0.6g EditionVersion 0.6g
Copyright © 1999-2006 Konstantin Boldyshev
Copyright © 1996-1999 Francois-Rene Rideau
$Date: 2006/02/11 08:26:26 $
This is the Linux Assembly HOWTO, version 0.6g. This document describes how to program in assembly language using free programming tools, focusing on development for or from the Linux Operating System, mostly on IA-32 (i386) platform. Included material may or may not be applicable to other hardware and/or software platforms.
Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.1; with no Invariant Sections, with no Front-Cover Texts, and no Back-Cover texts.
You can skip this chapter if you are familiar with HOWTOs, or just hate to read all this assembly-unrelated crap.
Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License Version 1.1; with no Invariant Sections, with no Front-Cover Texts, and no Back-Cover texts. A copy of the license is included in the GNU Free Documentation License appendix.
This document aims answering questions of those who program or want to program 32-bit x86 assembly using free software, particularly under the Linux operating system. At many places Universal Resource Locators (URL) are given for some software or documentation repository. This document also points to other documents about non-free, non-x86, or non-32-bit assemblers, although this is not its primary goal. Also note that there are FAQs and docs about programming on your favorite platform (whatever it is), which you should consult for platform-specific issues, not related directly to assembly programming.
Because the main interest of assembly programming is to build the guts of operating systems, interpreters, compilers, and games, where C compiler fails to provide the needed expressiveness (performance is more and more seldom as issue), we are focusing on development of such kind of software.
If you don't know what free software is, please do read carefully the GNU General Public License (GPL or copyleft), which is used in a lot of free software, and is the model for most of their licenses. It generally comes in a file named COPYING (or COPYING.LIB). Literature from the Free Software Foundation (FSF) might help you too. Particularly, the interesting feature of free software is that it comes with source code which you can consult and correct, or sometimes even borrow from. Read your particular license carefully and do comply to it.
This is an interactively evolving document: you are especially invited to ask questions, to answer questions, to correct given answers, to give pointers to new software, to point the current maintainer to bugs or deficiencies in the pages. In one word, contribute!
To contribute, please contact the maintainer.
Korean translation of this HOWTO is avalilable at http://kldp.org/HOWTO/html/Assembly-HOWTO/. Turkish translation of this HOWTO is available at http://belgeler.org/howto/assembly-howto.html. Incomplete Russian translation is available at http://volgograd.lug.ru/wiki/GrableVodstvo/articles/AssembleInLinux/. Also, there was a French translation of the early HOWTO versions, but I can't find it now.
Well, I wouldn't want to interfere with what you're doing, but here is some advice from the hard-earned experience.
Assembly can express very low-level things:
you can access machine-dependent registers and I/O
you can control the exact code behavior in critical sections that might otherwise involve deadlock between multiple software threads or hardware devices
you can break the conventions of your usual compiler, which might allow some optimizations (like temporarily breaking rules about memory allocation, threading, calling conventions, etc)
you can build interfaces between code fragments using incompatible conventions (e.g. produced by different compilers, or separated by a low-level interface)
you can get access to unusual programming modes of your processor (e.g. 16 bit mode to interface startup, firmware, or legacy code on Intel PCs)
you can produce reasonably fast code for tight loops to cope with a bad non-optimizing compiler (but then, there are free optimizing compilers available!)
you can produce hand-optimized code perfectly tuned for your particular hardware setup, though not to someone else's
you can write some code for your new language's optimizing compiler (that is something what very few ones will ever do, and even they not often)
i.e. you can be in complete control of your code
Assembly is a very low-level language (the lowest above hand-coding the binary instruction patterns). This means
it is long and tedious to write initially
it is quite bug-prone
your bugs can be very difficult to chase
your code can be fairly difficult to understand and modify, i.e. to maintain
the result is non-portable to other architectures, existing or upcoming
your code will be optimized only for a certain implementation of a same architecture: for instance, among Intel-compatible platforms each CPU design and its variations (relative latency, through-output, and capacity, of processing units, caches, RAM, bus, disks, presence of FPU, MMX, 3DNOW, SIMD extensions, etc) implies potentially completely different optimization techniques. CPU designs already include: Intel 386, 486, Pentium, PPro, PII, PIII, PIV; Cyrix 5x86, 6x86, M2; AMD K5, K6 (K6-2, K6-III), K7 (Athlon, Duron). New designs keep popping up, so don't expect either this listing and your code to be up-to-date.
you spend more time on a few details and can't focus on small and large algorithmic design, that are known to bring the largest part of the speed up (e.g. you might spend some time building very fast list/array manipulation primitives in assembly; only a hash table would have sped up your program much more; or, in another context, a binary tree; or some high-level structure distributed over a cluster of CPUs)
a small change in algorithmic design might completely invalidate all your existing assembly code. So that either you're ready (and able) to rewrite it all, or you're tied to a particular algorithmic design
On code that ain't too far from what's in standard benchmarks, commercial optimizing compilers outperform hand-coded assembly (well, that's less true on the x86 architecture than on RISC architectures, and perhaps less true for widely available/free compilers; anyway, for typical C code, GCC is fairly good);
And in any case, as moderator John Levine says on comp.compilers,
"compilers make it a lot easier to use complex data structures,
and compilers don't get bored halfway through
and generate reliably pretty good code."
They will also correctly propagate code transformations throughout the whole (huge) program when optimizing code between procedures and module boundaries.
All in all, you might find that though using assembly is sometimes needed, and might even be useful in a few cases where it is not, you'll want to:
minimize use of assembly code
encapsulate this code in well-defined interfaces
have your assembly code automatically generated from patterns expressed in a higher-level language than assembly (e.g. GCC inline assembly macros)
have automatic tools translate these programs into assembly code
have this code be optimized if possible
All of the above, i.e. write (an extension to) an optimizing compiler back-end.
Even when assembly is needed (e.g. OS development), you'll find that not so much of it is required, and that the above principles retain.
See the Linux kernel sources concerning this: as little assembly as needed, resulting in a fast, reliable, portable, maintainable OS. Even a successful game like DOOM was almost massively written in C, with a tiny part only being written in assembly for speed up.
As Charles Fiterman says on comp.compilers about human vs computer-generated assembly code:
The human should always win and here is why.
First the human writes the whole thing in a high level language.
Second he profiles it to find the hot spots where it spends its time.
Third he has the compiler produce assembly for those small sections of code.
Fourth he hand tunes them looking for tiny improvements over the machine generated code.
The human wins because he can use the machine.
Languages like ObjectiveCAML, SML, CommonLISP, Scheme, ADA, Pascal, C, C++, among others, all have free optimizing compilers that will optimize the bulk of your programs, and often do better than hand-coded assembly even for tight loops, while allowing you to focus on higher-level details, and without forbidding you to grab a few percent of extra performance in the above-mentioned way, once you've reached a stable design. Of course, there are also commercial optimizing compilers for most of these languages, too!
Some languages have compilers that produce C code, which can be further optimized by a C compiler: LISP, Scheme, Perl, and many other. Speed is fairly good.
As for speeding code up, you should do it only for parts of a program that a profiling tool has consistently identified as being a performance bottleneck.
Hence, if you identify some code portion as being too slow, you should
first try to use a better algorithm;
then try to compile it rather than interpret it;
then try to enable and tweak optimization from your compiler;
then give the compiler hints about how to optimize (typing information in LISP; register usage with GCC; lots of options in most compilers, etc).
then possibly fallback to assembly programming
Finally, before you end up writing assembly, you should inspect generated code, to check that the problem really is with bad code generation, as this might really not be the case: compiler-generated code might be better than what you'd have written, particularly on modern multi-pipelined architectures! Slow parts of a program might be intrinsically so. The biggest problems on modern architectures with fast processors are due to delays from memory access, cache-misses, TLB-misses, and page-faults; register optimization becomes useless, and you'll more profitably re-think data structures and threading to achieve better locality in memory access. Perhaps a completely different approach to the problem might help, then.
