 'COME FROM'.

Noncomputed 'COME FROM' was implemented in version 0.5 of C-INTERCAL,
but did not conform to modern-day semantics until version 0.7; it is
available in every version of CLC-INTERCAL and J-INTERCAL.  Computed
'COME FROM' support is available in every version of CLC-INTERCAL and in
C-INTERCAL from version 0.25 onwards, but not in J-INTERCAL; the variant
'NEXT FROM' of 'COME FROM' is available from CLC-INTERCAL version
1.-94.-8 and C-INTERCAL version 0.26 (both computed and noncomputed).
C-INTERCAL and CLC-INTERCAL also have a from-gerund form of 'COME FROM'
and 'NEXT FROM', which was also implemented from CLC-INTERCAL version
1.-94.-8 and C-INTERCAL version 0.26.

The basic rule of 'COME FROM' is that if a 'COME FROM' statement
references another statement, whenever that statement is reached,
control flow will be transferred to the 'COME FROM' after that statement
finishes executing.  ('NEXT FROM' is identical except that in addition
to the 'COME FROM' behaviour, the location immediately after the
statement that was nexted from is saved on the NEXT stack, in much the
same way as if the statement being nexted from was itself a 'NEXT'.)

Here are examples of noncomputed, computed, and from-gerund 'COME FROM':

     DO COME FROM (10)
     DO COME FROM #2$'.1~#1'
     DO COME FROM COMING FROM

(The last example is an infinite loop.  If it said 'DO NEXT FROM NEXTING
FROM', it would not be an infinite loop because the NEXT stack would
overflow and cause an error.  This also establishes the gerunds used for
'COME FROM' and 'NEXT FROM'.)

There are some things to be careful with involving 'COME FROM' and 'NEXT
FROM'.  First, if the statement come from or nexted from happens to be a
'NEXT', the 'NEXT' doesn't count as 'finishing executing' until the NEXT
stack entry created by the 'NEXT' is 'RESUME'd to.  In particular, this
means that if 'FORGET' is used to remove the entry, or a 'RESUME' with a
large argument resumes a lower entry, the 'COME FROM' doesn't steal
execution at all.

Second, you may be wondering what happens if two 'COME FROM's or 'NEXT
FROM's aim at the same line.  In a non-multithreaded program (whether a
program is multithreaded or not is determined by a compiler option for
those compilers that support it), this is an error; but it is only an
error if the statement that they both point to finishes running, and
both 'COME FROM's or 'NEXT FROM's try to execute as a result (they might
not if, for instance, one is abstained or has a double-oh-seven causing
it not to run some of the time).  If both 'COME FROM's or 'NEXT FROM's
are noncomputed, however, a compiler can (but does not have to) give a
compile time error if two 'COME FROM's or 'NEXT FROM's share a label,
and so that situation should be avoided in portable code.  (If it is
wanted, one solution that works for C-INTERCAL and CLC-INTERCAL is to
use computed 'COME FROM's or 'NEXT FROM's with a constant expression.)

8 System Libraries
******************

Some programming support libraries may be included automatically at the
end of your program by the C-INTERCAL compiler.  While such a
convenience feature might be judged not in the spirit of INTERCAL, the
required level of perversity is arguably restored by the way inclusion
is triggered: whenever your program refers to a line from specified
magic ranges without defining any line in those ranges in the program.

(CLC-INTERCAL does not have this feature, but it is trivial to
concatenate a copy of any desire library onto the end of the program.)

The following table maps magic line ranges to systen libraries.
Descriptions of the libraries follow it.

From    To      Versions    Description
---------------------------------------------------------------------
(1000)  (1999)  All         Basic System Library
(5000)  (5999)  >=0.29      Floatring Point Library

8.1 syslib
==========

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      no                all versions

INTERCAL has a system library, called 'syslib' (versions for bases other
than 2 will have a numeric suffix on the name).

The intention of the system library is to provide a range of useful
capabilities, like multiplication, that can otherwise be hard to write
in INTERCAL.  System library routines are used by 'NEXTING' to their
line number (*note NEXT::), where they will make changes to certain
variables depending on certain other variables (depending on which
routine is called), and 'RESUME' back to the original program.  As the
system library is itself written in INTERCAL, there are some
restrictions that need to be obeyed for calls to it to be guaranteed to
work; none of the variables it uses ('.1' to '.6' and ':1' to ':5')
should be read-only or overloaded (although the value of any variables
that aren't mentioned in the routine's description will be preserved by
the routine), and none of the lines in it should have their abstention
status changed by lines outside it (this can happen with blatant
infractions like 'DO ABSTAIN FROM (1500)' or more subtle problems like
gerund-abstention) or have 'COME FROM's or 'NEXT FROM's aiming at them.

The system library is currently available in all bases from 2 to 7
(*note TriINTERCAL::), but not every command is available in every base,
and C-INTERCAL is the only one of the three compilers listed above that
has the system library to ship with a version in bases other than 2.
(This table was originally based on the INTERCAL-72 manual, but has had
extra information added for bases other than 2.)  Here, "overflow
checked" means that #1 is assigned to .4 if there is not an overflow,
and #2 is assigned to .4 if there is; "overflow captured" means that if
there is overflow, the digit that overflowed is stored in the variable
referenced.  In all cases, division by 0 returns 0.

Line    Description                                        Bases
-----------------------------------------------------------------------
(1000)  .3 <- .1 plus .2, error exit on overflow           2, 3, 4,
                                                           5, 6, 7
(1009)  .3 <- .1 plus .2, overflow checked                 2, 3, 4,
                                                           5, 6, 7
(1010)  .3 <- .1 minus .2, no action on overflow           2, 3, 4,
                                                           5, 6, 7
(1020)  .1 <- .1 plus #1, no action on overflow            2, 3, 4,
                                                           5, 6, 7
(1030)  .3 <- .1 times .2, error exit on overflow          2, 3, 4,
                                                           5, 6, 7
(1039)  .3 <- .1 times .2, overflow checked                2, 3, 4,
                                                           5, 6, 7
(1040)  .3 <- .1 divided by .2                             2, 3, 4,
                                                           5, 6, 7
(1050)  .2 <- :1 divided by .1, error exit on overflow     2, 3, 4,
                                                           5, 6, 7
(1200)  .2 <- .1 times #2, overflow captured in .3         4, 6
(1210)  .2 <- .1 divided by #2, one digit after the        4, 6
        quartic or sextic point stored in .3
(1500)  :3 <- :1 plus :2, error exit on overflow           2, 3, 4,
                                                           5, 6, 7
(1509)  :3 <- :1 plus :2, overflow checked                 2, 3, 4,
                                                           5, 6, 7
(1510)  :3 <- :1 minus :2, no action on overflow           2, 3, 4,
                                                           5, 6, 7
(1520)  :1 <- .1 concatenated with .2                      2, 3, 4,
                                                           5, 6, 7
(1530)  :1 <- .1 times .2                                  2, 3, 4,
                                                           5, 6, 7
(1540)  :3 <- :1 times :2, error exit on overflow          2, 3, 4,
                                                           5, 6, 7
(1549)  :3 <- :1 times :2, overflow checked                2, 3, 4,
                                                           5, 6, 7
(1550)  :3 <- :1 divided by :2                             2, 3, 4,
                                                           5, 6, 7
(1700)  :2 <- :1 times #2, overflow captured in .1         4, 6
(1710)  :2 <- :1 divided by #2, one digit after the        4, 6
        quartic or sextic point stored in .1
(1720)  :2 <- :1 times the least significant digit of      5, 7
        .1, overflow captured in .2
(1900)  .1 <- uniform random number from #0 to #65535      2, 3, 4,
                                                           5, 6, 7
(1910)  .2 <- normal random number from #0 to .1, with     2, 3, 4,
        standard deviation .1 divided by #12               5, 6, 7

If you happen to be using base 2, and are either using the external call
system (*note External Calls::) or are willing to use it, it is possible
to use a version of the system library written in C for speed, rather
than the default version (which is written in INTERCAL).  To do this,
use the command line options '-eE' (before the INTERCAL file), and
'syslibc' (at the end of the command line).

8.2 floatlib
============

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
yes               all versions      no                all versions

INTERCAL also has a floating-point library, called 'floatlib', presently
available only in base 2.  It is used by several of the demonstration
programs shipped with the distribution.  In versions after 0.28 it is
included automatically at the end of your program by the compiler
whenever your program refers to a line from (5000) to (5999) without
defining any line in that range in the program.

Here is a summary of routines in floatlib.i:

Line    Description
-------------------------------------------------------------------
(5000)  :3 <- :1 plus :2
(5010)  :3 <- :1 minus :2
(5020)  :2 <- the integer part of :1, :3 <- the fractional part
        of :1
(5030)  :3 <- :1 times :2
(5040)  :3 <- :1 divided by :2
(5050)  :3 <- :1 modulo :2
(5060)  :2 <- :1 cast from a two's-complement integer into a
        floating-point number
(5070)  :2 <- :1 cast from a floating-point number into the
        nearest two's-complement ineger
(5080)  :2 <- :1 cast from a floating-point number into a
        decimal representation in scientific notation
(5090)  :2 <- :1 cast from a decimal representation in
        scientific notation into a floating-point number
(5100)  :2 <- the square root of :1
(5110)  :2 <- the natural logarithm of :1
(5120)  :2 <- e to the power of :1 (the exponential function)
(5130)  :3 <- :1 to the power of :2
(5200)  :2 <- sin :1
(5210)  :2 <- cos :1
(5220)  :2 <- tan :1
(5400)  :1 <- uniform random number between zero and one
        exclusive
(5410)  :2 <- :1 times phi
(5419)  :2 <- :1 divided by phi

Note: All of the above routines except (5020), (5060), (5080), (5200),
(5210), and (5400) also modify .5 as follows: .5 will contain #3 if the
result overflowed or if the arguments were out of domain, #2 if the
result underflowed, #1 otherwise.  (See below.)

The INTERCAL floating-point library uses the IEEE format for 32-bit
floating-point numbers, which uses bit 31 as a sign bit (1 being
negative), bits 30 through 23 hold the exponent with a bias of 127, and
bits 22 through 0 contain the fractional part of the mantissa with an
implied leading 1.  In mathematical notation:

'N = (1.0 + fraction) * 2^(exponent - 127) * -1^sign'

Thus the range of floating-point magnitudes is, roughly, from
5.877472*10^-39 up to 6.805647*10^38, positive and negative.  Zero is
specially defined as all bits 0.  (Actually, to be precise, zero is
defined as bits 30 through 0 as being 0.  Bit 31 can be 1 to represent
negative zero, which the library generally treats as equivalent to zero,
though don't hold me to that.)

Note that, contrary to the IEEE standard, exponents 0 and 255 are not
given special treatment (besides the representation for zero).  Thus
there is no representation for infinity or not-a-numbers, and there is
no gradual underflow capability.  Conformance with widely-accepted
standards was not considered to be a priority for an INTERCAL library.
(The fact that the general format conforms to IEEE at all is due to
sheer pragmatism.)

PART III: INTERCAL DIALECTS AND EXTENSIONS
******************************************

9 TriINTERCAL
*************

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.7+      version           no
                                    1.-94.-8+

One extension to INTERCAL that is implemented by both C-INTERCAL and
CLC-INTERCAL is known as TriINTERCAL, and extends INTERCAL to bases
other than binary.  Unlike ordinary INTERCAL programs, which have the
extension '.i', TriINTERCAL programs in bases from 3 to 7 (the only
allowed bases) have extensions from '.3i' to '.7i' respectively.

The change of numeric base only affects expressions, and in particular
the behaviour of operators, and the range of variables.  (The onespot
and twospot ranges become the highest number of trits or other digits in
the base required that fit inside the binary ranges, so for instance,
the maximum value of a onespot variable in ternary is 59048, or 3 to the
power 10 minus 1.)  Interleave/mingle is the simplest to explain; it
alternates digits just as it alternated bits in binary.  The other
operators all change, as follows:

   * Exclusive-or becomes two operators, known either as
     subtract-without-borrow and add-without-carry due to their
     mathematical interpretations, or what and sharkfin after their
     Atari syntax representations ('?' and '^').  (In Princeton syntax,
     these are the bookworm or yen sign, and a spike ('|').)  The two
     operators do the same thing in binary, but differ in higher bases.
     (Nevertheless, it is an error to use a sharkfin in binary, because
     it is a so-called 'controlled unary operator', as are the rest of
     the new operators defined in this section, which has a lower limit
     on which base it is allowed in.)  Instead of doing the exclusive-or
     operation, the bits being combined are either subtracted or added;
     if the result is out of range for the base being used, the base is
     added or subtracted from the result until it is in range.  (For the
     subtraction, the bit that was less significant is subtracted from
     the bit that was more significant in any given pair of bits, except
     for the subtraction between the most and least significant bits,
     where the most significant bit is subtracted from the least.)

   * The AND and OR operators are generalised into an entire sequence of
     operators; the number of operators available is the same as the
     base that is being used.  In base 3, the third operator is known as
     BUT; in other bases, there are no commonly accepted names for the
     extra operators, so names that reflect the notation are used here.

     The way to think of it is this: in base 2, an AND gives the result
     0 if either argument is a 0, and otherwise a 1, and likewise, an OR
     gives the result 1 if either argument is a 1, and otherwise a 0;
     they could be said to favour 0 over 1 and 1 over 0 respectively.
     In base 3, AND favours 0 over 2 over 1, OR favours 2 over 1 over 0,
     and BUT favours 1 over 0 over 2.  (The symbol for BUT is '@' (a
     'whirlpool', which is another name for the BUT operation) in Atari
     syntax, and '?' in Princeton syntax.)  The pattern continues: in
     base 4, AND favours 0 over 3 over 2 over 1, BUT favours 1 over 0
     over 3 over 2, 2BUT (written '2@' or '2?') favours 2 over 1 over 0
     over 3, and OR favours 3 over 2 over 1 over 0.  (This can be
     extended to higher bases following the same pattern, introducing
     operators '3@' or '3?', etc., to favour 3, etc., when neither AND
     (which always favours 0) nor OR (which favours the highest digit in
     the base) are available.)  All the whirlpool operators are
     controlled unary operators, which are only legal when both the base
     contains the favoured digit, and they aren't redundant to AND nor
     OR.

   * Select has its semantics modified to deal with more than one
     nonzero digit in the base.  It starts off by doing an AND (in
     whatever base is being used) between the two numbers being
     selected; then the bits of the result are sorted by the bits of the
     right-hand argument to the select, with bits corresponding to 0s in
     the right-hand argument ending up more significant than bits
     corresponding to high digits in the right-hand argument.  In base
     2, this has the same effect as a traditional-style select.

Note that the base doesn't affect anything other than variable ranges
and expressions; in particular, it doesn't affect the bit-reversal used
by Turing Tape I/O. (The tape still has characters written on it in
binary, even though the program uses a different base.)

10 Multithreading and Backtracking
**********************************

The multithreading and backtracking extensions to INTERCAL were
originally invented by Malcom Ryan, who implemented 'COME FROM'-based
multithreading as a modified version of C-INTERCAL, known as Threaded
INTERCAL, but did not implement backtracking.  (The same functionality
is implemented in C-INTERCAL today, but with different code.  Most
likely, this means that the original code was better.)  He also invented
the original version of Backtracking INTERCAL, but did not implement it;
the only known implementation is the C-INTERCAL one.  A different
version of multithreading, using 'WHILE', was implemented as part of
CLC-INTERCAL (like all extensions first available in CLC-INTERCAL, it is
most likely due to Claudio Calvelli) and then added to C-INTERCAL,
although its implications were not noticed for some time afterwards.

So nowadays, three freely-mixable threading-like extensions to INTERCAL
exist, all of which are implemented in C-INTERCAL.  (A fourth, Quantum
INTERCAL, is implemented in CLC-INTERCAL but not C-INTERCAL, and so will
not be discussed further here.)  If you're wondering about the
description of backtracking as a threading-like extension, it's
implemented with much of the same code as multithreading in C-INTERCAL,
because the INTERCAL version can be seen as roughly equivalent to
multithreading where the threads run one after another rather than
simultaneously.  (This conceptualisation is probably more confusing than
useful, though, and is also not strictly correct.  The same could
probably be said about INTERCAL as a whole, for that matter.)

10.1 Multithreading using COME FROM
===================================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.25+     version 0.05+     no

The original multithreading implementation worked by giving a new
meaning to what was previously an error condition.  If in a
multithreaded program (a program is marked as multithreaded using
options to a compiler) two or more 'COME FROM's or 'NEXT FROM's (or a
mixture of these) attempt to steal control simultaneously, the original
thread splits into multiple threads, one for each of the commands trying
to take control, and a different command gains control of the program in
each case.

From then on, all the threads run simultaneously.  The only thing shared
between threads (apart from the environment in which they run) is the
abstained/reinstated status of each command; everything else is
separate.  This means, for instance, that it's possible to change the
value of a variable in one thread, and it will not affect the
corresponding variable in other threads created this way.  Likewise,
there is a separate NEXT stack in each thread; if both a 'COME FROM' and
a 'NEXT FROM' aim at the same line, for instance, the 'NEXT FROM' thread
will end up with a NEXT stack entry that isn't in the 'COME FROM'
thread, created by the 'NEXT FROM' itself.  This is known as unwoven
thread creation; none of the threads created this way are 'woven' with
any of the other threads created this way.  (Whether threads are woven
depends on how they were created.)  If the thread being split was itself
woven with other threads, exactly one of the resulting threads after the
split is woven with the threads that the original thread was woven to,
but the rest will not be woven to anything.  (If that seems a somewhat
unusual rule: well, this is INTERCAL.)

In C-INTERCAL, there are other guarantees that can be made about unwoven
threads (that is, threads not woven to any other thread).  In
particular, they can all be guaranteed to run at approximately the same
speed; to be more precise, the number of commands that have been given
the chance to execute in any given thread will not differ by more than 2
from the number of commands that have been given the chance to execute
in any other thread that was created at the same time.  (However, 'COME
FROM's and 'NEXT FROM's can make this relationship less precise; it is
unspecified (in the technical sense that means the compiler can choose
any option it likes and change its mind on a whim without telling
anyone) whether a 'COME FROM' or 'NEXT FROM' aiming at the current
command counts towards the command total or not, thus causing the
relationship to become weaker the more of them have the chance to
execute.  In versions of C-INTERCAL from 0.27 onwards, there is a third
guarantee; that if a 'COME FROM' comes from itself, it will actually
give other threads at least some chance to run, at some speed, by
counting itself as a command every now and then; previously this
requirement didn't exist, meaning that a 'COME FROM' could block all
threads if it aimed for itself due to the speed restrictions and the
fact that 'COME FROM's need not count towards the total command count.)
Also, all commands, including any 'ONCE' or 'AGAIN' attached to the
command, are atomic; this means that it's impossible for another thread
to conflict with what the command is doing.  (In a departure from the
usual INTERCAL status quo, these guarantees are somewhat _better_ than
in most other languages that implement threading, amusingly continuing
to leave INTERCAL with the status of being unlike any other mainstream
language.)

The only way to communicate between unwoven threads is by changing the
abstention status of commands; this always affects all threads in the
program, whether woven or not.  (The combination of 'ABSTAIN' and 'ONCE'
is one way to communicate atomically, due to the atomic nature of
'ONCE'.)

If there are at least two threads, the 'GIVE UP' command ends the
current thread, rather than the current program.

10.2 Multithreading using WHILE
===============================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.27+     version 0.05+     no

The 'WHILE' command (which is not strictly speaking a command, but more
a sort of metacommand that joins commands) is a second method of
achieving multithreading.  (In CLC-INTERCAL, there are at least two
other meanings for 'WHILE', but only the one implemented in C-INTERCAL
is discussed here.)  The syntax is somewhat unusual, and consists of two
commands separated by the 'WHILE' keyword, but sharing the statement
identifier, execution chance, and any 'ONCE'/'AGAIN' keyword that may be
present.  For instance:

     (1) DO COME FROM ".2~.2"~#1 WHILE :1 <-
           "'?.1$.2'~'"':1/.1$.2'~#0"$#65535'"$
           "'"'&.1$.2'~'#0$#65535'"$#0'~#32767$#1"

(OK, maybe that's an unnecessarily complicated example, and maybe it
shouldn't have included the '/' operator which is part of another
INTERCAL extension (*note Operand Overloading::).  Still, I thought that
maybe you'd want to see how addition can be implemented in INTERCAL.)

A 'WHILE' command starts two threads (the original thread that ran that
command and a new one), one of which runs the command to the left of the
'WHILE' and one of which runs the command to the right.  Any line number
applies to the left-hand command, not the WHILE as a whole, which is a
metalanguage construct.  'NEXTING FROM', 'ABSTAINING FROM' or similar
behaviour with respect to the 'WHILE' itself is impossible, although
it's certainly possible to abstain from either of its operands (and
abstaining from the left operand has much the same effect as abstaining
from the 'WHILE' itself; the right-hand thread deliberately takes a bit
of time to get started just so that this behaviour happens).  The
right-command thread starts just before the left command is run (so
'NEXTING', etc., directly to the left command will not start that loop
in the first place); if that command finishes (which may be almost
immediately for something like a calculate command, or take a long time
for something like 'NEXT'), that thread loops and reruns that command as
long as the left command has not finished; 'COMING FROM' that command,
or a 'NEXT'/'NEXT FROM' from/aiming at that command, doesn't count as
finishing that command until it is 'RESUME'd back to (if possible; if
it's come from, that command can never end and the right-hand loop will
continue forever, or until it 'GIVE's 'UP' or the loop ends due to the
command ending later in another thread).  A 'WHILE' command itself
exists across all threads of a multithreaded program in a way; for each
left-hand command that ends (in any thread), the next time a right-hand
command of the same 'WHILE' ends it will cause the thread it's looping
in to end, regardless of whether that thread corresponds to the thread
in which the left-hand command ended.  (As well as a right-hand command
ending, there's also the possibility that it never got started; there is
a delay before the right-hand command runs during which a left-hand
command ending can prevent the right-hand thread starting in the first
place; this counts as the same sort of event as terminating a right-hand
loop, and can substitute for it anywhere a right-hand command ending is
mentioned.)  There is one exception, in that if two or more left-hand
commands end in a space of time in which no right-hand commands for that
'WHILE' ends, they together only cause one right-hand command to end.
(What, did you expect the logical and orthogonal behaviour?)

The two threads produced by a 'WHILE' (the original thread and a new
copy of it) have more in common than ordinary INTERCAL threads created
by 'COME FROM'; ordinary threads share only 'ABSTAIN'/'REINSTATE'
information, whereas the 'WHILE'-produced threads count as 'woven'
threads which also share variables and stashes.  (They still have
separate instruction pointers, separate instruction pointer stacks, such
as the NEXT stack, and separate choicepoint lists.  Overloading
information is shared, though.)  Being woven is a relationship between
two or more threads, rather than an attribute of a thread, although a
thread can be referred to as being unwoven if it is not woven to any
other thread.

Ordinary multithreading cannot create woven threads.  When threads are
created by multiple 'COME FROM's from an original thread, which was
woven with at least one other thread, one of the resulting threads
counts as the 'original' thread and remains woven; the rest are 'new'
threads which initially start out with the same data as the original,
but are not woven with anything.  Backtracking in a thread (*note
Backtracking::) causes it to unweave with any threads it may be woven
with at the time (so the data in the thread that backtracks is set back
to the data it, and the threads it was woven with at the time, had at
the time of the 'MAYBE', but the other threads continue with the same
data as before).  The only way to cause three or more threads to become
woven is with a new 'WHILE' inside one of the threads that is already
woven, which causes all the new threads to be woven together (the
weaving relationship is transitive).

