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640 lines
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640 lines
29 KiB
Markdown
IL65 / 'Sick' - Experimental Programming Language for 8-bit 6502/6510 microprocessors
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=====================================================================================
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*Written by Irmen de Jong (irmen@razorvine.net)*
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*Software license: GNU GPL 3.0, see file LICENSE*
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This is an experimental programming language for the 8-bit 6502/6510 microprocessor from the late 1970's and 1980's
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as used in many home computers from that era. IL65 is a medium to low level programming language,
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which aims to provide many conveniences over raw assembly code (even when using a macro assembler):
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- reduction of source code length
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- easier program understanding (because it's higher level, and more terse)
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- option to automatically run the compiled program in the Vice emulator
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- modularity, symbol scoping, subroutines
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- subroutines have enforced input- and output parameter definitions
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- various data types other than just bytes (16-bit words, floats, strings, 16-bit register pairs)
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- automatic variable allocations, automatic string variables and string sharing
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- constant folding in expressions (compile-time evaluation)
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- automatic type conversions
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- floating point operations
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- optional automatic preserving and restoring CPU registers state, when calling routines that otherwise would clobber these
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- abstracting away low level aspects such as zero page handling, program startup, explicit memory addresses
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- breakpoints, that let the Vice emulator drop into the monitor if execution hits them
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- source code labels automatically loaded in Vice emulator so it can show them in disassembly
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- conditional gotos
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- some code optimizations (such as not repeatedly loading the same value in a register)
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- @todo: loops
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- @todo: memory block operations
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It still allows for low level programming however and inline assembly blocks
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to write performance critical pieces of code, but otherwise compiles fairly straightforwardly
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into 6502 assembly code. This resulting code is assembled into a binary program by using
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an external macro assembler, [64tass](https://sourceforge.net/projects/tass64/).
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It can be compiled pretty easily for various platforms (Linux, Mac OS, Windows) or just ask me
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to provide a small precompiled executable if you need that.
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You need [Python 3.5](https://www.python.org/downloads/) or newer to run IL65 itself.
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IL65 is mainly targeted at the Commodore-64 machine, but should be mostly system independent.
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Memory Model
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------------
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Most of the 64 kilobyte address space can be accessed by your program.
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| type | memory area | note |
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|-----------------|-------------------------|-----------------------------------------------------------------|
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| Zero page | ``$00`` - ``$ff`` | contains many sensitive system variables |
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| Hardware stack | ``$100`` - ``$1ff`` | is used by the CPU and should normally not be accessed directly |
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| Free RAM or ROM | ``$0200`` - ``$ffff`` | free to use memory area, often a mix of RAM and ROM |
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A few memory addresses are reserved and cannot be used freely by your own code,
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because they have a special hardware function, or are reserved for internal use by the compiler:
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| reserved | address |
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|----------------|------------|
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| data direction | ``$00`` |
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| bank select | ``$01`` |
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| scratch var #1 | ``$02`` |
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| scratch var #2 | ``$03`` |
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| NMI vector | ``$fffa`` |
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| RESET vector | ``$fffc`` |
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| IRQ vector | ``$fffe`` |
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A particular 6502/6510 machine such as the Commodore-64 will have many other special addresses due to:
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- ROMs installed in the machine (BASIC, kernel and character generator roms)
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- memory-mapped I/O registers (for the video and sound chip for example)
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- RAM areas used for screen graphics and sprite data.
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### Usable Hardware Registers
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The following 6502 hardware registers are directly accessible in your code (and are reserved symbols):
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- ``A``, ``X``, ``Y``
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- ``AX``, ``AY``, ``XY`` (surrogate registers: 16-bit combined register pairs in LSB byte order lo/hi)
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- ``SC`` (status register's Carry flag)
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- ``SI`` (status register's Interrupt Disable flag)
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### Zero Page ("ZP")
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The zero page locations ``$02`` - ``$ff`` can be regarded as 254 other registers because
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they take less clock cycles to access and need fewer instruction bytes than access to other memory locations.
