A User's Guide to FreeBSD Programming ToolsJamesRaynardjraynard@FreeBSD.orgAugust 17, 19971997James RaynardThis document is an introduction to using some of the programming
tools supplied with FreeBSD, although much of it will be applicable to
many other versions of Unix. It does not attempt to describe
coding in any detail. Most of the document assumes little or no
previous programming knowledge, although it is hoped that most
programmers will find something of value in itIntroductionFreeBSD offers an excellent development environment. Compilers
for C, C++, and Fortran and an assembler come with the basic system,
not to mention a Perl interpreter and classic Unix tools such as
sed> and awk>. If that is not enough, there are
many more compilers and interpreters in the Ports collection. FreeBSD
is very compatible with standards such as POSIX> and
ANSI> C, as well with its own BSD heritage, so it is
possible to write applications that will compile and run with little
or no modification on a wide range of platforms.However, all this power can be rather overwhelming at first if
you've never written programs on a Unix platform before. This
document aims to help you get up and running, without getting too
deeply into more advanced topics. The intention is that this document
should give you enough of the basics to be able to make some sense of
the documentation.Most of the document requires little or no knowledge of
programming, although it does assume a basic competence with using
Unix and a willingness to learn!Introduction to ProgrammingA program is a set of instructions that tell the computer to do
various things; sometimes the instruction it has to perform depends
on what happened when it performed a previous instruction. This
section gives an overview of the two main ways in which you can give
these instructions, or commands as they are usually
called. One way uses an interpreter>, the other a
compiler>. As human languages are too difficult for a
computer to understand in an unambiguous way, commands are usually
written in one or other languages specially designed for the
purpose.InterpretersWith an interpreter, the language comes as an environment, where you
type in commands at a prompt and the environment executes them for
you. For more complicated programs, you can type the commands into a
file and get the interpreter to load the file and execute the commands
in it. If anything goes wrong, many interpreters will drop you into a
debugger to help you track down the problem.The advantage of this is that you can see the results of your
commands immediately, and mistakes can be corrected readily. The
biggest disadvantage comes when you want to share your programs with
someone. They must have the same interpreter, or you must have some
way of giving it to them, and they need to understand how to use it.
Also users may not appreciate being thrown into a debugger if they
press the wrong key! From a performance point of view, interpreters
can use up a lot of memory, and generally do not generate code as
efficiently as compilers.In my opinion, interpreted languages are the best way to start
if you have not done any programming before. This kind of environment
is typically found with languages like Lisp, Smalltalk, Perl and
Basic. It could also be argued that the Unix shell (sh>,
csh>) is itself an interpreter, and many people do in fact
write shell scripts to help with various
housekeeping> tasks on their machine. Indeed, part of the
original Unix philosophy was to provide lots of small utility
programs that could be linked together in shell scripts to perform
useful tasks.Interpreters available with FreeBSDHere is a list of interpreters that are available as FreeBSD
packages, with a brief discussion of some of the more popular
interpreted languages. To get one of these packages, all you need to do is to click on
the hotlink for the package, then run
$ pkg_add package name>as root. Obviously, you will need to have a fully functional FreeBSD
2.1.0 or later system for the package to work!BASIC>Short for Beginner's All-purpose Symbolic Instruction
Code. Developed in the 1950s for teaching University students to
program and provided with every self-respecting personal computer in
the 1980s, BASIC> has been the first programming language
for many programmers. It's also the foundation for Visual
Basic>.The Bywater
Basic Interpreter and the Phil
Cockroft's Basic Interpreter (formerly Rabbit Basic) are
available as FreeBSD FreeBSD
packagesLispA language that was developed in the late 1950s as an alternative to
the number-crunching languages that were popular at the time.
Instead of being based on numbers, Lisp is based on lists; in fact
the name is short for List Processing. Very popular in AI
(Artificial Intelligence) circles.Lisp is an extremely powerful and sophisticated language, but
can be rather large and unwieldy. FreeBSD has GNU
Common Lisp available as a package.PerlVery popular with system administrators for writing
scripts; also often used on World Wide Web servers for writing CGI>
scripts.Version 4, which is probably still the most widely-used
version, comes with FreeBSD; the newer Perl
Version 5 is available as a package.SchemeA dialect of Lisp that is rather more compact and
cleaner than Common Lisp. Popular in Universities as it is simple
enough to teach to undergraduates as a first language, while it has a
high enough level of abstraction to be used in research work.FreeBSD has packages of the
Elk Scheme Interpreter, the
MIT Scheme Interpreter and the
SCM Scheme Interpreter.IconThe Icon Programming Language.LogoBrian Harvey's LOGO Interpreter.PythonThe Python Object-Oriented Programming LanguageCompilersCompilers are rather different. First of all, you write your
code in a file (or files) using an editor. You then run the compiler
and see if it accepts your program. If it did not compile, grit your
teeth and go back to the editor; if it did compile and gave you a
program, you can run it either at a shell command prompt or in a
debugger to see if it works properly.If you run it in
the shell, you may get a core dump.Obviously, this is not quite as direct as using an interpreter.
However it allows you to do a lot of things which are very difficult
or even impossible with an interpreter, such as writing code which
interacts closely with the operating system—or even writing
your own operating system! It's also useful if you need to write very
efficient code, as the compiler can take its time and optimise the
code, which would not be acceptable in an interpreter. And
distributing a program written for a compiler is usually more
straightforward than one written for an interpreter—you can just
give them a copy of the executable, assuming they have the same
operating system as you.Compiled languages include Pascal, C and C++. C and C++ are rather
unforgiving languages, and best suited to more experienced
programmers; Pascal, on the other hand, was designed as an educational
language, and is quite a good language to start with. Unfortunately,
FreeBSD doesn't have any Pascal support, except for a Pascal-to-C
converter in the ports.As the edit-compile-run-debug cycle is rather tedious when
using separate programs, many commercial compiler makers have
produced Integrated Development Environments (IDEs
for short). FreeBSD does not have an IDE> as such; however
it is possible to use Emacs for this purpose. This is discussed in
.Compiling with ccThis section deals only with the GNU compiler for C and C++,
since that comes with the base FreeBSD system. It can be invoked by
either cc> or gcc>. The details of producing a
program with an interpreter vary considerably between interpreters,
and are usually well covered in the documentation and on-line help
for the interpreter.Once you've written your masterpiece, the next step is to convert it
into something that will (hopefully!) run on FreeBSD. This usually
involves several steps, each of which is done by a separate
program.Pre-process your source code to remove comments and do other
tricks like expanding macros in C.