There are many reasons to inspect compiler-generated assembly code. Here is what you'll do with such code:
check whether generated code can be obviously enhanced with hand-coded assembly (or by tweaking compiler switches)
when that's the case, start from generated code and modify it instead of starting from scratch
more generally, use generated code as stubs to modify, which at least gets right the way your assembly routines interface to the external world
track down bugs in your compiler (hopefully the rarer)
The standard way to have assembly code be generated is to invoke your compiler with the -S flag. This works with most Unix compilers, including the GNU C Compiler (GCC), but YMMV. As for GCC, it will produce more understandable assembly code with the -fverbose-asm command-line option. Of course, if you want to get good assembly code, don't forget your usual optimization options and hints!
As you probably noticed, in general case you don't need to use assembly language in Linux programming. Unlike DOS, you do not have to write Linux drivers in assembly (well, actually you can do it if you really want). And with modern optimizing compilers, if you care of speed optimization for different CPU's, it's much simpler to write in C. However, if you're reading this, you might have some reason to use assembly instead of C/C++.
You may need to use assembly, or you may want to use assembly. In short, main practical (need) reasons of diving into the assembly realm are small code and libc independence. Impractical (want), and the most often reason is being just an old crazy hacker, who has twenty years old habit of doing everything in assembly language.
However, if you're porting Linux to some embedded hardware you can be quite short at the size of whole system: you need to fit kernel, libc and all that stuff of (file|find|text|sh|etc.) utils into several hundreds of kilobytes, and every kilobyte costs much. So, one of the possible ways is to rewrite some (or all) parts of system in assembly, and this will really save you a lot of space. For instance, a simple httpd written in assembly can take less than 600 bytes; you can fit a server consisting of kernel, httpd and ftpd in 400 KB or less... Think about it.
The well-known GNU C/C++ Compiler (GCC), an optimizing 32-bit compiler at the heart of the GNU project, supports the x86 architecture quite well, and includes the ability to insert assembly code in C programs, in such a way that register allocation can be either specified or left to GCC. GCC works on most available platforms, notably Linux, *BSD, VSTa, OS/2, *DOS, Win*, etc.
GCC home page is http://gcc.gnu.org.
DOS port of GCC is called DJGPP.
There is also an OS/2 port of GCC called EMX; it works under DOS too, and includes lots of unix-emulation library routines. Look around the following site: ftp://ftp.leo.org/pub/comp/os/os2/leo/gnu/emx+gcc/.
The documentation of GCC includes documentation files in TeXinfo format. You can compile them with TeX and print then result, or convert them to .info, and browse them with emacs, or convert them to .html, or nearly whatever you like; convert (with the right tools) to whatever you like, or just read as is. The .info files are generally found on any good installation for GCC.
The right section to look for is C Extensions::Extended Asm::
Section Invoking GCC::Submodel Options::i386 Options:: might help too. Particularly, it gives the i386 specific constraint names for registers: abcdSDB correspond to %eax, %ebx, %ecx, %edx, %esi, %edi and %ebp respectively (no letter for %esp).
The DJGPP Games resource (not only for game hackers) had page specifically about assembly, but it's down. Its data have nonetheless been recovered on the DJGPP site, that contains a mine of other useful information: http://www.delorie.com/djgpp/doc/brennan/.
GCC depends on GAS for assembling and follows its syntax (see below); do mind that inline asm needs percent characters to be quoted, they will be passed to GAS. See the section about GAS below.
Find lots of useful examples in the linux/include/asm-i386/ subdirectory of the sources for the Linux kernel.
Because assembly routines from the kernel headers (and most likely your own headers, if you try making your assembly programming as clean as it is in the linux kernel) are embedded in extern inline functions, GCC must be invoked with the -O flag (or -O2, -O3, etc), for these routines to be available. If not, your code may compile, but not link properly, since it will be looking for non-inlined extern functions in the libraries against which your program is being linked! Another way is to link against libraries that include fallback versions of the routines.
Inline assembly can be disabled with -fno-asm, which will have the compiler die when using extended inline asm syntax, or else generate calls to an external function named asm() that the linker can't resolve. To counter such flag, -fasm restores treatment of the asm keyword.
More generally, good compile flags for GCC on the x86 platform are
gcc -O2 -fomit-frame-pointer -W -Wall
-O2 is the good optimization level in most cases. Optimizing besides it takes more time, and yields code that is much larger, but only a bit faster; such over-optimization might be useful for tight loops only (if any), which you may be doing in assembly anyway. In cases when you need really strong compiler optimization for a few files, do consider using up to -O6.
-fomit-frame-pointer allows generated code to skip the stupid frame pointer maintenance, which makes code smaller and faster, and frees a register for further optimizations. It precludes the easy use of debugging tools (gdb), but when you use these, you just don't care about size and speed anymore anyway.
-W -Wall enables all useful warnings and helps you to catch obvious stupid errors.
You can add some CPU-specific -m486 or such flag so that GCC will produce code that is more adapted to your precise CPU. Note that modern GCC has -mpentium and such flags (and PGCC has even more), whereas GCC 2.7.x and older versions do not. A good choice of CPU-specific flags should be in the Linux kernel. Check the TeXinfo documentation of your current GCC installation for more.
-m386 will help optimize for size, hence also for speed on computers whose memory is tight and/or loaded, since big programs cause swap, which more than counters any "optimization" intended by the larger code. In such settings, it might be useful to stop using C, and use instead a language that favors code factorization, such as a functional language and/or FORTH, and use a bytecode- or wordcode- based implementation.
Note that you can vary code generation flags from file to file, so performance-critical files will use maximum optimization, whereas other files will be optimized for size.
To optimize even more, option -mregparm=2 and/or corresponding function attribute might help, but might pose lots of problems when linking to foreign code, including libc. There are ways to correctly declare foreign functions so the right call sequences be generated, or you might want to recompile the foreign libraries to use the same register-based calling convention...
Note that you can add make these flags the default by editing file /usr/lib/gcc-lib/i486-linux/188.8.131.52/specs or wherever that is on your system (better not add -W -Wall there, though). The exact location of the GCC specs files on system can be found by gcc -v.
GCC allows (and requires) you to specify register constraints in your inline assembly code, so the optimizer always know about it; thus, inline assembly code is really made of patterns, not forcibly exact code.
Thus, you can put your assembly into CPP macros, and inline C functions, so anyone can use it in as any C function/macro. Inline functions resemble macros very much, but are sometimes cleaner to use. Beware that in all those cases, code will be duplicated, so only local labels (of 1: style) should be defined in that asm code. However, a macro would allow the name for a non local defined label to be passed as a parameter (or else, you should use additional meta-programming methods). Also, note that propagating inline asm code will spread potential bugs in them; so watch out doubly for register constraints in such inline asm code.
Lastly, the C language itself may be considered as a good abstraction to assembly programming, which relieves you from most of the trouble of assembling.
GAS is the GNU Assembler, that GCC relies upon.
Find it at the same place where you've found GCC, in the binutils package. The latest version of binutils is available from http://sources.redhat.com/binutils/.
Because GAS was invented to support a 32-bit unix compiler, it uses standard AT&T syntax, which resembles a lot the syntax for standard m68k assemblers, and is standard in the UNIX world. This syntax is neither worse, nor better than the Intel syntax. It's just different. When you get used to it, you find it much more regular than the Intel syntax, though a bit boring.
Here are the major caveats about GAS syntax:
Register names are prefixed with %, so that registers are %eax, %dl and so on, instead of just eax, dl, etc. This makes it possible to include external C symbols directly in assembly source, without any risk of confusion, or any need for ugly underscore prefixes.