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Theoretically you can use all of them in your program but there are a few limitations:
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- several locations (``$02``, ``$03``, ``$fb - $fc``, ``$fd - $fe``) are reserved for internal use as scratch registers by IL65
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- most other addresses often are in use by the machine's operating system or kernal,
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and overwriting them can crash the machine. Your program must take over the entire
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system to be able to safely use all zero page locations.
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- it's often more convenient to let IL65 allocate the particular locations for you and just
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use symbolic names in your code.
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For the Commodore-64 here is a list of free-to-use zero page locations even when its BASIC and KERNAL are active:
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``$02``; ``$03``; ``$04``; ``$05``; ``$06``; ``$2a``; ``$52``;
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``$f7`` - ``$f8``; ``$f9`` - ``$fa``; ``$fb`` - ``$fc``; ``$fd`` - ``$fe``
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The four reserved locations mentioned above are subtracted from this set, leaving you with
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five 1-byte and two 2-byte usable zero page registers.
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IL65 knows about all this: it will use the above zero page locations to place its ZP variables in,
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until they're all used up. You can instruct it to treat your program as taking over the entire
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machine, in which case (almost) all of the zero page locations are suddenly available for variables.
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IL65 can generate a special routine that saves and restores the zero page to let your program run
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and return safely back to the system afterwards - you don't have to take care of that yourself.
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**IRQ and the Zero page:**
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The normal IRQ routine in the C-64's kernal will read and write several locations in the zero page:
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``$a0 - $a2``; ``$91``; ``$c0``; ``$c5``; ``$cb``; ``$f5 - $f6``
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These locations will not be used by the compiler for zero page variables, so your variables will
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not interfere with the IRQ routine and vice versa. This is true for the normal zp mode but also
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for the mode where the whole zp has been taken over. So the normal IRQ vector is still
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running when your program is entered, even when you use ``%zp clobber``.
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@todo: some global way (in ZP block) to promote certian other blocks/variables from that block or even
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subroutine to the zeropage. Don't do this in the block itself because it's a global optimization
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and if blocks require it themselves you can't combine various modules anymore once ZP runs out.
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Data Types
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----------
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IL65 supports the following data types:
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| type | size | type identifier | example |
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|--------------------|------------|-----------------|---------------------------------------------------|
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| (unsigned) byte | 8 bits | ``.byte`` | ``$8f`` |
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| (unsigned) integer | 16 bits | ``.word`` | ``$8fee`` |
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| boolean | 1 byte | | ``true``, ``false`` (aliases for the numeric values 1 and 0) |
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| character | 1 byte | | ``'@'`` (converted to a numeric byte) |
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| floating-point | 40 bits | ``.float`` | ``1.2345`` (stored in 5-byte cbm MFLPT format) |
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| string | variable | ``.text``, ``.stext`` | ``"hello."`` (implicitly terminated by a 0-byte) |
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| pascal-string | variable | ``.ptext``, ``.pstext`` | ``"hello."`` (implicit first byte = length, no 0-byte |
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| address-of | 16 bits | | ``#variable`` |
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| indirect | variable | | ``[ address ]`` |
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Strings can be writen in your code as CBM PETSCII or as C-64 screencode variants,
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these will be translated by the compiler. PETSCII is the default, if you need screencodes you
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have to use the ``s`` variants of the type identifier.
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If you write a string with just one character in it, it is *always* considered to be a BYTE instead with
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that character's PETSCII value. So if you really need a string of length 1 you must declare it
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explicitly as a variable of type ``.text``, you cannot put ``"x"`` as a subroutine argument where
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the subroutine expects (the address of) a string. IL65's type system is unfortunately not strict enough to
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avoid this mistake, but it does print a warning if the situation is detected.
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For many floating point operations, the compiler has to use routines in the C-64 BASIC and KERNAL ROMs.
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So they will only work if the BASIC ROM (and KERNAL ROM) are banked in, and your code imports the ``c654lib.ill``.