Check the syntax of your code to see if you have obeyed the
rules of the language. If you have not, it will complain!
Convert the source code into assembly
language—this is very close to machine code, but still
understandable by humans. Allegedly.To be strictly
accurate, cc> converts the source code into its own,
machine-independent p-code> instead of assembly language
at this stage.Convert the assembly language into machine
code—yep, we are talking bits and bytes, ones and zeros
here.Check that you have used things like functions and global
variables in a consistent way. For example, if you have called a
non-existent function, it will complain.If you are trying to produce an executable from several
source code files, work out how to fit them all together.Work out how to produce something that the system's run-time
loader will be able to load into memory and run.Finally, write the executable on the file
system.The word compiling> is often used to refer to just
steps 1 to 4—the others are referred to as
linking>. Sometimes step 1 is referred to as
pre-processing> and steps 3-4 as
assembling>.Fortunately, almost all this detail is hidden from you, as
cc> is a front end that manages calling all these programs
with the right arguments for you; simply typing
$ cc foobar.c>will cause foobar.c> to be compiled by all the
steps above. If you have more than one file to compile, just do
something like
$ cc foo.c bar.c>Note that the syntax checking is just that—checking the
syntax. It will not check for any logical mistakes you may have made,
like putting the program into an infinite loop, or using a bubble
sort when you meant to use a binary sort.In case you
didn't know, a binary sort is an efficient way of sorting things into
order and a bubble sort isn't.There are lots and lots of options for cc>, which
are all in the man page. Here are a few of the most important ones,
with examples of how to use them.The output name of the file. If you do not use this
option, cc> will produce an executable called
a.out>.The reasons for this are buried in
the mists of history.$ cc foobar.c> executable is a.out>>
$ cc -o foobar foobar.c> executable is foobar>>Just compile the file, do not link it. Useful for toy
programs where you just want to check the syntax, or if you are using
a Makefile.$ cc -c foobar.cThis will produce an object file> (not an
executable) called foobar.o. This can be linked
together with other object files into an executable.Create a debug version of the executable. This makes
the compiler put information into the executable about which line of
which source file corresponds to which function call. A debugger can
use this information to show the source code as you step through the
program, which is very useful; the disadvantage
is that all this extra information makes the program much bigger.
Normally, you compile with while you are
developing a program and then compile a release
version without when you're satisfied it
works properly.$ cc -g foobar.cThis will produce a debug version of the
program.Note, we didn't use the
flag to specify the executable name, so we will get an executable
called a.out. Producing a debug version called
foobar is left as an exercise for the
reader!Create an optimised version of the executable. The
compiler performs various clever tricks to try and produce an
executable that runs faster than normal. You can add a number after
the to specify a higher level of optimisation,
but this often exposes bugs in the compiler's optimiser. For
instance, the version of cc that comes with the
2.1.0 release of FreeBSD is known to produce bad code with the
option in some circumstances.Optimisation is usually only turned on when compiling a release
version.$ cc -O -o foobar foobar.cThis will produce an optimised version of
foobar.The following three flags will force cc to
check that your code complies to the relevant international standard,
often referred to as the ANSI standard, though
strictly speaking it is an ISO standard.Enable all the warnings which the authors of
cc believe are worthwhile. Despite the name, it
will not enable all the warnings cc is capable
of.Turn off most, but not all, of the non-ANSI> C
features provided by cc. Despite the name, it does
not guarantee strictly that your code will comply to the
standard.Turn off allcc's non-ANSI> C features.Without these flags, cc will allow you to
use some of its non-standard extensions to the standard. Some of
these are very useful, but will not work with other compilers—in
fact, one of the main aims of the standard is to allow people to
write code that will work with any compiler on any system. This is
known as portable code.Generally, you should try to make your code as portable as
possible, as otherwise you may have to completely re-write the
program later to get it to work somewhere else—and who knows
what you may be using in a few years time?$ cc -Wall -ansi -pedantic -o foobar foobar.cThis will produce an executable foobar
after checking foobar.c for standard
compliance.Specify a function library to be used during when
linking.The most common example of this is when compiling a program that
uses some of the mathematical functions in C. Unlike most other
platforms, these are in a separate library from the standard C one
and you have to tell the compiler to add it.The rule is that if the library is called
libsomething.a, you
give cc the argument
. For example,
the math library is libm.a, so you give
cc the argument . A common
gotcha with the math library is that it has to be the
last library on the command line.$ cc -o foobar foobar.c -lmThis will link the math library functions into
foobar.If you are compiling C++ code, you need to add
, or if you are using
FreeBSD 2.2 or later, to the command line argument to link the C++
library functions. Alternatively, you can run c++
instead of cc, which does this for you.
c++ can also be invoked as g++
on FreeBSD.$ cc -o foobar foobar.cc -lg++For FreeBSD 2.1.6 and earlier>
$ cc -o foobar foobar.cc -lstdc++For FreeBSD 2.2 and later>
$ c++ -o foobar foobar.ccEach of these will both produce an executable
foobar from the C++ source file
foobar.cc. Note that, on Unix systems, C++
source files traditionally end in .C,
.cxx or .cc, rather than
the MS-DOS style .cpp
(which was already used for something else). gcc
used to rely on this to work out what kind of compiler to use on the
source file; however, this restriction no longer applies, so you may
now call your C++ files .cpp with
impunity!Common cc Queries and ProblemsQ. I am trying to write a program which uses the
sin() function and I get an error like this.
What does it mean?
/var/tmp/cc0143941.o: Undefined symbol `_sin' referenced from text segmentA. When using mathematical functions like
sin(), you have to tell cc to
link in the math library, like so:
$ cc -o foobar foobar.c -lmQ. All right, I wrote this simple program to practice using
. All it does is raise 2.1 to the power of 6.