10.3 Backtracking
=================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.25+     no                no

A somewhat unusual threading construct that's available is backtracking.
In case you haven't come across it before (the concept exists in other
languages but is implemented differently and usually in a less general
way), the basic idea is that instead of executing or not executing a
command, you can 'MAYBE' execute a command.  This causes the command to
be executed, but also creates a dormant thread in which the command
wasn't executed; at any time later, the program can either decide that
it liked the consequences of the command and 'GO AHEAD' and get rid of
the dormant thread, or decide that it didn't like the consquences of the
command and 'GO BACK' to the dormant thread, discarding the current one.
The dormant thread is more commonly called a 'choicepoint', that is, a
point at which a choice was made but a different choice can still be
made, and is generally not thought of as a thread at all by most
programmers.  (In case you're wondering: dormant threads are always
unwoven.)

To create a choicepoint, the statement identifier 'MAYBE' is used,
rather than the more usual 'DO' or 'PLEASE'.  (Combination statement
identifiers are still allowed, but must be in the order 'MAYBE PLEASE DO
NOT' with optionally some parts omitted, or different versions of 'NOT'
used, or both.)  Here's an example:

     MAYBE DON'T GIVE UP

When a command whose statement identifer contains 'MAYBE' is reached, it
is executed or not executed as normal, but in addition a choicepoint is
created containing the program as it is at that time.  Only 'ABSTAIN'
and 'REINSTATE', which always affect all threads in a program (even
choicepoints), can alter the values stored in the choicepoint; so in
this way, a choicepoint is also somewhat similar to the concept of a
continuation in other languages.  The choicepoint is placed on a
choicepoint stack, which is maintained separately for each thread in
much the same way that stashes and the 'NEXT' stack are.

The choicepoint does not actually do anything immediately, but if the
program doesn't like the look of where it's ended up, or it decides to
change its mind, or just wants to try all the possibilities, it can call
the 'GO BACK' command (which has no arguments, and is just the statement
identifier, optional execution chance, 'GO BACK', and optional 'ONCE' or
'AGAIN').  This causes the current thread to unweave from all other
threads and then replace itself with the thread created by the
choicepoint on top of the choicepoint stack.  The difference is that
this time, the abstention or reinstatement status of the command that
was modified with 'MAYBE' is temporarily reversed for determining
whether it runs or not (this reversal only lasts immediately after the
'GO BACK', and does not affect uses of the command in other threads or
later in the same thread), so unless it has been 'ABSTAIN'ed or
'REINSTATE'd in the meantime it will run if and only if it wasn't run
the first time.  The choicepoint stack's top entry is replaced by a
'stale' choicepoint that definitely isn't a thread; attempting to 'GO
BACK' to a stale choicepoint instead causes the stale choicepoint to be
deleted and the program to continue executing.  (This is what gives
INTERCAL's backtracking greater flexibility in some ways than some other
languages; to get backtracking without the stale choicepoints having an
effect, simply run 'COME FROM' the 'GO BACK' as the previous statement.)

Note that, though, when a thread splits into separate threads (whether
woven or unwoven), the choicepoint stack doesn't split completely, but
remains joined at the old top of stack.  The two choicepoint stacks can
add and remove items independently, but an attempt to 'GO BACK' to
before the current thread split off from any other threads that are
still running instead causes the current thread to end, although it will
'GO BACK' as normal if all other threads that split off from it or that
it split off from since the top choicepoint of the stack was created
have ended since.  This means that it's possible to backtrack past a
thread splitting and get the effect of the thread unsplitting, as long
as both resulting threads backtrack; this is another way in which
INTERCAL's backtracking is more flexible than that of some other
languages.

If, on the other hand, a program decides that it likes where it is and
doesn't need to 'GO BACK', or it wants to 'GO BACK' to a choicepoint
lower down the stack while skipping some of the ones nearer the top of
the stack, it can run the 'GO AHEAD' command, which removes the top
choicepoint on the stack, whether it's a genuine choicepoint or just a
stale one.

Both 'GO AHEAD' and 'GO BACK' cause errors if an attempt is made to use
them when the choicepoint stack is empty.

11 Operand Overloading
**********************

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.26+     version 0.05+     no

(Operand overloading in C-INTERCAL is nowhere near as advanced as it is
in CLC-INTERCAL.  This chapter only explains the partial implementation
used by C-INTERCAL; for a full implementation, see CLC-INTERCAL and its
documentation.)

Operand overloading is a method of using a onespot or twospot variable
as a substitute for an expression.  When a variable is overloaded to an
expression (which could be another variable, or something more complex),
any uses of that variable cause the expression to be substituted
instead.

At the beginning of the program, all variables stand for themselves; so
'.1' really does mean '.1', for instance.  The meaning of a variable can
be overloaded using the slat operator ('/'), which is the same in both
Princeton and Atari syntax: it is a binary operator whose left argument
must be a onespot or twospot variable and whose right argument can be
any expression.  The slat operator returns the true value of its left
argument, but as a side effect, changes the meaning of its left argument
to be its right argument.  Here is an example:

     DO .1 <- .2/'.3~.4'

The example causes '.2''s true value to be assigned to '.1' (unless of
course '.1' is read-only), but also causes '.2' from then on to actually
mean ''.3~.4'', except when it's the left operand of a slat operator.
So for instance, 'DO .1 <- .2' would actually assign ''.3~.4'' to '.1'.
Somewhat confusingly, this also works in the other direction; 'DO .2 <-
.1' would assign '.1' to ''.3~.4'', which would have the effect of
changing the values of '.3' and '.4' so that ''.3~.4'' had the correct
value, or throw an error if it couldn't manage this.  (The general rule
in this case is that any variable or constant in the expression that
overloads the variable is at risk of being changed; this is known as a
'reverse assignment'.  Code like 'DO .1 <- .1/#1' is entirely capable of
changing the value of '#1', although to protect new INTERCAL users
C-INTERCAL will refuse to carry out operations that change the value of
constants unless a command-line switch (*note -v::) is used to give it
permission.  In C-INTERCAL, changing the value of a constant only
changes meshes with that value, but in CLC-INTERCAL it can also change
non-mesh uses of that constant, so doing so is not portable anyway.)

When multiple overloading rules are in effect, they are all applied;
overloading '.1' to ''.2~.3'' and '.2' to ''.3$.4'' will cause '.1' to
refer to '''.3$.4'~.3''.  However, this expansion stops if this would
cause a loop; to be precise, overloading is not expanded if the
expansion is nested within the same expansion at a higher level (so
'.1/.2' and '.2/.1' together cause '.1' to expand to '.2', which expands
to '.1', which cannot expand any further).  In C-INTERCAL, the
expression on the right hand side of a slat is not evaluated and not
expanded by operand overloading.

'STASHING' a variable causes its overloading information to be stashed
too; 'RETRIEVING' it causes its overload rule to also be retrieved from
the stash (or any overload rule on the variable to be removed if there
wasn't one when the variable was stashed).

Overloading a onespot variable to a twospot variable or vice versa is
possible, but the results are unlikely to be predictable, especially if
a onespot variable is used to handle a twospot value.  Possible outcomes
include truncating the value down to the right bitwidth, throwing an
error if a value outside the onespot range is used, and even temporarily
handling the entire twospot value as long as it doesn't end up
eventually being assigned a value greater than twospot.

Note that reverse assignments can cause unpredictable behaviour if an
attempt is made to reverse-assign the same variable twice in the same
expression.  In particular, sequences of commands like 'DO .1 <-
.2/'.3$.3' DO .2 <- #6' are liable to succeed assigning garbage to '.3'
rather than failing as they ought to do, and likewise any situation
where a variable is reverse-assigned twice in the same expression may
assign garbage to it.  This behaviour is seen as unsatisfactory, though,
and plans exist to improve it for future versions.

12 PIC-INTERCAL
***************

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.26+     no                no

PIC-INTERCAL is a simplified version of INTERCAL designed especially for
embedded systems, designed to minimise code and data usage by INTERCAL
programs so that they can fit on devices whose memory is measured in
bytes rather than megabytes.  (It is named after the first
microcontroller for which code was successfully generated, and which
influenced the choices of commands, the PIC16F628 manufactured by
Microchip, and is most likely to be portable to other microcontrollers
in the same range.)  C-INTERCAL only compiles as far as C code when
producing PIC-INTERCAL; it is up to the user to find the appropriate
cross-compiler to translate this C into the relevant dialect of machine
code.  (Two header files in the distribution, 'src/pick1.h' and
'src/pick2.h', don't have any effect on the compiler but are referenced
by the generated code, and the intent is for the user to change them to
suit the behaviour of the PIC compiler used, because these are not as
standardised as C compilers for everyday systems.)

There are several restrictions on PIC-INTERCAL programs:

   * It's impossible to store more than one item in the STASH for any
     given variable.

   * Many errors are not checked at runtime; it is the programmer's job
     to ensure that runtime errors are avoided.  (The few errors that
     are detected will send the program into an infinite loop, as there
     is no sensible way to exit from a PIC program.)

   * Double-oh-sevens are not randomised, but instead depend merely on
     whether the probability given is greater than 50% or not.

   * The NEXT stack is limited to 16 entries rather than the usual 80.

   * 'ABSTAIN' and 'REINSTATE' still work, but cannot be computed
     'ABSTAIN's, and will not necessarily work when used to affect the
     system library or calls to it.

   * 'READ OUT' and 'WRITE IN' don't work.  (See below for a
     replacement.)

   * 'COME FROM' and 'NEXT FROM' must aim at a label, not an expression
     or gerund.

   * Multithreading and TriINTERCAL cannot be used on PICs.  (Operand
     overloading can be used, but only if your PIC cross-compiler
     supports function pointers; some don't.)

In order to provide I/O capabilities, a new command 'PIN' is available.
It controls up to 16 I/O pins on the PIC or other embedded system; an
I/O pin is capable of receiving or sending voltages to an electrical or
electronic circuit.  This explanation assumes that the device being
controlled is a PIC16F628A, and therefore has its pins in two blocks of
8 named 'PORTA' and 'PORTB'; for other microcontrollers, adapting the
code in 'src/pick1.h' is likely to be necessary to tell the compiler how
to control the I/O pins, and the way in which this done will affect
which I/O pins it is that the program will end up being able to
communicate with.

The 'PIN' command takes one twospot variable as its argument, like this:

     DO PIN :2

The twospot variable is conceptually divided into 4 blocks of 8 bits.
The highest two blocks control the directions of the pins in 'PORTB'
(most significant block) and 'PORTA' (second most significant block); a
1 on any bit means that the corresponding I/O pin should be set to send
data, and a 0 means that it should be set to receive data.  The lower
two blocks control the values on the pins that are sending (and are
ignored for receiving pins); the second least significant block controls
'PORTB' and the least significant block controls 'PORTA', with a 1
causing the program to set the output voltage to that of the
microcontroller's negative voltage supply rail, and a 0 causing the
program to set the output voltage to that of the microcontroller's
positive voltage supply rail.  (These voltages may vary on other
systems; consult your system's datasheet and the changes you made to the
header files.)  After setting the pins, the 'PIN' command then reads
them as part of the same operation, this time setting the values of the
lower blocks that are receiving, rather than setting the pins from the
lower blocks that are sending.  However, 1 and 0 bits on all bits of the
twospot variable have the opposite meaning when doing this, so that 1
means receiving/positive voltage rail and 0 means sending/negative
voltage rail.  There is no way to input without output, or vice versa,
but it's trivial to just send the same output again (which has no
effect, because the voltage on sending pins is maintained at the same
level until it is changed), or to ignore the input received.

13 CREATE
*********

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.28+     see text          no

The 'CREATE' command allows the creation of new syntax at runtime.
CLC-INTERCAL has had such a command since 1.-94.-8, but its syntax is
completely different and incompatible with the C-INTERCAL version, and
so is not documented here (see the CLC-INTERCAL documentation for more
details).  The C-INTERCAL version is only defined if the '-a' option is
used on the command line (and a runtime error E000 otherwise), because
it forces the operand overloading code to be introduced and so slows
down every variable access in the program.

The syntax of the 'CREATE' command is to write 'CREATE', then a line
label, then anything.  OK, well not quite anything; you're restricted to
syntax that is supported by the 'just-in-case' compiler that runs on
comments at compile time just in case they gain a meaning later (see
below).  The anything provides an example statement to 'CREATE';
statements which look the same (but may differ in details) are created.
Typical syntax for a 'CREATE' statement would therefore look something
like this:

     DO CREATE (5) SWITCH .1 WITH .2

There is also computed 'CREATE', working identically to ordinary
'CREATE' except that the line number is taken from an expression and the
created command must start with a letter (to avoid an ambiguity if the
expression giving the line label happens to be an array reference), with
a syntax like this:

     DO CREATE .5 SWITCH .1 WITH .2

Here, a new 'SWITCH WITH' statement (there is no such statement in
INTERCAL normally) is being created.  This command makes it possible to
do this:

     DO SWITCH .3 WITH .4

Normally that line would be an error (E000) due to being unrecognised,
but having been 'CREATE'd, it's now a real statement.  (The gerund to
affect created statements is 'COMMENT', just like before they were
created; the gerund to affect 'CREATE' itself is 'CREATION' ('CREATING'
is also allowed, but not as elegant).)  When the created statement is
encountered, it 'NEXT's to line (5), the line number specified in the
'CREATE' statement.  In order for the code there to be able to affect
the variables mentioned in the statement, the variables ':1601' (for the
first variable or expression mentioned), ':1602' (for the second
variable or expression mentioned), and so on, are 'STASH'ed and then
overloaded to the respective expressions or variables mentioned in the
created command; so ':1601' has been overloaded to mean '.3' and ':1602'
has been overloaded to mean '.4' at this point.  Then, the code at (5)
runs; if it returns via a 'RESUME #1', ':1601' and ':1602' will be
'RETRIEVE'd automatically and the program will continue from after the
created statement.  (If you do not resume to that point, say if you're
creating a flow control statement, you'll have to deal with the stashes
for the 1600-range variables yourself.)

So what syntax is available in created statements?  All the capital
letters except 'V' (which is an operator in INTERCAL) are available and
can be used freely and as many times as desired; they match themselves
literally.  However, they are not allowed to spell an INTERCAL keyword
at any point (so watch out for 'DO' and 'FROM', for instance).
Whitespace is allowed, but is ignored (both in the 'CREATE' template
statement, and in the code being created; so 'DO SW ITCH :8 WITH :50'
will also have been created).  Then, there are three groups of matchable
data: scalar variables (onespot or twospot variables, as used in the
examples above) match other scalar variables, array elements (like ',4
SUB '.5~.6'') match other array elements, and other expressions match
other other expressions.  Two matchable data may not appear
consecutively in a created command, but must be separated by at least
one capital letter (to prevent array-subscript-related ambiguities;
remember that the just-in-case compiler has to compile these statements
at compile time without knowing what they are).  The actual expressions
used in the 'CREATE' statement don't matter; they're just examples for
the runtime to match against.

It is also possible (from C-INTERCAL version 0.29 onwards) to create new
operators.  Such operators are always binary operators (that is, they
take two arguments and parse like mingle or select), and always return
32-bit results.  There are three types of legal names for such
operators, all of which are treated equivalently: lowercase letters,
punctuation marks otherwise unused in INTERCAL, and overstrikes
consisting of a character, a backspace, and another character (apart
from overstrikes already used for built-in INTERCAL operators).  The
syntax for creating an operator looks like one of these:

     DO CREATE (5) x
     DO CREATE .5 =

The arguments to the operator will be overloaded onto :1601 and :1602
(which are, like with 'CREATE'd statements, stashed before the
overloading happens), and the return value is read from :1603 (which is
stashed, then overloaded to itself).  All these three variables are
retrieved again after the operator finishes evaluating.

Note that it is a very unwise idea to use a 'CREATE'd operator in the
expression for a computed 'COME FROM' or 'NEXT FROM', because this
always leads to an infinite regress; whenever any line label is reached
(including the line label that the 'CREATE' statement pointed at), the
expression needs to be evaluated in order to determine whether to 'COME
FROM' that point, which in turn involves evaluating lines which have
labels.

Some other points: a newer 'CREATE' statement supercedes an older
'CREATE' statement if they give equivalent templates, multiple 'CREATE'
statements may aim at the same line (this is the recommended technique
for creating a statement that can handle expressions even if they're
array elements or variables; you do this by specifying multiple
templates in multiple 'CREATE' statements), and strange things happen if
a twospot variable in the 1600-range is used as an argument to a created
statement itself (because of the stash/retrieve, such a variable can
usually be read, but may not always be able to be written without the
data being lost).

14 External Calls
*****************

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.28+     no                no

C-INTERCAL has a feature allowing INTERCAL and non-INTERCAL code to be
mixed.  This is achieved by causing the non-INTERCAL programs to
participate in the INTERCAL line-numbering model.  The same feature
allows expansion libraries to be linked into the code.

To create a combined program containing INTERCAL and non-INTERCAL code,
use 'ick' as the compiler as normal, but specify both the INTERCAL and
non-INTERCAL source files on the command line, and use the '-e'
command-line option.  'ick' will invoke other compilers as necessary,
after modifying the source files accordingly.  At present, external
calls are only supported to and from C and Funge-98.

In each case, it will be the INTERCAL program that is invoked first.
(This means that it is impossible to link together more than one
INTERCAL program, but you probably don't want to, because concatenating
the programs is likely to have a similar effect.)  You can get the
INTERCAL program to 'NEXT' to the non-INTERCAL program immediately, or
the non-INTERCAL program to 'COME FROM' or 'NEXT FROM' the INTERCAL
program immediately, to obtain the effect of running the non-INTERCAL
program first.

Note that external calls are incompatible with PIC-INTERCAL and with
multithreading; note also that you must use 'gcc' as your compiler, and
GNU cpp and ld, for them to work in the current version of C-INTERCAL.

14.1 External Calls to C
========================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.28+     no                no

Linking C and INTERCAL programs is achieved by placing various
constructs into the C programs that are equivalent to various INTERCAL
constructs.  It is possible to simulate a line with a label and a dummy
command (which serves as a 'COME FROM' suckpoint and 'NEXT' target), a
command with a line label, 'NEXT', 'RESUME', and 'FORGET', and 'COME
FROM' and 'NEXT FROM'.  Onespot and twospot variables are accessible
from inside the C program, where they can be read and written; however,
the INTERCAL program cannot access any variables inside the C program
that weren't part of the INTERCAL program originally.

To prevent various logical impossibilities, there are restrictions on
where these can be used and what preparation is needed before they are
used.  Also, the semantics are not always exactly what you might expect
for technical reasons.

It should be observed that the INTERCAL link intrudes on the user
namespace.  To prevent possible namespace clashes, no identifiers
starting with 'ick_' or 'ICK_' should be used anywhere in the linked C
program for any reason, except where specified in this manual.

14.1.1 External C Call Infrastructure
-------------------------------------

For a C program to be connected to an INTERCAL program, it needs to be
marked with the correct header file, and needs to have functions marked
for communication with the INTERCAL program.

'#include <ick_ec.h>'
     The header file 'ick_ec.h' must be included using the preprocessor
     in any file which uses any of the INTERCAL external call functions,
     variables, or macros.  (Note that this file may not necessarily
     exist, or exist in the usual place; 'ick' will deal with making
     sure the correct header file is included.)  This will include
     'stdint.h' (a standard C header file, which must exist on your
     system), so that you can access INTERCAL variables (the INTERCAL
     types onespot, twospot, tail, hybrid correspond to the C types
     uint16_t, uint32_t, uint16_t*, uint32_t* respectively); also, it
     will provide the prototypes for all the functions and definitions
     for all the macros needed to use the external calls system with C.

'ICK_EC_FUNC_START'
'ICK_EC_FUNC_END'
     Many of the INTERCAL interface macros ('ick_linelabel',
     'ick_comefrom', and 'ick_nextfrom') make it possible to jump from
     an INTERCAL program to a C program.  Because C doesn't allow
     jumping into the middle of a function, there has to be some way to
     create a block of code which _can_ be jumped into.  This is what
     these two macros achieve.

     This declaration and definition:

          ICK_EC_FUNC_START(identifier)
          {
            /* code goes here */
          }
          ICK_EC_FUNC_END

     is equivalent to this:

          void identifier(void)
          {
            /* code goes here */
          }

     except that it is possible to jump from an INTERCAL program into
     the declared and defined program.  (If you need to write a
     prototype for the function early, 'void identifier(void);' is
     perfectly acceptable, but an early prototype is not required unless
     you call the function from earlier within the C code.)  Of course,
     you can substitute any identifier that's legal as a function name
     for 'identifier' (as long as it doesn't start with 'ick_' or
     'ICK_').  The resulting function is a function (for instance, you
     can take its address or call it in the usual ways); the only
     differences are that it can be jumped into from INTERCAL code and
     that it is constrained to take no arguments and return no data.
     (It can still access global and INTERCAL variables.)  If the
     function is jumped into from INTERCAL code, but then control flow
     reaches the end of the function, or the function 'return;'s but was
     not called from C, the resulting behaviour is undefined; C-INTERCAL
     will attempt to continue by some means at that point, but may fail.
     If a function is unsure whether it gained control from C or from
     INTERCAL code, it may use 'ick_return_or_resume' (described below).

     Because you are not allowed to declare two C functions with the
     same name (even in different modules), all functions declared with
     'ICK_EC_FUNC_START' must have unique names across the entire
     compilation.

14.1.2 ick_startup
------------------

It is sometimes necessary for a C program to do its own initialisation
before the INTERCAL program starts running.  To do so, it can use the
'ick_startup' macro inside a function declared with 'ICK_EC_FUNC_START';
the syntax is 'ick_startup(block)', where the argument is an expression,
statement, or compound statement to run.  The argument itself must not
contain any ick_-prefixed macros or functions except possibly
ick_create, may have side effects, and must fit the C preprocessor's
idea of what a macro argument should look like (it's more used to
parsing expressions than blocks; the general rule is to avoid commas
except when they're directly or indirectly inside parentheses or
strings).

14.1.3 ick_linelabel
--------------------

A line label is something that can be 'NEXT'ed to and 'COME FROM'.
Unlike an INTERCAL line label, it does not label a statement, and
therefore attempts to 'ABSTAIN' or 'REINSTATE' it may be errors, or may
be ignored (it's unspecified which, which means that either may happen
for any or no reason, but exactly one will happen in any given case,
although the choice might not be consistent).

The macro 'ick_linelabel(expression);' may appear anywhere a compound
statement would normally be able to appear.  (That is, it looks like a
function call being used as a standalone expression, but in fact the
places where it can appear are more limited.)  In contrast to ordinary
line labels, an expression can be used rather than just a constant;
however, the behaviour is undefined if the expression has side-effects.
Upon encountering the line label, any 'COME FROM's or 'NEXT FROM's
aiming at the line label (including 'ick_comefrom's and 'ick_nextfrom's)
will steal control from the program; 'RESUMING' after a 'NEXT FROM' will
work, but suffers from the same caveats as setjmp/longjmp do (any auto
variables that change their value between the 'NEXT FROM' and 'RESUME'
will have their value clobbered (i.e.  their value is no longer reliable
and should not be accessed)).  Note that the INTERCAL variables are
immune to this problem.  You can also avoid the problem by marking
variables as 'volatile' in the C program.

It is possible to 'NEXT' or 'ick_next' to a 'ick_linelabel', which has
the same effect as saving the 'NEXT' stack, calling the function
containing the 'ick_linelabel' and then immediately doing a C 'goto' to
an imaginary label preceding it.  Due to this possibility, an
'ick_linelabel' is only allowed within a function defined with
'ICK_EC_FUNC_START'.