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The largest 5-byte MFLPT float that can be stored is: 1.7014118345e+38 (negative: -1.7014118345e+38)
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The ``#`` prefix is used to take the address of something. This is sometimes useful,
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for instance when you want to manipulate the *address* of a memory mapped variable rather than
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the value it represents. You can take the address of a string as well, but the compiler already
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treats those as a value that you manipulate via its address, so the ``#`` is ignored here.
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For most other types this prefix is not supported.
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**Indirect addressing:** The ``[address]`` syntax means: the contents of the memory at address, or "indirect addressing".
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By default, if not otherwise known, a single byte is assumed. You can add the ``.byte`` or ``.word`` or ``.float``
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type identifier, inside the bracket, to make it clear what data type the address points to.
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For instance: ``[address .word]`` (notice the space, to distinguish this from a dotted symbol name).
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For an indirect goto call, the 6502 CPU has a special instruction
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(``jmp`` indirect) and an indirect subroutine call (``jsr`` indirect) is emitted
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using a couple of instructions.
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Program Structure
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-----------------
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In IL65 every line in the source file can only contain *one* statement or definitons.
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Compilation is done on *one* main source code file, but other files can be imported.
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A source file can start with global *directives* (starting with ``%``) and continues
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with imports and block definitions.
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### Comments
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Everything after a semicolon '``;``' is a comment and is ignored.
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If the comment is the only thing on the line, it is copied into the resulting assembly source code.
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This makes it easier to understand and relate the generated code.
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### Output Mode
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The default format of the generated program is a "raw" binary where code starts at ``$c000``.
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You can generate other types of programs as well, by telling IL65 via an output mode directive
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at the beginning of your program:
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| mode directive | meaning |
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|-----------------------|------------------------------------------------------------------------------------|
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| ``%output raw`` | no load address bytes |
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| ``%output prg`` | include the first two load address bytes, (default is ``$0801``), no BASIC program |
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| ``%output prg,basic`` | as 'prg', but include a BASIC start program with SYS call, default code start is immediately after the BASIC program at ``$081d``, or after that. |
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| | |
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| ``%address $0801`` | override program start address (default is set to ``$c000`` for raw mode and ``$0801`` for C-64 prg mode). Cannot be used if output mode is ``prg,basic`` because BASIC programs always have to start at ``$0801``. |
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### ZeroPage Options
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You can tell the compiler how to treat the *zero page*. Normally it is considered a 'no-go' area
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except for the frew free locations mentioned under "Memory Model".
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However you can specify some options globally in your program by using the zp directive
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to change this behavior:
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- ``%zp clobber``
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Use the whole zeropage for variables. It is not possible to exit your program
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correctly back to BASIC, other than resetting the machine.
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It does make your program smaller and faster because many more variables can
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be stored in the ZP, which is more efficient.
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- ``%zp clobber, restore``
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Use the whole zeropage, but make a backup copy of the original values at program start.
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When your program exits, the original ZP is restored (except for the software jiffy clock
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in ``$a0 - $a2``) and you drop back to the BASIC prompt.
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Not that the default IRQ routine is *still enabled* when your program is entered!
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See the paragraph on the zero page for more info about this.
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If you use ``%zp clobber``, you can no longer use most BASIC or KERNAL routines,
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because these depend on most of the locations in the ZP. This includes the floating-point
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logic and several utility routines that do I/O, such as ``print_string``.
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### Importing, Including and Binary-Including other files or raw assembly code
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- ``%import "filename[.ill]"``
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Must be used *after* any global option directives, and outside of a block,
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but otherwise can be placed anywhere in the program.
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Reads and compiles the named IL65 file and stores the resulting definitions
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as if they were a part of your current program.
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- ``%asminclude "filename.txt", scopelabel``
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This directive can only be used inside a block.
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The assembler will include the file as raw assembly source text at this point, il65 will not process this at all.
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The scopelabel will be used as a prefix to access the labels from the included source code,
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otherwise you would risk symbol redefinitions or duplications.
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- ``%asmbinary "filename.bin" [, <offset>[, <length>]]``
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This directive can only be used inside a block.