#include <stdio.h>
int main() {
float f;
f = pow(2.1, 6);
printf("2.1 ^ 6 = %f\n", f);
return 0;
}
and I compiled it as:
$ cc temp.c -lm
like you said I should, but I get this when I run it:
$ ./a.out
2.1 ^ 6 = 1023.000000This is not the right answer! What is
going on?A. When the compiler sees you call a function, it checks if it
has already seen a prototype for it. If it has not, it assumes the
function returns an int, which is
definitely not what you want here.Q. So how do I fix this?A. The prototypes for the mathematical functions are in
math.h. If you include this file, the compiler
will be able to find the prototype and it will stop doing strange
things to your calculation!
#include <math.h>
#include <stdio.h>
int main() {
...After recompiling it as you did before, run it:
$ ./a.out
2.1 ^ 6 = 85.766121If you are using any of the mathematical functions,
always include math.h and
remember to link in the math library.Q. I compiled a file called foobar.c and I
cannot find an executable called foobar. Where's
it gone?A. Remember, cc will call the executable
a.out unless you tell it differently. Use the
option:
$ cc -o foobar foobar.cQ. OK, I have an executable called foobar,
I can see it when I run ls, but when I type in
foobar at the command prompt it tells me there is
no such file. Why can it not find it?A. Unlike MS-DOS, Unix does not look in the
current directory when it is trying to find out which executable you
want it to run, unless you tell it to. Either type
./foobar, which means run the file called
foobar in the current directory, or
change your PATH
environment variable so that it looks something like
bin:/usr/bin:/usr/local/bin:.
The dot at the end means look in the current directory if it is not in
any of the others.Q. I called my executable test, but
nothing happens when I run it. What is going on?A. Most Unix systems have a program called
test in /usr/bin and the
shell is picking that one up before it gets to checking the current
directory. Either type:
$ ./test
or choose a better name for your program!Q. I compiled my program and it seemed to run all right at
first, then there was an error and it said something about core
dumped. What does that mean?A. The name core dump dates back to the
very early days of Unix, when the machines used core memory for
storing data. Basically, if the program failed under certain
conditions, the system would write the contents of core memory to
disk in a file called core, which the programmer
could then pore over to find out what went wrong.Q. Fascinating stuff, but what I am supposed to do now?A. Use gdb to analyse the core (see ).Q. When my program dumped core, it said something about a
segmentation fault. What's that?A. This basically means that your program tried to perform some sort
of illegal operation on memory; Unix is designed to protect the
operating system and other programs from rogue programs.Common causes for this are:
Trying to write to a NULL pointer, eg
char *foo = NULL;
strcpy(foo, "bang!");Using a pointer that hasn't been initialised, eg
char *foo;
strcpy(foo, "bang!");
The pointer will have some random value that, with luck,
will point into an area of memory that isn't available to
your program and the kernel will kill your program before
it can do any damage. If you're unlucky, it'll point
somewhere inside your own program and corrupt one of your
data structures, causing the program to fail
mysteriously.Trying to access past the end of an array, eg
int bar[20];
bar[27] = 6; Trying to store something in read-only memory, eg
char *foo = "My string";
strcpy(foo, "bang!");
Unix compilers often put string literals like
"My string" into
read-only areas of memory.Doing naughty things with
malloc() and free(), eg
char bar[80];
free(bar);
or
char *foo = malloc(27);
free(foo);
free(foo);Making one of these mistakes will not always lead to an
error, but they are always bad practice. Some systems and
compilers are more tolerant than others, which is why programs
that ran well on one system can crash when you try them on an
another.Q. Sometimes when I get a core dump it says bus
error. It says in my Unix book that this means a hardware
problem, but the computer still seems to be working. Is this
true?A. No, fortunately not (unless of course you really do have a hardware
problem…). This is usually another way of saying that you
accessed memory in a way you shouldn't have.Q. This dumping core business sounds as though it could be quite
useful, if I can make it happen when I want to. Can I do this, or
do I have to wait until there's an error?A. Yes, just go to another console or xterm, do
$ ps
to find out the process ID of your program, and do
$ kill -ABRT pid
where pid is the
process ID you looked up.This is useful if your program has got stuck in an infinite
loop, for instance. If your program happens to trap
SIGABRT, there are several other signals which have
a similar effect.MakeWhat is make?When you're working on a simple program with only one or two source
files, typing in
$ cc file1.c file2.c
is not too bad, but it quickly becomes very tedious when there are
several files—and it can take a while to compile, too.One way to get around this is to use object files and only recompile
the source file if the source code has changed. So we could have
something like:
$ cc file1.o file2.o … file37.c &hellip
if we'd changed file37.c, but not any of the
others, since the last time we compiled. This may speed up the
compilation quite a bit, but doesn't solve the typing
problem.Or we could write a shell script to solve the typing problem, but it
would have to re-compile everything, making it very inefficient on a
large project.What happens if we have hundreds of source files lying about? What if
we're working in a team with other people who forget to tell us when
they've changed one of their source files that we use?Perhaps we could put the two solutions together and write something
like a shell script that would contain some kind of magic rule saying
when a source file needs compiling. Now all we need now is a program
that can understand these rules, as it's a bit too complicated for the
shell.This program is called make. It reads in a
file, called a makefile, that tells it how
different files depend on each other, and works out which files need
to be re-compiled and which ones don't. For example, a rule could say
something like if fromboz.o is older than
fromboz.c, that means someone must have changed
fromboz.c, so it needs to be
re-compiled. The makefile also has rules telling make
how to re-compile the source file, making it a
much more powerful tool.Makefiles are typically kept in the same directory as the
source they apply to, and can be called
makefile, Makefile or
MAKEFILE. Most programmers use the name
Makefile, as this puts it near the top of a
directory listing, where it can easily be seen.They
don't use the MAKEFILE form as block capitals
are often used for documentation files like