14.1.4 ick_labeledblock
-----------------------

In INTERCAL programs, labels don't stand on their own, but instead label
a statement.  The difference between a standalone line label and a line
label that labels a statement is that 'COME FROM's will come from the
_label itself_ (which is before the next statement) when aiming at a
standalone line label, but the _end of the statement_ when aiming at a
labeled statement.  To achieve the same effect in C, the macro
'ick_labeledblock' is available; it can be used as
'ick_labeledblock(expression,expression)' or
'ick_labeledblock(expression,statement)'; the first argument is the
label, and the second argument is an expression or statement to label
(if an expression is labeled, it will be converted to a statement that
evaluates it for its side effects and discards the result).  It is even
permitted to label a block statement in this way.  Note, however, that
you have to contend with the C preprocessor's ideas of where macro
arguments begin and end when doing this.  Other than the position of the
'COME FROM' target created by the label, this behaves the same way as
'ick_linelabel' (so for instance, computed line labels are allowed, but
the expression that computes them must not have side effects, and it is
only allowed within a function defined with 'ICK_EC_FUNC_START').

14.1.5 ick_comefrom and ick_nextfrom
------------------------------------

The 'ick_comefrom' and 'ick_nextfrom' macros are, like the other
INTERCAL flow control macros (as opposed to functions), only allowed
within a function defined with 'ICK_EC_FUNC_START'.  They act almost
exactly like the INTERCAL statements of the same name (although note
that C statements cannot be 'ABSTAIN'ed 'FROM' even if they act the same
way as INTERCAL statements); they are written as
'ick_comefrom(expression);' and 'ick_nextfrom(expression);' respectively
(note that they must be called as statements, and cannot be used as part
of an expression).  Whenever a standalone line label is encountered
whose expression evaluates to the same number as the expression inside
the 'ick_comefrom' or 'ick_nextfrom', and that number is at most 65535,
then control will be transferred to the 'ick_comefrom' or
'ick_nextfrom', leaving a 'NEXT' stack entry behind in the case of
'ick_nextfrom'; likewise, if the end of a labeled statement, expression
or block is reached and the label has the right number.  Some caveats:
the expression need not be constant, but must not have side effects,
must not be negative, and must fit into the range of an 'unsigned long'
in the C program (and the statement will do nothing if the expression
evaluates to a value larger than 65535).  In keeping with the best C
traditions, these caveats are not checked, but instead result in
undefined behaviour if breached.

There are also versions 'ick_comefromif' and 'ick_nextfromif', which
take a second parameter, which is a condition that specifies whether
control is actually stolen from the target.  The condition may have side
effects, and is only run when the line numbers match; it should return 0
or NULL to leave control flow alone, or nonzero to steal control, and
should be either an integral type or a pointer type.  Although side
effects are allowed, the condition must not look at or alter 'auto' or
'register' variables in the enclosing function, not even if they are
also marked 'volatile'.  (Global and 'static' variables are fine,
though.)

14.1.6 ick_next
---------------

'ick_next' is a macro that acts like the INTERCAL statement 'NEXT'.
Contrary to the other INTERCAL-like macros, it can be used in any
function regardless of whether it was defined with 'ICK_EC_FUNC_START';
however, it must still be used as a statement by itself, and a call to
it looks like 'ick_next(expression);'.  The expression is the label to
'NEXT' to, and works under the same rules as the expressions for
'ick_comefrom'; it need not be constant (unlike in C-INTERCAL!), but
must not have side effects, must not be negative, must fit into the
range of an unsigned long, and is ignored if it is over 65535.  If there
happen to be multiple labels with the correct value at the time, the
compiler will 'NEXT' to one of them.  Bear in mind that there is a limit
of 80 entries to the 'NEXT' stack, and that this limit is enforced.

If the resulting 'NEXT' stack entry is 'RESUME'd to, the program will
continue after the 'ick_next' as if via 'setjmp', with all the usual
restrictions that that entails; if the resulting 'NEXT' stack entry is
forgotten, then the 'ick_next' call will never return.  (Note that the
'as if via setjmp' condition allows you to preserve the vales of 'auto'
and 'alloca'-allocated storage as long as its value has not changed
since the 'ick_next' was called, which is a significantly more lenient
condition than that normally imposed on such variables (*note External
Calls and auto::).)

14.1.7 ick_resume
-----------------

'ick_resume' is a macro, but there are few restrictions on its use; it
is permitted to use it inside an expression (but it returns void, making
this not particularly useful), and acts like a function which takes an
unsigned short argument, returns void, and has a prototype (but you
cannot take its address; if you need to be able to do that, write a
wrapper function for it).  It can be used within any function regardless
of how it was declared, and never returns; instead, it pops the
specified number of 'NEXT' stack entries and resumes execution at the
last one popped, just as the INTERCAL statement does.  This causes the
same errors as the INTERCAL statement if the number of entries popped is
zero or larger than the 'NEXT' stack.

There is also a macro 'ick_return_or_resume();'; it can only be used
inside a function defined with 'ICK_EC_FUNC_START', and is equivalent to
'return;' if the function was called from C, or 'ick_resume(1);' if the
function was called from INTERCAL.  It's therefore a safe way to return
from such a C function if you don't know how control reached it in the
first place.

14.1.8 ick_forget
-----------------

The 'ick_forget' macro removes 'NEXT' stack entries, and the
corresponding C stack entries.  It must be called as a statement by
itself, and its invocation looks like this: 'ick_forget(expr);', where
the expression is the number of 'NEXT' stack entries to forget (all of
them will be forgotten if the number is higher than the number of
entries).  The expression will be casted to an 'unsigned short'.

'ick_forget' can only be used inside a function declared with
'ICK_EC_FUNC_START'.  As it is removing stack entries both in INTERCAL
and in C, it will clobber the value of all 'auto' variables created
since the highest remaining 'NEXT' stack entry came into being (or since
the start of the program, if the 'NEXT' stack is emptied by the command)
and also deallocate all 'alloca' storage allocated since then.  It also
causes the return address of the current function to become undefined,
so that function must not return; control may leave it via 'RESUME', or
via 'COME FROM', or via 'NEXT' or 'NEXT FROM' followed by the relevant
'NEXT' stack entry being forgotten (the function is still 'running' but
suspended while the 'NEXT' stack entry still exists).  (Note that these
restrictions are stronger than those on 'RESUME'; this is because
'RESUME' preserves most of the stack, but 'FORGET' destroys parts of the
stack and therefore cannot avoid destroying the data stored there.  It
could be much worse; a previous (never released) version of the code
didn't remove those parts of the stack in many circumstances, leading to
a stack leak that caused programs to segfault after a while.)

14.1.9 ick_get/setone/twospot
-----------------------------

This class of four functions make it possible to get and set INTERCAL
scalar variables from C code.  Their prototypes are as follows:

     uint16_t ick_getonespot(unsigned short varnumber);
     void ick_setonespot(unsigned short varnumber, uint16_t newvalue);
     uint32_t ick_gettwospot(unsigned short varnumber);
     void ick_settwospot(unsigned short varnumber, uint32_t newvalue);

The program will error out with a fatal error (*note E200::) if the
variable you request is mentioned nowhere in the INTERCAL program; if
you attempt to set an 'IGNORE'd variable, the attempt will silently fail
(just as if you assigned to it in an INTERCAL program).  The get
functions are safe to use in a computed line label, so you can use them
to produce computed line labels that depend on INTERCAL variables.
('uint16_t' and 'uint32_t' are standard C data types; if your system
doesn't provide them, get better system header files.)

If you care about speed, note that .1 is the fastest variable of all to
access, and otherwise variables first mentioned near the top of the
INTERCAL program will be faster to access than variables mentioned lower
down.

14.1.10 ick_create
------------------

The 'ick_create' function (prototype: 'void ick_create(char*, unsigned
long)') allows the external calls system to be used to create new
INTERCAL syntax; to do this, you give a 'signature' representing the
syntax you want to define and a line number to the function (which are
its two arguments, respectively).  The signature defines the syntax that
you are defining; whenever that syntax is encountered within the
INTERCAL program, it will 'NEXT' to the line number you specify, which
can do various clever things and then 'RESUME' back to the INTERCAL
program (or if you're defining a flow-control operation, you might want
to leave the 'NEXT' stack entry there and do other things).  However,
note that the overloading of ':1601', etc., will still take place as in
the INTERCAL version of 'CREATE' if the '-a' option is used (*note
-a::), so care is needed when writing flow control statements that they
work both with and without the option and don't cause 'STASH' leaks
(which means no 'FORGET'ting the relevant 'NEXT' stack entry, and no
looking at 1600-range variables).  This allows the external calls system
to define whole new INTERCAL commands, with the same power as any other
programming language.

There are various restrictions on what syntax you can 'CREATE' with this
method, which are best explained by an explanation of the relevant
C-INTERCAL compiler internals.  When an INTERCAL program is compiled by
C-INTERCAL, any unrecognised statements it comes across are compiled by
a 'just-in-case' compiler that attempts to compile them anyway with no
knowledge of their syntax, just in case the syntax becomes defined
later.  (E000 (*note E000::) will be thrown when such statements are
encountered at runtime, unless the syntax has been 'CREATE'd since to
give a statement a meaning.)  For the just-in-case compiler to run, the
resulting statement must be completely unrecognised; this means that it
may contain no keywords (not even a sequence of letters that forms a
keyword, such as 'FROM' or 'DO'), it must consist only of variable
names, expressions, and capital letters other than 'V' (because 'V' is a
unary operator, so otherwise there would be ambiguity), and in which any
two variable names or expressions are separated by at least one capital
letter.  The compiler will produce a 'signature' for the unknown command
that can be defined.

A signature consists of a sequence of characters (and is represented as
a null-terminated string; the runtime makes a shallow copy of the string
and keeps it until the end of the program, so arrangements must be made
to ensure that the storage in which the string is allocated stays around
that long, but this opens up interesting possibilities in which the
signature that was actually 'CREATE'd can be modified retroactively);
whitespace is not allowed in a signature.  Capital letters can be used
(apart from 'V'), and match the same capital letters literally in the
INTERCAL syntax being created; also available are the special characters
'.,;~', which match respectively a scalar variable (a onespot or twospot
variable such as ':1'), an array variable (such as ';2'), an array
element (such as ',3 SUB #4 #5'), and an expression that isn't a
variable name and isn't an array element (such as '.4$.5').  If you want
to be able to match other things (say, to be able to match all
expressions), you will need to submit multiple signatures using multiple
calls to 'ick_create'; maybe you could write a library to do that
automatically.

'CREATE'd operators also have signatures, but of quite a different form.
The signature for a single-character operator is a lowercase u, followed
by its character code in hexadecimal (no leading zeros, and in
lowercase); the signature for an overstrike is a lowercase o, followed
by the lower relevant character code in hexadecimal, followed by a
lowercase x, followed by the higher relevant character code in
hexadecimal.

The routine that is 'NEXT'ed to will presumably want to be able to see
what in the INTERCAL program was matched by the signature, so a range of
function-like macros is provided to access that.  They must be run from
within the invocation of the function which was 'NEXT'ed into by the
created syntax (*note External Calls and auto:: for when a function
invocation ends, which could be sooner than you think when the
C-INTERCAL external calls system is used), and are undefined behaviour
when that invocation did not gain control from a 'CREATE'd statement.
Here are their effective prototypes:

     int ick_c_width(int);
     int ick_c_isarray(int);
     unsigned short ick_c_varnumber(int);
     uint32_t ick_c_value(int);
     /* These require -a to work */
     uint32_t ick_c_getvalue(int);
     void ick_c_setvalue(int, uint32_t);

The first argument to all these macros is the position of the match in
the signature (0 for the first non-capital-letter match in the
signature, 1 for the second, and so on until no more items are left in
the signature to match); specifying a position that isn't in the
signature is undefined behaviour.

'ick_c_width' returns the data type, as a width in bits, of the
expression (or the width in bits of an element of the passed in array),
and 'ick_c_isarray' returns 1 if the argument was an array variable or 0
if it was an expression (array elements and scalar variables are
expressions).  'ick_c_varnumber' returns the variable's number (for
instance 123 for '.123'), or 0 if the corresponding argument was not a
variable; in the cases where the argument was a variable, these three
functions together provide enough information to figure out which
variable (which is useful if you're writing an extension which takes a
variable name as an argument).

'ick_c_value' returns the value of the corresponding expression at the
time the 'CREATE'd command was called; 'ick_c_getvalue' is almost
equivalent, but only works if the '-a' option (*note -a::) was used
during compilation, and returns the value of the corresponding
expression now.  (The uint32_t return type is large enough to hold
either a onespot or twospot value, and will be zero-extended if the
corresponding expression had onespot type.)  'ick_c_setvalue' also
depends on '-a', and will assign to the corresponding expression (be
careful not to provide a value that is too large for it!).  In the case
that the corresponding expression is not a variable, this will attempt
to perform a reverse assignment to the expression, and can produce
ordinary INTERCAL errors if it fails.  It is not possible to redimension
an array this way, as this is assignment, not a calculate operation.

14.1.11 External Calls and auto
-------------------------------

Because the external calls system merges the INTERCAL 'NEXT' stack with
the C return value and data storage stack (note for pedants: the C
standards nowhere mandate the existence of such a stack, or even mention
one, but the restrictions stated in them imply that implementations have
to act as if such a stack existed, because of the way the scoping rules
and recursion work), the external calls system therefore has severe
effects on data that happens to be stored there.  (In INTERCAL terms,
imagine what would happen if data could be stored on the 'NEXT' stack;
if C used the more sensible system of having a 'STASH' for each
variable, these problems would never occur in the first place, instead
causing an entirely different set of problems.)  Similar considerations
apply to the common nonstandard C extension 'alloca', which dynamically
alters the size of the stack; also, in what goes below, 'register'
variables should be considered to be 'auto', because the compiler may
choose to allocate them on the stack.  Theoretical considerations would
lead one to conclude that variable-length arrays should obey most of the
same restrictions; in practice, though, it's unwise to attempt to mix
those with INTERCAL code at all, except by separating them into separate
functions which aren't flagged with 'ICK_EC_FUNC_START' and use no
'ick_'-prefixed identifiers, even indirectly.  (They may cause a compile
to fail completely because they don't mix well with 'goto'.)

In the description below, INTERCAL commands should be taken to include
the equivalent C macros.

'NEXT'/'NEXT FROM' paired with 'RESUME' have the least effect, and the
most obvious effect, on 'auto' variables in the function that was
'NEXT'ed from, which is the same effect that the standard C function
'longjmp' has.  That is, 'alloca' storage stays intact, and 'auto'
variables have their values 'clobbered' (that is, their value is no
longer reliable and should not be used) if they changed since the
corresponding 'NEXT' and are not marked as 'volatile'.  (This is a very
easy restriction to get around, because changing the values of such
variables is quite difficult without using statically-allocated pointers
to point to them (a dubious practice in any case), and 'volatile' is
trivial to add to the declaration.)

'COME FROM' has more restrictions; it deallocates all 'alloca' storage
in the function that was 'COME FROM', and functions that called it or
that called functions that called it, etc., using C calls (as opposed to
'NEXT'), and those invocations of the functions will cease to exist
(thus destroying any 'auto' variables in them), even in the case of
'COMING FROM' a function into the same function.  'auto' variables in
the function that is come into will start uninitialised, even if
initialisers are given in their declaration, and it will be a 'new'
invocation of that function.  (It is quite possible that the
uninitialised values in the 'auto' variables will happen by chance to
have the values they had in some previous invocation of the function,
though, because they are likely to be stored in much the same region of
memory; but it is highly unwise to rely on this.)  Note that 'volatile'
will not help here.  Observant or source-code-reading readers may note
that there is a mention of an 'ick_goto' in the source code to
C-INTERCAL; this is undocumented and this manual does not officially
claim that such a macro exists (after all, if it did, what in INTERCAL
could it possibly correspond to?), but if such a macro does exist it
obeys the same restrictions as 'COME FROM'.

'FORGET' is the worst of all in terms of preserving data on the stack;
it deallocates 'alloca' data and clobbers or deletes 'auto' variables in
all function invocations that have come into existence since the 'NEXT'
that created the topmost remaining 'NEXT' stack entry was called, or
since the start of the program if the 'NEXT' stack is emptied, and the
current function will continue in a new invocation.  'volatile' is
useless in preventing this, because the relevant parts of the stack
where the data were stored are deleted by the command (that's what
'FORGET' does, remove stack).  If any of these data are required, they
have to be backed up into static storage (variables declared with
'static' or global variables), or into heap storage (as in with
'malloc'), or other types of storage (such as temporary files) which are
not on the stack.  (Incidentally, suddenly deleting parts of the stack
is excellent at confusing C debuggers; but even 'RESUME' and 'COME FROM'
tend to be sufficient to confuse such debuggers.  More worrying is
probably the fact that the C standard provides a portable method for
deleting the stack like that, and in fact the external calls runtime
library is written in standard freestanding-legal C89 (with the
exception of '+printflow' debug output which requires a hosted
implementation), meaning that in theory it would be possible to split it
out to create an implementation of a C-plus-COME-FROM-and-NEXT language,
and doing so would not be particularly difficult.)

Note that INTERCAL variables are not stored on the C stack, nor are any
of the metadata surrounding them, and so are not affected unduly by
control flow operations.

14.2 External Calls to Funge-98
===============================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.29+     no                no

C-INTERCAL supports linking INTERCAL programs with Funge-98 programs (to
be precise, only Befunge-98 programs are currently supported).  However,
it does not ship with a Funge-98 interpreter, and such an interpreter
needs to be linked to the resulting program in order to run the Befunge
program.  Therefore, you need to convert a third-party Funge-98
interpreter to a library usable by C-INTERCAL before you can use this
part of the external calls system (*note Creating the Funge-98
Library::); however, this only has to be done once.

Once the library has been created, you can link an INTERCAL program with
a Befunge-98 program by invoking 'ick' like this:

     ick -e intercalprogram.i befungeprogram.b98

You can link no more than one Befunge-98 program at once (just like you
can link no more than one INTERCAL program at once).  Also, the INTERCAL
program must come first on the command line.

It is legal to link INTERCAL, C, and Befunge-98 simultaneously; however,
the identifiers used in the third-party Funge-98 interpreter have not
been mangled to avoid collisions, and therefore problems may be caused
if the C program uses the same identifiers as the Funge-98 interpreter.

14.2.1 Creating the Funge-98 Library
------------------------------------

Before external calls to Funge-98 can be used, the relevant library must
be compiled.  (After the library has been compiled, then you will need
to reinstall C-INTERCAL; however, you will not need to recompile
C-INTERCAL.)

At present, only the cfunge Funge-98 interpreter
(<https://launchpad.net/cfunge/+index>) can be converted into a library
suitable for use by C-INTERCAL; also, doing this is only supported on
POSIX systems (although if someone gets it to work on DOS/Windows, the
author of this manual would be interested to hear about it).  Also, a
source-code distribution (rather than a binary distribution) is needed.
One way to obtain the latest cfunge sources is via the bzr
version-control system, using the following command (correct as of the
time of writing, but as always, links can become dead):

     bzr branch lp:cfunge

(As a licensing note, note that cfunge is licensed under the GNU General
Public licence version 3, whereas C-INTERCAL is licensed under version 2
and all later versions of that licence; although these terms are
obviously compatible with each other, you must ensure yourself that your
program has appropriate licensing terms to allow a GPLv3 library to be
linked to it.)

Once you have downloaded the cfunge sources, you need to compile them
into a library suitable for use with C-INTERCAL (note that this is a
somewhat different process to compiling them into a standalone Funge-98
interpreter).  There is a script provided in the C-INTERCAL distribution
to do this, 'etc/cftoec.sh'.  It must be run in the 'etc' subdirectory
of the C-INTERCAL distribution (i.e.  the directory the script itself is
in), and must be given the path to the root directory of the cfunge
source distribution (that is, the directory that contains the 'src',
'lib' and 'tools' subdirectories of that distribution) as its only
argument.  Note that it may give some compiler warnings on compilation;
my experience is that warnings about C99 inlining can be safely ignored
(they reflect a deficiency in 'gcc' itself that luckily seems to be
irrelevant in this case), but other warnings may indicate problems in
the exact versions of the sources that you downloaded (and errors
definitely indicate such problems).

Once the library has been created, it will appear as the new file
'lib/libick_ecto_b98.a' in the C-INTERCAL distribution (the cfunge
distribution will be left unchanged); reinstalling C-INTERCAL will
install this file to its proper location.  (It is also in a valid
location to be able to be run if you aren't installing C-INTERCAL but
instead just running it from the distribution's directory.)

14.2.2 The IFFI Fingerprint
---------------------------

This section will not make much sense to a non-Funge programmer;
therefore, if you are not used to Funge, you probably want to skip it.

To a Funge program, the external calls interface is accessed via a
Funge-98 'fingerprint' defined by the interpreter.  The name of the
fingerprint is 0x49464649, or as text, 'IFFI'.

When a program formed by linking INTERCAL and Befunge-98 is run, the
first thing that happens is some internal INTERCAL initialisation which
is not visible to either program, and then initialisation routines
specified in the Befunge-98 program run (if an initialisation routine is
also specified in a linked C program using ick_startup, it is
unspecified whether the C or Befunge-98 initialisation happens first.)
In the Befunge program, the initialisation routine consists of
everything that happens until the 'Y' command in the 'IFFI' fingerprint
is run; the author of the Funge-98 must load the 'IFFI' fingerprint
themselves during this initialisation to access that command.  (This is
so that the Befunge program ends up complying with the Funge-98
standard; commands not defined in that standard cannot be used until a
fingerprint is loaded.)  During initialisation, no commands from the
'IFFI' fingerprint may be used except 'Y' and 'A'.  (If a different
command is used, 'C', 'M', and 'X' remove the arguments they would use
from the stack (if any) but otherwise do nothing, and the other commands
in the 'IFFI' fingerprint reflect.)

After the 'Y' command is called, the INTERCAL program starts running; in
order for the Befunge program to regain control, it has to be 'NEXT'ed
to from the INTERCAL program, or 'COME' or 'NEXT FROM' the INTERCAL
program, or contain the line label to which syntax in the INTERCAL
program was 'CREATE'd.  (In other words, the normal INTERCAL ways of
transferring information between parts of a program.)  In order to do
this, therefore, line labels and INTERCAL control flow statements must
be placed into the Befunge program.

Code like 'COME FROM (100)' is a single statement in INTERCAL, but
several statements in Funge-98; therefore, some method of telling the
interpreter where to start executing to look for 'COME FROM's, 'NEXT
FROM's, and line labels is needed.  The method used by C-INTERCAL is
that of the 'marker'; a marker is represented by character 0xB7 (a
mid-dot in Latin-1) in the input Funge-98 program, but is transformed to
a capital 'M' by 'ick'.  (The reason for using a special character for a
marker and transforming it rather than just using 'M' is to prevent
occurences of 'M' in comments and string literals, etc., having an
effect on the control flow of the program.)  Whenever a 'NEXT' or line
label is encountered (in the INTERCAL program, the Funge program or
elsewhere), the Funge program is executed starting from each marker in
each cardinal direction to look for line labels or 'COME'/'NEXT FROM's
respectively.  Therefore, 'COME FROM (100)' is written in Funge-98 as
'Maa*C' (where the M is a marker in the source code), and likewise the
line label '(100)' would be written as 'Maa*L'.  (This code can be
written in any cardinal direction, that is left to right, top to bottom,
right to left, or bottom to top, but not diagonally or flying.)  There
are likely to be unused directions from markers, which will be evaluated
too; you can (and must) close these off by reflecting code execution
back into that marker, another marker, or a non-marker 'M'.  Note also
that a marker remains in Funge-space even if the 'M' on the same square
is deleted (the marker itself is not visible to the 'g' command,
though).