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The assembler will include the file as binary bytes at this point, il65 will not process this at all.
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The optional offset and length can be used to select a particular piece of the file.
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- ``%asm {`` [raw assembly code lines] ``}``
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This directive includes raw unparsed assembly code at that exact spot in the program.
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The ``%asm {`` and ``}`` start and end markers each have to be on their own unique line.
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### Program Start and Entry Point
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Every program has to have one entry point where code execution begins.
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The compiler looks for the ``start`` label in the ``main`` block for this.
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For proper program termination, this block has to end with a ``return`` statement (or a ``goto`` call).
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Blocks and other details are described below.
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The initial values of your variables will be restored automatically when the program is (re)started,
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*except for string variables*. It is assumed they are unchanged by your program.
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If you do modify them in-place, you should take care yourself that they work as
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expected when the program is restarted.
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### Blocks
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~ blockname [address] {
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[directives...]
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[statements...]
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}
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Blocks form the separate pieces of code and data of your program. They are combined and
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arranged to a single output program. No code or data can occur outside a block.
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A block is also a *scope* in your program so the symbols in the block don't clash with
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symbols of the same name defined elsewhere. You can refer to the symbols in a particular block
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by using a *dotted name*: ``blockname.symbolname``.
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Block names must be unique in your entire program,
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except "ZP": the contents of every block with that name are merged into one.
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This block name refers to the zero page. Its start address is always set to $04,
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because $00/$01 are used by the hardware and $02/$03 are reserved as general purpose scratch registers.
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Block address must be >= $0200 (because $00-$fff is the ZP and $100-$200 is the cpu stack)
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You can omit the blockname but then you can only refer to the contents of the block via its absolute address,
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which is required in this case. If you omit *both*, the block is ignored altogether (and a warning is displayed).
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This is a way to quickly "comment out" a piece of code that is unfinshed or may contain errors that you
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want to work on later, because the contents of the ignored block are not fully parsed.
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### Assignments
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Assignment statements assign a single value to one or more variables or memory locations.
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If you know that you have to assign the same value to more than one thing at once, it is more
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efficient to write it as a multi-assign instead of several separate assignments. The compiler
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tries to detect this situation however and optimize it itself if it finds the case.
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target = value-expression
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target1 = target2 = target3 [,...] = value-expression
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### Augmented Assignments
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A special assignment is the *augmented assignment* where the value is modified in-place.
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Several assignment operators are available: ``+=``, ``-=``, ``&=``, ``|=``, ``^=``, ``<<=``, ``>>=``
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### Expressions
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In most places where a number or other value is expected, you can use just the number, or a full constant expression.
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The expression is parsed and evaluated by Python itself at compile time, and the (constant) resulting value is used in its place.
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Ofcourse the special il65 syntax for hexadecimal numbers ($xxxx), binary numbers (%bbbbbb),
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and the address-of (#xxxx) is supported. Other than that it must be valid Python syntax.
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Expressions can contain function calls to the math library (sin, cos, etc) and you can also use
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all builtin functions (max, avg, min, sum etc). They can also reference idendifiers defined elsewhere in your code,
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if this makes sense.
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### Subroutine Definition
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Subroutines are parts of the code that can be repeatedly invoked using a subroutine call from elsewhere.
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Their definition, using the sub statement, includes the specification of the required input- and output parameters.
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For now, only register based parameters are supported (A, X, Y and paired registers,
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the carry status bit SC and the interrupt disable bit SI as specials).
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For subroutine return values, the special SZ register is also available, it means the zero status bit.
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The syntax is:
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sub <identifier> ([proc_parameters]) -> ([proc_results]) {
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... statements ...
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}
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**proc_parameters =**
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comma separated list of "<parametername>:<register>" pairs specifying the input parameters.
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You can omit the parameter names as long as the arguments "line up".
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(actually, the Python parameter passing rules apply, so you can also mix positional
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and keyword arguments, as long as the keyword arguments come last)
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**proc_results =**
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comma separated list of <register> names specifying in which register(s) the output is returned.