README.Example of using makeHere's a very simple make file:
foo: foo.c
cc -o foo foo.c
It consists of two lines, a dependency line and a creation line.The dependency line here consists of the name of the program
(known as the target), followed by a colon,
then whitespace, then the name of the source file. When
make reads this line, it looks to see if
foo exists; if it exists, it compares the time
foo was last modified to the time
foo.c was last modified. If
foo does not exist, or is older than
foo.c, it then looks at the creation line to
find out what to do. In other words, this is the rule for working out
when foo.c needs to be re-compiled.The creation line starts with a tab (press the
tab key) and then the command you would type to
create foo if you were doing it at a command
prompt. If foo is out of date, or does not
exist, make then executes this command to create
it. In other words, this is the rule which tells make how to
re-compile foo.c.So, when you type make, it will make
sure that foo is up to date with respect to your
latest changes to foo.c. This principle can be
extended to Makefiles with hundreds of
targets—in fact, on FreeBSD, it is possible to compile the
entire operating system just by typing make
world in the appropriate directory!Another useful property of makefiles is that the targets don't have
to be programs. For instance, we could have a make file that looks
like this:
foo: foo.c
cc -o foo foo.c
install:
cp foo /home/meWe can tell make which target we want to make by typing:
$ make targetmake will then only look at that target and ignore any
others. For example, if we type make foo with the
makefile above, make will ignore the install target.If we just type make on its own, make
will always look at the first target and then stop without looking at
any others. So if we typed make here, it will
just go to the foo target, re-compile
foo if necessary, and then stop without going on
to the install target.Notice that the install target doesn't
actually depend on anything! This means that the command on the
following line is always executed when we try to make that target by
typing make install. In this case, it will
copy foo into the user's home directory. This is
often used by application makefiles, so that the application can be
installed in the correct directory when it has been correctly
compiled.This is a slightly confusing subject to try and explain. If you
don't quite understand how make works, the best
thing to do is to write a simple program like hello
world and a make file like the one above and experiment. Then
progress to using more than one source file, or having the source
file include a header file. The touch command is
very useful here—it changes the date on a file without you
having to edit it.FreeBSD MakefilesMakefiles can be rather complicated to write. Fortunately,
BSD-based systems like FreeBSD come with some very powerful ones as
part of the system. One very good example of this is the FreeBSD
ports system. Here's the essential part of a typical ports
Makefile:
MASTER_SITES= ftp://freefall.cdrom.com/pub/FreeBSD/LOCAL_PORTS/
DISTFILES= scheme-microcode+dist-7.3-freebsd.tgz
.include <bsd.port.mk>Now, if we go to the directory for this port and type
make, the following happens:A check is made to see if the source code for this port is
already on the system.If it isn't, an FTP connection to the URL in
MASTER_SITES is set up to download the
source.The checksum for the source is calculated and compared it with
one for a known, good, copy of the source. This is to make sure that
the source was not corrupted while in transit.Any changes required to make the source work on FreeBSD are
applied—this is known as patching.Any special configuration needed for the source is done.
(Many Unix program distributions try to work out which version of
Unix they are being compiled on and which optional Unix features are
present—this is where they are given the information in the
FreeBSD ports scenario).The source code for the program is compiled. In effect,
we change to the directory where the source was unpacked and do
make—the program's own make file has the
necessary information to build the program.We now have a compiled version of the program. If we
wish, we can test it now; when we feel confident about the program,
we can type make install. This will cause the
program and any supporting files it needs to be copied into the
correct location; an entry is also made into a package
database, so that the port can easily be uninstalled later
if we change our mind about it.Now I think you'll agree that's rather impressive for a four
line script!The secret lies in the last line, which tells
make to look in the system makefile called
bsd.port.mk. It's easy to overlook this line,
but this is where all the clever stuff comes from—someone has
written a makefile that tells make to do all the
things above (plus a couple of other things I didn't mention,
including handling any errors that may occur) and anyone can get
access to that just by putting a single line in their own make
file!If you want to have a look at these system makefiles, they're
in /usr/share/mk, but it's probably best to wait
until you've had a bit of practice with makefiles, as they are very
complicated (and if you do look at them, make sure you have a flask
of strong coffee handy!)More advanced uses of makeMake is a very powerful tool, and can do much
more than the simple example above shows. Unfortunately, there are
several different versions of make, and they all
differ considerably. The best way to learn what they can do is
probably to read the documentation—hopefully this introduction will
have given you a base from which you can do this.The version of make that comes with FreeBSD is the Berkeley
make; there is a tutorial for it in
/usr/share/doc/psd/12.make. To view it, do
$ zmore paper.ascii.gz
in that directory.Many applications in the ports use GNU
make, which has a very good set of info
pages. If you have installed any of these ports, GNU
make will automatically have been installed as
gmake. It's also available as a port and package
in its own right.To view the info pages for GNU make,
you will have to edit the dir file in the
/usr/local/info directory to add an entry for
it. This involves adding a line like
* Make: (make). The GNU Make utility.
to the file. Once you have done this, you can type
info and then select
make from the menu (or in
Emacs, do C-h
i).DebuggingThe DebuggerThe debugger that comes with FreeBSD is called
gdb (GNU
debugger). You start it up by typing
$ gdb progname
although most people prefer to run it inside
Emacs. You can do this by:
M-x gdb RET progname RETUsing a debugger allows you to run the program under more
controlled circumstances. Typically, you can step through the program
a line at a time, inspect the value of variables, change them, tell
the debugger to run up to a certain point and then stop, and so on.
