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097c677641
This allows us to get rid of the zasm.sh wrapper.
164 lines
5.2 KiB
Markdown
164 lines
5.2 KiB
Markdown
# Writing the glue code
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Collapse OS's kernel code is loosely knit. It supplies parts that you're
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expected to glue together in a "glue code" asm file. Here is what a minimal
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glue code for a shell on a Classic [RC2014][rc2014] with an ACIA link would
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look like:
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; The RAM module is selected on A15, so it has the range 0x8000-0xffff
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.equ RAMSTART 0x8000
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.equ RAMEND 0xffff
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.equ ACIA_CTL 0x80 ; Control and status. RS off.
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.equ ACIA_IO 0x81 ; Transmit. RS on.
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jp init
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; interrupt hook
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.fill 0x38-$
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jp aciaInt
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.inc "err.h"
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.inc "ascii.h"
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.inc "core.asm"
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.inc "str.asm"
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.inc "parse.asm"
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.equ ACIA_RAMSTART RAMSTART
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.inc "acia.asm"
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.equ STDIO_RAMSTART ACIA_RAMEND
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.equ STDIO_GETC aciaGetC
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.equ STDIO_PUTC aciaPutC
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.inc "stdio.asm"
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; *** BASIC ***
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; RAM space used in different routines for short term processing.
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.equ SCRATCHPAD_SIZE 0x20
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.equ SCRATCHPAD STDIO_RAMEND
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.inc "lib/util.asm"
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.inc "lib/ari.asm"
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.inc "lib/parse.asm"
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.inc "lib/fmt.asm"
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.equ EXPR_PARSE parseLiteralOrVar
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.inc "lib/expr.asm"
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.inc "basic/util.asm"
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.inc "basic/parse.asm"
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.inc "basic/tok.asm"
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.equ VAR_RAMSTART SCRATCHPAD+SCRATCHPAD_SIZE
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.inc "basic/var.asm"
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.equ BUF_RAMSTART VAR_RAMEND
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.inc "basic/buf.asm"
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.equ BAS_RAMSTART BUF_RAMEND
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.inc "basic/main.asm"
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init:
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di
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; setup stack
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ld sp, RAMEND
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im 1
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call aciaInit
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call basInit
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ei
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jp basStart
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Once this is written, you can build it with `zasm`, which takes code from stdin
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and spits binary to stdout. Because out code has includes, however, you need
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to supply zasm with include folders or files. The invocation would look like
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emul/zasm/zasm kernel/ apps/ < glue.asm > collapseos.bin
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## Building zasm
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Collapse OS has its own assembler written in z80 assembly. We call it
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[zasm][zasm]. Even on a "modern" machine, it is that assembler that is used,
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but because it is written in z80 assembler, it needs to be emulated (with
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[libz80][libz80]).
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So, the first step is to build zasm. Open `emul/README.md` and follow
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instructions there.
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## Platform constants
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The upper part of the code contains platform-related constants, information
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related to the platform you're targeting. You might want to put it in an
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include file if you're writing multiple glue code that targets the same machine.
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In all cases, `RAMSTART` are necessary. `RAMSTART` is the offset at which
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writable memory begins. This is where the different parts store their
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variables.
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`RAMEND` is the offset where writable memory stop. This is generally
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where we put the stack, but as you can see, setting up the stack is the
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responsibility of the glue code, so you can set it up however you wish.
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`ACIA_*` are specific to the `acia` part. Details about them are in `acia.asm`.
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If you want to manage ACIA, you need your platform to define these ports.
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## Header code
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Then comes the header code (code at `0x0000`), a task that also is in the glue
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code's turf. `jr init` means that we run our `init` routine on boot.
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`jp aciaInt` at `0x38` is needed by the `acia` part. Collapse OS doesn't dictate
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a particular interrupt scheme, but some parts might. In the case of `acia`, we
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require to be set in interrupt mode 1.
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## Includes
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This is the most important part of the glue code and it dictates what will be
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included in your OS. Each part is different and has a comment header explaining
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how it works, but there are a couple of mechanisms that are common to all.
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### Defines
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Parts can define internal constants, but also often document a "Defines" part.
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These are constant that are expected to be set before you include the file.
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See comment in each part for details.
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### RAM management
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Many parts require variables. They need to know where in RAM to store these
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variables. Because parts can be mixed and matched arbitrarily, we can't use
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fixed memory addresses.
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This is why each part that needs variable define a `<PARTNAME>_RAMSTART`
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constant that must be defined before we include the part.
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Symmetrically, each part define a `<PARTNAME>_RAMEND` to indicate where its
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last variable ends.
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This way, we can easily and efficiently chain up the RAM of every included part.
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### Tables grafting
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A mechanism that is common to some parts is "table grafting". If a part works
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on a list of things that need to be defined by the glue code, it will place a
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label at the very end of its source file. This way, it becomes easy for the
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glue code to "graft" entries to the table. This approach, although simple and
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effective, only works for one table per part. But it's often enough.
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For example, to define block devices:
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[...]
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.equ BLOCKDEV_COUNT 4
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.inc "blockdev.asm"
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; List of devices
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.dw fsdevGetB, fsdevPutB
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.dw stdoutGetB, stdoutPutB
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.dw stdinGetB, stdinPutB
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.dw mmapGetB, mmapPutB
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[...]
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### Initialization
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Then, finally, comes the `init` code. This can be pretty much anything really
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and this much depends on the part you select. But if you want a shell, you will
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usually end it with `basStart`, which never returns.
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[rc2014]: https://rc2014.co.uk/
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[zasm]: ../emul/README.md
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[libz80]: https://github.com/ggambetta/libz80
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