Here are the commands in the 'IFFI' fingerprint:
'A'
     This command pops a line number and then an 0"gnirts"-format string
     from the stack; they are used as the line number and signature to
     'CREATE' syntax in the INTERCAL program; for details of the format
     of the signature, see *note ick_create::.  Although using this
     command during speculative execution works, doing so is not
     recommended; if the target line number for 'CREATE'd syntax is
     changed during speculative execution to find the line that that
     syntax corresponds to, its effect is delayed until after the
     original line is found and execution continues from that point.
     (Side effects during speculative execution are never recommended,
     because they might or might not be optimised away.)
'C'
     During speculative execution to find 'COME FROM's and 'NEXT FROM's,
     pops a line label off the top of the stack and does a 'COME FROM'
     that location.  During speculative excution to find line labels,
     pops the top of the stack and ends that particular speculative
     execution as a failure.  When not doing speculative execution, pops
     and discards the top element of the stack.
'D'
     This command must only be used when the Funge program is executing
     a 'CREATE'd command, and allows access to the arguments that
     command has.  It pops an integer off the top of the stack, and
     treats it as an argument position (0-based, so 0 refers to the
     first argument, 1 refers to the second, and so on).  Note that
     providing an invalid argument number, or running this command when
     not implementing a 'CREATE'd command, leads to undefined behaviour
     (possibly a reflection, possibly a segfault, possibly worse).

     The command pushes information about the argument chosen onto the
     stack; the following information is pushed from bottom to top:
        * The data type of the argument, in bits (16 if the argument was
          a onespot variable or expression of onespot type, and 32 if
          the argument was a twospot variable or expression of twospot
          type).  Note that this is under the C-INTERCAL typing rules,
          rather than the INTERCAL-72 typing rules (that is, select's
          type is always that of its right argument no matter how many
          bits are actually selected).
        * 1 if the argument is an array variable, 0 if it is a scalar
          value.
        * 0 if the argument is not a variable, or the variable's number
          if it is (e.g. '.123' would push 123 here, but '.1~.2' would
          push 0).
        * The argument's value at the time that the 'CREATE'd
          instruction was called.
        * The argument's value now, or alternatively a repeat of the
          previous stack element if '-a' (*note -a::) was not used.
          (Without '-a', the information needed to re-evaluate the
          expression is not available.)
'F'
     During speculative execution, this command reflects; otherwise,
     this command pops an integer from the top of stack, and 'FORGET's
     that many 'NEXT' stack entries (or all of them if the argument
     given is negative).
'G'
     This command pops an integer from the top of stack.  If it is
     positive, the value of the onespot variable whose name is the
     popped integer is pushed onto the stack; if it is negative, the
     value of the twospot variable whose name is minus the popped
     integer is pushed onto the stack; and if it is zero, the command
     reflects.  If the referenced variable is not in the INTERCAL
     program at all, this causes an INTERCAL error due to referencing a
     nonexistent variable.
'L'
     During speculative execution to find 'COME FROM's and 'NEXT FROM's,
     this command pops and discards the top stack element, then ends
     that speculative execution.  During speculative execution to find a
     line label, this command pops an integer from the top of stack and
     succeeds with that integer as the line label (that is, it is
     possible to 'NEXT' to an 'L' in the Funge program if a marker,
     followed by code to push the correct line number onto the stack,
     precedes that 'L').  When not doing speculative execution, the
     integer on the top of the stack is used as a line label (assuming
     it is in the range 1-65535, otherwise it is popped and discarded),
     and a search is made for 'COME FROM's and 'NEXT FROM's aiming for
     that line label (including in the INTERCAL program and the Befunge
     program itself, as well as programs in any other language which may
     be linked in).  Note that just as in INTERCAL, it is possible to
     'NEXT' to a line label which has a 'COME FROM' aiming for it, in
     which case the 'COME FROM' will come from that line label as soon
     as the 'NEXT' transfers control to it.
'M'
     Does nothing if not in speculative execution, or ends the current
     speculative execution with failure.  (This is so that code like
           v
          >M5C
           ^
     does exactly the same thing as 'COME FROM (5)', even when, for
     instance, it is entered from the left in the Funge program, rather
     than gaining control from the line label '(5)'.)
'N'
     During speculative execution, reflects.  Otherwise, pops the top
     stack element, interprets it as a line label, and 'NEXT's to that
     line label (this may start speculative execution to look for line
     labels, but might not if it isn't needed, for instance if the line
     label in question is in the INTERCAL program or in a C program
     linked to the Befunge program).
'R'
     During speculative execution, reflects.  Otherwise, pops the top
     stack element, removes that many items from the 'NEXT' stack, and
     'RESUME's at the last item removed.  (If the top stack element was
     zero, negative, or too large, this will cause a fatal error in the
     INTERCAL program.)
'S'
     Pops a variable number (interpreted as onespot if positive, or
     minus the number of a twospot variable if negative) and an integer
     from the stack, and sets the referenced variable to the integer.
     This reflects if an attempt is made to set the nonexistent variable
     0, causes a fatal error in the INTERCAL program if an attempt is
     made to set a variable that doesn't exist there, and does not set
     read-only variables (but pops the stack anyway).  If the integer is
     too high for the variable it is being stored in, only the least
     significant 16 or 32 bits from it will be used; and likewise, if it
     is negative, it will be treated as the two's complement of the
     number given.
'V'
     Pops a 'CREATE'd argument index and an integer from the top of
     stack.  (This is undefined behaviour if not in the implementation
     of a 'CREATE'd statement, or if the referenced argument does not
     exist; as with the 'D' instruction, 0 refers to the first argument,
     1 to the second, and so on.)  If the '-a' option is not used, this
     command does nothing; otherwise, the value of the argument will be
     set to the integer.  (This involves doing a reverse assignment if
     the argument is a non-variable expression, as usual, and causes a
     fatal error in the INTERCAL program if the reverse assignment is
     impossible or an attempt is made to assign a scalar to an array.)
'X'
     This is identical to 'C', except that it does a 'NEXT FROM' rather
     than a 'COME FROM'.

As with external calls to C, terminating any program involved (whether
the INTERCAL program with 'GIVE UP', the Befunge program with '@' or
'q', or a C program with 'exit()') causes all programs involved to
terminate, and likewise a fatal error will end all programs with an
error.

One final point which is probably worth mentioning is that flow control
instructions only record the IP's position and direction, nothing else;
so for instance, if the stack is modified in one part of the code, those
modifications will remain even after a 'RESUME', for instance.

14.3 Miscellaneous External Calls
=================================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.29+     no                no

It is possible to specify other information to the external calls system
by using the filename list after all the options are given.  To be
precise, certain filename patterns are recognised and used to change the
options that are used to compile the externally-called files.

The '.c99' extension is treated identically to '.c', except that it
causes the file with that extension to be preprocessed as C99 (the more
modern version of the C standard, the older C89 is more common), and
that all C files involved will be compiled and linked as C99.  (This
corresponds to '-std=c99' in 'gcc'.)  Likewise, the '.c11' extension can
be used to indicate C11.

The '.a' extension indicates that an object-code library should be
linked in to the final program.  This is most commonly used to link in
the maths library 'libm.a' and other such system libraries.  If the
filename is of the form 'lib*.a', then the file will be searched for in
the standard directories for libraries on your system, and also where
the C-INTERCAL libraries are stored (which may be the same place);
otherwise, the current directory will be searched.  (Specifying 'libm.a'
on the command line corresponds to passing '-lm' to 'gcc'.)

14.4 Using External Calls
=========================

Whatever language your source files are written in, when '-e' is used
(*note -e::), the compiler will go through much the same steps.

First, the INTERCAL program specified is compiled into a C program that
uses the INTERCAL external call conventions for its control flow
operations.  The resulting '.c' file will be left behind in the same
directory (even if '-g' isn't used); if you look at it, you'll see the
'#include <ick_ec.h>' line, and the other hallmarks of an external call
program (for instance, INTERCAL 'NEXT's will translate into slightly
modified 'ick_next's; the modification is simply to allow the correct
line number to be displayed in case of error).

After that, the resulting files are preprocessed twice.  First, the C
preprocessor is run on the files; then, a special C-INTERCAL
'preprocessor' is run on the files.  ('Preprocessor' is a bit of a
misnomer here, as it's near the end of the compilation process;
'postprocessor' would likely be more accurate, or maybe
'interprocessor'.)  Its job is to fix line labels between the gotos that
are used to implement jumping into the middle of a C function, to assign
unique numbers to things that need them, and to keep track of which
functions need to be checked for line labels and for 'COME FROM's and
'NEXT FROM's.  The resulting file will have the extension '.cio'; it is
almost human-readable, especially if you run it through a C code
indenter, and consists of C code (which might be a thin wrapper around
some other language) and instructions to 'gcc'.  The '.cio' file will be
left behind for you to look at, if you like.

Once the '.cio' files have been produced, 'gcc' is used to compile all
the '.cio' files and link them together into an executable; the
executable will have the same name as the INTERCAL source, minus any
extension (and on DJGPP, assuming that its version of 'gcc' could handle
the resulting command line (not necessarily guaranteed), a '.exe'
extension is added), and will consist of all the C files linked together
with the INTERCAL.  Any functions named 'main' in the C files will be
deleted; likewise, if there is a name clash between any two functions,
the one in the file named earlier on the command line will be used.
There is presumably some use for this feature, although I haven't
figured out what it is yet.

Extending this to other compiled languages is mostly a problem of
determining how they fit into the INTERCAL control structure, which is
not a trivial task, and of figuring out how to link them to C code,
which in some cases is trivial (especially if the language is one that
'gcc' can compile!)  and in other cases is very difficult.  If anyone
has any ideas of new languages that could be added to the external calls
system, feel free to contact the current C-INTERCAL maintainer with
suggestions or patches.

14.5 Expansion Libraries
========================

INTERCAL-72       C-INTERCAL        CLC-INTERCAL      J-INTERCAL
------------------------------------------------------------------------
no                version 0.28+     no                no

The C-INTERCAL distribution comes with libraries that can be used to
extend its capabilities; they are implemented using the external call
mechanism, and are in effect standard files to include using that
mechanism.  To use an expansion library, give the '-e' option to 'ick'
(note that this means you cannot use them with the debugger or profiler,
nor with multithreaded or backtracking programs), and specify the
expansion library's name at the end of the command line (or to be
precise, anywhere after the initial INTERCAL file).  The libraries
themselves are written in C and have a '.c' extension, and are
human-readable; C-INTERCAL will look for them in the same places as it
looks for the system library (including in the current directory, so you
can test your own expansion libraries without having to install them).

Expansion libraries use C identifiers which start with the string
'ick_my_' (this is not used by the compiler, and is explicitly not
affected by the prohibition on identifiers starting 'ick_' when writing
an expansion library), and use line labels in the range (1600) to
(1699).  (Most programs will be avoiding this range anyway, because it's
inside the (1000) to (1999) range reserved for the system library, but
the system library doesn't use it, in much the same way that the
identifiers used are inside the range reserved for the compiler, but the
compiler doesn't use them.)

Expansion libraries are available from C-INTERCAL version 0.28;
CLC-INTERCAL has a similar concept (that of 'preloads'), but implemented
a completely different way.

syslibc
-------

'syslibc' is an implementation of the base-2 INTERCAL system library in
C (*note System Libraries::); using it in programs running in other
bases is accepted by the compiler, but likely to produce unpredictable
results.  When using this expansion library, you also need to give the
'-E' option (*note -E: -E+.) so that the main system library is not
included, or it will be used in preference to the expansion library.
All documented features of the INTERCAL base-2 system library are
implemented, but most undocumented features are not, so INTERCAL
programs which relied on them (dubious behaviour in any case) will not
work with 'syslibc'.  The main reason to use this library is to increase
the speed of an INTERCAL program; however, note that the speed gains in
arithmetic will be accompanied by the performance penalty of using the
external calls infrastructure, unless you were already using it.

compunex
--------

As an example of using 'ick_create', a very simple expansion library is
provided to enable a computed NEXT capability, by defining a new command
'COMPUNEX'.  It is used as 'DO .1 COMPUNEX' (allowing any expression in
place of the .1), and is similar to an ordinary 'NEXT', but has two
limitations: it takes up two 'NEXT' stack entries, and the top one
should not be 'RESUMEd' past or forgotten (thus it isn't a particularly
useful command, except maybe to produce the equivalent of something like
function pointers).  By the way, note that C-INTERCAL avoids computed
'NEXT' mainstream for much the same way that CLC-INTERCAL avoids 'NEXT'
altogether; it makes things too easy.  This example is provided mostly
just to demonstrate the syntax, and the care that needs to be taken with
implementing flow control operators.

'compunex' is double-deprecated; an alternative is the following
sequence of commands involving computed 'CREATE':

     DO CREATE .1 ABC
     DO ABC

This sequence emulates all features of 'NEXT' (although it has different
gerunds and is two statements, not one), making it much more useful for
simulating computed 'NEXT' than 'COMPUNEX' is.  (There's no need to
avoid forgetting the return value; although this skips the 'CREATE'
cleanup, none is required because the created statement 'ABC' (any other
statement would do just as well) takes no arguments.)

15 Differences to Other Compilers
*********************************

The C-INTERCAL compiler exists in a world of several other compilers.

Differences to the Princeton compiler
-------------------------------------

The Princeton compiler was the first INTERCAL compiler available, and
compiled INTERCAL-72.  Using 'convickt' (*note convickt::) to translate
its programs from the original EBCDIC to Latin-1 or Atari-syntax ASCII
is required to run them under the C-INTERCAL compiler, but apart from
that there should be no problems; everything that that compiler can do
can be reproduced by C-INTERCAL, even including some of its bugs.  The
only potential problems may be where constructs were nonportable or
dubious to begin with (such as the 'IGNORE'/'RETRIEVE' interaction), or
where commands intended to be syntax errors were used in the program but
have a meaning in C-INTERCAL.  For extra portability, it's possible to
use the '-t' compiler option to 'ick' (*note -t::) to tell it to
interpret the program as INTERCAL-72, but as C-INTERCAL's dialect of
INTERCAL is basically backward-compatible anyway this mostly serves to
check newer programs for compatibility with older compilers.

Differences to the Atari compiler
---------------------------------

The Atari compiler was an uncompleted implementation of INTERCAL-72,
optimistically pre-described in some 1982 additions to the original
INTERCAL-72 manual.  Despite the implementation's never actually
existing, the documentation of the syntax provided a model for
C-INTERCAL.  If any Atari 800 INTERCAL source code actually existed,
there would be no need to use 'convickt' on it.

Differences to J-INTERCAL
-------------------------

The J-INTERCAL compiler is an implementation of INTERCAL written in Java
that compiles INTERCAL into Java (and so has a similar relationship with
Java to that of the C-INTERCAL compiler (which is written in C and
compiles into C) with C). J-INTERCAL has much the same feature set as
older versions of C-INTERCAL, with a few changes (such as the addition
of Esperanto and error messages coming up in different situations).
J-INTERCAL programs should run fine on C-INTERCAL without trouble (as it
is also an Atari syntax compiler), except in nonportable cases such as
'IGNORE'/'RETRIEVE' interaction.

Differences to CLC-INTERCAL
---------------------------

The CLC-INTERCAL compiler is the most modern INTERCAL compiler apart
from C-INTERCAL (both compilers are maintained and updated every now and
then as of the time of writing, so which is more modern is normally a
matter of when you happen to check).  Unlike the other three compilers
mentioned above, it has a quite significant feature set, including many
features not implemented or only partially implemented in C-INTERCAL,
and is responsible for the origin of many of the features added in more
recent versions of C-INTERCAL.  Generally speaking, a CLC-INTERCAL
program that uses its advanced features is unlikely to run on
C-INTERCAL, or vice versa, whatever you do (apart from completely
rewriting the more advanced parts of the program).

However, there are certain steps that can be taken to transfer less
advanced programs from one compiler to the other.  First, translate the
program to Latin-1 Princeton syntax (if translating from CLC-INTERCAL to
C-INTERCAL) or Atari syntax (if translating from C-INTERCAL to
CLC-INTERCAL), maybe using 'convickt', if necessary.  (Note that here
the program is being translated to the syntax that is not default for
the target compiler.)  Then use command-line arguments to switch the
compiler into the correct emulation mode for the other compiler;
C-INTERCAL uses the options '-xX', and on CLC-INTERCAL this is done by
selecting the appropriate preloads, or by changing the program's file
extension to '.ci'.  In each case other options may be needed to turn on
various extensions (maybe '-m' or '-v' if translating to C-INTERCAL,
maybe the preload for gerund-based 'COME FROM' if translating to
CLC-INTERCAL), and if translating to CLC-INTERCAL you need to append the
system library to your program yourself because CLC-INTERCAL doesn't
load it automatically.

In the case of very simple programs, or if you want to spend the effort
in translating compiler-specific code from one compiler to another, you
may be able to work without emulation options.  (This is a good target
to aim for, in any case.)  In such a case, you would do nothing other
than possibly edit the program to be more portable and a possible
character set and syntax change using 'convickt'.  If you need
compiler-specific code, you may be able to detect the compiler in the
code itself and adapt accordingly; making use of the 'IGNORE'/'RETRIEVE'
interaction is one way to do this, as it differs between C-INTERCAL,
J-INTERCAL, and CLC-INTERCAL.  The other things to watch out for when
doing this are that CLC-INTERCAL needs an explicit option to enable the
use of 'NEXT', that CLC-INTERCAL doesn't load the system library itself
(you need to manually append it to the end of the program) and that you
probably shouldn't number a line (666) unless you know what you're
doing, because that line number has a special meaning in CLC-INTERCAL.

PART IV: APPENDICES AND INDICES
*******************************

Appendix A Character Sets
*************************

The following table explains the equivalences between the various
character sets used for INTERCAL: 7-bit ASCII Atari syntax, 5-bit Baudot
Princeton syntax, 8-bit EBCDIC Princeton syntax, and 8-bit Latin-1
Princeton syntax.  (The Baudot and EBCDIC are the CLC-INTERCAL versions,
which are used by INTERCAL compilers but basically nowhere else.)  The
characters themselves are not shown in the table below, because they
would have to be shown in some syntax, which would be misleading.
(Atari syntax is used throughout this manual; you could convert from
that, assuming you have an ASCII table handy.)  You can also use the
'convickt' command-line tool to translate INTERCAL programs from one
format to another (*note convickt::).  Note that Baudot has more than
one 'shift state'; the shift state (1, 2, 3, or 4) is written before the
hexadecimal code for each character, and * represents a character
available in every shift state.  To change from one shift state to
another, use character 1f to change from shift states 3 or 4 to 1, or
from 1 or 2 to 2, and character 1b to change from shift states 1 or 2 to
3, or from 3 or 4 to 4.

Atari   Baudot   EBCDIC   Latin-1
------------------------------------
09      N/A      09       09
0a      * 02     0a       0a
0d      * 08     0d       0d
20      * 04     40       20
21      3 0d     4f       21
22      3 11     7f       22
23      4 06     7b       23
24      4 01     4a       a2
25      4 1c     6c       25
26      3 1a     50       26
27      3 0b     7d       27
28      3 0f     4d       28
29      3 12     5d       29
2a      4 09     5c       2a
2b      4 03     4e       2b
2c      3 0c     6b       2c
2d      3 03     60       2d
2e      3 1c     4b       2e
2f      3 1d     61       2f
30      3 16     f0       30
31      3 17     f1       31
32      3 13     f2       32
33      3 01     f3       33
34      3 0a     f4       34
35      3 10     f5       35
36      3 15     f6       36
37      3 07     f7       37
38      3 06     f8       38
39      3 18     f9       39
3a      3 0e     7a       3a
3b      3 1e     5e       3b
3c      4 0f     4c       3c
3d      4 07     7e       3d
3e      4 12     6e       3e
3f      4 0c     65       a5
40      3 19     6f       3f
41      1 03     c1       41
42      1 19     c2       42
43      1 0e     c3       43
44      1 09     c4       44
45      1 01     c5       45
46      1 0d     c6       46
47      1 1a     c7       47
48      1 14     c8       48
49      1 06     c9       49
4a      1 0b     d1       4a
4b      1 0f     d2       4b
4c      1 13     d3       4c
4d      1 1c     d4       4d
4e      1 0c     d5       4e
4f      1 18     d6       4f
50      1 16     d7       50
51      1 17     d8       51
52      1 0a     d9       52
53      1 05     e2       53
54      1 10     e3       54
55      1 07     e4       55
56      1 1e     e5       56
57      1 12     e6       57
58      1 1d     e7       58
59      1 15     e8       59
5a      1 11     e9       5a
5b      4 10     9e       5b
5c      4 05     N/A      5c
5d      4 13     5a       5d
5e      4 0d     6a       7c
5f      4 15     7c       40
60      N/A      N/A      60
61      2 03     81       61
62      2 19     82       62
63      2 0e     83       63
64      2 09     84       64
65      2 01     85       65
66      2 0d     86       66
67      2 1a     87       67
68      2 14     88       68
69      2 06     89       69
6a      2 0b     91       6a
6b      2 0f     92       6b
6c      2 13     93       6c
6d      2 1c     94       6d
6e      2 0c     95       6e
6f      2 18     96       6f
70      2 16     97       70
71      2 17     98       71
72      2 0a     99       72
73      2 05     a2       73
74      2 10     a3       74
75      2 07     a4       75
76      2 1e     a5       76
77      2 12     a6       77
78      2 1d     a7       78
79      2 15     a8       79
7a      2 11     a9       7a
7b      4 0a     9c       7b
7c      4 1e     fe       N/A
7d      4 11     dc       7d
7e      4 0b     a1       7e

Appendix B convickt
*******************

A variety of character sets have historically been used to represent
INTERCAL programs.  Atari syntax was designed specifically for use with
ASCII-7, and all Atari-syntax-based INTERCAL compilers accept that
character set as possible input.  (C-INTERCAL also accepts Latin-1 and
UTF-8.)  However, the story is more complicated with Princeton syntax;
the original Princeton compiler was designed to work with EBCDIC, but
because modern computers are often not designed to work with this
character set other character sets are often used to represent it,
particularly Latin-1.  The CLC-INTERCAL compiler accepts Latin-1, a
custom dialect of EBCDIC, Baudot, and a punched-card format as input;
C-INTERCAL can cope with Latin-1 Princeton syntax, but for the other
character sets, for other compilers, or just for getting something
human-readable, it's useful to have a conversion program.  'convickt' is
an INTERCAL character set conversion program designed with these needs
in mind.

The syntax for using 'convickt' is

     convickt INPUTSET OUTPUTSET [PADDING]

(that is, the input and output character sets are compulsory, but the
parameter specifying what sort of padding to use is optional).

The following values for INPUTSET and OUTPUTSET are permissible:

'latin1'
     Latin-1, or to give it its official name ISO-8859-1, is the
     character set most commonly used for transmitting CLC-INTERCAL
     programs, and therefore nowadays the most popular character set for
     Princeton syntax programs.  Because it is identical to ASCII-7 in
     all codepoints that don't have the high bit set, most of the
     characters in it can be read by most modern editors and terminals.
     It is also far more likely to be supported by modern editors than
     EBCDIC, Baudot, or punched cards, all of which have fallen into
     relative disuse since 1972.  It is also the only input character
     set that C-INTERCAL supports for Princeton syntax programs.  It
     uses 8 bit characters.