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If the register name ends with a '?', that means the register doesn't contain a real return value but
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is clobbered in the process so the original value it had before calling the sub is no longer valid.
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This is not immediately useful for your own code, but the compiler needs this information to
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emit the correct assembly code to preserve the cpu registers if needed when the call is made.
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For convenience: a single '?' als the result spec is shorthand for ``A?, X?, Y?`` ("I don't know
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what the changed registers are, assume the worst")
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Subroutines that are pre-defined on a specific memory location (usually routines from ROM),
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can also be defined using the 'sub' statement. But in this case you don't supply a block with statements,
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but instead assign a memory address to it:
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sub <identifier> ([proc_parameters]) -> ([proc_results]) = <address>
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example:
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sub CLOSE (logical: A) -> (A?, X?, Y?) = $FFC3"
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### Subroutine Calling
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You call a subroutine like this:
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subroutinename_or_address ( [arguments...] )
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or:
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subroutinename_or_address ![register(s)] ( [arguments...] )
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If the subroutine returns one or more values as results, you must use an assignment statement
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to store those values somewhere:
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outputvar1, outputvar2 = subroutine ( arg1, arg2, arg3 )
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The output variables must occur in the correct sequence of return registers as specified
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in the subroutine's definiton. It is possible to not specify any of them but the compiler
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will issue a warning then if the result values of a subroutine call are discarded.
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If you don't have a variable to store the output register in, it's then required
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to list the register itself instead as output variable.
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Arguments should match the subroutine definition. You are allowed to omit the parameter names.
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If no definition is available (because you're directly calling memory or a label or something else),
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you can freely add arguments (but in this case they all have to be named).
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To jump to a subroutine (without returning), prefix the subroutine call with the word 'goto'.
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Unlike gotos in other languages, here it take arguments as well, because it
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essentially is the same as calling a subroutine and only doing something different when it's finished.
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**Register preserving calls:** use the ``!`` followed by a combination of A, X and Y (or followed
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by nothing, which is the same as AXY) to tell the compiler you want to preserve the origial
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value of the given registers after the subroutine call. Otherwise, the subroutine may just
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as well clobber all three registers. Preserving the original values does result in some
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stack manipulation code to be inserted for every call like this, which can be quite slow.
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#### Calling Convention
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Subroutine arguments and results are passed via registers (and sometimes implicitly
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via certain memory locations).
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@todo support call non-register args (variable parameter passing)
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In IL65 the "caller saves" principle applies to registers used in a subroutine.
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This means the code that calls a subroutine or performs some function that clobber certain
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registers (A, X or Y), is responsible for storing and restoring the original values if
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that is required.
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*You should assume that the 3 hardware registers A, X and Y are volatile and their contents
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cannot be depended upon, unless you make sure otherwise*.
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Normally, the registers are NOT preserved when calling a subroutine or when a certian
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operations are performed. Most calls will be simply a few instructions to load the
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values in the registers and then a JSR or JMP.
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By using the ``%saveregisters`` directive (globally or in a block) you can tell the
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compiler to preserve all registers. This does generate a lot of extra code that puts
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original values on the stack and gets them off the stack again once the subroutine is done.
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In this case however you don't have to worry about A, X and Y losing their original values
|
|
and you can essentially treat them as three local variables instead of scratch data.
|
|
|
|
You can also use a ``!`` on a single subroutine call to preserve register values, instead of
|
|
setting this behavior for the entire block or even program. See the paragraph on Subroutine Calling
|
|
for more info.
|
|
|
|
|
|
### Conditional Execution Flow
|
|
|
|
Conditional execution flow means that the flow of execution changes based on certiain conditions,
|
|
rather than having fixed gotos or subroutine calls. IL65 has a *conditional goto* statement for this,
|
|
that is translated into a comparison (if needed) and then a conditional branch instruction:
|
|
|
|
if[_XX] [<expression>] goto <label>
|
|
|
|
The if-status XX is one of: [cc, cs, vc, vs, eq, ne, true, not, zero, pos, neg, lt, gt, le, ge]
|
|
It defaults to 'true' (=='ne', not-zero) if omitted. ('pos' will translate into 'pl', 'neg' into 'mi')
|
|
@todo signed: lts==neg?, gts==eq+pos?, les==neg+eq?, ges==pos?
