This textbook provides a gentle introduction to assembly language programming. What makes this introduction "gentle" is that it assumes the reader is already comfortable with C or C++ coding. We use this assumed knowledge to bridge backward towards the low level ISA (Instruction Set Architecture).
We drive home a very sharp point:
Assembly language is nothing to be scared of!As mentioned, if you are already familiar with C (or languages descended from C such as C++), this book begins with what you already know. Later chapters dive more deeply into the corners and recesses of the ARM V8 ISA and are suitable for those wishing to master the rich instruction set of the 64 bit ARM processors.
Yes, absolutely.
In fact, we would argue that the study of assembly language is extremely important to the building of competent software engineers. Further, we would argue that teaching the x86 instruction set is cruel as that ISA was born in the 1970s and has simply gotten more muddled with age.
The MIPS instruction set is another ISA that is often covered in College level courses. While kinder and gentler than the x86 ISA, the MIPS processor isn't nearly as relevant as the ARM family. Phones, tablets, laptops and even desktops contain ARM V8 processors making the study of the ARM ISA far more topical. Perhaps even more "cool".
Assembly language programming is quite closely dependent upon the underlying hardware architecture. The host operating environment plays an outsized role in determining how assembly language programs are constructed. A "calling convention" refers to how functions are called and how parameters are passed.
In this book we will use the ARM LINUX conventions. This means:
-
You will need to run a ARM Linux VM on the Macintosh - even on ARM-based Macs. Why? Apple uses a different calling convention. The convention used in this book should work on all ARM Linux machines while the Apple calling convention is specific to Apple Silicon-based machine. In the future, we hope to add a chapter offering an explanation of the differences.
-
You will need to run WSL (Windows Subsystem for Linux) on ARM-based Windows machines. These do exist!
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You will need to run an ARM Linux VM on x86-based Windows machines. This is true even if you are on an ARM-based Windows machine for the same reasons indicated above for Apple Silicon. In the future, we hope to add a chapter detailing the Windows calling convention.
You'll notice right away that we make use of the C-runtime directly
rather than make OS service calls. So, for instance, if we want to
call write()
, we call write
from the assembly language. This
version of the system call write
is a wrapper function built into
the C-runtime which handles the low level details of performing a
system call. See the chapter on what actually
happens inside these wrapper functions.
As commendable as the ARM designs are, ARM's naming conventions for their Intellectual Properties are horrid. In this book, AARCH64 and ARM V8 are taken to be synonyms for the 64 bit ARM Instruction Set Architecture (ISA).
It is very difficult to find documentation at the ARM site because they have so many versions, so many names for the same thing and so much documentation in general. It really can be maddening.
Within the text we will provide germane links as appropriate.
Here is a link to "a" main instruction set page.
Getting the tools for assembly language development is quite
straight forward - perhaps you already have them. Using apt
from
the Linux terminal, say:
sudo apt update
sudo apt install build-essential gdb
Then you'll need your favorite editor. We currently use vi
for quick
edits and Visual Studio Code for any heavy lifting.
We use gcc
, the C "compiler". g++
could also be used. What sense
does that make... using the "compiler" to "compile" assembly language?
Well, to answer that one must understand that the word "compiler" refers to only one step in a build sequence. What we talk about as being the "compiler" is actually an umbrella that includes:
-
A preprocessor that acts on any
#
preprocessor command like#include
. These commands are not part of C or C++. Rather they are commands to the preprocessor. -
The actual compiler, whose job it is turn high level languages such as C and C++ into assembly language.
-
The assembler, which turns assembly language into machine code which is not quite ready for execution.
-
And finally, the linker, which combines potentially many intermediate machine code files (called object files), potentially many library files (statically linked .dlls on Windows and .a files on Linux). The linker is the last step in this chain.
Here is a video explaining this process.
We use gcc and g++ directly because, being umbrellas, they automate the above steps with other benefits such as automatically linking in the C runtime.
Suppose you've implemented main()
in a C file (main.c) and want to
call out to an assembly language file you have written (asm.s). It can
be done in several ways.
gcc main.c asm.s
That's all you need for a minimal build. The resulting program will be
written to a.out
. All the intermediate files generated will be
removed.
gcc -c main.c
gcc -c asm.s
gcc main.o asm.o
Used in this way, .o
files are left on disk. Using the previous
method, the .o
files are removed without you seeing them.
Suppose main()
is implemented in assembly language and main.s
is
self-contained, then simply:
gcc main.s
Often, you will want to enable the debugger gdb
. Do this:
gcc -g main.s
Using gcc to "compile" a program causes the following to be called on Ubuntu running on ARM:
/usr/bin/cpp
/usr/lib/gcc/aarch64-linux-gnu/11/cc1
/usr/bin/as
/usr/lib/gcc/aarch64-linux-gnu/11/collect2 which is...