'ebcdic'
     EBCDIC is an 8-bit character set that was an alternative to ASCII
     in 1972, and is the character set used by the original Princeton
     compiler.  Unfortunately, there is no single standard version; the
     version of EBCDIC used by 'convickt' is the one that CLC-INTERCAL
     uses.  It is the default input character set that CLC-INTERCAL uses
     (although more recent versions of CLC-INTERCAL instead try to guess
     the input character set based on the input program.)

'baudot'
     Baudot is a 5-bit character set with shift codes; therefore when
     storing it in a file on an 8-bit computer, padding is needed to
     fill in the remaining three bits.  The standard Baudot character
     set does not contain all the characters needed by INTERCAL;
     therefore, CLC-INTERCAL uses repeated shift codes to add two more
     sets of characters.  'convickt' uses the CLC-INTERCAL version of
     Baudot, so as to be able to translate programs designed for that
     compiler; however, standard Baudot is also accepted in input if it
     contains no redundant shift codes, and if the input contains no
     characters not in standard Baudot, the output will be written so
     that it is both correct standard Baudot and correct CLC-INTERCAL
     Baudot for those characters.

'atari'
     This option causes 'convickt' to attempt a limited conversion to or
     from Atari syntax; this uses ASCII-7 as the character set, but also
     tries to translate between Atari and Princeton syntax at the
     character level, which is sometimes but not always effective.  For
     instance, '?' is translated from Atari to Princeton as a yen sign,
     and from Princeton to Atari as a whirlpool ('@'); this sort of
     behaviour is often capable of translating expressions
     automatically, but will fail when characters outside ASCII-7
     (Atari) or Latin-1 (Princeton) are used, and will not, for
     instance, translate a Princeton 'V', backspace, '-' into Atari '?',
     but instead leave it untouched.  ASCII-7 is a 7-bit character set,
     so on an 8 bit computer, there is one bit of padding that needs to
     be generated; note, however, that it is usual nowadays to clear the
     top bit when transmitting ASCII-7, which the 'printable' and 'zero'
     padding styles will do, but the 'random' style may not do.

When using a character set where not all bits in each byte are
specified, a third argument can be given to specify what sort of padding
to use for the top bits of each character.  There are three options for
this:

Option      Meaning
-----------------------------------------------------------------
printable   Keep the output in the range 32-126 where possible
zero        Zero the high bits in the output
random      Pad with random bits (avoiding all-zero bytes)

Note that not all conversions are possible.  If a character cannot be
converted, it will normally be converted to a NUL byte (which is invalid
in every character set); note that this will prevent round-tripping,
because NUL is interpreted as end-of-input if given in the input.  There
is one exception; if the character that could not be converted is a tab
character, it will be converted to the other character set's
representation of a space character, if possible, because the two
characters have the same meaning in INTERCAL (the only difference is if
the command is a syntax error that's printed as an error message).  (The
exception exists to make it possible to translate existing INTERCAL
source code into Baudot.)

Appendix C Optimizer Idiom Language
***********************************

One file in the C-INTERCAL distribution ('src/idiotism.oil') is written
in Optimizer Idiom Language, a programming language designed especially
for expressing optimizer idioms for INTERCAL in an easily editable form
(well, at least it's easier than the unmaintainable set of idioms
hard-coded in C that were used in previous versions of the INTERCAL
compiler).

C.1 OIL Basics
==============

The structure of an OIL file consists of a sequence of idioms.  An
optimizer idiom looks for a certain pattern in an expression (which
could be an INTERCAL expression, or an expression that has already been
partly optimized and therefore contains some non-INTERCAL operators),
and replaces it with a replacement that's 'simpler' in some sense (in
the case of C-INTERCAL, 'simpler' is interpreted to mean 'compiles into
a faster or smaller executable when run through a C compiler').  When an
OIL program acts on an input INTERCAL file, it keeps on matching idioms
to simplify expressions, until none of the idioms act any more (and if a
situation occurs where idioms can keep matching indefinitely, the
compiler goes into an infinite loop; so don't allow that to happen); at
present, the idioms are tried from left to right, from the leaves of an
expression to its root, and from the start of the OIL file to the end;
but don't rely on that, because it's subject to change (and gets
confusing when you think about what happens when the program actually
does a replacement).  Anyway, the point is that if an idiom can match an
expression, and another idiom doesn't change it first, then the idiom
will be matched against that part of the expression eventually, and the
program won't end until there are no idioms that match the optimized
expression.

At present, the only place that OIL is used in the C-INTERCAL compiler
is when the '-O' option (*note -O: -O+.) is used in base 2.  (Syntax is
planned to extend OIL to higher bases, and some of this is documented
and even implemented, but there's no way to use it.)  The idioms are
read from the file 'src/idiotism.oil' during the compilation of the
C-INTERCAL from sources; you can change the idioms, but you will then
have to recompile the distribution (and if you are using the 'config.sh'
method, also reinstall, but that will be pretty fast.)

C.2 OIL Syntax
==============

An OIL file is encoded as an ASCII text file using no codepoints outside
the range 0-127; using 10 for newline (as on a UNIX or Linux system) is
always acceptable, but using 13 then 10 (as is common on Windows or DOS)
for newline is acceptable only if your C compiler recognizes that as a
newline.  I have no idea what happens if you use just 13 on an Apple
computer on which that is the common newline convention.

Comments can be given anywhere in the file by writing lines starting
with semicolons (known as hybrids to INTERCAL programmers).  It's also
possible to write a semicolon after part of a line to comment out the
rest of the line.  Inside braced C expressions, comments can be given
anywhere whitespace would be allowed by placing them between '/*' and
'*/' (in such cases, the comments will be copied verbatim to the C
temporary files used when building the C-INTERCAL compiler, where your C
compiler will ignore them).  Whitespace is ignored nearly everywhere;
the only places it isn't ignored are in the middle of a decimal
constant, inside square brackets, immediately after one of the
characters '.:#_}', and anywhere that C doesn't allow it in quoted C
code.  (This means that you can even place it inside operators like &&
if you like, as long as they're part of OIL code and not C code,
although doing this is not recommended.)  If you use whitespace in a
situation where it isn't ignored, that's almost certainly an error.

Idioms are grouped into groups of idioms by placing an identifier in
square brackets before the group; this follows the rules for C
identifiers, except that there's a maximum length of 30 characters.
This identifier is the 'name' of the group, which has no effect except
on optimizer debug output; for that matter, the only effect a group has
is that all idioms in the group look the same in optimizer debug output,
because they have the same name.  It's recommended that idioms only have
the same name if they are the same idiom, possibly written in several
ways.  For example, a shift by 0 has no effect and may as well be
removed from the output; the way to express this in OIL is:

     [nullshift]
     (_1 >> #0)->(_1)
     (_1 << #0)->(_1)

Here, nullshift is the name of the group of idioms, and two idioms are
given; one which removes a null rightshift, and one which removes a null
leftshift.

As the example above shows, the syntax of an idiom itself is

     (pattern)->(replacement)

The parentheses here are actually part of the pattern and/or
replacement, and as such sparks (apostrophes) or rabbit-ears (double
quotes) can be used instead; they're shown in the syntax because the
outer layer of parenthesising is always required.  Both the pattern and
replacement are OIL expressions, although they both have their own
special syntax elements as well.

C.3 OIL Expressions
===================

An OIL expression is built around subexpressions connected by infix
binary operators and/or preceded by prefix unary operators, the same way
as in C or INTERCAL (although unary operators must be entirely before
their argument; the one character later position is not allowed.)  As in
INTERCAL, there is no operator precedence; expressions must be very
fully bracketed to show unambiguously what the precedences must be, and
then more so; for instance, bracketing marks must be placed around the
argument of a unary operator in most circumstances.  Bracketing of
expressions can be done with parentheses, sparks (apostrophes) or
rabbit-ears (double-quotes).

The following unary and binary operators are allowed in OIL expressions:

'$'            INTERCAL mingle
'~'            INTERCAL select
'&16'          INTERCAL unary AND (16-bit)
'V16'          INTERCAL unary OR (16-bit)
'?16'          INTERCAL unary XOR (16-bit)
'^16'          INTERCAL unary sharkfin (16-bit)
'@16'          INTERCAL unary whirlpool (16-bit)
'@216..@516'   INTERCAL unary generalised whirlpool (16-bit)
'&32'          INTERCAL unary AND (32-bit)
'V32'          INTERCAL unary OR (32-bit)
'?32'          INTERCAL unary XOR (32-bit)
'^32'          INTERCAL unary sharkfin (32-bit)
'@32'          INTERCAL unary whirlpool (32-bit)
'@232..@532'   INTERCAL unary generalised whirlpool (32-bit)
'&'            C binary bitwise AND
'|'            C binary bitwise OR
'^'            C binary bitwise XOR
'+'            C addition
'-'            C subtraction
'*'            C multiplication
'/'            C integer division
'%'            C modulus
'>'            C greater than
'<'            C less than
'~'            C unary bitwise complement
'!='           C not equals operator
'=='           C equals operator
'&&'           C logical AND
'||'           C logical OR
'>>'           C bitwise rightshift
'<<'           C bitwise leftshift
'!'            C unary logical NOT

(Note that in some cases two operators are expressed the same way, but
that this doesn't matter because one is unary and the other is binary so
that there can't be any ambiguity, only confusion.  Also note that
unlike INTERCAL unary logic operators, OIL unary logic operators must
have a bitwidth stated.)

It hasn't yet been explained what operands these operators have to
operate on; the syntax for those depends on whether it's a pattern or
replacement that the expression is representing.

C.4 OIL Patterns
================

Patterns are simply OIL expressions; the expressions match either
original INTERCAL input or expressions produced by earlier idioms.  Each
operator must match the same operator in the (possibly
partially-optimised) input; the operands themselves are pattern
templates specifying what operands in the input they can match.

One special simple form of match is possible: '#NUMBER', where NUMBER is
in decimal, matches a constant with that value.  (Unlike in INTERCAL,
this constant is not limited to being a onespot value; it is, however,
limited to being at most twospot, as are all operands and intermediate
values in OIL.)

Otherwise, an operand consists of the following parts, written in order:

  1. A character to specify the data type of what's being matched.
     Usually, this will be '_' to specify that any data type can be
     matched.  In a few cases, you may want to use '.' or ':' to specify
     that you only want to match a onespot or twospot value respectively
     (that is, 16- or 32-bit).  You can also use '#'; this specifies a
     value that can be any width, but must be known to be a constant
     with a known value at optimize time (either because it was
     hardcoded as a constant originally or because a constant was
     produced there by the optimizer, for instance via a constant
     folding optimization).

  2. Optionally, an expression in braces ('{' and '}').  This expression
     is written in C, not OIL (as are all expressions in braces), and
     puts an extra condition on whether the pattern matches.  The exact
     meaning of this will be explained later.

  3. A reference number, which must be one decimal digit long.  A
     reference number of 0 causes the operand to be discarded
     immediately after matching; normally, you will want to specify a
     positive reference number.  Two operands with the same reference
     number must be exactly the same for the pattern to match (for
     instance, both references to the same variable, or identical
     subexpressions).  The reference number also allows the operand to
     be referenced by C expressions on other operands and by
     replacements.  Reference numbers must be unique within the idiom
     (unless two or more reference numbers are deliberately the same so
     that the operands they reference have to be identical to produce a
     match), and they are scoped only as far as the containing idiom;
     they don't carry from one idiom to another.

Note that syntax like '#2' is ambiguous given what comes so far; the
first interpretation is the one that is taken in practice, and if the
second interpretation is wanted the operand should be expressed as
'#{1}2', using a no-op braced expression to tell them apart.  This
particular no-op is recommended because it's detected and optimized by
the 'OIL' compiler.

Braced expressions, which must be written purely in C, add extra
conditions; they must return nonzero to allow a possible match or zero
to prevent one.  They can reference the following variables and
functions:

'c'
'cNUMBER'

     This accesses a calculation made automatically by the compiled OIL
     program to identify which bits of the operand can possibly be set,
     and which ones cannot be.  'c' by itself refers to the operand to
     which the braced expression is attached; if a number is given, it
     refers to another node (the number is interpreted as a reference
     number).  The actual value of 'c' is a 32-bit unsigned integer,
     each bit of which is true, or 1, if there is any chance that the
     corresponding bit of the operand might be 1, and false, or 0, if
     it's known for certain that the corresponding bit of the operand is
     0.

     For instance:

          _{!(c&4294901760LU)}1

     The constant given here is FFFF0000 when expressed in hexadecimal;
     the point is that the expression matches any operand that is known
     to have a value no greater than 65535.  Unless the operand is the
     argument to a unary AND, this check generally makes more sense than
     explicitly specifying '.' rather than '_', because it will identify
     both 16- and 32-bit values as long as they're small enough to fit
     into a onespot variable.  This code could, for instance, be used to
     check that an argument to a mingle must be small enough before
     optimising it (this is important because an optimisation shouldn't
     optimise an error - in this case, an overflowing mingle - into a
     non-error).

'x'
'xNUMBER'

     'x' is like 'c', and refers to operands in the same way, except
     that it can only refer to an operand marked with '#'.  It holds the
     value of that constant (a 32-bit unsigned integer), which will be
     known to the optimizer at optimize time.  One common use of this is
     to detect whether a constant happens to be a power of 2, although
     there are many other possibilities that may be useful.

'r'

     When inside a loop, 'r' is the value of the loop counter.  (It's
     almost certainly a mistake if you have a loop but don't reference
     the loop counter at least once, and usually at least twice, within
     the loop.)  *Note OIL Loops::.

'and16'
'and32'
'or16'
'or32'
'xor16'
'xor32'
'iselect'
'mingle'

     These are all functions with one argument (apart from iselect and
     mingle, which each take two arguments); they exist so that INTERCAL
     operators can be used by C expressions.  They all take unsigned
     longs as input and output, even if they are onespot operators.
     Note that it's entirely possible for these to cause a compile-time
     error if used on invalid arguments (such as mingling with an
     operand over 65535), or to silently truncate an invalid argument
     down to the right number of bits; both of these should be avoided
     if possible, so the optimiser should check first to make sure that
     it doesn't use any of these functions on invalid arguments.

'xselx'

     This function returns its argument selected with itself; so
     'xselx(c)' is shorthand for 'iselect(c,c)'.  When the argument is
     very complicated, this can save a lot of space in the original OIL
     program.

'setbitcount'

     This function simply returns the number of bits with value 1 in its
     argument.  This is sometimes useful with respect to various
     select-related optimisations, and can be a useful alternative to
     having to take logarithms in various situations.

'smudgeright'
'smudgeleft'

     The 'smudgeright' function returns its argument but with all the
     bits less significant than the most significant bit with value 1
     set to 1; likewise, 'smudgeleft' returns its argument with all the
     bits more significant than the least significant bit with value 1
     set to 1.

Note that all OIL calculation is done internally using unsigned 32-bit
numbers, and C expressions you write should do the same.  The practical
upshot of this is that you should write 'LU' after any constant you
write in C code; if you don't do this, you are reasonably likely to get
compiler warnings, and the resulting program may not work reliably,
although the OIL compiler itself will not complain.

Here's a more complicated example of an optimizer operand:

     #{!(x&2863311530LU)&&iselect(x,1431655765LU)==
       xselx(iselect(x,1431655765LU))}3

It helps to understand this if you know that 2863311530 in hexadecimal
is AAAAAAAA and 1431655765 in hexadecimal is 55555555.  (It's worth
putting a comment with some frequently-used decimal constants in an OIL
input file to help explain what these numbers mean and make the code
more maintainable.)  The operand matches any constant integer which has
no bits in common with AAAAAAAA, and for which if any bit in common with
55555555 is set, all less significant bits in common with that number
are also set.

C.5 OIL Replacements
====================

Replacements have much the same syntax as patterns.  The expressions are
parsed in much the same way; however, one peculiarity of replacements is
that bitwidths must be specified.  INTERCAL has a typecaster that
figures out whether each expression is 16 bits or 32 bits wide, but it
runs before the optimizer, and as the optimizer can produce expressions
whose bitwidths don't obey INTERCAL's rules, this information needs to
be inserted somehow in a replacement.  In C-INTERCAL, it usually doesn't
matter what the bitwidth is, and in cases where it doesn't matter the
normal operators ('$', '~', and so on) can be used.  (The bitwidth of
the entire replacement may be different from the bitwidth of the
original, thus leading to, say, a 32-bit unary logical operation applied
to a "16-bit" argument; but this is not a problem, as it just means that
there's an implied typecast in there somewhere.)  In cases where it does
matter (due to C-INTERCAL's lenient interpretation of bitwidth on mingle
inputs, the only place it matters is in the input to INTERCAL unary
logical operators), both the bitwidth of the operator and the argument
on which it operates must be explicitly given, and given as the same
value; to set the bitwidth of an operator's result, simply write the
bitwidth (16 or 32 for onespot and twospot respectively) immediately
after the operator; for instance, '!=32' will generate a not-equals
operation with a 32-bit bitwidth.  If an operator's width is set to 16,
and during the course of execution of the optimized program, a value
that doesn't fit into 16 bits is encountered, that's undefined behaviour
and anything might happen (most likely, though, the program will just
act as though its width had been set to 32 bits instead); this error
condition is not detected.  Also note that operators like '&32' already
have a bitwidth specified, so specifying '&3232' (or worse, '&3216') is
not allowed.

Replacement operands are simpler than pattern operands, because there
are only a few forms they can take.

'_NUMBER'
'.NUMBER'
':NUMBER'

     This tells the optimiser to copy the operand or expression with
     reference number NUMBER to this point in the replacement used for
     the expression matched by the pattern.  The three forms are
     identical; the last two are provided for aesthetic reasons (it can
     look better and be clearer to match '.1' in the pattern with '.1'
     in the replacement, for instance).  You cannot use '#NUMBER' here
     to copy in a constant from the left-hand side, though, nor
     '#{1}NUMBER', because the first means something else and the second
     is undefined behaviour (that is, no behaviour for the second case
     has been specifically implemented in the compiler and therefore its
     behaviour is unpredictable and subject to change in future
     versions); use '_NUMBER' to copy over a constant with an unknown at
     optimizer compile time (but known at optimize time) value from the
     left hand side, as you can do with any other operand being copied.

'#NUMBER'

     Insert a constant with the literal value NUMBER here.

'#{EXPRESSION}0'

     Calculate the value of EXPRESSION (a C expression, which can
     reference the same variables and functions as a C expression in a
     pattern can; see *note C functions in OIL::) and insert a constant
     with the calculated value here.  (That is, a value is calculated at
     optimise-time and the resulting value is therefore constant at
     runtime.)

As an example, here's an idiom that moves C bitwise AND operations
inside leftshifts.  (This is useful because if the optimizer has
generated a large sequence of mixed ANDs and bitshifts, moving all the
ANDs to one end allows them to be clumped together and optimized down to
one AND, whilst the shifts can all be combined into one large shift.)

     ((_1 << #{1}2) & #{1}3)->((_1 & #{x3>>x2}0) << _2)

C.6 OIL Loops
=============

When writing idioms, sometimes instead of using very complicated
expressions to try to match multiple situations at once it's easier to
have a separate idiom for each possible situation; for instance, it's
easier to write idioms for right-shift by 1, right-shift by 2,
right-shift by 3, etc., rather than a general idiom to rightshift by any
amount.  When the idioms follow a pattern, as they will do in basically
every case of this sort, it's possible to automatically generate them
using a loop.  For instance, idioms to optimize a one-bit rightshift and
a two-bit rightshift are:

     (_1~#{xselx(x)<<1==x&&x}2)->((_1&_2)>>#1)
     (_1~#{xselx(x)<<2==x&&x}2)->((_1&_2)>>#2)

Adding a loop to automatically generate the idioms, and placing a name
for the group of idioms at the start, produces the following code:

     [rshift]
     <#1-#31
     (_1~#{xselx(x)<<r==x&&x}2)->((_1&_2)>>#{r}0)
     >

That's 31 different idioms, generated with a loop.  As the above example
shows, a loop starts with '<#NUMBER-#NUMBER' and ends with '>'; a
different idiom is generated for each possible value of the loop counter
'r' in the range given by the opening line of the loop.  Loops must be
placed around idioms, but inside a group of idioms.  Note the use of
'#{r}0' to generate a constant whose value is equal to the value of the
loop counter.

C.7 OIL Tips
============

Here are some tips for the best use of OIL:

   * The OIL compiler has a few deficiencies, such as error messages
     that don't give you much of an idea of what you did wrong (to
     compensate for this, it does give a reasonably accurate line and
     character number where the error happened), limits on things like
     how deep expressions can be nested and how many idioms are allowed
     (if you hit the first, you should really break it up into smaller
     idioms if possible, and if you hit the second, increase 'MAXTOFREE'
     in oil.y; this isn't a limit on the number of idioms but on the
     number of strings that are allocated internally to process the
     idioms), and lack of error checking (invalid OIL may produce errors
     in the OIL compiler, or cause the output C code to contain errors
     or warnings, or may even appear to work).

   * When you have symmetrical operators in an idiom (like C binary
     logical operators), you need to write the idiom both ways round (in
     the same group of idioms, preferably), or write another idiom to
     standardise the format first; the first method can get very tedious
     when there are many symmetrical operators in an idiom, and the
     second is prone to optimizer loops and subtle errors (both methods
     have been used in the provided 'idiotism.oil' file).

   * Idioms should preferably be as general as possible, broken down
     into many separate idioms rather than all as one big idiom, and
     match the smallest part of the expression being optimized that is
     necessary for the idiom to be correct in all circumstances; all of
     these help to improve the performance of the optimizer in terms of
     what it can optimize.

   * If a program's optimizing incorrectly, or you just want to see how
     the optimizer deals with a particular program, it's possible to
     debug the optimizer by giving the '-h', '-H', or '-hH' (*note -h::)
     switch to the C-INTERCAL compiler, which will cause debug
     information to be output on stderr.  '-h' will show the initial and
     final expressions for each expression that was given as input to
     the optimizer, as well as a list of all optimizations used, in a
     language that's a sort of mix of C, INTERCAL, and OIL; '-H' will do
     the same, and also show the intermediate stages in the
     optimization.  '-hH' is like '-H', but produces its output entirely
     in C, so that the various intermediate stages can be tried with a C
     compiler, or for people who are fed up of reading INTERCAL.  '-H'
     can be a useful learning resource for people who want to understand
     how a particular INTERCAL expression works.

   * Make sure that the optimizer doesn't change a statement from a
     run-time error into something that silently succeeds!  Checking
     which bits can and can't be 1 is one good way to avoid this,
     especially with mingles.  Likewise, don't optimise a run-time error
     into a compile-time error (although creating a compile-time warning
     in this situation is fine).

   * You can help!  If you find an idiom that the optimizer isn't
     optimizing correctly, feel free to add it, or multiple idioms that
     come to the same thing, to 'idiotism.oil'.  In such a case, it
     would help other users if you would submit your new optimizer idiom
     to the project (*note Reporting Bugs::); this will help other users
     and future releases of INTERCAL, and also has a chance of allowing
     other users to check your new idioms to see if they cause problems
     or could be written better.

C.8 OIL Example
===============

To finish off this appendix, here's an example of the power of OIL; this
is the optimization of an idiom from the INTERCAL-72 system library, as
shown with '-H'; this should give a good idea of how OIL programs work.
(All the relevant idioms are in 'idiotism.oil' as of the time of
writing.)  Note how the expression is reduced one small step at a time;
the smallness of the steps makes the optimizer more general, because if
the original expression had been slightly different, the optimizer
wouldn't have come to the same result but could have optimized it quite
a bit of the way, up to the point where the optimizations were no longer
valid; in an older version of INTERCAL, this idiom was simply hardcoded
as a special case and so slight variations of it weren't optimized at
all.  If you look at the idioms themselves, it'll also be apparent how
'c' (the record of which bits of an expression can be 1 and which bits
can't be) is important information in being able to apply an
optimization more aggressively.