The order of operands is source(s) first, and destination last, as opposed to the Intel convention of destination first and sources last. Hence, what in Intel syntax is mov eax,edx (move contents of register edx into register eax) will be in GAS syntax mov %edx,%eax.
The operand size is specified as a suffix to the instruction name. The suffix is b for (8-bit) byte, w for (16-bit) word, and l for (32-bit) long. For instance, the correct syntax for the above instruction would have been movl %edx,%eax. However, gas does not require strict AT&T syntax, so the suffix is optional when size can be guessed from register operands, and else defaults to 32-bit (with a warning).
Immediate operands are marked with a $ prefix, as in addl $5,%eax (add immediate long value 5 to register %eax).
Missing operand prefix indicates that it is memory-contents; hence movl $foo,%eax puts the address of variable foo into register %eax, but movl foo,%eax puts the contents of variable foo into register %eax.
Indexing or indirection is done by enclosing the index register or indirection memory cell address in parentheses, as in testb $0x80,17(%ebp) (test the high bit of the byte value at offset 17 from the cell pointed to by %ebp).
Note: There are few programs which may help you to convert source code between AT&T and Intel assembler syntaxes; some of the are capable of performing conversion in both directions.
GAS has comprehensive documentation in TeXinfo format, which comes at least with the source distribution. Browse extracted .info pages with Emacs or whatever. There used to be a file named gas.doc or as.doc around the GAS source package, but it was merged into the TeXinfo docs. Of course, in case of doubt, the ultimate documentation is the sources themselves! A section that will particularly interest you is Machine Dependencies::i386-Dependent::
Again, the sources for Linux (the OS kernel) come in as excellent examples; see under linux/arch/i386/ the following files: kernel/*.S, boot/compressed/*.S, math-emu/*.S.
If you are writing kind of a language, a thread package, etc., you might as well see how other languages ( OCaml, Gforth, etc.), or thread packages (QuickThreads, MIT pthreads, LinuxThreads, etc), or whatever else do it.
Finally, just compiling a C program to assembly might show you the syntax for the kind of instructions you want. See section Do you need assembly? above.
Good news are that starting from binutils 2.10 release, GAS supports Intel syntax too. It can be triggered with .intel_syntax directive. Unfortunately this mode is not documented (yet?) in the official binutils manual, so if you want to use it, try to examine http://www.lxhp.in-berlin.de/lhpas86.html, which is an extract from AMD 64bit port of binutils 2.11.
Binutils (184.108.40.206.25+) now fully support 16-bit mode (registers and addressing) on i386 PCs. Use .code16 and .code32 to switch between assembly modes.
Also, a neat trick used by several people (including the oskit authors) is to force GCC to produce code for 16-bit real mode, using an inline assembly statement asm(".code16\n"). GCC will still emit only 32-bit addressing modes, but GAS will insert proper 32-bit prefixes for them.
GAS has some macro capability included, as detailed in the texinfo docs. Moreover, while GCC recognizes .s files as raw assembly to send to GAS, it also recognizes .S files as files to pipe through CPP before feeding them to GAS. Again and again, see Linux sources for examples.
GAS also has GASP (GAS Preprocessor), which adds all the usual macroassembly tricks to GAS. GASP comes together with GAS in the GNU binutils archive. It works as a filter, like CPP and M4. I have no idea on details, but it comes with its own texinfo documentation, which you would like to browse (info gasp), print, grok. GAS with GASP looks like a regular macro-assembler to me.
The Netwide Assembler project provides cool i386 assembler, written in C, that should be modular enough to eventually support all known syntaxes and object formats.
Binary release on your usual metalab mirror in devel/lang/asm/ directory. Should also be available as .rpm or .deb in your usual Linux distribution.
The syntax is Intel-style. Comprehensive macroprocessing support is integrated.
Supported object file formats are bin, aout, coff, elf, as86, obj (DOS), win32, rdf (their own format).
NASM can be used as a backend for the free LCC compiler (support files included).
Unless you're using BCC as a 16-bit compiler (which is out of scope of this 32-bit HOWTO), you should definitely use NASM instead of say AS86 or MASM, because it runs on all platforms.
NASM comes with a disassembler, NDISASM.
Its hand-written parser makes it much faster than GAS, though of course, it doesn't support three bazillion different architectures. If you like Intel-style syntax, as opposed to GAS syntax, then it should be the assembler of choice...
Note: There are few programs which may help you to convert source code between AT&T and Intel assembler syntaxes; some of the are capable of performing conversion in both directions.
There are other assemblers with various interesting and outstanding features which may be of your interest as well.
They can be in various stages of development, and can be non-classic/high-level/whatever else.
AS86 is a 80x86 assembler (16-bit and 32-bit) with integrated macro support. It has mostly Intel-syntax, though it differs slightly as for addressing modes. Some time ago it was used in a several projects, including the Linux kernel, but eventually most of those projects have moved to GAS or NASM. AFAIK, only ELKS continues to use it.
AS86 can be found at http://www.cix.co.uk/~mayday/, in bin86 package with linker (ld86), or as separate archive. Documentation is available as the man page and as.doc from the source package. When in doubt, the source code itself is often a good doc: though it is not very well commented, the programming style is straightforward. You might try to see how as86 is(was) used in ELKS, LILO, or Tunes 0.0.0.25...
A completely outdated version 0.4 of AS86 is distributed by HJLu just to compile the Linux kernel versions prior to 2.4, in a package named bin86, available in any Linux GCC repository. But I advise no one to use it for anything else but compiling Linux. This version supports only a hacked minix object file format, which is not supported by the GNU binutils or anything, and it has a few bugs in 32-bit mode, so you really should better keep it only for compiling Linux.
|Using AS86 with BCC|
Here's the GNU Makefile entry for using BCC to transform .s asm into both a.out .o object and .l listing:
Remove the %.l, -A-l, and -A$*.l, if you don't want any listing. If you want something else than a.out, you can examine BCC docs about the other supported formats, and/or use the objcopy utility from the GNU binutils package.
YASM is a complete rewrite of the NASM assembler under the GNU GPL (some portions are under the "new" BSD License). It is designed from the ground up to allow for multiple syntaxes to be supported (eg, NASM, TASM, GAS, etc.) in addition to multiple output object formats. Another primary module of the overall design is an optimizer module.
It looks promising; it is under heavy development, and you may want to take part. See http://www.tortall.net/projects/yasm/.
FASM (flat assembler) is a fast, efficient 80x86 assembler that runs in 'flat real mode'. Unlike many other 80x86 assemblers, FASM only requires the source code to include the information it really needs. It is written in itself and is very small and fast. It runs on DOS/Windows/Linux and can produce flat binary, DOS EXE, Win32 PE, COFF and Linux ELF output. See http://flatassembler.net.
osimpa is an assembler for Intel 80386 processors and subsequent, written entirely in the GNU Bash command interpreter shell. The predecessor of osimpa was shasm. osimpa is much cleaned up, can create useful Linux ELF executables, and has various HLL-like extensions and programmer convenience commands.
It is (of course) slower than other assemblers. It has its own syntax (and uses its own names for x86 opcodes) Fairly good documentation is included. Check it out: ftp://linux01.gwdg.de/pub/cLIeNUX/interim/. Probably you'll not use it on regular basis, but at least it deserves your interest as an interesting idea.
Aasm is an advanced assembler designed to support several target architectures. It has been designed to be easily extended and, should be considered as a good alternative to monolithic assembler development for each new target CPUs and binary file formats.
Aasm should make assembly programming easier for developer, by providing a set of advanced features including symbol scopes, an expressions engine, big integer support, macro capability, numerous and accurate warning messages... Its dynamic modular architecture enables Aasm to extend its set of features with plug-ins by taking advantages of dynamic libraries.