You can even attach to a program that's already running, or load a
core file to investigate why the program crashed. It's even possible
to debug the kernel, though that's a little trickier than the user
applications we'll be discussing in this section.gdb has quite good on-line help, as well as
a set of info pages, so this section will concentrate on a few of the
basic commands.Finally, if you find its text-based command-prompt style
off-putting, there's a graphical front-end for it xxgdb
in the ports collection.This section is intended to be an introduction to using
gdb and does not cover specialised topics such as
debugging the kernel.Running a program in the debuggerYou'll need to have compiled the program with the
option to get the most out of using
gdb. It will work without, but you'll only see the
name of the function you're in, instead of the source code. If you
see a line like:
… (no debugging symbols found) …when
gdb starts up, you'll know that the program wasn't
compiled with the option.At the gdb prompt, type break
main. This will tell the debugger to skip over the
preliminary set-up code in the program and start at the beginning of
your code. Now type run to start the
program—it will start at the beginning of the set-up code and
then get stopped by the debugger when it calls
main(). (If you've ever wondered where
main() gets called from, now you know!).You can now step through the program, a line at a time, by
pressing n. If you get to a function call, you can
step into it by pressing s. Once you're in a
function call, you can return from stepping into a function call by
pressing f. You can also use up and
down to take a quick look at the caller.Here's a simple example of how to spot a mistake in a program
with gdb. This is our program (with a deliberate
mistake):
#include <stdio.h>
int bazz(int anint);
main() {
int i;
printf("This is my program\n");
bazz(i);
return 0;
}
int bazz(int anint) {
printf("You gave me %d\n", anint);
return anint;
}This program sets i to be 5
and passes it to a function bazz() which prints
out the number we gave it.When we compile and run the program we get
$ cc -g -o temp temp.c
$ ./temp
This is my program
anint = 4231That wasn't what we expected! Time to see what's going
on!$ gdb temp
GDB is free software and you are welcome to distribute copies of it
under certain conditions; type "show copying" to see the conditions.
There is absolutely no warranty for GDB; type "show warranty" for details.
GDB 4.13 (i386-unknown-freebsd), Copyright 1994 Free Software Foundation, Inc.
(gdb) break main> Skip the set-up code>
Breakpoint 1 at 0x160f: file temp.c, line 9. gdb puts breakpoint at main()>>
(gdb) run> Run as far as main()>>
Starting program: /home/james/tmp/temp Program starts running>
Breakpoint 1, main () at temp.c:9 gdb stops at main()>>
(gdb) n> Go to next line>
This is my program Program prints out>
(gdb) s> step into bazz()>>
bazz (anint=4231) at temp.c:17 gdb displays stack frame>
(gdb)Hang on a minute! How did anint get to be
4231? Didn't we set it to be 5
in main()? Let's move up to
main() and have a look.(gdb) up> Move up call stack>
#1 0x1625 in main () at temp.c:11 gdb displays stack frame>
(gdb) p i> Show us the value of i>>
$1 = 4231 gdb displays 4231>>
Oh dear! Looking at the code, we forgot to initialise
i. We meant to put
…>
main() {
int i;
i = 5;
printf("This is my program\n");
&hellip>
but we left the i=5; line out. As we didn't
initialise i, it had whatever number happened to be
in that area of memory when the program ran, which in this case
happened to be 4231.gdb displays the stack frame
every time we go into or out of a function, even if we're using
up and down to move around the
call stack. This shows the name of the function and the values of
its arguments, which helps us keep track of where we are and what's
going on. (The stack is a storage area where the program stores
information about the arguments passed to functions and where to go
when it returns from a function call).Examining a core fileA core file is basically a file which contains the complete
state of the process when it crashed. In the good old
days, programmers had to print out hex listings of core files
and sweat over machine code manuals, but now life is a bit easier.
Incidentally, under FreeBSD and other 4.4BSD systems, a core file is
called progname>.core> instead of just
core, to make it clearer which program a core
file belongs to.To examine a core file, start up gdb in the
usual way. Instead of typing break or
run, type
(gdb) core progname.core
If you're not in the same directory as the core file, you'll have to
do dir /path/to/core/file first.You should see something like this:
$ gdb a.out
GDB is free software and you are welcome to distribute copies of it
under certain conditions; type "show copying" to see the conditions.
There is absolutely no warranty for GDB; type "show warranty" for details.
GDB 4.13 (i386-unknown-freebsd), Copyright 1994 Free Software Foundation, Inc.
(gdb) core a.out.core
Core was generated by `a.out'.
Program terminated with signal 11, Segmentation fault.
Cannot access memory at address 0x7020796d.
#0 0x164a in bazz (anint=0x5) at temp.c:17
(gdb)In this case, the program was called
a.out, so the core file is called
a.out.core. We can see that the program crashed
due to trying to access an area in memory that was not available to
it in a function called bazz.Sometimes it's useful to be able to see how a function was
called, as the problem could have occurred a long way up the call
stack in a complex program. The bt command causes
gdb to print out a back-trace of the call
stack:
(gdb) bt
#0 0x164a in bazz (anint=0x5) at temp.c:17
#1 0xefbfd888 in end ()
#2 0x162c in main () at temp.c:11
(gdb)The end() function is called when
a program crashes; in this case, the bazz()
function was called from main().Attaching to a running programOne of the neatest features about gdb is
that it can attach to a program that's already running. Of course,
that assumes you have sufficient permissions to do so. A common
problem is when you are stepping through a program that forks, and
you want to trace the child, but the debugger will only let you trace
the parent.What you do is start up another gdb, use
ps to find the process ID for the child, and
do(gdb) attach pid
in gdb, and then debug as usual.That's all very well, you're probably thinking,
but by the time I've done that, the child process will be over
the hill and far away. Fear not, gentle reader, here's how to
do it (courtesy of the gdb info pages):
&hellip
if ((pid = fork()) < 0) /* _Always_ check this */
error();
else if (pid == 0) { /* child */
int PauseMode = 1;
while (PauseMode)
sleep(10); /* Wait until someone attaches to us */
&hellip
} else { /* parent */
&hellip
Now all you have to do is attach to the child, set
PauseMode to 0, and
wait for the sleep() call to return!Using Emacs as a Development EnvironmentEmacsUnfortunately, Unix systems don't come with the kind of
everything-you-ever-wanted-and-lots-more-you-didn't-in-one-gigantic-package
integrated development environments that other systems
have.At least, not unless you pay out very large sums
of money. However, it is possible to set up your
own environment. It may not be as pretty, and it may not be quite as
integrated, but you can set it up the way you want it. And it's free.