     .3 <- ((((((((.3 $ 0x0) ~ (0x7fff $ 0x1)) $ 0x0) ~ (0x7fff $ 0x1))
     $ 0x0) ~ (0x3fff $ 0x3)) $ 0x0) ~ (0xfff $ 0xf))
     [minglefold]
     .3 <- ((((((((.3 $ 0x0) ~ 0x2aaaaaab) $ 0x0) ~ (0x7fff $ 0x1)) $
     0x0) ~ (0x3fff $ 0x3)) $ 0x0) ~ (0xfff $ 0xf))
     [lshift16]
     .3 <- ((((((((((.3 >> 0x0) & 0x7fff) << 0x1) | 0x0) $ 0x0) ~
     (0x7fff $ 0x1)) $ 0x0) ~ (0x3fff $ 0x3)) $ 0x0) ~ (0xfff $ 0xf))
     [noopor]
     .3 <- (((((((((.3 >> 0x0) & 0x7fff) << 0x1) $ 0x0) ~ (0x7fff $
     0x1)) $ 0x0) ~ (0x3fff $ 0x3)) $ 0x0) ~ (0xfff $ 0xf))
     [minglefold]
     .3 <- (((((((((.3 >> 0x0) & 0x7fff) << 0x1) $ 0x0) ~ 0x2aaaaaab) $
     0x0) ~ (0x3fff $ 0x3)) $ 0x0) ~ (0xfff $ 0xf))
     [lshift16]
     .3 <- (((((((((((.3 >> 0x0) & 0x7fff) << 0x1) >> 0x0) & 0x7fff) <<
     0x1) | 0x0) $ 0x0) ~ (0x3fff $ 0x3)) $ 0x0) ~ (0xfff $ 0xf))
     [noopor]
     .3 <- ((((((((((.3 >> 0x0) & 0x7fff) << 0x1) >> 0x0) & 0x7fff) <<
     0x1) $ 0x0) ~ (0x3fff $ 0x3)) $ 0x0) ~ (0xfff $ 0xf))
     [minglefold]
     .3 <- ((((((((((.3 >> 0x0) & 0x7fff) << 0x1) >> 0x0) & 0x7fff) <<
     0x1) $ 0x0) ~ 0xaaaaaaf) $ 0x0) ~ (0xfff $ 0xf))
     [lshift16]
     .3 <- ((((((((((((.3 >> 0x0) & 0x7fff) << 0x1) >> 0x0) & 0x7fff) <<
     0x1) >> 0x1) & 0x1fff) << 0x3) | 0x0) $ 0x0) ~ (0xfff $ 0xf))
     [noopor]
     .3 <- (((((((((((.3 >> 0x0) & 0x7fff) << 0x1) >> 0x0) & 0x7fff) <<
     0x1) >> 0x1) & 0x1fff) << 0x3) $ 0x0) ~ (0xfff $ 0xf))
     [minglefold]
     .3 <- (((((((((((.3 >> 0x0) & 0x7fff) << 0x1) >> 0x0) & 0x7fff) <<
     0x1) >> 0x1) & 0x1fff) << 0x3) $ 0x0) ~ 0xaaaaff)
     [lshift16]
     .3 <- (((((((((((((.3 >> 0x0) & 0x7fff) << 0x1) >> 0x0) & 0x7fff)
     << 0x1) >> 0x1) & 0x1fff) << 0x3) >> 0x3) & 0x1ff) << 0x7) | 0x0)
     [noopor]
     .3 <- ((((((((((((.3 >> 0x0) & 0x7fff) << 0x1) >> 0x0) & 0x7fff) <<
     0x1) >> 0x1) & 0x1fff) << 0x3) >> 0x3) & 0x1ff) << 0x7)
     [nullshift]
     .3 <- (((((((((((.3 & 0x7fff) << 0x1) >> 0x0) & 0x7fff) << 0x1) >>
     0x1) & 0x1fff) << 0x3) >> 0x3) & 0x1ff) << 0x7)
     [combinelrshift]
     .3 <- ((((((((((.3 & 0x7fff) << 0x1) & 0x7fff) << 0x1) >> 0x1) &
     0x1fff) << 0x3) >> 0x3) & 0x1ff) << 0x7)
     [andintolshift]
     .3 <- ((((((((((.3 & 0x7fff) & 0x3fff) << 0x1) << 0x1) >> 0x1) &
     0x1fff) << 0x3) >> 0x3) & 0x1ff) << 0x7)
     [combinellshift]
     .3 <- (((((((((.3 & 0x7fff) & 0x3fff) << 0x2) >> 0x1) & 0x1fff) <<
     0x3) >> 0x3) & 0x1ff) << 0x7)
     [combinelrshift]
     .3 <- ((((((((.3 & 0x7fff) & 0x3fff) << 0x1) & 0x1fff) << 0x3) >>
     0x3) & 0x1ff) << 0x7)
     [andintolshift]
     .3 <- ((((((((.3 & 0x7fff) & 0x3fff) & 0xfff) << 0x1) << 0x3) >>
     0x3) & 0x1ff) << 0x7)
     [combinellshift]
     .3 <- (((((((.3 & 0x7fff) & 0x3fff) & 0xfff) << 0x4) >> 0x3) &
     0x1ff) << 0x7)
     [combinelrshift]
     .3 <- ((((((.3 & 0x7fff) & 0x3fff) & 0xfff) << 0x1) & 0x1ff) <<
     0x7)
     [andintolshift]
     .3 <- ((((((.3 & 0x7fff) & 0x3fff) & 0xfff) & 0xff) << 0x1) << 0x7)
     [combinellshift]
     .3 <- (((((.3 & 0x7fff) & 0x3fff) & 0xfff) & 0xff) << 0x8)
     [combineand]
     .3 <- ((((.3 & 0x3fff) & 0xfff) & 0xff) << 0x8)
     [combineand]
     .3 <- (((.3 & 0xfff) & 0xff) << 0x8)
     [combineand]
     .3 <- ((.3 & 0xff) << 0x8)

Appendix D Copying
******************

The majority of the files in the C-INTERCAL distribution are licensed
under the GNU General Public License (version 2 or later), but with some
exceptions.  The files 'ick-wrap.c' and 'pickwrap.c' are licensed under
a license that allows them to be used for any purpose and redistributed
at will, and are explicitly not GPL'd.  This means that C source code
generated by the compiler has the same copyright conditions as the
original INTERCAL source.  (Note that the libraries 'libick.a' and
'libickmt.a' are GPL, though, so you cannot redistribute an executable
produced by 'ick' or by linking a C file to either of those libraries
unless the original INTERCAL source was GPL.) For similar reasons, the
expansion libraries 'syslibc.c' and 'compunex.c' are explicitly public
domain.  Also, this manual, and the files that are the source code for
creating it, are licensed under the GNU Free Documentation License
rather than the GPL, and the licenses themselves ('fdl-1-2.texi' and
'COPYING.txt') are licensed under a license that allows verbatim
redistribution but not creation of derivative works.  All other files,
though (including the 'man' pages, which are not part of _this_ manual),
are licensed under the GPL. For the full text of the GPL, see the file
'COPYING.txt' in the distribution.

D.1 GNU Free Documentation License
==================================

                      Version 1.2, November 2002

     Copyright  2000,2001,2002 Free Software Foundation, Inc.
     51 Franklin St, Fifth Floor, Boston, MA  02110-1301, USA

     Everyone is permitted to copy and distribute verbatim copies
     of this license document, but changing it is not allowed.

  0. PREAMBLE

     The purpose of this License is to make a manual, textbook, or other
     functional and useful document "free" in the sense of freedom: to
     assure everyone the effective freedom to copy and redistribute it,
     with or without modifying it, either commercially or
     noncommercially.  Secondarily, this License preserves for the
     author and publisher a way to get credit for their work, while not
     being considered responsible for modifications made by others.

     This License is a kind of "copyleft", which means that derivative
     works of the document must themselves be free in the same sense.
     It complements the GNU General Public License, which is a copyleft
     license designed for free software.

     We have designed this License in order to use it for manuals for
     free software, because free software needs free documentation: a
     free program should come with manuals providing the same freedoms
     that the software does.  But this License is not limited to
     software manuals; it can be used for any textual work, regardless
     of subject matter or whether it is published as a printed book.  We
     recommend this License principally for works whose purpose is
     instruction or reference.

  1. APPLICABILITY AND DEFINITIONS

     This License applies to any manual or other work, in any medium,
     that contains a notice placed by the copyright holder saying it can
     be distributed under the terms of this License.  Such a notice
     grants a world-wide, royalty-free license, unlimited in duration,
     to use that work under the conditions stated herein.  The
     "Document", below, refers to any such manual or work.  Any member
     of the public is a licensee, and is addressed as "you".  You accept
     the license if you copy, modify or distribute the work in a way
     requiring permission under copyright law.

     A "Modified Version" of the Document means any work containing the
     Document or a portion of it, either copied verbatim, or with
     modifications and/or translated into another language.

     A "Secondary Section" is a named appendix or a front-matter section
     of the Document that deals exclusively with the relationship of the
     publishers or authors of the Document to the Document's overall
     subject (or to related matters) and contains nothing that could
     fall directly within that overall subject.  (Thus, if the Document
     is in part a textbook of mathematics, a Secondary Section may not
     explain any mathematics.)  The relationship could be a matter of
     historical connection with the subject or with related matters, or
     of legal, commercial, philosophical, ethical or political position
     regarding them.

     The "Invariant Sections" are certain Secondary Sections whose
     titles are designated, as being those of Invariant Sections, in the
     notice that says that the Document is released under this License.
     If a section does not fit the above definition of Secondary then it
     is not allowed to be designated as Invariant.  The Document may
     contain zero Invariant Sections.  If the Document does not identify
     any Invariant Sections then there are none.

     The "Cover Texts" are certain short passages of text that are
     listed, as Front-Cover Texts or Back-Cover Texts, in the notice
     that says that the Document is released under this License.  A
     Front-Cover Text may be at most 5 words, and a Back-Cover Text may
     be at most 25 words.

     A "Transparent" copy of the Document means a machine-readable copy,
     represented in a format whose specification is available to the
     general public, that is suitable for revising the document
     straightforwardly with generic text editors or (for images composed
     of pixels) generic paint programs or (for drawings) some widely
     available drawing editor, and that is suitable for input to text
     formatters or for automatic translation to a variety of formats
     suitable for input to text formatters.  A copy made in an otherwise
     Transparent file format whose markup, or absence of markup, has
     been arranged to thwart or discourage subsequent modification by
     readers is not Transparent.  An image format is not Transparent if
     used for any substantial amount of text.  A copy that is not
     "Transparent" is called "Opaque".

     Examples of suitable formats for Transparent copies include plain
     ASCII without markup, Texinfo input format, LaTeX input format,
     SGML or XML using a publicly available DTD, and standard-conforming
     simple HTML, PostScript or PDF designed for human modification.
     Examples of transparent image formats include PNG, XCF and JPG.
     Opaque formats include proprietary formats that can be read and
     edited only by proprietary word processors, SGML or XML for which
     the DTD and/or processing tools are not generally available, and
     the machine-generated HTML, PostScript or PDF produced by some word
     processors for output purposes only.

     The "Title Page" means, for a printed book, the title page itself,
     plus such following pages as are needed to hold, legibly, the
     material this License requires to appear in the title page.  For
     works in formats which do not have any title page as such, "Title
     Page" means the text near the most prominent appearance of the
     work's title, preceding the beginning of the body of the text.

     A section "Entitled XYZ" means a named subunit of the Document
     whose title either is precisely XYZ or contains XYZ in parentheses
     following text that translates XYZ in another language.  (Here XYZ
     stands for a specific section name mentioned below, such as
     "Acknowledgements", "Dedications", "Endorsements", or "History".)
     To "Preserve the Title" of such a section when you modify the
     Document means that it remains a section "Entitled XYZ" according
     to this definition.

     The Document may include Warranty Disclaimers next to the notice
     which states that this License applies to the Document.  These
     Warranty Disclaimers are considered to be included by reference in
     this License, but only as regards disclaiming warranties: any other
     implication that these Warranty Disclaimers may have is void and
     has no effect on the meaning of this License.

  2. VERBATIM COPYING

     You may copy and distribute the Document in any medium, either
     commercially or noncommercially, provided that this License, the
     copyright notices, and the license notice saying this License
     applies to the Document are reproduced in all copies, and that you
     add no other conditions whatsoever to those of this License.  You
     may not use technical measures to obstruct or control the reading
     or further copying of the copies you make or distribute.  However,
     you may accept compensation in exchange for copies.  If you
     distribute a large enough number of copies you must also follow the
     conditions in section 3.

     You may also lend copies, under the same conditions stated above,
     and you may publicly display copies.

  3. COPYING IN QUANTITY

     If you publish printed copies (or copies in media that commonly
     have printed covers) of the Document, numbering more than 100, and
     the Document's license notice requires Cover Texts, you must
     enclose the copies in covers that carry, clearly and legibly, all
     these Cover Texts: Front-Cover Texts on the front cover, and
     Back-Cover Texts on the back cover.  Both covers must also clearly
     and legibly identify you as the publisher of these copies.  The
     front cover must present the full title with all words of the title
     equally prominent and visible.  You may add other material on the
     covers in addition.  Copying with changes limited to the covers, as
     long as they preserve the title of the Document and satisfy these
     conditions, can be treated as verbatim copying in other respects.

     If the required texts for either cover are too voluminous to fit
     legibly, you should put the first ones listed (as many as fit
     reasonably) on the actual cover, and continue the rest onto
     adjacent pages.

     If you publish or distribute Opaque copies of the Document
     numbering more than 100, you must either include a machine-readable
     Transparent copy along with each Opaque copy, or state in or with
     each Opaque copy a computer-network location from which the general
     network-using public has access to download using public-standard
     network protocols a complete Transparent copy of the Document, free
     of added material.  If you use the latter option, you must take
     reasonably prudent steps, when you begin distribution of Opaque
     copies in quantity, to ensure that this Transparent copy will
     remain thus accessible at the stated location until at least one
     year after the last time you distribute an Opaque copy (directly or
     through your agents or retailers) of that edition to the public.

     It is requested, but not required, that you contact the authors of
     the Document well before redistributing any large number of copies,
     to give them a chance to provide you with an updated version of the
     Document.

  4. MODIFICATIONS

     You may copy and distribute a Modified Version of the Document
     under the conditions of sections 2 and 3 above, provided that you
     release the Modified Version under precisely this License, with the
     Modified Version filling the role of the Document, thus licensing
     distribution and modification of the Modified Version to whoever
     possesses a copy of it.  In addition, you must do these things in
     the Modified Version:

       A. Use in the Title Page (and on the covers, if any) a title
          distinct from that of the Document, and from those of previous
          versions (which should, if there were any, be listed in the
          History section of the Document).  You may use the same title
          as a previous version if the original publisher of that
          version gives permission.

       B. List on the Title Page, as authors, one or more persons or
          entities responsible for authorship of the modifications in
          the Modified Version, together with at least five of the
          principal authors of the Document (all of its principal
          authors, if it has fewer than five), unless they release you
          from this requirement.

       C. State on the Title page the name of the publisher of the
          Modified Version, as the publisher.

       D. Preserve all the copyright notices of the Document.

       E. Add an appropriate copyright notice for your modifications
          adjacent to the other copyright notices.

       F. Include, immediately after the copyright notices, a license
          notice giving the public permission to use the Modified
          Version under the terms of this License, in the form shown in
          the Addendum below.

       G. Preserve in that license notice the full lists of Invariant
          Sections and required Cover Texts given in the Document's
          license notice.

       H. Include an unaltered copy of this License.

       I. Preserve the section Entitled "History", Preserve its Title,
          and add to it an item stating at least the title, year, new
          authors, and publisher of the Modified Version as given on the
          Title Page.  If there is no section Entitled "History" in the
          Document, create one stating the title, year, authors, and
          publisher of the Document as given on its Title Page, then add
          an item describing the Modified Version as stated in the
          previous sentence.

       J. Preserve the network location, if any, given in the Document
          for public access to a Transparent copy of the Document, and
          likewise the network locations given in the Document for
          previous versions it was based on.  These may be placed in the
          "History" section.  You may omit a network location for a work
          that was published at least four years before the Document
          itself, or if the original publisher of the version it refers
          to gives permission.

       K. For any section Entitled "Acknowledgements" or "Dedications",
          Preserve the Title of the section, and preserve in the section
          all the substance and tone of each of the contributor
          acknowledgements and/or dedications given therein.

       L. Preserve all the Invariant Sections of the Document, unaltered
          in their text and in their titles.  Section numbers or the
          equivalent are not considered part of the section titles.

       M. Delete any section Entitled "Endorsements".  Such a section
          may not be included in the Modified Version.

       N. Do not retitle any existing section to be Entitled
          "Endorsements" or to conflict in title with any Invariant
          Section.

       O. Preserve any Warranty Disclaimers.

     If the Modified Version includes new front-matter sections or
     appendices that qualify as Secondary Sections and contain no
     material copied from the Document, you may at your option designate
     some or all of these sections as invariant.  To do this, add their
     titles to the list of Invariant Sections in the Modified Version's
     license notice.  These titles must be distinct from any other
     section titles.

     You may add a section Entitled "Endorsements", provided it contains
     nothing but endorsements of your Modified Version by various
     parties--for example, statements of peer review or that the text
     has been approved by an organization as the authoritative
     definition of a standard.

     You may add a passage of up to five words as a Front-Cover Text,
     and a passage of up to 25 words as a Back-Cover Text, to the end of
     the list of Cover Texts in the Modified Version.  Only one passage
     of Front-Cover Text and one of Back-Cover Text may be added by (or
     through arrangements made by) any one entity.  If the Document
     already includes a cover text for the same cover, previously added
     by you or by arrangement made by the same entity you are acting on
     behalf of, you may not add another; but you may replace the old
     one, on explicit permission from the previous publisher that added
     the old one.

     The author(s) and publisher(s) of the Document do not by this
     License give permission to use their names for publicity for or to
     assert or imply endorsement of any Modified Version.

  5. COMBINING DOCUMENTS

     You may combine the Document with other documents released under
     this License, under the terms defined in section 4 above for
     modified versions, provided that you include in the combination all
     of the Invariant Sections of all of the original documents,
     unmodified, and list them all as Invariant Sections of your
     combined work in its license notice, and that you preserve all
     their Warranty Disclaimers.

     The combined work need only contain one copy of this License, and
     multiple identical Invariant Sections may be replaced with a single
     copy.  If there are multiple Invariant Sections with the same name
     but different contents, make the title of each such section unique
     by adding at the end of it, in parentheses, the name of the
     original author or publisher of that section if known, or else a
     unique number.  Make the same adjustment to the section titles in
     the list of Invariant Sections in the license notice of the
     combined work.

     In the combination, you must combine any sections Entitled
     "History" in the various original documents, forming one section
     Entitled "History"; likewise combine any sections Entitled
     "Acknowledgements", and any sections Entitled "Dedications".  You
     must delete all sections Entitled "Endorsements."

  6. COLLECTIONS OF DOCUMENTS

     You may make a collection consisting of the Document and other
     documents released under this License, and replace the individual
     copies of this License in the various documents with a single copy
     that is included in the collection, provided that you follow the
     rules of this License for verbatim copying of each of the documents
     in all other respects.

     You may extract a single document from such a collection, and
     distribute it individually under this License, provided you insert
     a copy of this License into the extracted document, and follow this
     License in all other respects regarding verbatim copying of that
     document.

  7. AGGREGATION WITH INDEPENDENT WORKS

     A compilation of the Document or its derivatives with other
     separate and independent documents or works, in or on a volume of a
     storage or distribution medium, is called an "aggregate" if the
     copyright resulting from the compilation is not used to limit the
     legal rights of the compilation's users beyond what the individual
     works permit.  When the Document is included in an aggregate, this
     License does not apply to the other works in the aggregate which
     are not themselves derivative works of the Document.

     If the Cover Text requirement of section 3 is applicable to these
     copies of the Document, then if the Document is less than one half
     of the entire aggregate, the Document's Cover Texts may be placed
     on covers that bracket the Document within the aggregate, or the
     electronic equivalent of covers if the Document is in electronic
     form.  Otherwise they must appear on printed covers that bracket
     the whole aggregate.

  8. TRANSLATION

     Translation is considered a kind of modification, so you may
     distribute translations of the Document under the terms of section
     4.  Replacing Invariant Sections with translations requires special
     permission from their copyright holders, but you may include
     translations of some or all Invariant Sections in addition to the
     original versions of these Invariant Sections.  You may include a
     translation of this License, and all the license notices in the
     Document, and any Warranty Disclaimers, provided that you also
     include the original English version of this License and the
     original versions of those notices and disclaimers.  In case of a
     disagreement between the translation and the original version of
     this License or a notice or disclaimer, the original version will
     prevail.

     If a section in the Document is Entitled "Acknowledgements",
     "Dedications", or "History", the requirement (section 4) to
     Preserve its Title (section 1) will typically require changing the
     actual title.

  9. TERMINATION

     You may not copy, modify, sublicense, or distribute the Document
     except as expressly provided for under this License.  Any other
     attempt to copy, modify, sublicense or distribute the Document is
     void, and will automatically terminate your rights under this
     License.  However, parties who have received copies, or rights,
     from you under this License will not have their licenses terminated
     so long as such parties remain in full compliance.

  10. FUTURE REVISIONS OF THIS LICENSE

     The Free Software Foundation may publish new, revised versions of
     the GNU Free Documentation License from time to time.  Such new
     versions will be similar in spirit to the present version, but may
     differ in detail to address new problems or concerns.  See
     <http://www.gnu.org/copyleft/>.

     Each version of the License is given a distinguishing version
     number.  If the Document specifies that a particular numbered
     version of this License "or any later version" applies to it, you
     have the option of following the terms and conditions either of
     that specified version or of any later version that has been
     published (not as a draft) by the Free Software Foundation.  If the
     Document does not specify a version number of this License, you may
     choose any version ever published (not as a draft) by the Free
     Software Foundation.

ADDENDUM: How to use this License for your documents
====================================================

To use this License in a document you have written, include a copy of
the License in the document and put the following copyright and license
notices just after the title page:

       Copyright (C)  YEAR  YOUR NAME.
       Permission is granted to copy, distribute and/or modify this document
       under the terms of the GNU Free Documentation License, Version 1.2
       or any later version published by the Free Software Foundation;
       with no Invariant Sections, no Front-Cover Texts, and no Back-Cover
       Texts.  A copy of the license is included in the section entitled ``GNU
       Free Documentation License''.

If you have Invariant Sections, Front-Cover Texts and Back-Cover Texts,
replace the "with...Texts."  line with this:

         with the Invariant Sections being LIST THEIR TITLES, with
         the Front-Cover Texts being LIST, and with the Back-Cover Texts
         being LIST.

If you have Invariant Sections without Cover Texts, or some other
combination of the three, merge those two alternatives to suit the
situation.

If your document contains nontrivial examples of program code, we
recommend releasing these examples in parallel under your choice of free
software license, such as the GNU General Public License, to permit
their use in free software.

Index
*****

This is the index of everything in this manual.  (Note that in some
versions of the manual this is called 'Main Index' to prevent it
transforming into a page called 'index.html' in the HTML version of the
manual.  The complications that that caused were really odd.)