The input module supports Intel syntax (like nasm, tasm, masm, etc.). The x86 assembler module supports all opcodes up to P6 including MMX, SSE and 3DNow! extensions. F-CPU and SPARC assembler modules are under development. Several output modules are available for ELF, COFF, IntelHex, and raw binary formats.
The Table Driven Assembler (TDASM) is a free portable cross assembler for any kind of assembly language. It should be possible to use it as a compiler to any target microprocessor using a table that defines the compilation process.
It is available from http://www.penguin.cz/~niki/tdasm/.
HLA is a High Level Assembly language. It uses a high level language like syntax (similar to Pascal, C/C++, and other HLLs) for variable declarations, procedure declarations, and procedure calls. It uses a modified assembly language syntax for the standard machine instructions. It also provides several high level language style control structures (if, while, repeat..until, etc.) that help you write much more readable code.
HLA is free and comes with source, Linux and Win32 versions available. On Win32 you need MASM and a 32-bit version of MS-link on Win32, on Linux you nee GAS, because HLA produces specified assembler code and uses that assembler for final assembling and linking.
TALC is another free MASM/Win32 based compiler (however it supports ELF output, does it?).
TAL stands for Typed Assembly Language. It extends traditional untyped assembly languages with typing annotations, memory management primitives, and a sound set of typing rules, to guarantee the memory safety, control flow safety,and type safety of TAL programs. Moreover, the typing constructs are expressive enough to encode most source language programming features including records and structures, arrays, higher-order and polymorphic functions, exceptions, abstract data types, subtyping, and modules. Just as importantly, TAL is flexible enough to admit many low-level compiler optimizations. Consequently, TAL is an ideal target platform for type-directed compilers that want to produce verifiably safe code for use in secure mobile code applications or extensible operating system kernels.
Free Pascal has an internal 32-bit assembler (based on NASM tables) and a switchable output that allows:
Binary (ELF and coff when crosscompiled .o) output
AS (aout,coff, elf32)
The MASM and TASM output are not as good debugged as the other two, but can be handy sometimes.
The assembler's look and feel are based on Turbo Pascal's internal BASM, and the IDE supports similar highlighting, and FPC can fully integrate with gcc (on C level, not C++).
Using a dummy RTL, one can even generate pure assembler programs.
Win32Forth is a free 32-bit ANS FORTH system that successfully runs under Win32s, Win95, Win/NT. It includes a free 32-bit assembler (either prefix or postfix syntax) integrated into the reflective FORTH language. Macro processing is done with the full power of the reflective language FORTH; however, the only supported input and output contexts is Win32For itself (no dumping of .obj file, but you could add that feature yourself, of course). Find it at ftp://ftp.forth.org/pub/Forth/Compilers/native/windows/Win32For/.
Terse is a programming tool that provides THE most compact assembler syntax for the x86 family! However, it is evil proprietary software. It is said that there was a project for a free clone somewhere, that was abandoned after worthless pretenses that the syntax would be owned by the original author. Thus, if you're looking for a nifty programming project related to assembly hacking, I invite you to develop a terse-syntax frontend to NASM, if you like that syntax.
As an interesting historic remark, on comp.compilers,
1999/07/11 19:36:51, the moderator wrote:
"There's no reason that assemblers have to have awful syntax. About
30 years ago I used Niklaus Wirth's PL360, which was basically a S/360
assembler with Algol syntax and a a little syntactic sugar like while
loops that turned into the obvious branches. It really was an
assembler, e.g., you had to write out your expressions with explicit
assignments of values to registers, but it was nice. Wirth used it to
write Algol W, a small fast Algol subset, which was a predecessor to
Pascal. As is so often the case, Algol W was a significant
improvement over many of its successors. -John"
You may find more about them, together with the basics of x86 assembly programming, in the Raymond Moon's x86 assembly FAQ.
Note that all DOS-based assemblers should work inside the Linux DOS Emulator, as well as other similar emulators, so that if you already own one, you can still use it inside a real OS. Recent DOS-based assemblers also support COFF and/or other object file formats that are supported by the GNU BFD library, so that you can use them together with your free 32-bit tools, perhaps using GNU objcopy (part of the binutils) as a conversion filter.
Assembly programming is a bore, but for critical parts of programs.
You should use the appropriate tool for the right task, so don't choose assembly when it does not fit; C, OCaml, perl, Scheme, might be a better choice in the most cases.
However, there are cases when these tools do not give fine enough control on the machine, and assembly is useful or needed. In these cases you'll appreciate a system of macroprocessing and metaprogramming that allows recurring patterns to be factored each into one indefinitely reusable definition, which allows safer programming, automatic propagation of pattern modification, etc. Plain assembler often is not enough, even when one is doing only small routines to link with C.
Whatever is the macro support from your assembler, or whatever language you use (even C!), if the language is not expressive enough to you, you can have files passed through an external filter with a Makefile rule like that:
%.s: %.S other_dependencies $(FILTER) $(FILTER_OPTIONS) < $< > $@
CPP is truly not very expressive, but it's enough for easy things, it's standard, and called transparently by GCC.
As an example of its limitations, you can't declare objects so that destructors are automatically called at the end of the declaring block; you don't have diversions or scoping, etc.
CPP comes with any C compiler. However, considering how mediocre it is, stay away from it if by chance you can make it without C.
M4 gives you the full power of macroprocessing, with a Turing equivalent language, recursion, regular expressions, etc. You can do with it everything that CPP cannot.
However, its disfunctional quoting and unquoting semantics force you to use explicit continuation-passing tail-recursive macro style if you want to do advanced macro programming (which is remindful of TeX -- BTW, has anyone tried to use TeX as a macroprocessor for anything else than typesetting ?). This is NOT worse than CPP that does not allow quoting and recursion anyway.
The right version of M4 to get is GNU m4 1.4 (or later if exists), which has the most features and the least bugs or limitations of all. m4 is designed to be slow for anything but the simplest uses, which might still be ok for most assembly programming (you are not writing million-lines assembly programs, are you?).
Instead of using an external filter that expands macros, one way to do things is to write programs that write part or all of other programs.
For instance, you could use a program outputting source code
to generate sine/cosine/whatever lookup tables,
to extract a source-form representation of a binary file,
to compile your bitmaps into fast display routines,
to extract documentation, initialization/finalization code, description tables, as well as normal code from the same source files,
to have customized assembly code, generated from a perl/shell/scheme script that does arbitrary processing,
to propagate data defined at one point only into several cross-referencing tables and code chunks.
Think about it!
Compilers like GCC, SML/NJ, Objective CAML, MIT-Scheme, CMUCL, etc, do have their own generic assembler backend, which you might choose to use, if you intend to generate code semi-automatically from the according languages, or from a language you hack: rather than write great assembly code, you may instead modify a compiler so that it dumps great assembly code!
There is a project, using the programming language Icon (with an experimental ML version), to build a basis for producing assembly-manipulating code. See around http://www.eecs.harvard.edu/~nr/toolkit/
The TUNES Project for a Free Reflective Computing System is developing its own assembler as an extension to the Scheme language, as part of its development process. It doesn't run at all yet, though help is welcome.
The assembler manipulates abstract syntax trees, so it could equally serve as the basis for a assembly syntax translator, a disassembler, a common assembler/compiler back-end, etc. Also, the full power of a real language, Scheme, make it unchallenged as for macroprocessing/metaprogramming.
This is the preferred way if you are developing mixed C-asm project. Check GCC docs and examples from Linux kernel .S files that go through gas (not those that go through as86).
32-bit arguments are pushed down stack in reverse syntactic order (hence accessed/popped in the right order), above the 32-bit near return address. %ebp, %esi, %edi, %ebx are callee-saved, other registers are caller-saved; %eax is to hold the result, or %edx:%eax for 64-bit results.