/usr/bin/ld
cpp
is the C preprocessor - it is a general tool can is used by other
languages as well (C++, for example).
cc1
is the actual compiler.
as
is the assembler.
ld
is the linker.
You can see why we default to using the umbrella command in this book.
We start by providing what we're calling "bridging" from C and C++ to assembly language. We use the knowledge you already have to learn new knowledge - how cool is that!
Chapter | Markdown | |
---|---|---|
1 | Hello World | NA |
2 | If Statements | NA |
3 | Loops | |
.... a | .... While Loops | NA |
.... b | .... For Loops | NA |
.... c | .... Implementing Continue | NA |
.... d | .... Implementing Break | NA |
4 | Interludes | |
.... a | .... Registers | NA |
.... b | .... Load and Store | NA |
.... c | .... More About ldr |
NA |
.... d | .... Register Sizes | NA |
5 | switch |
NA |
6 | Functions | |
.... a | .... Calling and Returning | NA |
.... b | .... Passing Parameters | NA |
.... c | .... Calling common C runtime functions | NA |
7 | FizzBuzz - a Complete Program | NA |
8 | Structs | |
.... a | .... Alignment | NA |
.... b | .... Defining | NA |
.... c | .... Using | NA |
9 | const |
NA |
10 | Casting | NA |
Floating point operations use their own instructions and their own set of registers. Therefore, floating point operations are covered in their own section:
Chapter | Markdown | |
---|---|---|
1 | Floating Point | |
.... a | .... What Are Floating Point Numbers? | NA |
.... b | .... Registers (simplified) | NA |
.... c | .... Literals | NA |
.... d | .... fmov Not Yet Written |
NA |
.... e | .... Conversion To / From Integers | NA |
.... f | .... Four Basic Operations Not Yet Written | NA |
.... g | .... Selected Additional Operations Not Yet Written | NA |
.... z | .... Half Precision Floats | NA |
What would a book about assembly language be without bit bashing?
Chapter | Markdown | |
---|---|---|
1 | Bit Fields | |
.... a | .... Without Bit Fields | NA |
.... b | .... With Bit Fields | NA |
.... c | .... Review of Newly Described Instructions | NA |
Chapter | Markdown | |
---|---|---|
--- | Determining string literal lengths for C functions | NA |
Here are some project specifications to offer a challenge to your growing mastery. Here are very brief descriptions presented in alphabetical order.
Perhaps before you tackle these, check out the fully described FIZZBUZZ program first.
The DIRENT project demonstrates how a
complex struct
can be used in assembly language.
The PI project demonstrates floating point instructions. The program will "throw darts at a target," calculating an approximation of PI by tracking how many darts "hit the target" versus the total number of darts "thrown".
The SNOW project uses 1970's era tech to animate a simple particle system. This project demonstrates a reasonable design process of breaking down complex problems into simpler parts.
The WALKIES presents a cute little animation demonstrating looping with some pointer dereferencing.
Perry Kivolowitz's career in the Computer Sciences spans just under five decades. He launched more than 5 companies, mostly relating to hardware, image processing and visual effects (for motion pictures and television). Perry received Emmy recognition for his work on the The Gathering, the pilot episode of Babylon 5. Later he received an Emmy Award for Engineering along with his colleagues at SilhouetteFX, LLC. SilhouetteFX is used in almost every significant motion picture for rotoscoping, paint, tracking, 2D to 3D reconstruction, compositing and more.
In 1996 Perry received an Academy Award for Scientific and Technical Achievement for his invention of Shape Driven Warping and Morphing. This is the technique responsible for many of the famous effects in Forrest Gump, Titanic and Stargate.
Twenty twenty two marks Perry's 18th year teaching Computer Science at the college level, ten years at the UW Madison and now 8 at Carthage College.
Assembly language is a passion for Perry having worked in the following ISAs:
-
Univac 1100
-
Digital Equipment Corporation PDP-11
-
Digital Equipment Corporation VAX-11
-
Motorola 68000
-
ARM beginning with AARCH64
This work is dedicated to my wife Sara and sons Ian and Evan.
Perry has created a library of about 200 programming projects suitable for CS 1, CS 2, Data Structures, Networking, Operating Systems and Computer Organization classes. If a publisher of CS text books be interested in purchasing the library, please reach out.
Also, check out Get Off My L@wn, a Zombie novel for coders. You read that right... elite programmer Doug Handsman retires to his wife Ruth Ann's native northern Wisconsin. And then, well, the apocalypse happens. Bummer.
Rated 4.3 out of 5 with more than 70 reviews, it's a fun read and costs next to nothing.