* Menu:

* ":                                     Grouping Rules.     (line 2099)
* #:                                     Constants and Variables.
                                                             (line 2058)
* $:                                     Mingle.             (line 2207)
* %:                                     Execution Chance.   (line 1980)
* &:                                     Unary Binary Logic. (line 2320)
* ':                                     Grouping Rules.     (line 2099)
* +help:                                 Options to Generated Programs.
                                                             (line  954)
* +instapipe:                            Options to Generated Programs.
                                                             (line  978)
* +mystery:                              Options to Generated Programs.
                                                             (line 1005)
* +printflow:                            Options to Generated Programs.
                                                             (line  987)
* +printflow, enabling:                  Debug Options.      (line  820)
* +traditional:                          Options to Generated Programs.
                                                             (line  973)
* +wimpmode:                             Options to Generated Programs.
                                                             (line  962)
* ,:                                     Constants and Variables.
                                                             (line 2058)
* -@:                                    Other Options.      (line  938)
* -a:                                    Language-affecting Options.
                                                             (line  694)
* -b:                                    Language-affecting Options.
                                                             (line  641)
* -C:                                    Language-affecting Options.
                                                             (line  716)
* -c:                                    Output Options.     (line  876)
* -d:                                    Debug Options.      (line  768)
* -e:                                    Language-affecting Options.
                                                             (line  667)
* -E:                                    Language-affecting Options.
                                                             (line  679)
* -f:                                    Optimizer Options.  (line  906)
* -F:                                    Optimizer Options.  (line  913)
* -g:                                    Debug Options.      (line  775)
* -h:                                    Debug Options.      (line  785)
* -H:                                    Debug Options.      (line  785)
* -help:                                 Options to Generated Programs.
                                                             (line  954)
* -hH:                                   Debug Options.      (line  785)
* -instapipe:                            Options to Generated Programs.
                                                             (line  978)
* -l:                                    Debug Options.      (line  796)
* -m:                                    Language-affecting Options.
                                                             (line  655)
* -mystery:                              Options to Generated Programs.
                                                             (line 1005)
* -o:                                    Output Options.     (line  891)
* -O:                                    Optimizer Options.  (line  923)
* -P:                                    Language-affecting Options.
                                                             (line  721)
* -p:                                    Debug Options.      (line  804)
* -printflow:                            Options to Generated Programs.
                                                             (line  987)
* -t:                                    Language-affecting Options.
                                                             (line  689)
* -traditional:                          Options to Generated Programs.
                                                             (line  973)
* -u:                                    Debug Options.      (line  828)
* -U:                                    Debug Options.      (line  851)
* -v:                                    Language-affecting Options.
                                                             (line  703)
* -w:                                    Debug Options.      (line  820)
* -wimpmode:                             Options to Generated Programs.
                                                             (line  962)
* -X:                                    Language-affecting Options.
                                                             (line  734)
* -x:                                    Language-affecting Options.
                                                             (line  746)
* -y:                                    Debug Options.      (line  838)
* -Y:                                    Debug Options.      (line  844)
* .:                                     Constants and Variables.
                                                             (line 2058)
* .b98:                                  External Calls to Funge-98.
                                                             (line 4410)
* .b98, no external library:             Errors.             (line 1497)
* /:                                     Operand Overloading.
                                                             (line 3586)
* 16 bit overflow:                       Errors.             (line 1237)
* 32 bit overflow:                       Errors.             (line 1327)
* ::                                     Constants and Variables.
                                                             (line 2058)
* ;:                                     Constants and Variables.
                                                             (line 2058)
* ?:                                     Unary Binary Logic. (line 2320)
* @:                                     TriINTERCAL.        (line 3232)
* ^:                                     TriINTERCAL.        (line 3232)
* About this manual:                     About this manual.  (line  120)
* ABSTAIN:                               ABSTAIN and REINSTATE.
                                                             (line 2687)
* abstain, at program start:             Statement Identifiers.
                                                             (line 1929)
* abstain, during execution:             ABSTAIN and REINSTATE.
                                                             (line 2687)
* ABSTAIN, nonexistent target:           Errors.             (line 1151)
* ABSTAIN, self-abstaining:              ONCE and AGAIN.     (line 2003)
* abstained state:                       Statement Identifiers.
                                                             (line 1929)
* ABSTAINING:                            ABSTAIN and REINSTATE.
                                                             (line 2687)
* add-without-carry:                     TriINTERCAL.        (line 3232)
* AGAIN:                                 ONCE and AGAIN.     (line 2003)
* alloca:                                External Calls and auto.
                                                             (line 4323)
* ampersand:                             Unary Binary Logic. (line 2320)
* and:                                   Unary Binary Logic. (line 2320)
* and16:                                 OIL Patterns.       (line 5445)
* and32:                                 OIL Patterns.       (line 5445)
* Arabic numberals, enabling:            Options to Generated Programs.
                                                             (line  962)
* array, invalid dimension:              Errors.             (line 1202)
* array, out of bounds:                  Errors.             (line 1209)
* array, wrong dimension:                Errors.             (line 1209)
* arrays, dimensioning:                  Calculate.          (line 2496)
* arrays, subscripting:                  Array Subscript.    (line 2395)
* assigning to constants:                Language-affecting Options.
                                                             (line  703)
* assignment:                            Calculate.          (line 2496)
* Atari compiler:                        Differences to Other Compilers.
                                                             (line 4876)
* Atari syntax:                          Princeton and Atari Syntax.
                                                             (line 1860)
* Atari, character set:                  Character Sets.     (line 4950)
* auto:                                  External Calls and auto.
                                                             (line 4323)
* backtracking:                          Backtracking.       (line 3499)
* Backtracking INTERCAL:                 Multithreading and Backtracking.
                                                             (line 3312)
* backtracking, debugging:               Options to Generated Programs.
                                                             (line  987)
* backtracking, enabling:                Language-affecting Options.
                                                             (line  655)
* backtracking, not enabled:             Errors.             (line 1302)
* backtracking, out of memory:           Errors.             (line 1511)
* Baudot:                                CLC-INTERCAL I/O.   (line 2892)
* Baudot <1>:                            Character Sets.     (line 4950)
* Befunge:                               External Calls to Funge-98.
                                                             (line 4410)
* Befunge, fingerprint:                  The IFFI Fingerprint.
                                                             (line 4490)
* Befunge, installing:                   Creating the Funge-98 Library.
                                                             (line 4440)
* Befunge, marker:                       The IFFI Fingerprint.
                                                             (line 4524)
* Befunge, no external library:          Errors.             (line 1497)
* black lagoon:                          Errors.             (line 1112)
* blocks, labeled:                       ick_labeledblock.   (line 4048)
* book:                                  Unary Binary Logic. (line 2320)
* breakpoints, too many:                 Errors.             (line 1482)
* buffer overflow:                       Errors.             (line 1339)
* bugs, reporting:                       Reporting Bugs.     (line  507)
* BUT:                                   TriINTERCAL.        (line 3232)
* c:                                     OIL Patterns.       (line 5392)
* C:                                     External Calls to C.
                                                             (line 3905)
* C code, debugging:                     Debug Options.      (line  775)
* C code, leaving in place:              Debug Options.      (line  775)
* C, auto/alloca:                        External Calls and auto.
                                                             (line 4323)
* C, CREATE:                             ick_create.         (line 4208)
* C, external call infrastructure:       External C Call Infrastructure.
                                                             (line 3932)
* C, stopping after C is generated:      Output Options.     (line  876)
* C, system library:                     Expansion Libraries.
                                                             (line 4807)
* C, within OIL:                         OIL Patterns.       (line 5390)
* C-INTERCAL, distributing:              Distributing.       (line  568)
* C-INTERCAL, I/O:                       C-INTERCAL I/O.     (line 2850)
* C-INTERCAL, obtaining a copy:          Obtaining.          (line  170)
* C-INTERCAL, unpacking:                 Unpacking.          (line  196)
* C-INTERCAL, unzipping:                 Unpacking.          (line  196)
* c1--c9:                                OIL Patterns.       (line 5392)
* C11:                                   Miscellaneous External Calls.
                                                             (line 4694)
* C99:                                   Miscellaneous External Calls.
                                                             (line 4694)
* calculate:                             Calculate.          (line 2496)
* CALCULATING:                           Calculate.          (line 2496)
* calls, external:                       External Calls.     (line 3873)
* character sets:                        Princeton and Atari Syntax.
                                                             (line 1828)
* character sets <1>:                    Character Sets.     (line 4950)
* character sets, converting:            convickt.           (line 5072)
* choicepoints:                          Backtracking.       (line 3499)
* choicepoints, activating:              Backtracking.       (line 3537)
* choicepoints, creating:                Backtracking.       (line 3519)
* choicepoints, discarding:              Backtracking.       (line 3573)
* CLC-INTERCAL:                          Differences to Other Compilers.
                                                             (line 4899)
* CLC-INTERCAL compatibility mode:       Language-affecting Options.
                                                             (line  746)
* CLC-INTERCAL I/O:                      CLC-INTERCAL I/O.   (line 2892)
* clockface mode:                        Language-affecting Options.
                                                             (line  716)
* code generation, stopping at C code:   Output Options.     (line  876)
* COME FROM:                             COME FROM and NEXT FROM.
                                                             (line 2978)
* COME FROM, ambiguity:                  Errors.             (line 1349)
* COME FROM, in C:                       ick_comefrom and ick_nextfrom.
                                                             (line 4071)
* COME FROM, in Funge:                   The IFFI Fingerprint.
                                                             (line 4563)
* COME FROM, multithreading:             Multithreading using COME FROM.
                                                             (line 3340)
* COME FROM, no target:                  Errors.             (line 1318)
* command line options:                  Invoking ick.       (line  613)
* command line, showing intermediates:   Debug Options.      (line  844)
* COMMENT:                               Syntax Error.       (line 2447)
* comment:                               Syntax Error.       (line 2447)
* COMMENTING:                            Syntax Error.       (line 2447)
* COMMENTS:                              Syntax Error.       (line 2447)
* comments, OIL:                         OIL Syntax.         (line 5226)
* compatibility, CLC-INTERCAL:           Language-affecting Options.
                                                             (line  746)
* compatibility, INTERCAL-72:            Language-affecting Options.
                                                             (line  689)
* compiling, ick itself:                 Simple Installation.
                                                             (line  284)
* compiling, INTERCAL source code:       Invoking ick.       (line  613)
* compunex:                              Expansion Libraries.
                                                             (line 4824)
* computed NEXT:                         Expansion Libraries.
                                                             (line 4824)
* config.sh:                             Simple Installation.
                                                             (line  284)
* configuring:                           Simple Installation.
                                                             (line  284)
* connected threads:                     Multithreading using WHILE.
                                                             (line 3411)
* constant:                              Constants and Variables.
                                                             (line 2058)
* constant, twospot:                     Errors.             (line 1082)
* constants, assigning to:               Language-affecting Options.
                                                             (line  703)
* controlled unary operator:             TriINTERCAL.        (line 3232)
* converting between character sets:     convickt.           (line 5072)
* convickt:                              convickt.           (line 5072)
* copying conditions:                    Copying.            (line 5767)
* copyright:                             Copying.            (line 5767)
* CREATE:                                CREATE.             (line 3756)
* CREATE, enabling:                      Language-affecting Options.
                                                             (line  694)
* CREATE, in C:                          ick_create.         (line 4208)
* CREATE, in Funge:                      The IFFI Fingerprint.
                                                             (line 4551)
* CREATE, operators:                     CREATE.             (line 3832)
* CREATE, signatures:                    ick_create.         (line 4245)
* creating syntax:                       CREATE.             (line 3756)
* Debian:                                Simple Installation.
                                                             (line  370)
* debug options:                         Debug Options.      (line  762)
* debugging, C code:                     Debug Options.      (line  775)
* debugging, flow:                       Options to Generated Programs.
                                                             (line  987)
* debugging, internal errors:            Debug Options.      (line  851)
* debugging, lexical analyser:           Debug Options.      (line  768)
* debugging, multithreaded programs:     Options to Generated Programs.
                                                             (line  987)
* debugging, OIL:                        Debug Options.      (line  785)
* debugging, optimizer:                  Debug Options.      (line  785)
* debugging, parser:                     Debug Options.      (line  768)
* debugging, runtime:                    The yuk debugger.   (line 1684)
* debugging, yuk:                        The yuk debugger.   (line 1684)
* dialect options:                       Language-affecting Options.
                                                             (line  630)
* dialects of syntax:                    Princeton and Atari Syntax.
                                                             (line 1828)
* dimensioning arrays:                   Calculate.          (line 2496)
* directory problems:                    Debug Options.      (line  828)
* directory problems, source file:       Errors.             (line 1448)
* distributing C-INTERCAL:               Distributing.       (line  568)
* DJGPP:                                 Installation on DOS.
                                                             (line  389)
* DO:                                    Statement Identifiers.
                                                             (line 1929)
* dormant thread:                        Backtracking.       (line 3499)
* DOS:                                   Installation on DOS.
                                                             (line  389)
* double-oh-seven:                       Execution Chance.   (line 1980)
* dumping core on error:                 Debug Options.      (line  851)
* duplicate line label:                  Errors.             (line 1158)
* E000:                                  Errors.             (line 1073)
* E017:                                  Errors.             (line 1082)
* E079:                                  Errors.             (line 1088)
* E099:                                  Errors.             (line 1096)
* E111:                                  Errors.             (line 1103)
* E123:                                  Errors.             (line 1112)
* E127:                                  Errors.             (line 1125)
* E127, debugging:                       Debug Options.      (line  828)
* E129:                                  Errors.             (line 1137)
* E139:                                  Errors.             (line 1151)
* E182:                                  Errors.             (line 1158)
* E197:                                  Errors.             (line 1171)
* E200:                                  Errors.             (line 1178)
* E222:                                  Errors.             (line 1189)
* E240:                                  Errors.             (line 1202)
* E241:                                  Errors.             (line 1209)
* E252:                                  Errors.             (line 1219)
* E256:                                  Errors.             (line 1226)
* E256, avoiding:                        Language-affecting Options.
                                                             (line  721)
* E275:                                  Errors.             (line 1237)
* E277:                                  Errors.             (line 1248)
* E281:                                  Errors.             (line 1265)
* E333:                                  Errors.             (line 1276)
* E345:                                  Errors.             (line 1284)
* E404:                                  Errors.             (line 1293)
* E405:                                  Errors.             (line 1302)
* E436:                                  Errors.             (line 1312)
* E444:                                  Errors.             (line 1318)
* E533:                                  Errors.             (line 1327)
* E553:                                  Errors.             (line 1339)
* E555:                                  Errors.             (line 1349)
* E562:                                  Errors.             (line 1361)
* E579:                                  Errors.             (line 1371)
* E621:                                  Errors.             (line 1380)
* E632:                                  Errors.             (line 1389)
* E633:                                  Errors.             (line 1397)
* E652:                                  Errors.             (line 1411)
* E652, avoiding:                        Language-affecting Options.
                                                             (line  721)
* E666:                                  Errors.             (line 1421)
* E774:                                  Errors.             (line 1435)
* E774, disabling:                       Language-affecting Options.
                                                             (line  641)
* E777:                                  Errors.             (line 1448)
* E778:                                  Errors.             (line 1455)
* E778, debugging:                       Debug Options.      (line  851)
* E810:                                  Errors.             (line 1475)
* E811:                                  Errors.             (line 1482)
* E888:                                  Errors.             (line 1489)
* E899:                                  Errors.             (line 1496)
* E990:                                  Errors.             (line 1505)
* E991:                                  Errors.             (line 1511)
* E993:                                  Errors.             (line 1521)
* E994:                                  Errors.             (line 1529)
* E995:                                  Errors.             (line 1537)
* E997:                                  Errors.             (line 1545)
* E998:                                  Errors.             (line 1555)
* E999:                                  Errors.             (line 1564)
* E999, debugging:                       Debug Options.      (line  828)
* ears:                                  Grouping Rules.     (line 2099)
* ears, nesting limit:                   Errors.             (line 1265)
* EBCDIC:                                Character Sets.     (line 4950)
* embedded systems:                      PIC-INTERCAL.       (line 3665)
* end of file:                           Errors.             (line 1361)
* environment variables:                 Environment Variables.
                                                             (line 1013)
* EOF:                                   Errors.             (line 1361)
* errors:                                Errors.             (line 1069)
* errors and warnings:                   Errors and Warnings.
                                                             (line 1042)
* examples, OIL:                         OIL Example.        (line 5675)
* exclusive or:                          Unary Binary Logic. (line 2320)
* execution chance:                      Execution Chance.   (line 1980)
* exiting:                               GIVE UP.            (line 2942)
* exor:                                  Unary Binary Logic. (line 2320)
* expansion libraries:                   Expansion Libraries.
                                                             (line 4773)
* expressions:                           Expressions.        (line 2047)
* expressions, OIL:                      OIL Expressions.    (line 5275)
* external calls:                        External Calls.     (line 3873)
* external calls, and auto:              External Calls and auto.
                                                             (line 4323)
* external calls, Befunge:               External Calls to Funge-98.
                                                             (line 4410)
* external calls, C infrastructure:      External C Call Infrastructure.
                                                             (line 3932)
* external calls, C11:                   Miscellaneous External Calls.
                                                             (line 4694)
* external calls, C99:                   Miscellaneous External Calls.
                                                             (line 4694)
* external calls, debugging:             Debug Options.      (line  844)
* external calls, enabling:              Language-affecting Options.
                                                             (line  667)
* external calls, from Funge's view:     The IFFI Fingerprint.
                                                             (line 4490)
* external calls, Funge:                 External Calls to Funge-98.
                                                             (line 4410)
* external calls, libraries:             Miscellaneous External Calls.
                                                             (line 4694)
* external calls, miscellaneous:         Miscellaneous External Calls.
                                                             (line 4694)
* external calls, to C:                  External Calls to C.
                                                             (line 3905)
* external calls, using:                 Using External Calls.
                                                             (line 4722)
* external libraries, unavailable:       Errors.             (line 1497)
* extreme optimization:                  Optimizer Options.  (line  913)
* FDL:                                   GNU Free Documentation License.
                                                             (line 5790)
* file type, unsupported:                Errors.             (line 1555)
* fingerprint:                           The IFFI Fingerprint.
                                                             (line 4490)
* floatlib:                              floatlib.           (line 3156)
* flow control, INTERCAL-72:             NEXT FORGET and RESUME.
                                                             (line 2540)
* flow optimization:                     Optimizer Options.  (line  906)
* flow, printing:                        Options to Generated Programs.
                                                             (line  987)
* flushing:                              Options to Generated Programs.
                                                             (line  978)
* foreign functions:                     External Calls.     (line 3873)
* FORGET:                                NEXT FORGET and RESUME.
                                                             (line 2540)
* FORGET, in C:                          ick_forget.         (line 4155)
* FORGET, in Funge:                      The IFFI Fingerprint.
                                                             (line 4600)
* FORGETTING:                            NEXT FORGET and RESUME.
                                                             (line 2540)
* Free Documentation License:            GNU Free Documentation License.
                                                             (line 5790)
* functions, OIL in C:                   OIL Patterns.       (line 5390)
* Funge:                                 External Calls to Funge-98.
                                                             (line 4410)
* Funge, fingerprint:                    The IFFI Fingerprint.
                                                             (line 4490)
* Funge, installing:                     Creating the Funge-98 Library.
                                                             (line 4440)
* Funge, marker:                         The IFFI Fingerprint.
                                                             (line 4524)
* Funge, no external library:            Errors.             (line 1497)
* generated programs, options:           Options to Generated Programs.
                                                             (line  947)
* GFDL:                                  GNU Free Documentation License.
                                                             (line 5790)
* GIVE UP:                               GIVE UP.            (line 2942)
* GNU Free Documentation License:        GNU Free Documentation License.
                                                             (line 5790)
* GO AHEAD:                              Backtracking.       (line 3573)
* GO AHEAD, no choicepoint:              Errors.             (line 1293)
* GO AHEAD, not enabled:                 Errors.             (line 1302)
* GO BACK:                               Backtracking.       (line 3537)
* GO BACK, no choicepoint:               Errors.             (line 1293)
* GO BACK, not enabled:                  Errors.             (line 1302)
* goto, time-reversed:                   COME FROM and NEXT FROM.
                                                             (line 2978)
* grouping rules:                        Grouping Rules.     (line 2099)
* help with options:                     Other Options.      (line  938)
* hybrid:                                Constants and Variables.
                                                             (line 2058)
* I/O:                                   READ OUT and WRITE IN.
                                                             (line 2776)
* I/O, Baudot:                           CLC-INTERCAL I/O.   (line 2892)
* I/O, C-INTERCAL:                       C-INTERCAL I/O.     (line 2850)
* I/O, CLC-INTERCAL:                     CLC-INTERCAL I/O.   (line 2892)
* I/O, INTERCAL-72:                      INTERCAL-72 I/O.    (line 2793)
* I/O, out of memory:                    Errors.             (line 1219)
* I/O, PIC-INTERCAL:                     PIC-INTERCAL.       (line 3714)
* ick, command line options:             Invoking ick.       (line  613)
* ick, errors:                           Errors.             (line 1069)
* ick, errors and warnings:              Errors and Warnings.
                                                             (line 1042)
* ick, installing:                       Installation.       (line  158)
* ick, invoking:                         Invoking ick.       (line  613)
* ick, options:                          Invoking ick.       (line  613)
* ick, uninstalling:                     Uninstalling.       (line  472)
* ick, warnings:                         Warnings.           (line 1576)
* ick-0-29.pax.*:                        Unpacking.          (line  196)
* ick_comefrom:                          ick_comefrom and ick_nextfrom.
                                                             (line 4071)
* ick_comefromif:                        ick_comefrom and ick_nextfrom.
                                                             (line 4093)
* ick_ec.h:                              External C Call Infrastructure.
                                                             (line 3937)
* ICK_EC_FUNC_END:                       External C Call Infrastructure.
                                                             (line 3951)
* ICK_EC_FUNC_START:                     External C Call Infrastructure.
                                                             (line 3951)
* ick_forget:                            ick_forget.         (line 4155)
* ick_getonespot:                        ick_get/setone/twospot.
                                                             (line 4183)
* ick_gettwospot:                        ick_get/setone/twospot.
                                                             (line 4183)
* ick_labeledblock:                      ick_labeledblock.   (line 4048)
* ick_linelabel:                         ick_linelabel.      (line 4015)
* ick_next:                              ick_next.           (line 4107)
* ick_nextfrom:                          ick_comefrom and ick_nextfrom.
                                                             (line 4071)
* ick_nextfromif:                        ick_comefrom and ick_nextfrom.