FP stack: I'm not sure, but I think result is in st(0), whole stack caller-saved. The SVR4 i386 ABI specs at http://www.caldera.com/developer/devspecs/ is a good reference point if you want more details.
Note that GCC has options to modify the calling conventions by reserving registers, having arguments in registers, not assuming the FPU, etc. Check the i386 .info pages.
Beware that you must then declare the cdecl or regparm(0) attribute for a function that will follow standard GCC calling conventions. See C Extensions::Extended Asm:: section from the GCC info pages. See also how Linux defines its asmlinkage macro...
Some C compilers prepend an underscore before every symbol, while others do not.
Particularly, Linux a.out GCC does such prepending, while Linux ELF GCC does not.
If you need to cope with both behaviors at once, see how existing packages do. For instance, get an old Linux source tree, the Elk, qthreads, or OCaml...
You can also override the implicit C->asm renaming by inserting statements like
void foo asm("bar") (void);
Note that the objcopy utility from the binutils package should allow you to transform your a.out objects into ELF objects, and perhaps the contrary too, in some cases. More generally, it will do lots of file format conversions.
Often you will be told that using C library (libc) is the only way, and direct system calls are bad. This is true. To some extent. In general, you must know that libc is not sacred, and in most cases it only does some checks, then calls kernel, and then sets errno. You can easily do this in your program as well (if you need to), and your program will be dozen times smaller, and this will result in improved performance as well, just because you're not using shared libraries (static binaries are faster). Using or not using libc in assembly programming is more a question of taste/belief than something practical. Remember, Linux is aiming to be POSIX compliant, so does libc. This means that syntax of almost all libc "system calls" exactly matches syntax of real kernel system calls (and vice versa). Besides, GNU libc(glibc) becomes slower and slower from version to version, and eats more and more memory; and so, cases of using direct system calls become quite usual. However, the main drawback of throwing libc away is that you will possibly need to implement several libc specific functions (that are not just syscall wrappers) on your own (printf() and Co.), and you are ready for that, aren't you? :-)
Here is summary of direct system calls pros and cons.
the smallest possible size; squeezing the last byte out of the system
the highest possible speed; squeezing cycles out of your favorite benchmark
full control: you can adapt your program/library to your specific language or memory requirements or whatever
no pollution by libc cruft
no pollution by C calling conventions (if you're developing your own language or environment)
static binaries make you independent from libc upgrades or crashes, or from dangling #! path to an interpreter (and are faster)
just for the fun out of it (don't you get a kick out of assembly programming?)
If any other program on your computer uses the libc, then duplicating the libc code will actually wastes memory, not saves it.
Services redundantly implemented in many static binaries are a waste of memory. But you can make your libc replacement a shared library.
Size is much better saved by having some kind of bytecode, wordcode, or structure interpreter than by writing everything in assembly. (the interpreter itself could be written either in C or assembly.) The best way to keep multiple binaries small is to not have multiple binaries, but instead to have an interpreter process files with #! prefix. This is how OCaml works when used in wordcode mode (as opposed to optimized native code mode), and it is compatible with using the libc. This is also how Tom Christiansen's Perl PowerTools reimplementation of unix utilities works. Finally, one last way to keep things small, that doesn't depend on an external file with a hardcoded path, be it library or interpreter, is to have only one binary, and have multiply-named hard or soft links to it: the same binary will provide everything you need in an optimal space, with no redundancy of subroutines or useless binary headers; it will dispatch its specific behavior according to its argv; in case it isn't called with a recognized name, it might default to a shell, and be possibly thus also usable as an interpreter!
You cannot benefit from the many functionalities that libc provides besides mere linux syscalls: that is, functionality described in section 3 of the manual pages, as opposed to section 2, such as malloc, threads, locale, password, high-level network management, etc.
Therefore, you might have to reimplement large parts of libc, from printf() to malloc() and gethostbyname. It's redundant with the libc effort, and can be quite boring sometimes. Note that some people have already reimplemented "light" replacements for parts of the libc -- check them out! (Redhat's minilibc, Rick Hohensee's libsys, Felix von Leitner's dietlibc, Christian Fowelin's libASM, asmutils project is working on pure assembly libc)
Static libraries prevent you to benefit from libc upgrades as well as from libc add-ons such as the zlibc package, that does on-the-fly transparent decompression of gzip-compressed files.
The few instructions added by the libc can be a ridiculously small speed overhead as compared to the cost of a system call. If speed is a concern, your main problem is in your usage of system calls, not in their wrapper's implementation.
Using the standard assembly API for system calls is much slower than using the libc API when running in micro-kernel versions of Linux such as L4Linux, that have their own faster calling convention, and pay high convention-translation overhead when using the standard one (L4Linux comes with libc recompiled with their syscall API; of course, you could recompile your code with their API, too).
See previous discussion for general speed optimization issue.
If syscalls are too slow to you, you might want to hack the kernel sources (in C) instead of staying in userland.
If you've pondered the above pros and cons, and still want to use direct syscalls, then here is some advice.
You can easily define your system calling functions in a portable way in C (as opposed to unportable using assembly), by including asm/unistd.h, and using provided macros.
Since you're trying to replace it, go get the sources for the libc, and grok them. (And if you think you can do better, then send feedback to the authors!)
As an example of pure assembly code that does everything you want, examine Linux assembly resources.
Result is returned in eax, with a negative result being an error, whose opposite is what libc would put into errno. The user-stack is not touched, so you needn't have a valid one when doing a syscall.
Linux Kernel Internals, and especially How System Calls Are Implemented on i386 Architecture? chapter will give you more robust overview.
As for the invocation arguments passed to a process upon startup, the general principle is that the stack originally contains the number of arguments argc, then the list of pointers that constitute *argv, then a null-terminated sequence of null-terminated variable=value strings for the environment. For more details, do examine Linux assembly resources, read the sources of C startup code from your libc (crt0.S or crt1.S), or those from the Linux kernel (exec.c and binfmt_*.c in linux/fs/).
If you want to perform direct port I/O under Linux, either it's something very simple that does not need OS arbitration, and you should see the IO-Port-Programming mini-HOWTO; or it needs a kernel device driver, and you should try to learn more about kernel hacking, device driver development, kernel modules, etc, for which there are other excellent HOWTOs and documents from the LDP.
Some people have even done better, writing small and robust XFree86 drivers in an interpreted domain-specific language, GAL, and achieving the efficiency of hand C-written drivers through partial evaluation (drivers not only not in asm, but not even in C!). The problem is that the partial evaluator they used to achieve efficiency is not free software. Any taker for a replacement?
Anyway, in all these cases, you'll be better when using GCC inline assembly with the macros from linux/asm/*.h than writing full assembly source files.
Such thing is theoretically possible (proof: see how DOSEMU can selectively grant hardware port access to programs), and I've heard rumors that someone somewhere did actually do it (in the PCI driver? Some VESA access stuff? ISA PnP? dunno). If you have some more precise information on that, you'll be most welcome. Anyway, good places to look for more information are the Linux kernel sources, DOSEMU sources, and sources for various low-level programs under Linux... (perhaps GGI if it supports VESA).
Basically, you must either use 16-bit protected mode or vm86 mode.
The first is simpler to setup, but only works with well-behaved code that won't do any kind of segment arithmetics or absolute segment addressing (particularly addressing segment 0), unless by chance it happens that all segments used can be setup in advance in the LDT.
The later allows for more "compatibility" with vanilla 16-bit environments, but requires more complicated handling.
In both cases, before you can jump to 16-bit code, you must
mmap any absolute address used in the 16-bit code (such as ROM, video buffers, DMA targets, and memory-mapped I/O) from /dev/mem to your process' address space,
setup the LDT and/or vm86 mode monitor.
grab proper I/O permissions from the kernel (see the above section)
Again, carefully read the source for the stuff contributed to the DOSEMU project, particularly these mini-emulators for running ELKS and/or simple .COM programs under Linux/i386.
