.. | ||
cfsin | ||
forth | ||
hw | ||
libz80@8a1f935daa | ||
runbin | ||
shell | ||
zasm | ||
.gitignore | ||
emul.c | ||
emul.h | ||
Makefile | ||
README.md |
emul
This folder contains a couple of tools running under the [libz80][libz80] emulator.
Not real hardware
In the few emulated apps described below, we don't try to emulate real hardware because the goal here is to facilitate userspace development.
These apps run on imaginary hardware and use many cheats to simplify I/Os.
For real hardware emulation (which helps developing drivers), see the hw
folder.
Build
First, make sure that the libz80
git submodule is checked out. If not, run
git submodule init && git submodule update
.
After that, you can run make
and it builds all applications.
shell
Running shell/shell
runs the BASIC shell in an emulated machine. The goal of
this machine is not to simulate real hardware, but rather to serve as a
development platform. What we do here is we emulate the z80 part, the 64K
memory space and then hook some fake I/Os to stdin, stdout and a small storage
device that is suitable for Collapse OS's filesystem to run on.
Through that, it becomes easier to develop userspace applications for Collapse OS.
By default, the shell initialized itself with a CFS device containing the
contents of cfsin/
at launch (it's packed on the fly). You can specify an
alternate CFS device file (it has to be packaed already) through the -f
flag.
By default, the shell runs interactively, but you can also pipe contents through
stdin instead. The contents will be interpreted exactly as if you had typed it
yourself and the result will be spit in stdout (it includes your typed in
contents because the Collapse OS console echoes back every character that is
sent to it.). This feature is useful for automated tests in tools/tests/shell
.
zasm
zasm/zasm
is apps/zasm
wrapped in an emulator. It is quite central to the
Collapse OS project because it's used to assemble everything, including itself!
The program takes no parameter. It reads source code from stdin and spits
binary in stdout. It supports includes and had both apps/
and kernel
folder
packed into a CFS that was statically included in the executable at compile
time.
The file zasm/zasm.bin
is a compiled binary for apps/zasm/glue.asm
and
zasm/kernel.bin
is a compiled binary for tools/emul/zasm/glue.asm
. It is
used to bootstrap the assembling process so that no assembler other than zasm
is required to build Collapse OS.
This binary is fed to libz80 to produce the zasm/zasm
"modern" binary and
once you have that, you can recreate zasm/zasm.bin
and zasm/kernel.bin
.
This is why it's included as a binary in the repo, but yes, it's redundant with the source code.
Those binaries can be updated with the make updatebootstrap
command. If they
are up-to date and that zasm isn't broken, this command should output the same
binary as before.
avra
In the zasm
folder, there's also avra
which is a zasm compiled as an AVR
assembler. It works the same way as zasm except it expects AVR mnemonics and
spits AVR binaries.
runbin
This is a very simple tool that reads binary z80 code from stdin, loads it in
memory starting at address 0 and then run the code until it halts. The exit
code of the program is the value of A
when the program halts.
This is used for unit tests.
forth
Collapse OS' Forth interpreter, which will probably soon replace the whole OS.
At this point, it is not yet entirely self-hosting, but will be eventually. Because of that aim, it currently builds in a particular manner.
There are 3 build stages.
Stage 0: This stage is created with zasm by assembling forth/forth.asm
and z80c.bin
through stage0.asm
. This yields forth0.bin
. We then wrap
this binary with stage.c
to create the stage1
binary, which allows us to
get to the next stage.
z80c.bin
is a "chicken-and-egg" typf of binary that is committed in the repo.
It is the result of compiling z80c.fs
, but this needs stage2.
Stage 1: The stage1
binary allows us to augment forth0.bin
with
the compiled dictionary of a full Forth interpreter. We feed it with
$(FORTHSRCS)
and then dump the resulting compiled dict.
From there, we can create forth1.bin
, which is wrapped by both the forth
and stage2
executables. forth
is the interpreter you'll use.
Stage 2: stage2
is used to resolve the chicken-and-egg problem and use
the power of a full Forth intepreter, including an assembler, to assemble
z80c.bin
. This is a manual step executed through make fbootstrap
.
Normally, running this step should yield the exact same z80c.bin
as before,
unless of course you've changed the source.
Problems?
If the libz80-wrapped zasm executable works badly (hangs, spew garbage, etc.),
it's probably because you've broken your bootstrap binaries. They're easy to
mistakenly break. To verify if you've done that, look at your git status. If
kernel.bin
or zasm.bin
are modified, try resetting them and then run
make clean all
. Things should go better afterwards.
If that doesn't work, there's also the nuclear option of git reset --hard
and git clean -fxd
.
If that still doesn't work, it might be because the current commit you're on is broken, but that is rather rare: the repo on Github is plugged on Travis and it checks that everything is smooth.