And you have the source to it.The key to it all is Emacs. Now there are some people who
loathe it, but many who love it. If you're one of the former, I'm
afraid this section will hold little of interest to you. Also, you'll
need a fair amount of memory to run it—I'd recommend 8MB in
text mode and 16MB in X as the bare minimum to get reasonable
performance.Emacs is basically a highly customisable editor—indeed,
it has been customised to the point where it's more like an operating
system than an editor! Many developers and sysadmins do in fact
spend practically all their time working inside Emacs, leaving it
only to log out.It's impossible even to summarise everything Emacs can do here, but
here are some of the features of interest to developers:
Very powerful editor, allowing search-and-replace on
both strings and regular expressions (patterns), jumping to start/end
of block expression, etc, etc.Pull-down menus and online help.Language-dependent syntax highlighting and
indentation.Completely customisable.You can compile and debug programs within
Emacs.On a compilation error, you can jump to the offending
line of source code.Friendly-ish front-end to the info
program used for reading GNU hypertext documentation, including the
documentation on Emacs itself.Friendly front-end to gdb,
allowing you to look at the source code as you step through your
program.You can read Usenet news and mail while your program
is compiling.And doubtless many more that I've overlooked.Emacs can be installed on FreeBSD using the Emacs
port.Once it's installed, start it up and do C-h
t to read an Emacs tutorial—that means hold down
the control key, press h, let go of
the control key, and then press t.
(Alternatively, you can you use the mouse to select Emacs
Tutorial from the Help menu).Although Emacs does have menus, it's well worth learning the
key bindings, as it's much quicker when you're editing something to
press a couple of keys than to try and find the mouse and then click
on the right place. And, when you're talking to seasoned Emacs users,
you'll find they often casually throw around expressions like
M-x replace-s RET foo RET bar RET
so it's useful to know what they mean. And in any case, Emacs has far
too many useful functions for them to all fit on the menu
bars.Fortunately, it's quite easy to pick up the key-bindings, as
they're displayed next to the menu item. My advice is to use the
menu item for, say, opening a file until you understand how it works
and feel confident with it, then try doing C-x C-f. When you're happy
with that, move on to another menu command.If you can't remember what a particular combination of keys
does, select Describe Key from the
Help menu and type it in—Emacs will tell you
what it does. You can also use the Command
Apropos menu item to find out all the commands which
contain a particular word in them, with the key binding next to
it.By the way, the expression above means hold down the
Meta key, press x, release the
Meta key, type replace-s
(short for replace-string—another feature of
Emacs is that you can abbreviate commands), press the
return key, type foo (the
string you want replaced), press the return key,
type bar (the string you want to replace foo with)
and press return again. Emacs will then do the
search-and-replace operation you've just requested.If you're wondering what on earth the Meta key
is, it's a special key that many Unix workstations have.
Unfortunately, PC's don't have one, so it's usually the
alt key (or if you're unlucky, the escape
key).Oh, and to get out of Emacs, do C-x C-c
(that means hold down the control key, press
x, press c and release the
control key). If you have any unsaved files open,
Emacs will ask you if you want to save them. (Ignore the bit in the
documentation where it says C-z is the usual way
to leave Emacs—that leaves Emacs hanging around in the
background, and is only really useful if you're on a system which
doesn't have virtual terminals).Configuring EmacsEmacs does many wonderful things; some of them are built in,
some of them need to be configured.Instead of using a proprietary macro language for
configuration, Emacs uses a version of Lisp specially adapted for
editors, known as Emacs Lisp. This can be quite useful if you want to
go on and learn something like Common Lisp, as it's considerably
smaller than Common Lisp (although still quite big!).The best way to learn Emacs Lisp is to download the Emacs
TutorialHowever, there's no need to actually know any Lisp to get
started with configuring Emacs, as I've included a sample
.emacs file, which should be enough to get you
started. Just copy it into your home directory and restart Emacs if
it's already running; it will read the commands from the file and
(hopefully) give you a useful basic setup.A sample .emacs fileUnfortunately, there's far too much here to explain it in detail;
however there are one or two points worth mentioning.Everything beginning with a ;> is a
comment and is ignored by Emacs.In the first line, the
-*- Emacs-Lisp -*- is so that we can
edit the .emacs file itself within Emacs and get
all the fancy features for editing Emacs Lisp. Emacs usually tries to
guess this based on the filename, and may not get it right for
.emacs. The tab key is bound to an
indentation function in some modes, so when you press the tab key, it
will indent the current line of code. If you want to put a
tab character in whatever you're writing, hold the
control key down while you're pressing the
tab key.This file supports syntax highlighting for C, C++,
Perl, Lisp and Scheme, by guessing the language from the
filename.Emacs already has a pre-defined function called
next-error. In a compilation output window, this
allows you to move from one compilation error to the next by doing
M-n; we define a complementary function,
previous-error, that allows you to go to a
previous error by doing M-p. The nicest feature of
all is that C-c C-c will open up the source file
in which the error occurred and jump to the appropriate
line. We enable Emacs's ability to act as a server, so
that if you're doing something outside Emacs and you want to edit a
file, you can just type in
$ emacsclient filename
and then you can edit the file in your Emacs!Many
Emacs users set their EDITOR environment to
emacsclient so this happens every time they need
to edit a file.A sample .emacs file;; -*-Emacs-Lisp-*-
;; This file is designed to be re-evaled; use the variable first-time
;; to avoid any problems with this.
(defvar first-time t
"Flag signifying this is the first time that .emacs has been evaled")
;; Meta
(global-set-key "\M- " 'set-mark-command)
(global-set-key "\M-\C-h" 'backward-kill-word)
(global-set-key "\M-\C-r" 'query-replace)
(global-set-key "\M-r" 'replace-string)
(global-set-key "\M-g" 'goto-line)
(global-set-key "\M-h" 'help-command)
;; Function keys
(global-set-key [f1] 'manual-entry)
(global-set-key [f2] 'info)
(global-set-key [f3] 'repeat-complex-command)
(global-set-key [f4] 'advertised-undo)
(global-set-key [f5] 'eval-current-buffer)
(global-set-key [f6] 'buffer-menu)
(global-set-key [f7] 'other-window)
(global-set-key [f8] 'find-file)
(global-set-key [f9] 'save-buffer)
(global-set-key [f10] 'next-error)
(global-set-key [f11] 'compile)
(global-set-key [f12] 'grep)
(global-set-key [C-f1] 'compile)
(global-set-key [C-f2] 'grep)
(global-set-key [C-f3] 'next-error)
(global-set-key [C-f4] 'previous-error)
(global-set-key [C-f5] 'display-faces)
(global-set-key [C-f8] 'dired)
(global-set-key [C-f10] 'kill-compilation)
;; Keypad bindings
(global-set-key [up] "\C-p")
(global-set-key [down] "\C-n")
(global-set-key [left] "\C-b")
(global-set-key [right] "\C-f")
(global-set-key [home] "\C-a")
(global-set-key [end] "\C-e")
(global-set-key [prior] "\M-v")
(global-set-key [next] "\C-v")
(global-set-key [C-up] "\M-\C-b")
(global-set-key [C-down] "\M-\C-f")
(global-set-key [C-left] "\M-b")
(global-set-key [C-right] "\M-f")
(global-set-key [C-home] "\M-<")
(global-set-key [C-end] "\M->")
(global-set-key [C-prior] "\M-<")
(global-set-key [C-next] "\M->")
;; Mouse
(global-set-key [mouse-3] 'imenu)
;; Misc
(global-set-key [C-tab] "\C-q\t") ; Control tab quotes a tab.