Most DOS extenders come with some interface to DOS services. Read their docs about that, but often, they just simulate int 0x21 and such, so you do "as if" you are in real mode (I doubt they have more than stubs and extend things to work with 32-bit operands; they most likely will just reflect the interrupt into the real-mode or vm86 handler).
DJGPP comes with its own (limited) glibc derivative/subset/replacement, too.
It is possible to cross-compile from Linux to DOS, see the devel/msdos/ directory of your local FTP mirror for metalab.unc.edu; Also see the MOSS DOS-extender from the Flux project from the university of Utah.
Other documents and FAQs are more DOS-centered; we do not recommend DOS development.
Windows and Co. This document is not about Windows programming, you can find lots of documents about it everywhere... The thing you should know is that there is the cygwin32.dll library, for GNU programs to run on Win32 platform; thus, you can use GCC, GAS, all the GNU tools, and many other Unix applications.
Control is what attracts many OS developers to assembly, often is what leads to or stems from assembly hacking. Note that any system that allows self-development could be qualified an "OS", though it can run "on the top" of an underlying system (much like Linux over Mach or OpenGenera over Unix).
Hence, for easier debugging purpose, you might like to develop your "OS" first as a process running on top of Linux (despite the slowness), then use the Flux OS kit (which grants use of Linux and BSD drivers in your own OS) to make it stand-alone. When your OS is stable, it is time to write your own hardware drivers if you really love that.
This HOWTO will not cover topics such as bootloader code, getting into 32-bit mode, handling Interrupts, the basics about Intel protected mode or V86/R86 braindeadness, defining your object format and calling conventions.
The main place where to find reliable information about that all, is source code of existing OSes and bootloaders. Lots of pointers are on the following webpage: http://www.tunes.org/Review/OSes.html
Finally, if you still want to try this crazy idea and write something in assembly (if you've reached this section -- you're real assembly fan), here's what you need to start.
As you've read before, you can write for Linux in different ways; I'll show how to use direct kernel calls, since this is the fastest way to call kernel service; our code is not linked to any library, does not use ELF interpreter, it communicates with kernel directly.
I will show the same sample program in two assemblers, nasm and gas, thus showing Intel and AT&T syntax.
You may also want to read Introduction to UNIX assembly programming tutorial, it contains sample code for other UNIX-like OSes.
First of all you need assembler (compiler) -- nasm or gas.
Second, you need a linker -- ld, since assembler produces only object code. Almost all distributions have gas and ld, in the binutils package.
As for nasm, you may have to download and install binary packages for Linux and docs from the nasm site; note that several distributions (Stampede, Debian, SuSe, Mandrake) already have nasm, check first.
If you're going to dig in, you should also install include files for your OS, and if possible, kernel source.
Linux is 32-bit, runs in protected mode, has flat memory model, and uses the ELF format for binaries.
A program can be divided into sections: .text for your code (read-only), .data for your data (read-write), .bss for uninitialized data (read-write); there can actually be a few other standard sections, as well as some user-defined sections, but there's rare need to use them and they are out of our interest here. A program must have at least .text section.
Now we will write our first program. Here is sample code:
section .text ;section declaration ;we must export the entry point to the ELF linker or global _start ;loader. They conventionally recognize _start as their ;entry point. Use ld -e foo to override the default. _start: ;write our string to stdout mov edx,len ;third argument: message length mov ecx,msg ;second argument: pointer to message to write mov ebx,1 ;first argument: file handle (stdout) mov eax,4 ;system call number (sys_write) int 0x80 ;call kernel ;and exit mov ebx,0 ;first syscall argument: exit code mov eax,1 ;system call number (sys_exit) int 0x80 ;call kernel section .data ;section declaration msg db "Hello, world!",0xa ;our dear string len equ $ - msg ;length of our dear string
.text # section declaration # we must export the entry point to the ELF linker or .global _start # loader. They conventionally recognize _start as their # entry point. Use ld -e foo to override the default. _start: # write our string to stdout movl $len,%edx # third argument: message length movl $msg,%ecx # second argument: pointer to message to write movl $1,%ebx # first argument: file handle (stdout) movl $4,%eax # system call number (sys_write) int $0x80 # call kernel # and exit movl $0,%ebx # first argument: exit code movl $1,%eax # system call number (sys_exit) int $0x80 # call kernel .data # section declaration msg: .ascii "Hello, world!\n" # our dear string len = . - msg # length of our dear string
First step of building an executable is compiling (or assembling) object file from the source:
For nasm example:
$ nasm -f elf hello.asm
For gas example:
$ as -o hello.o hello.S
This makes hello.o object file.
As a demonstration of a fact that there's a universe other than x86, here comes an example program for MIPS by Spencer Parkin. BTW, if you've got here, you may also want to see A Collection of Assembler Hello World Programs.
# hello.S by Spencer T. Parkin # This is my first MIPS-RISC assembly program! # To compile this program type: # > gcc -o hello hello.S -non_shared # This program compiles without errors or warnings # on a PlayStation2 MIPS R5900 (EE Core). # EE stands for Emotion Engine...lame! # The -non_shared option tells gcc that we`re # not interrested in compiling relocatable code. # If we were, we would need to follow the PIC- # ABI calling conventions and other protocols. #include <asm/regdef.h> // ...for human readable register names #include <asm/unistd.h> // ...for system serivices .rdata # begin read-only data segment .align 2 # because of the way memory is built hello: .asciz "Hello, world!\n" # a null terminated string .align 4 # because of the way memory is built length: .word . - hello # length = IC - (hello-addr) .text # begin code segment .globl main # for gcc/ld linking .ent main # for gdb debugging info. main: # We must specify -non_shared to gcc or we`ll need these 3 lines that fallow. # .set noreorder # disable instruction reordering # .cpload t9 # PIC ABI crap (function prologue) # .set reorder # re-enable instruction reordering move a0,$0 # load stdout fd la a1,hello # load string address lw a2,length # load string length li v0,__NR_write # specify system write service syscall # call the kernel (write string) li v0,0 # load return code j ra # return to caller .end main # for dgb debugging info. # That`s all folks!
Your main resource for Linux/UNIX assembly programming material is:
Do visit it, and get plenty of pointers to assembly projects, tools, tutorials, documentation, guides, etc, concerning different UNIX operating systems and CPUs. Because it evolves quickly, I will no longer duplicate it here.
If you're are interested in Linux/UNIX assembly programming (or have questions, or are just curious) I especially invite you to join Linux assembly programming mailing list.
This is an open discussion of assembly programming under Linux, *BSD, BeOS, or any other UNIX/POSIX like OS; also it is not limited to x86 assembly (Alpha, Sparc, PPC and other hackers are welcome too!).
Mailing list address is <firstname.lastname@example.org>.
To subscribe send a messgage to <email@example.com> with the following line in the body of the message:
Detailed information and list archives are available at http://linuxassembly.org/list.html.
Here are frequently asked questions (with answers) about Linux assembly programming. Some of the questions (and the answers) were taken from the the linux-assembly mailing list.