                                                             (line 4093)
* ick_resume:                            ick_resume.         (line 4133)
* ick_return_or_resume:                  ick_resume.         (line 4145)
* ick_setonespot:                        ick_get/setone/twospot.
                                                             (line 4183)
* ick_settwospot:                        ick_get/setone/twospot.
                                                             (line 4183)
* ick_startup:                           ick_startup.        (line 4000)
* idiom:                                 OIL Syntax.         (line 5261)
* idiom optimization:                    Optimizer Options.  (line  923)
* idiotism.oil:                          OIL Basics.         (line 5186)
* IFFI:                                  The IFFI Fingerprint.
                                                             (line 4490)
* IFFI, commands:                        The IFFI Fingerprint.
                                                             (line 4549)
* IGNORE:                                IGNORE and REMEMBER.
                                                             (line 2654)
* IGNORE/RETRIEVE interaction:           STASH and RETRIEVE. (line 2629)
* IGNORING:                              IGNORE and REMEMBER.
                                                             (line 2654)
* ignorret test:                         STASH and RETRIEVE. (line 2629)
* illegal array dimension:               Errors.             (line 1202)
* illegal line label value:              Errors.             (line 1171)
* illegal opcode:                        Errors.             (line 1529)
* illegal variable number:               Errors.             (line 1178)
* impossible reverse assignment:         Errors.             (line 1248)
* initial abstention:                    Statement Identifiers.
                                                             (line 1929)
* input:                                 READ OUT and WRITE IN.
                                                             (line 2776)
* input, C-INTERCAL:                     C-INTERCAL I/O.     (line 2850)
* input, CLC-INTERCAL:                   CLC-INTERCAL I/O.   (line 2892)
* input, EOF:                            Errors.             (line 1361)
* input, in Arabic numerals:             Options to Generated Programs.
                                                             (line  962)
* input, INTERCAL-72:                    INTERCAL-72 I/O.    (line 2793)
* input, invalid:                        Errors.             (line 1371)
* installation:                          Installation.       (line  158)
* installation, Debian:                  Simple Installation.
                                                             (line  370)
* installation, simple:                  Simple Installation.
                                                             (line  284)
* installation, Ubuntu:                  Simple Installation.
                                                             (line  370)
* installation, via autoconf and make:   Simple Installation.
                                                             (line  284)
* installing, DOS:                       Installation on DOS.
                                                             (line  389)
* INTERCAL compilers:                    Differences to Other Compilers.
                                                             (line 4853)
* INTERCAL, syntax:                      Syntax.             (line 1810)
* INTERCAL-72 compatibility mode:        Language-affecting Options.
                                                             (line  689)
* INTERCAL-72, I/O:                      INTERCAL-72 I/O.    (line 2793)
* interleave:                            Mingle.             (line 2207)
* internal errors:                       Errors.             (line 1455)
* internal errors, debugging:            Debug Options.      (line  851)
* internal errors, dumping core:         Debug Options.      (line  851)
* invalid array dimension:               Errors.             (line 1202)
* invalid line label value:              Errors.             (line 1171)
* invalid variable number:               Errors.             (line 1178)
* invocation flag, unnown:               Errors.             (line 1505)
* iselect:                               OIL Patterns.       (line 5445)
* J-INTERCAL:                            Differences to Other Compilers.
                                                             (line 4886)
* labeled blocks:                        ick_labeledblock.   (line 4048)
* language-affecting options:            Language-affecting Options.
                                                             (line  630)
* Latin-1:                               Character Sets.     (line 4950)
* lexical analyser, debugging:           Debug Options.      (line  768)
* libick_ecto_b98.a:                     Creating the Funge-98 Library.
                                                             (line 4440)
* libraries:                             Expansion Libraries.
                                                             (line 4773)
* libraries, Befunge:                    Creating the Funge-98 Library.
                                                             (line 4440)
* libraries, external calls:             Miscellaneous External Calls.
                                                             (line 4694)
* libraries, Funge:                      Creating the Funge-98 Library.
                                                             (line 4440)
* line label:                            Line Labels.        (line 1891)
* line label, duplicate:                 Errors.             (line 1158)
* line label, illegal value:             Errors.             (line 1171)
* line label, in Funge:                  The IFFI Fingerprint.
                                                             (line 4614)
* line labels, C:                        ick_linelabel.      (line 4015)
* line number:                           Line Labels.        (line 1891)
* line too long:                         Errors.             (line 1421)
* loops, entire program:                 TRY AGAIN.          (line 2960)
* loops, OIL:                            OIL Loops.          (line 5579)
* make:                                  Simple Installation.
                                                             (line  284)
* make install:                          Simple Installation.
                                                             (line  284)
* marker:                                The IFFI Fingerprint.
                                                             (line 4524)
* MAXTOFREE:                             OIL Tips.           (line 5613)
* MAYBE:                                 Backtracking.       (line 3519)
* MAYBE, not enabled:                    Errors.             (line 1302)
* mesh:                                  Constants and Variables.
                                                             (line 2058)
* microcontrollers:                      PIC-INTERCAL.       (line 3665)
* mingle:                                OIL Patterns.       (line 5445)
* mingle <1>:                            Mingle.             (line 2207)
* miscellaneous external calls:          Miscellaneous External Calls.
                                                             (line 4694)
* multithreading:                        Multithreading and Backtracking.
                                                             (line 3312)
* multithreading, connected threads:     Multithreading using WHILE.
                                                             (line 3411)
* multithreading, debugging:             Options to Generated Programs.
                                                             (line  987)
* multithreading, enabling:              Language-affecting Options.
                                                             (line  655)
* multithreading, not enabled:           Errors.             (line 1302)
* multithreading, out of memory:         Errors.             (line 1511)
* multithreading, separate threads:      Multithreading using COME FROM.
                                                             (line 3340)
* N'T:                                   Statement Identifiers.
                                                             (line 1929)
* nesting limit:                         Errors.             (line 1265)
* NEXT:                                  NEXT FORGET and RESUME.
                                                             (line 2540)
* NEXT FROM:                             COME FROM and NEXT FROM.
                                                             (line 2978)
* NEXT FROM, in C:                       ick_comefrom and ick_nextfrom.
                                                             (line 4071)
* NEXT FROM, in Funge:                   The IFFI Fingerprint.
                                                             (line 4677)
* NEXT FROM, multithreading:             Multithreading using COME FROM.
                                                             (line 3340)
* NEXT FROM, no target:                  Errors.             (line 1318)
* NEXT stack:                            NEXT FORGET and RESUME.
                                                             (line 2540)
* NEXT, computed:                        Expansion Libraries.
                                                             (line 4824)
* NEXT, in C:                            ick_next.           (line 4107)
* NEXT, in Funge:                        The IFFI Fingerprint.
                                                             (line 4641)
* NEXT, nonexistent target:              Errors.             (line 1137)
* NEXT, stack overflow:                  Errors.             (line 1112)
* NEXTING:                               NEXT FORGET and RESUME.
                                                             (line 2540)
* no source file:                        Errors.             (line 1448)
* non-INTERCAL-72 warning:               Warnings.           (line 1602)
* NOT:                                   Statement Identifiers.
                                                             (line 1929)
* obtaining C-INTERCAL:                  Obtaining.          (line  170)
* OIL:                                   Optimizer Idiom Language.
                                                             (line 5176)
* OIL, basics:                           OIL Basics.         (line 5186)
* OIL, comments:                         OIL Syntax.         (line 5226)
* OIL, debugging:                        Debug Options.      (line  785)
* OIL, example:                          OIL Example.        (line 5675)
* OIL, execution:                        OIL Basics.         (line 5186)
* OIL, expressions:                      OIL Expressions.    (line 5275)
* OIL, functions in C:                   OIL Patterns.       (line 5390)
* OIL, idiom groups:                     OIL Syntax.         (line 5242)
* OIL, idioms:                           OIL Syntax.         (line 5261)
* OIL, loops:                            OIL Loops.          (line 5579)
* OIL, operators:                        OIL Expressions.    (line 5288)
* OIL, optimizing code:                  Optimizer Options.  (line  923)
* OIL, patterns:                         OIL Patterns.       (line 5334)
* OIL, replacements:                     OIL Replacements.   (line 5504)
* OIL, syntax:                           OIL Syntax.         (line 5219)
* OIL, tips:                             OIL Tips.           (line 5611)
* ONCE:                                  ONCE and AGAIN.     (line 2003)
* onespot:                               Constants and Variables.
                                                             (line 2058)
* onespot overflow:                      Errors.             (line 1237)
* onespot, overflow warning:             Warnings.           (line 1623)
* operand overloading:                   Operand Overloading.
                                                             (line 3586)
* operand overloading, impossible:       Errors.             (line 1248)
* operands, OIL, in patterns:            OIL Patterns.       (line 5348)
* operands, OIL, in replacements:        OIL Replacements.   (line 5533)
* operator:                              Operators.          (line 2192)
* operators, OIL:                        OIL Expressions.    (line 5288)
* optimization:                          Optimizer Options.  (line  902)
* optimization, control flow:            Optimizer Options.  (line  906)
* optimization, extreme:                 Optimizer Options.  (line  913)
* optimization, flow:                    Optimizer Options.  (line  906)
* optimization, idioms:                  Optimizer Options.  (line  923)
* optimization, OIL:                     Optimizer Options.  (line  923)
* Optimizer Idiom Language:              Optimizer Idiom Language.
                                                             (line 5176)
* optimizer options:                     Optimizer Options.  (line  902)
* optimizer, debugging:                  Debug Options.      (line  785)
* options, debug:                        Debug Options.      (line  762)
* options, dialect:                      Language-affecting Options.
                                                             (line  630)
* options, help:                         Other Options.      (line  938)
* options, language-affecting:           Language-affecting Options.
                                                             (line  630)
* options, optimizer:                    Optimizer Options.  (line  902)
* options, other:                        Other Options.      (line  935)
* options, output:                       Output Options.     (line  869)
* options, to generated programs:        Options to Generated Programs.
                                                             (line  947)
* options, to ick:                       Invoking ick.       (line  613)
* or:                                    Unary Binary Logic. (line 2320)
* or16:                                  OIL Patterns.       (line 5445)
* or32:                                  OIL Patterns.       (line 5445)
* other languages:                       External Calls.     (line 3873)
* other languages, C:                    External Calls to C.
                                                             (line 3905)
* other options:                         Other Options.      (line  935)
* out of bounds:                         Errors.             (line 1209)
* out of memory:                         Errors.             (line 1284)
* out of memory, backtracking:           Errors.             (line 1511)
* out of memory, during compile:         Errors.             (line 1421)
* out of memory, during STASH:           Errors.             (line 1189)
* out of memory, I/O:                    Errors.             (line 1219)
* out of memory, multithreading:         Errors.             (line 1511)
* output:                                READ OUT and WRITE IN.
                                                             (line 2776)
* output file, failure to write:         Errors.             (line 1490)
* output options:                        Output Options.     (line  869)
* output, C only:                        Output Options.     (line  876)
* output, C-INTERCAL:                    C-INTERCAL I/O.     (line 2850)
* output, CLC-INTERCAL:                  CLC-INTERCAL I/O.   (line 2892)
* output, flushing:                      Options to Generated Programs.
                                                             (line  978)
* output, in Arabic numerals:            Options to Generated Programs.
                                                             (line  962)
* output, INTERCAL-72:                   INTERCAL-72 I/O.    (line 2793)
* output, to standard output:            Output Options.     (line  891)
* overflow, in constant:                 Errors.             (line 1082)
* overflow, over 16 bits:                Errors.             (line 1237)
* overflow, over 32 bits:                Errors.             (line 1327)
* overflow, over onespot:                Errors.             (line 1237)
* overflow, over twospot:                Errors.             (line 1327)
* overflow, warning:                     Warnings.           (line 1623)
* parser, debugging:                     Debug Options.      (line  768)
* patches, submitting:                   Reporting Bugs.     (line  507)
* patterns:                              OIL Patterns.       (line 5334)
* patterns, operands:                    OIL Patterns.       (line 5348)
* PIC-INTERCAL:                          PIC-INTERCAL.       (line 3665)
* PIC-INTERCAL, command line option:     Language-affecting Options.
                                                             (line  721)
* PIC-INTERCAL, unsupported command:     Errors.             (line 1226)
* PIN:                                   PIC-INTERCAL.       (line 3714)
* PIN, in a non-PIC program:             Errors.             (line 1411)
* PLEASE:                                Statement Identifiers.
                                                             (line 1929)
* PLEASE, proportion required:           Errors.             (line 1088)
* politesse:                             Errors.             (line 1088)
* portability, unary operators:          Warnings.           (line 1663)
* positional precedence:                 Grouping Rules.     (line 2099)
* Princeton compiler:                    Differences to Other Compilers.
                                                             (line 4858)
* Princeton syntax:                      Princeton and Atari Syntax.
                                                             (line 1833)
* Princeton syntax, option:              Language-affecting Options.
                                                             (line  734)
* printflow, enabling:                   Debug Options.      (line  820)
* profiling:                             Debug Options.      (line  804)
* quitting:                              GIVE UP.            (line 2942)
* r:                                     OIL Patterns.       (line 5431)
* rabbit-ears:                           Grouping Rules.     (line 2099)
* rabbit-ears, nesting limit:            Errors.             (line 1265)
* random bug:                            Language-affecting Options.
                                                             (line  641)
* random bug, error message:             Errors.             (line 1435)
* READ OUT:                              READ OUT and WRITE IN.
                                                             (line 2776)
* read-only variables:                   IGNORE and REMEMBER.
                                                             (line 2654)
* read-write variables:                  IGNORE and REMEMBER.
                                                             (line 2654)
* READING OUT:                           READ OUT and WRITE IN.
                                                             (line 2776)
* REINSTATE:                             ABSTAIN and REINSTATE.
                                                             (line 2687)
* reinstate, at program start:           Statement Identifiers.
                                                             (line 1929)
* reinstate, during execution:           ABSTAIN and REINSTATE.
                                                             (line 2687)
* REINSTATE, self-reinstating:           ONCE and AGAIN.     (line 2003)
* reinstated state:                      Statement Identifiers.
                                                             (line 1929)
* REINSTATING:                           ABSTAIN and REINSTATE.
                                                             (line 2687)
* REINTSTATE, nonexistent target:        Errors.             (line 1151)
* releasing C-INTERCAL:                  Distributing.       (line  568)
* REMEMBER:                              IGNORE and REMEMBER.
                                                             (line 2654)
* REMEMBERING:                           IGNORE and REMEMBER.
                                                             (line 2654)
* replacements:                          OIL Replacements.   (line 5504)
* replacements, operands:                OIL Replacements.   (line 5533)
* reporting bugs:                        Reporting Bugs.     (line  507)
* RESUME:                                NEXT FORGET and RESUME.
                                                             (line 2540)
* RESUME, by 0:                          Errors.             (line 1380)
* RESUME, in C:                          ick_resume.         (line 4133)
* RESUME, in Funge:                      The IFFI Fingerprint.
                                                             (line 4648)
* RESUMING:                              NEXT FORGET and RESUME.
                                                             (line 2540)
* RETRIEVE:                              STASH and RETRIEVE. (line 2601)
* RETRIEVE, without stashing:            Errors.             (line 1312)
* RETRIEVE/IGNORE interaction:           STASH and RETRIEVE. (line 2629)
* RETRIEVING:                            STASH and RETRIEVE. (line 2601)
* reverse assignment:                    Operand Overloading.
                                                             (line 3586)
* reverse assignment, error:             Errors.             (line 1248)
* reverse assignment, impossible:        Errors.             (line 1248)
* reverse goto:                          COME FROM and NEXT FROM.
                                                             (line 2978)
* Roman numerals:                        INTERCAL-72 I/O.    (line 2793)
* Roman numerals, disabling:             Options to Generated Programs.
                                                             (line  962)
* runtime debugger:                      The yuk debugger.   (line 1684)
* self-abstaining:                       ONCE and AGAIN.     (line 2003)
* self-reinstating:                      ONCE and AGAIN.     (line 2003)
* SENESTMAX:                             Errors.             (line 1265)
* separate threads:                      Multithreading using COME FROM.
                                                             (line 3340)
* setbitcount:                           OIL Patterns.       (line 5465)
* sharkfin:                              TriINTERCAL.        (line 3232)
* sharkfin, in base 2:                   Errors.             (line 1545)
* signatures:                            ick_create.         (line 4245)
* simple installation:                   Simple Installation.
                                                             (line  284)
* skeleton file, directory problems:     Debug Options.      (line  828)
* skeleton file, errors:                 Errors.             (line 1564)
* slat:                                  Operand Overloading.
                                                             (line 3586)
* smudgeleft:                            OIL Patterns.       (line 5473)
* smudgeright:                           OIL Patterns.       (line 5473)
* spark:                                 Grouping Rules.     (line 2099)
* spark, nesting limit:                  Errors.             (line 1265)
* src/idiotism.oil:                      OIL Basics.         (line 5186)
* stack overflow:                        Errors.             (line 1112)
* stack, instruction pointer:            NEXT FORGET and RESUME.
                                                             (line 2540)
* stack, NEXT:                           NEXT FORGET and RESUME.
                                                             (line 2540)
* stack, variable:                       STASH and RETRIEVE. (line 2601)
* standard output:                       Output Options.     (line  891)
* startup code, C:                       ick_startup.        (line 4000)
* STASH:                                 STASH and RETRIEVE. (line 2601)
* stash failure:                         Errors.             (line 1312)
* stashes:                               STASH and RETRIEVE. (line 2601)
* STASHING:                              STASH and RETRIEVE. (line 2601)
* statement identifier:                  Statement Identifiers.
                                                             (line 1929)
* statements:                            Statements.         (line 2433)
* statements, INTERCAL:                  Statements.         (line 2433)
* SUB:                                   Array Subscript.    (line 2395)
* submitting patches:                    Reporting Bugs.     (line  507)
* subscripts:                            Array Subscript.    (line 2395)
* subtract-without-borrow:               TriINTERCAL.        (line 3232)
* syntax error:                          Errors.             (line 1073)
* syntax error <1>:                      Syntax Error.       (line 2447)
* syntax, Atari:                         Princeton and Atari Syntax.
                                                             (line 1860)
* syntax, creating:                      CREATE.             (line 3756)
* syntax, dialects:                      Princeton and Atari Syntax.
                                                             (line 1828)
* syntax, INTERCAL:                      Syntax.             (line 1810)
* syntax, of OIL:                        OIL Syntax.         (line 5219)
* syntax, Princeton:                     Language-affecting Options.
                                                             (line  734)
* syntax, Princeton <1>:                 Princeton and Atari Syntax.
                                                             (line 1833)
* syslib:                                syslib.             (line 3065)
* syslib, directory problems:            Debug Options.      (line  828)
* syslib, errors:                        Errors.             (line 1125)
* syslibc:                               Expansion Libraries.
                                                             (line 4807)
* system libraries:                      System Libraries.   (line 3044)
* system library, directory problems:    Debug Options.      (line  828)
* system library, disabling:             Language-affecting Options.
                                                             (line  679)
* system library, errors:                Errors.             (line 1125)
* system library, in C:                  Expansion Libraries.
                                                             (line 4807)
* tail:                                  Constants and Variables.
                                                             (line 2058)
* ternary:                               TriINTERCAL.        (line 3232)
* Threaded INTERCAL:                     Multithreading and Backtracking.
                                                             (line 3312)
* threading:                             Multithreading and Backtracking.
                                                             (line 3312)
* threading, connected:                  Multithreading using WHILE.
                                                             (line 3411)
* threading, dormant:                    Backtracking.       (line 3499)
* threading, in series:                  Backtracking.       (line 3499)
* threading, separate:                   Multithreading using COME FROM.
                                                             (line 3340)
* threading, unwoven:                    Multithreading using COME FROM.
                                                             (line 3340)
* threading, woven:                      Multithreading using WHILE.
                                                             (line 3411)
* time-reversed goto:                    COME FROM and NEXT FROM.
                                                             (line 2978)
* tips, OIL:                             OIL Tips.           (line 5611)
* too many input files:                  Errors.             (line 1421)
* TriINTERCAL:                           TriINTERCAL.        (line 3232)
* TriINTERCAL, operators in base 2:      Errors.             (line 1545)
* TRY AGAIN:                             TRY AGAIN.          (line 2960)
* TRY AGAIN, not last:                   Errors.             (line 1521)
* Turing Tape:                           C-INTERCAL I/O.     (line 2850)
* twospot:                               Constants and Variables.
                                                             (line 2058)
* twospot overflow:                      Errors.             (line 1327)
* Ubuntu:                                Simple Installation.
                                                             (line  370)
* unary binary logic:                    Unary Binary Logic. (line 2320)
* unary operator, infix:                 Grouping Rules.     (line 2162)
* unary operator, prefix:                Grouping Rules.     (line 2162)
* unary operators, portability:          Warnings.           (line 1663)
* uninstalling:                          Uninstalling.       (line  472)
* unpacking C-INTERCAL:                  Unpacking.          (line  196)
* unsupported file type:                 Errors.             (line 1505)
* unsupported file type <1>:             Errors.             (line 1555)
* unwoven threads:                       Multithreading using COME FROM.
                                                             (line 3340)
* unzipping C-INTERCAL:                  Unpacking.          (line  196)
* usage instructions, printing:          Other Options.      (line  938)
* using external calls:                  Using External Calls.
                                                             (line 4722)
* V:                                     Unary Binary Logic. (line 2320)
* variable:                              Constants and Variables.
                                                             (line 2058)
* variable, illegal number:              Errors.             (line 1178)
* variables, assignment:                 Calculate.          (line 2496)
* variables, from C:                     ick_get/setone/twospot.
                                                             (line 4183)
* variables, Funge, accessing:           The IFFI Fingerprint.
                                                             (line 4605)
* variables, Funge, setting:             The IFFI Fingerprint.
                                                             (line 4654)
* variables, ignoring:                   IGNORE and REMEMBER.
                                                             (line 2654)
* variables, limit:                      Errors.             (line 1276)
* variables, read-only:                  IGNORE and REMEMBER.
                                                             (line 2654)
* variables, read-write:                 IGNORE and REMEMBER.
                                                             (line 2654)
* variables, remembering:                IGNORE and REMEMBER.
                                                             (line 2654)
* variables, stashes:                    STASH and RETRIEVE. (line 2601)
* W016:                                  Warnings.           (line 1582)
* W018:                                  Warnings.           (line 1589)
* W112:                                  Warnings.           (line 1602)
* W128:                                  Warnings.           (line 1612)
* W239:                                  Warnings.           (line 1634)
* W276:                                  Warnings.           (line 1623)
* W278:                                  Warnings.           (line 1643)
* W450:                                  Warnings.           (line 1654)
* W534:                                  Warnings.           (line 1663)
* W622:                                  Warnings.           (line 1674)
* warnings:                              Warnings.           (line 1576)
* warnings, enabling:                    Debug Options.      (line  796)
* warnings, non-INTERCAL-72:             Warnings.           (line 1602)
* what:                                  Unary Binary Logic. (line 2320)
* WHILE:                                 Multithreading using WHILE.
                                                             (line 3411)
* WHILE, not enabled:                    Errors.             (line 1302)
* whirlpool:                             TriINTERCAL.        (line 3232)
* whirlpool, in base 2:                  Errors.             (line 1545)
* wimpmode:                              Options to Generated Programs.
                                                             (line  962)
* woven threads:                         Multithreading using WHILE.
                                                             (line 3411)
* WRITE IN:                              READ OUT and WRITE IN.
                                                             (line 2776)
* WRITING IN:                            READ OUT and WRITE IN.
                                                             (line 2776)
* wrong array dimension:                 Errors.             (line 1209)
* x:                                     OIL Patterns.       (line 5422)
* x1--x9:                                OIL Patterns.       (line 5422)
* xor:                                   Unary Binary Logic. (line 2320)
* xor16:                                 OIL Patterns.       (line 5445)
* xor32:                                 OIL Patterns.       (line 5445)
* xselx:                                 OIL Patterns.       (line 5458)
* yuk:                                   The yuk debugger.   (line 1684)
* yuk, breakpoint overflow:              Errors.             (line 1482)
* yuk, command line option:              Debug Options.      (line  838)
* yuk, commands:                         The yuk debugger.   (line 1711)
* yuk, input overflow:                   Errors.             (line 1475)
* yuk, profiling:                        Debug Options.      (line  804)
* yuk, too many breakpoints:             Errors.             (line 1482)