(setq backup-by-copying-when-mismatch t)
;; Treat 'y' or <CR> as yes, 'n' as no.
(fset 'yes-or-no-p 'y-or-n-p)
(define-key query-replace-map [return] 'act)
(define-key query-replace-map [?\C-m] 'act)
;; Load packages
(require 'desktop)
(require 'tar-mode)
;; Pretty diff mode
(autoload 'ediff-buffers "ediff" "Intelligent Emacs interface to diff" t)
(autoload 'ediff-files "ediff" "Intelligent Emacs interface to diff" t)
(autoload 'ediff-files-remote "ediff"
"Intelligent Emacs interface to diff") (if first-time
(setq auto-mode-alist
(append '(("\\.cpp$" . c++-mode)
("\\.hpp$" . c++-mode)
("\\.lsp$" . lisp-mode)
("\\.scm$" . scheme-mode)
("\\.pl$" . perl-mode)
) auto-mode-alist)))
;; Auto font lock mode
(defvar font-lock-auto-mode-list
(list 'c-mode 'c++-mode 'c++-c-mode 'emacs-lisp-mode 'lisp-mode 'perl-mode 'scheme-mode)
"List of modes to always start in font-lock-mode")
(defvar font-lock-mode-keyword-alist
'((c++-c-mode . c-font-lock-keywords)
(perl-mode . perl-font-lock-keywords))
"Associations between modes and keywords")
(defun font-lock-auto-mode-select ()
"Automatically select font-lock-mode if the current major mode is
in font-lock-auto-mode-list"
(if (memq major-mode font-lock-auto-mode-list)
(progn
(font-lock-mode t))
)
)
(global-set-key [M-f1] 'font-lock-fontify-buffer)
;; New dabbrev stuff
;(require 'new-dabbrev)
(setq dabbrev-always-check-other-buffers t)
(setq dabbrev-abbrev-char-regexp "\\sw\\|\\s_")
(add-hook 'emacs-lisp-mode-hook
'(lambda ()
(set (make-local-variable 'dabbrev-case-fold-search) nil)
(set (make-local-variable 'dabbrev-case-replace) nil)))
(add-hook 'c-mode-hook
'(lambda ()
(set (make-local-variable 'dabbrev-case-fold-search) nil)
(set (make-local-variable 'dabbrev-case-replace) nil)))
(add-hook 'text-mode-hook
'(lambda ()
(set (make-local-variable 'dabbrev-case-fold-search) t)
(set (make-local-variable 'dabbrev-case-replace) t)))
;; C++ and C mode...
(defun my-c++-mode-hook ()
(setq tab-width 4)
(define-key c++-mode-map "\C-m" 'reindent-then-newline-and-indent)
(define-key c++-mode-map "\C-ce" 'c-comment-edit)
(setq c++-auto-hungry-initial-state 'none)
(setq c++-delete-function 'backward-delete-char)
(setq c++-tab-always-indent t)
(setq c-indent-level 4)
(setq c-continued-statement-offset 4)
(setq c++-empty-arglist-indent 4))
(defun my-c-mode-hook ()
(setq tab-width 4)
(define-key c-mode-map "\C-m" 'reindent-then-newline-and-indent)
(define-key c-mode-map "\C-ce" 'c-comment-edit)
(setq c-auto-hungry-initial-state 'none)
(setq c-delete-function 'backward-delete-char)
(setq c-tab-always-indent t)
;; BSD-ish indentation style
(setq c-indent-level 4)
(setq c-continued-statement-offset 4)
(setq c-brace-offset -4)
(setq c-argdecl-indent 0)
(setq c-label-offset -4))
;; Perl mode
(defun my-perl-mode-hook ()
(setq tab-width 4)
(define-key c++-mode-map "\C-m" 'reindent-then-newline-and-indent)
(setq perl-indent-level 4)
(setq perl-continued-statement-offset 4))
;; Scheme mode...
(defun my-scheme-mode-hook ()
(define-key scheme-mode-map "\C-m" 'reindent-then-newline-and-indent))
;; Emacs-Lisp mode...
(defun my-lisp-mode-hook ()
(define-key lisp-mode-map "\C-m" 'reindent-then-newline-and-indent)
(define-key lisp-mode-map "\C-i" 'lisp-indent-line)
(define-key lisp-mode-map "\C-j" 'eval-print-last-sexp))
;; Add all of the hooks...
(add-hook 'c++-mode-hook 'my-c++-mode-hook)
(add-hook 'c-mode-hook 'my-c-mode-hook)
(add-hook 'scheme-mode-hook 'my-scheme-mode-hook)
(add-hook 'emacs-lisp-mode-hook 'my-lisp-mode-hook)
(add-hook 'lisp-mode-hook 'my-lisp-mode-hook)
(add-hook 'perl-mode-hook 'my-perl-mode-hook)
;; Complement to next-error
(defun previous-error (n)
"Visit previous compilation error message and corresponding source code."
(interactive "p")
(next-error (- n)));; Misc...