An answer from Paul Furber:
Ok you have a number of options to graphics in Linux. Which one you use depends on what you want to do. There isn't one Web site with all the information but here are some tips: SVGALib: This is a C library for console SVGA access. Pros: very easy to learn, good coding examples, not all that different from equivalent gfx libraries for DOS, all the effects you know from DOS can be converted with little difficulty. Cons: programs need superuser rights to run since they write directly to the hardware, doesn't work with all chipsets, can't run under X-Windows. Search for svgalib-1.4.x on http://ftp.is.co.za Framebuffer: do it yourself graphics at SVGA res Pros: fast, linear mapped video access, ASM can be used if you want :) Cons: has to be compiled into the kernel, chipset-specific issues, must switch out of X to run, relies on good knowledge of linux system calls and kernel, tough to debug Examples: asmutils (http://www.linuxassembly.org) and the leaves example and my own site for some framebuffer code and tips in asm (http://ma.verick.co.za/linux4k/) Xlib: the application and development libraries for XFree86. Pros: Complete control over your X application Cons: Difficult to learn, horrible to work with and requires quite a bit of knowledge as to how X works at the low level. Not recommended but if you're really masochistic go for it. All the include and lib files are probably installed already so you have what you need. Low-level APIs: include PTC, SDL, GGI and Clanlib Pros: very flexible, run under X or the console, generally abstract away the video hardware a little so you can draw to a linear surface, lots of good coding examples, can link to other APIs like OpenGL and sound libs, Windows DirectX versions for free Cons: Not as fast as doing it yourself, often in development so versions can (and do) change frequently. Examples: PTC and GGI have excellent demos, SDL is used in sdlQuake, Myth II, Civ CTP and Clanlib has been used for games as well. High-level APIs: OpenGL - any others? Pros: clean api, tons of functionality and examples, industry standard so you can learn from SGI demos for example Cons: hardware acceleration is normally a must, some quirks between versions and platforms Examples: loads - check out www.mesa3d.org under the links section. To get going try looking at the svgalib examples and also install SDL and get it working. After that, the sky's the limit.
There's an early version of the Assembly Language Debugger, which is designed to work with assembly code, and is portable enough to run on Linux and *BSD. It is already functional and should be the right choice, check it out!
You can also try gdb ;). Although it is source-level debugger, it can be used to debug pure assembly code, and with some trickery you can make gdb to do what you need (unfortunately, nasm '-g' switch does not generate proper debug info for gdb; this is nasm bug, I think). Here's an answer from Dmitry Bakhvalov:
Personally, I use gdb for debugging asmutils. Try this: 1) Use the following stuff to compile: $ nasm -f elf -g smth.asm $ ld -o smth smth.o 2) Fire up gdb: $ gdb smth 3) In gdb: (gdb) disassemble _start Place a breakpoint at _start+1 (If placed at _start the breakpoint wouldnt work, dunno why) (gdb) b *0x8048075 To step thru the code I use the following macro: (gdb)define n >ni >printf "eax=%x ebx=%x ...etc...",$eax,$ebx,...etc... >disassemble $pc $pc+15 >end Then start the program with r command and debug with n. Hope this helps.
An additional note from ???:
I have such a macro in my .gdbinit for quite some time now, and it for sure makes life easier. A small difference : I use "x /8i $pc", which guarantee a fixed number of disassembled instructions. Then, with a well chosen size for my xterm, gdb output looks like it is refreshed, and not scrolling.
If you want to set breakpoints across your code, you can just use int 3 instruction as breakpoint (instead of entering address manually in gdb).
If you're using gas, you should consult gas and gdb related tutorials.
Definitely strace can help a lot (ktrace and kdump on FreeBSD), it is used to trace system calls and signals. Read its manual page (man strace) and strace --help output for details.
Short answer is -- noway. This is protected mode, use OS services instead. Again, you can't use int 0x10, int 0x13, etc. Fortunately almost everything can be implemented by means of system calls or library functions. In the worst case you may go through direct port access, or make a kernel patch to implement needed functionality, or use LRMI library to access BIOS functions.
Yes, indeed it is. While in general it is not a good idea (it hardly will speedup anything), there may be a need of such wizardy. The process of writing a module itself is not that hard -- a module must have some predefined global function, it may also need to call some external functions from the kernel. Examine kernel source code (that can be built as module) for details.
Meanwhile, here's an example of a minimum dumb kernel module (module.asm) (source is based on example by mammon_ from APJ #8):
section .text global init_module global cleanup_module global kernel_version extern printk init_module: push dword str1 call printk pop eax xor eax,eax ret cleanup_module: push dword str2 call printk pop eax ret str1 db "init_module done",0xa,0 str2 db "cleanup_module done",0xa,0 kernel_version db "2.2.18",0
The only thing this example does is reporting its actions. Modify kernel_version to match yours, and build module with:
$ nasm -f elf -o module.m module.asm
$ ld -r -o module.o module.m
Now you can play with it using insmod/rmmod/lsmod (root privilidged are required); a lot of fun, huh?
A laconic answer from H-Peter Recktenwald:
ebx := 0 (in fact, any value below .bss seems to do) sys_brk eax := current top (of .bss section) ebx := [ current top < ebx < (esp - 16K) ] sys_brk eax := new top of .bss
An extensive answer from Tiago Gasiba:
section .bss var1 resb 1 section .text ; ;allocate memory ; %define LIMIT 0x4000000 ; about 100Megs mov ebx,0 ; get bottom of data segment call sys_brk cmp eax,-1 ; ok? je erro1 add eax,LIMIT ; allocate +LIMIT memory mov ebx,eax call sys_brk cmp eax,-1 ; ok? je erro1 cmp eax,var1+1 ; has the data segment grown? je erro1 ; ;use allocated memory ; ; now eax contains bottom of ; data segment mov ebx,eax ; save bottom mov eax,var1 ; eax=beginning of data segment repeat: mov word [eax],1 ; fill up with 1's inc eax cmp ebx,eax ; current pos = bottom? jne repeat ; ;free memory ; mov ebx,var1 ; deallocate memory call sys_brk ; by forcing its beginning=var1 cmp eax,-1 ; ok? je erro2
An answer from Patrick Mochel:
When you call sys_open, you get back a file descriptor, which is simply an index into a table of all the open file descriptors that your process has. stdin, stdout, and stderr are always 0, 1, and 2, respectively, because that is the order in which they are always open for your process from there. Also, notice that the first file descriptor that you open yourself (w/o first closing any of those magic three descriptors) is always 3, and they increment from there. Understanding the index scheme will explain what select does. When you call select, you are saying that you are waiting certain file descriptors to read from, certain ones to write from, and certain ones to watch from exceptions from. Your process can have up to 1024 file descriptors open, so an fd_set is just a bit mask describing which file descriptors are valid for each operation. Make sense? Since each fd that you have open is just an index, and it only needs to be on or off for each fd_set, you need only 1024 bits for an fd_set structure. 1024 / 32 = 32 longs needed to represent the structure. Now, for the loose example. Suppose you want to read from a file descriptor (w/o timeout). - Allocate the equivalent to an fd_set. .data my_fds: times 32 dd 0 - open the file descriptor that you want to read from. - set that bit in the fd_set structure. First, you need to figure out which of the 32 dwords the bit is in. Then, use bts to set the bit in that dword. bts will do a modulo 32 when setting the bit. That's why you need to first figure out which dword to start with. mov edx, 0 mov ebx, 32 div ebx lea ebx, my_fds bts ebx[eax * 4], edx - repeat the last step for any file descriptors you want to read from. - repeat the entire exercise for either of the other two fd_sets if you want action from them. That leaves two other parts of the equation - the n paramter and the timeout parameter. I'll leave the timeout parameter as an exercise for the reader (yes, I'm lazy), but I'll briefly talk about the n parameter. It is the value of the largest file descriptor you are selecting from (from any of the fd_sets), plus one. Why plus one? Well, because it's easy to determine a mask from that value. Suppose that there is data available on x file descriptors, but the highest one you care about is (n - 1). Since an fd_set is just a bitmask, the kernel needs some efficient way for determining whether to return or not from select. So, it masks off the bits that you care about, checks if anything is available from the bits that are still set, and returns if there is (pause as I rummage through kernel source). Well, it's not as easy as I fantasized it would be. To see how the kernel determines that mask, look in fs/select.c in the kernel source tree. Anyway, you need to know that number, and the easiest way to do it is to save the value of the last file descriptor open somewhere so you don't lose it. Ok, that's what I know. A warning about the code above (as always) is that it is not tested. I think it should work, but if it doesn't let me know. But, if it starts a global nuclear meltdown, don't call me. ;-)
That's all for now, folks.