|
|
|
|
The <expression> is optional. If it is provided, it will be evaluated first. Only the [true] and [not] and [zero]
|
|
if-statuses can be used when such a *comparison expression* is used. An example is:
|
|
|
|
if_not A > 55 goto more_iterations
|
|
|
|
|
|
Conditional jumps are compiled into 6502's branching instructions (such as ``bne`` and ``bcc``) so
|
|
the rather strict limit on how *far* it can jump applies. The compiler itself can't figure this
|
|
out unfortunately, so it is entirely possible to create code that cannot be assembled successfully.
|
|
You'll have to restructure your gotos in the code (place target labels closer to the branch)
|
|
if you run into this type of assembler error.
|
|
|
|
|
|
Debugging (with Vice)
|
|
---------------------
|
|
|
|
The ``%breakpoint`` directive instructs the compiler to put
|
|
a *breakpoint* at that position in the code. It's a logical breakpoint instead of a physical
|
|
BRK instruction because that will usually halt the machine altogether instead of breaking execution.
|
|
Instead, a NOP instruction is generated and in a special output file the list of breakpoints is written.
|
|
|
|
This file is called "yourprogramname.vice-mon-list" and is meant to be used by the Vice C-64 emulator.
|
|
It contains a series of commands for Vice's monitor, this includes source labels and the breakpoint settings.
|
|
If you use the vice autostart feature of the compiler, it will be automatically processed by Vice.
|
|
If you launch Vice manually, you can use a command line option to load the file: ``x64 -moncommands yourprogramname.vice-mon-list``
|
|
|
|
Vice will use the label names in memory disassembly, and will activate the breakpoints as well
|
|
so if your program runs and it hits a breakpoint, Vice will halt execution and drop into the monitor.
|
|
|
|
|
|
|
|
|
|
@Todo
|
|
-----
|
|
|
|
### IF_XX:
|
|
|
|
if[_XX] [<expression>] {
|
|
...
|
|
}
|
|
[ else {
|
|
... ; evaluated when the condition is not met
|
|
} ]
|
|
|
|
|
|
==> DESUGARING ==>
|
|
|
|
(no else:)
|
|
|
|
if[_!XX] [<expression>] goto il65_if_999_end ; !XX being the conditional inverse of XX
|
|
.... (true part)
|
|
il65_if_999_end ; code continues after this
|
|
|
|
|
|
(with else):
|
|
if[_XX] [<expression>] goto il65_if_999
|
|
... (else part)
|
|
goto il65_if_999_end
|
|
il65_if_999 ... (true part)
|
|
il65_if_999_end ; code continues after this
|
|
|
|
|
|
### IF X <COMPARISON> Y:
|
|
|
|
==> DESUGARING ==>
|
|
compare X, Y
|
|
if_XX goto ....
|
|
XX based on <COMPARISON>.
|
|
|
|
|
|
|
|
|
|
### While
|
|
|
|
|
|
while[_XX] <expression> {
|
|
...
|
|
continue
|
|
break
|
|
}
|
|
|
|
==> DESUGARING ==>
|
|
|
|
goto il65_while_999_check ; jump to the check
|
|
il65_while_999
|
|
... (code)
|
|
goto il65_while_999 ;continue
|
|
goto il65_while_999_end ;break
|
|
il65_while_999_check
|
|
if[_XX] <expression> goto il65_while_999 ; loop condition
|
|
il65_while_999_end ; code continues after this
|
|
|
|
|
|
### Repeat
|
|
|
|
repeat {
|
|
...