(transient-mark-mode 1)
(setq mark-even-if-inactive t)
(setq visible-bell nil)
(setq next-line-add-newlines nil)
(setq compile-command "make")
(setq suggest-key-bindings nil)
(put 'eval-expression 'disabled nil)
(put 'narrow-to-region 'disabled nil)
(put 'set-goal-column 'disabled nil)
;; Elisp archive searching
(autoload 'format-lisp-code-directory "lispdir" nil t)
(autoload 'lisp-dir-apropos "lispdir" nil t)
(autoload 'lisp-dir-retrieve "lispdir" nil t)
(autoload 'lisp-dir-verify "lispdir" nil t)
;; Font lock mode
(defun my-make-face (face colour &optional bold)
"Create a face from a colour and optionally make it bold"
(make-face face)
(copy-face 'default face)
(set-face-foreground face colour)
(if bold (make-face-bold face))
)
(if (eq window-system 'x)
(progn
(my-make-face 'blue "blue")
(my-make-face 'red "red")
(my-make-face 'green "dark green")
(setq font-lock-comment-face 'blue)
(setq font-lock-string-face 'bold)
(setq font-lock-type-face 'bold)
(setq font-lock-keyword-face 'bold)
(setq font-lock-function-name-face 'red)
(setq font-lock-doc-string-face 'green)
(add-hook 'find-file-hooks 'font-lock-auto-mode-select)
(setq baud-rate 1000000)
(global-set-key "\C-cmm" 'menu-bar-mode)
(global-set-key "\C-cms" 'scroll-bar-mode)
(global-set-key [backspace] 'backward-delete-char)
; (global-set-key [delete] 'delete-char)
(standard-display-european t)
(load-library "iso-transl")))
;; X11 or PC using direct screen writes
(if window-system
(progn
;; (global-set-key [M-f1] 'hilit-repaint-command)
;; (global-set-key [M-f2] [?\C-u M-f1])
(setq hilit-mode-enable-list
'(not text-mode c-mode c++-mode emacs-lisp-mode lisp-mode
scheme-mode)
hilit-auto-highlight nil
hilit-auto-rehighlight 'visible
hilit-inhibit-hooks nil
hilit-inhibit-rebinding t)
(require 'hilit19)
(require 'paren))
(setq baud-rate 2400) ; For slow serial connections
)
;; TTY type terminal
(if (and (not window-system)
(not (equal system-type 'ms-dos)))
(progn
(if first-time
(progn
(keyboard-translate ?\C-h ?\C-?)
(keyboard-translate ?\C-? ?\C-h)))))
;; Under UNIX
(if (not (equal system-type 'ms-dos))
(progn
(if first-time
(server-start))))
;; Add any face changes here
(add-hook 'term-setup-hook 'my-term-setup-hook)
(defun my-term-setup-hook ()
(if (eq window-system 'pc)
(progn
;; (set-face-background 'default "red")
)))
;; Restore the "desktop" - do this as late as possible
(if first-time
(progn
(desktop-load-default)
(desktop-read)))
;; Indicate that this file has been read at least once
(setq first-time nil)
;; No need to debug anything now
(setq debug-on-error nil)
;; All done
(message "All done, %s%s" (user-login-name) ".")
Extending the Range of Languages Emacs UnderstandsNow, this is all very well if you only want to program in the
languages already catered for in the .emacs file
(C, C++, Perl, Lisp and Scheme), but what happens if a new language
called whizbang comes out, full of exciting
features?The first thing to do is find out if whizbang
comes with any files that tell Emacs about the language. These
usually end in .el, short for Emacs
Lisp. For example, if whizbang is a FreeBSD
port, we can locate these files by doing
$ find /usr/ports/lang/whizbang -name "*.el" -print
and install them by copying them into the Emacs site Lisp directory. On
FreeBSD 2.1.0-RELEASE, this is
/usr/local/share/emacs/site-lisp.So for example, if the output from the find command was
/usr/ports/lang/whizbang/work/misc/whizbang.el
we would do
$ cp /usr/ports/lang/whizbang/work/misc/whizbang.el /usr/local/share/emacs/site-lispNext, we need to decide what extension whizbang source files
have. Let's say for the sake of argument that they all end in
.wiz. We need to add an entry to our
.emacs file to make sure Emacs will be able to
use the information in whizbang.el.Find the auto-mode-alist entry in
.emacs and add a line for whizbang, such
as:
…>
("\\.lsp$" . lisp-mode)
("\\.wiz$" . whizbang-mode)
("\\.scm$" . scheme-mode)
…>
This means that Emacs will automatically go into
whizbang-mode when you edit a file ending in
.wiz.Just below this, you'll find the
font-lock-auto-mode-list entry. Add
whizbang-mode to it like so:
;; Auto font lock mode
(defvar font-lock-auto-mode-list
(list 'c-mode 'c++-mode 'c++-c-mode 'emacs-lisp-mode 'whizbang-mode 'lisp-mode 'perl-mode 'scheme-mode)
"List of modes to always start in font-lock-mode")
This means that Emacs will always enable
font-lock-mode (ie syntax highlighting) when
editing a .wiz file.And that's all that's needed. If there's anything else you want
done automatically when you open up a .wiz file,
you can add a whizbang-mode hook (see
my-scheme-mode-hook for a simple example that
adds auto-indent).Further ReadingBrian Harvey and Matthew Wright
Simply Scheme
MIT 1994.
ISBN 0-262-08226-8Randall Schwartz
Learning Perl
O'Reilly 1993
ISBN 1-56592-042-2Patrick Henry Winston and Berthold Klaus Paul Horn
Lisp (3rd Edition)
Addison-Wesley 1989
ISBN 0-201-08319-1Brian W. Kernighan and Rob Pike
The Unix Programming Environment
Prentice-Hall 1984
ISBN 0-13-937681-XBrian W. Kernighan and Dennis M. Ritchie
The C Programming Language (2nd Edition)
Prentice-Hall 1988
ISBN 0-13-110362-8Bjarne Stroustrup
The C++ Programming Language
Addison-Wesley 1991
ISBN 0-201-53992-6W. Richard Stevens
Advanced Programming in the Unix Environment
Addison-Wesley 1992
ISBN 0-201-56317-7W. Richard Stevens
Unix Network Programming
Prentice-Hall 1990
ISBN 0-13-949876-1