Each version includes a few fixes and minor corrections, that need not to be repeatedly mentioned every time.
|Revision 0.6g||11 Feb 2006||Revised by: konst|
|Added AASM, updated FASM, added MIPS example to Quick Start section, added URLs to Turkish and Russian translations, misc URL updates|
|Revision 0.6f||17 Aug 2002||Revised by: konst|
|Added FASM, added URL to Korean translation, added URL to SVR4 i386 ABI specs, update on HLA/Linux, small fix in hello.S example, misc URL updates|
|Revision 0.6e||12 Jan 2002||Revised by: konst|
|Added URL describing GAS Intel syntax; Added OSIMPA(former SHASM); Added YASM; FAQ update.|
|Revision 0.6d||18 Mar 2001||Revised by: konst|
|Added Free Pascal; new NASM URL again|
|Revision 0.6c||15 Feb 2001||Revised by: konst|
|Added SHASM; new answer in FAQ, new NASM URL, new mailing list address|
|Revision 0.6b||21 Jan 2001||Revised by: konst|
|new questions in FAQ, corrected few URLs|
|Revision 0.6a||10 Dec 2000||Revised by: konst|
|Remade section on AS86 (thanks to Holluby Istvan for pointing out obsolete information). Fixed several URLs that can be incorrectly rendered from sgml to html.|
|Revision 0.6||11 Nov 2000||Revised by: konst|
|HOWTO is completely rewritten using DocBook DTD. Layout is totally rearranged; too much changes to list them here.|
|Revision 0.5n||07 Nov 2000||Revised by: konst|
|Added question regarding kernel modules to FAQ, fixed NASM URLs, GAS has Intel syntax too|
|Revision 0.5m||22 Oct 2000||Revised by: konst|
|Linux 2.4 system calls can have 6 args, Added ALD note to FAQ, fixed mailing list subscribe address|
|Revision 0.5l||23 Aug 2000||Revised by: konst|
|Added TDASM, updates on NASM|
|Revision 0.5k||11 Jul 2000||Revised by: konst|
|Few additions to FAQ|
|Revision 0.5j||14 Jun 2000||Revised by: konst|
|Complete rearrangement of Introduction and Resources sections. FAQ added to Resources, misc cleanups and additions.|
|Revision 0.5i||04 May 2000||Revised by: konst|
|Added HLA, TALC; rearrangements in Resources, Quick Start Assemblers sections. Few new pointers.|
|Revision 0.5h||09 Apr 2000||Revised by: konst|
|finally managed to state LDP license on document, new resources added, misc fixes|
|Revision 0.5g||26 Mar 2000||Revised by: konst|
|new resources on different CPUs|
|Revision 0.5f||02 Mar 2000||Revised by: konst|
|new resources, misc corrections|
|Revision 0.5e||10 Feb 2000||Revised by: konst|
|URL updates, changes in GAS example|
|Revision 0.5d||01 Feb 2000||Revised by: konst|
|Resources (former "Pointers") section completely redone, various URL updates.|
|Revision 0.5c||05 Dec 1999||Revised by: konst|
|New pointers, updates and some rearrangements. Rewrite of sgml source.|
|Revision 0.5b||19 Sep 1999||Revised by: konst|
|Discussion about libc or not libc continues. New web pointers and and overall updates.|
|Revision 0.5a||01 Aug 1999||Revised by: konst|
|Quick Start section rearranged, added GAS example. Several new web pointers.|
|Revision 0.5||01 Aug 1999||Revised by: konstfare|
|GAS has 16-bit mode. New maintainer (at last): Konstantin Boldyshev. Discussion about libc or not libc. Added Quick Start section with examples of assembly code.|
|Revision 0.4q||22 Jun 1999||Revised by: fare|
|process argument passing (argc, argv, environ) in assembly. This is yet another "last release by Fare before new maintainer takes over". Nobody knows who might be the new maintainer.|
|Revision 0.4p||06 Jun 1999||Revised by: fare|
|clean up and updates|
|Revision 0.4o||01 Dec 1998||Revised by: fare|
|Revision 0.4m||23 Mar 1998||Revised by: fare|
|corrections about gcc invocation|
|Revision 0.4l||16 Nov 1997||Revised by: fare|
|release for LSL 6th edition|
|Revision 0.4k||19 Oct 1997||Revised by: fare|
|Revision 0.4j||07 Sep 1997||Revised by: fare|
|Revision 0.4i||17 Jul 1997||Revised by: fare|
|info on 16-bit mode access from Linux|
|Revision 0.4h||19 Jun 1997||Revised by: fare|
|still more on "how not to use assembly"; updates on NASM, GAS.|
|Revision 0.4g||30 Mar 1997||Revised by: fare|
|Revision 0.4f||20 Mar 1997||Revised by: fare|
|Revision 0.4e||13 Mar 1997||Revised by: fare|
|Release for DrLinux|
|Revision 0.4d||28 Feb 1997||Revised by: fare|
|Vapor announce of a new Assembly-HOWTO maintainer|
|Revision 0.4c||09 Feb 1997||Revised by: fare|
|Added section Do you need assembly?.|
|Revision 0.4b||03 Feb 1997||Revised by: fare|
|NASM moved: now is before AS86|
|Revision 0.4a||20 Jan 1997||Revised by: fare|
|CREDITS section added|
|Revision 0.4||20 Jan 1997||Revised by: fare|
|first release of the HOWTO as such|
|Revision 0.4pre1||13 Jan 1997||Revised by: fare|
|text mini-HOWTO transformed into a full linuxdoc-sgml HOWTO, to see what the SGML tools are like|
|Revision 0.3l||11 Jan 1997||Revised by: fare|
|Revision 0.3k||19 Dec 1996||Revised by: fare|
|What? I had forgotten to point to terse???|
|Revision 0.3j||24 Nov 1996||Revised by: fare|
|point to French translated version|
|Revision 0.3i||16 Nov 1996||Revised by: fare|
|NASM is getting pretty slick|
|Revision 0.3h||06 Nov 1996||Revised by: fare|
|more about cross-compiling -- See on sunsite: devel/msdos/|
|Revision 0.3g||02 Nov 1996||Revised by: fare|
|Created the History. Added pointers in cross-compiling section. Added section about I/O programming under Linux (particularly video).|
|Revision 0.3f||17 Oct 1996||Revised by: fare|
|Revision 0.3c||15 Jun 1996||Revised by: fare|
|Revision 0.2||04 May 1996||Revised by: fare|
|Revision 0.1||23 Apr 1996||Revised by: fare|
|Francois-Rene "Fare" Rideau creates and publishes the first mini-HOWTO, because "I'm sick of answering ever the same questions on comp.lang.asm.x86"|
I would like to thank all the people who have contributed ideas, answers, remarks, and moral support, and additionally the following persons, by order of appearance:
Linus Torvalds for Linux
Bruce Evans for bcc from which as86 is extracted
Raymond Moon for his FAQ
Eric Dumas for his translation of the mini-HOWTO into French (sad thing for the original author to be French and write in English)
Marc Lehman for his insight on GCC invocation
Abhijit Menon-Sen for helping me figure out the argument passing convention
This version of the document is endorsed by Konstantin Boldyshev.
Modifications (including translations) must remove this appendix according to the license agreement.
$Id: Assembly-HOWTO.sgml,v 1.8 2006/02/11 08:26:26 konst Exp $
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