|
|
continue
|
|
break
|
|
} until[_XX] <expressoin>
|
|
|
|
==> DESUGARING ==>
|
|
|
|
il65_repeat_999
|
|
... (code)
|
|
goto il65_repeat_999 ;continue
|
|
goto il65_repeat_999_end ;break
|
|
if[_!XX] <expression> goto il65_repeat_999 ; loop condition via conditional inverse of XX
|
|
il65_repeat_999_end ; code continues after this
|
|
|
|
|
|
### For
|
|
|
|
for <loopvar> = <from_expression> to <to_expression> [step <step_expression>] {
|
|
...
|
|
break
|
|
continue
|
|
}
|
|
|
|
|
|
@todo how to do signed integer loopvars?
|
|
|
|
|
|
==> DESUGARING ==>
|
|
|
|
loopvar = <from_expression>
|
|
compare loopvar, <to_expression>
|
|
if_ge goto il65_for_999_end ; loop condition
|
|
step = <step_expression> ; (store only if step < -1 or step > 1)
|
|
il65_for_999
|
|
goto il65_for_999_end ;break
|
|
goto il65_for_999_loop ;continue
|
|
.... (code)
|
|
il65_for_999_loop
|
|
loopvar += step ; (if step > 1 or step < -1)
|
|
loopvar++ ; (if step == 1)
|
|
loopvar-- ; (if step == -1)
|
|
goto il65_for_999 ; continue the loop
|
|
il65_for_999_end ; code continues after this
|
|
|
|
|
|
|
|
### Macros
|
|
|
|
@todo macros are meta-code (written in Python syntax) that actually runs in a preprecessing step
|
|
during the compilation, and produces output value that is then replaced on that point in the input source.
|
|
Allows us to create pre calculated sine tables and such. Something like:
|
|
|
|
var .array sinetable ``[sin(x) * 10 for x in range(100)]``
|
|
|
|
|
|
### Memory Block Operations
|
|
|
|
@todo matrix,list,string memory block operations:
|
|
- matrix type operations (whole matrix, per row, per column, individual row/column)
|
|
operations: set, get, copy (from another matrix with the same dimensions, or list with same length),
|
|
shift-N (up, down, left, right, and diagonals, meant for scrolling)
|
|
rotate-N (up, down, left, right, and diagonals, meant for scrolling)
|
|
clear (set whole matrix to the given value, default 0)
|
|
|
|
- list operations (whole list, individual element)
|
|
operations: set, get, copy (from another list with the same length), shift-N(left,right), rotate-N(left,right)
|
|
clear (set whole list to the given value, default 0)
|
|
|
|
- list and matrix operations ofcourse work identical on vars and on memory mapped vars of these types.
|
|
|
|
- strings: identical operations as on lists.
|
|
|
|
- matrix with row-interleave can only be a memory mapped variable and can be used to directly
|
|
access a rectangular area within another piece of memory - such as a rectangle on the (character) screen
|
|
|
|
these should call (or emit inline) optimized pieces of assembly code, so they run as fast as possible
|
|
|
|
|
|
|
|
### Bitmap Definition (for Sprites and Characters)
|
|
|
|
to define CHARACTERS (8x8 monochrome or 4x8 multicolor = 8 bytes)
|
|
--> PLACE in memory on correct address (???k aligned)
|
|
and SPRITES (24x21 monochrome or 12x21 multicolor = 63 bytes)
|
|
--> PLACE in memory on correct address (base+sprite pointer, 64-byte aligned)
|
|
|
|
|
|
### More Datatypes
|
|
|
|
@todo pointers/addresses? (as opposed to normal WORDs)
|
|
@todo signed integers (byte and word)?
|
|
|
|
|
|
### Some support for simple arithmetic
|
|
|
|
A *= Y
|
|
A = X * Y
|
|
A /= Y
|
|
A = Y / Y
|
|
|
|
|
|
Troubleshooting
|
|
---------------
|
|
|
|
Getting assembler error about undefined symbols such as ``not defined 'c64flt'``?
|
|
This happens when your program uses floating point values, and you forgot to import the ``c64lib``.
|
|
If you use floating points, the program will need routines from that library.
|
|
Fix it by adding an ``%import c64lib``.
|
|
|